JP4337961B2 - Electrical energy converter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electrical energy converter, and more particularly to an electrical energy converter such as an induction motor in which a magnetism generating mechanism (stator side) and a rotating mechanism (rotor side) are assembled so as to be separable from each other. .
[0002]
[Prior art and problems]
Electric energy converters that convert electric energy into rotational energy, heat energy, and the like, such as induction motors and induction heaters, are widely used in various fields.
[0003]
In addition, today, a stator (stator) and a rotor (rotor) of an electric motor that are conventionally integrally formed, a stator is accommodated in a magnetic generation mechanism part, and a rotor is accommodated in a rotation mechanism part. Separation type induction that can further diversify the application by further developing the function of induction motor by constructing the magnetism generating mechanism and rotating mechanism as separate and independent devices and assembling them so that they are magnetically coupled. Electric motors have been proposed (for example, JP-A-8-35664 and JP-A-10-98860).
[0004]
[Problems to be solved by the invention]
However, in general, as the magnetic gap length is increased, the magnetic coupling degree is decreased, and the mechanical output characteristics of low torque and high speed rotation are present, and it is very difficult to use as it is.
[0005]
In order to improve this, for example, as a general technique of induction motors, the number of drive coils is increased and arranged at a high density to increase the number of electrical angles per one rotation angle (one mechanical angle). It is conceivable to apply a method for achieving torque.
[0006]
However, the total number of drive coils that can be practically arranged in one given plane is limited due to constraints such as size and cost, and there is a limit to achieving higher torque.
[0007]
In addition, if a so-called printed coil manufacturing method is used to form a pattern on a circuit board in a coil shape, the printed coil can be formed in a complicated shape. Since the patterns cannot be stacked and there is a limit to increasing the number of windings, it is not suitable as a coil forming method for a separate type motor in which high torque is desired.
[0008]
Furthermore, when a large number of drive coils are arranged on the same circumference, the pitch between the poles in the same phase, that is, the coil pitch is inevitably shortened, and when the magnetic gap length is lengthened, the magnetic flux generated from the drive coil is converted into a one-turn coil of the rotating plate. Cannot be sufficiently interlinked, and the driving energy cannot be sufficiently transmitted. In other words, in the separation type electric motor having a long magnetic gap length, it is necessary to increase the torque while arranging the drive coil at an appropriate interval so that a certain degree of inter-electrode pitch can be secured. There is a problem that the magnetism generating mechanism becomes large and cannot be made into a small device.
[0009]
Furthermore, as a method for changing the mechanical output characteristics of changing the low torque and high speed rotation to the high torque and low speed rotation, a method of providing a gear reduction mechanism is conceivable. Here, when the gear reduction mechanism is provided in the separate induction motor, it is necessary that the mechanical output section including the bearing is completed in the rotation mechanism section. In order to achieve higher torque and lower speed rotation, it is also desired that the gear reduction mechanism be multi-staged or stacked in the axial direction.
[0010]
However, since the conventional separation type induction motor, particularly the flat separation type induction motor, is a shaft rotation method in which the output shaft rotates, the gear reduction mechanism is made multi-stage while satisfying the condition that it can be separated and is flat and thin. Or stacking in the axial direction is difficult.
[0011]
As described above, in the conventional electric energy converter including the separation type induction motor, it has been difficult to realize a high efficiency and high torque with a small and simple configuration.
[0012]
In addition, because of the separation type, there is a state in which the drive coil is driven in a state where the rotation mechanism unit is not mounted on the magnetism generation mechanism unit. There is a problem that a large current flows through the output transistor, and if this is left unattended, it will be destroyed.
[0013]
As described above, in a conventional electric energy converter, it is difficult to realize a high-efficiency, high-torque type with a small and simple configuration, and there are restrictions such as being affected by load fluctuations. It has been difficult to provide a device that sufficiently exhibits the feature of being a separation type, and its application has been limited.
[0014]
The present invention has been made in view of the above circumstances, and the electric energy capable of achieving a high torque with a smaller shape without impairing the shape characteristics of the separation-type electric energy converter that can be separated. The object is to provide a converter.
[0015]
It is another object of the present invention to provide an electric energy converter that can solve the problems of conventional electric energy converters that are affected by load fluctuations.
[0016]
Furthermore, it aims at providing the application expansion | deployment to the apparatus which fully demonstrated the characteristic that it is a separation type.
[0017]
[Means for solving the problems]
  The electric energy converter according to the present invention outputs a current having a predetermined frequency.PolyphaseA current supply source, a magnetism generating mechanism driven by the current supply source to generate a rotating magnetic field, and a rotatable1 turn coil groupGood conductorAnd backGood soft magnetic materialAnd byA rotating mechanism section having a rotating body, the magnetism generating mechanism section and the rotating mechanism section are assembled so as to be separable from each other, and both are arranged opposite to each other with a magnetic gap therebetween, and the rotating magnetic field generated from the magnetism generating mechanism section is rotated. An electric energy converter that acts on a body and drives the rotating body to rotate, wherein magnetism generating mechanism portions are arranged on circumferences having different diameters, respectively.Has spatial phase arrangementHas a drive coil array consisting of multiple drive coils.The current supply source is generated by the rotating magnetic field formed by the magnetic flux generated from each driving coil array and is generated between the driving coil array and the one-turn coil chain array in the rotating body directly facing the driving coil array. The rotating body is driven by driving the drive coils so that the torque compensates the torque generated by the other drive coil arrays, or by driving each of the drive coil arrays corresponding to each phase of the multi-phase drive. The rotation mechanism section is formed by independently arranging rotating bodies having unique output shafts on both sides of the magnetism generation mechanism section, respectively.It is characterized by being.
[0018]
The current supply source of the electric energy converter according to the present invention is configured such that each generated torque corresponding to the drive coil array generated in the rotating body by the rotating magnetic field formed by the magnetic flux generated from each drive coil is caused by the other drive coil arrays. It is desirable that the drive coil be driven (corresponding to an “independent ring pair” to be described later) so as to compensate for the generated torque valley.
[0019]
The electric energy converter according to the present invention may include a plurality of torque generating mechanisms including the drive coil array, the rotating body, and a current supply source.
[0020]
Furthermore, the current supply source of the electric energy converter according to the present invention generates a set of generated torque as a whole in the rotating body by driving each of the drive coil arrays corresponding to each phase of the multiphase drive. (Corresponding to a “deformation ring pair” described later).
[0021]
The electric energy converter according to the present invention may include a plurality of torque generating mechanisms including the drive coil array, the rotating body, and a current supply source.
[0022]
Further, the electric energy converter according to the present invention is configured such that each generated torque corresponding to the drive coil array generated in the rotating body by the rotating magnetic field formed by the magnetic flux generated from each drive coil is generated by the other drive coil arrays. A first torque generation mechanism unit comprising a current supply source for driving the drive coil, a drive coil array, and a rotating body so as to compensate for the valley of
A second torque comprising a current supply source, a drive coil array, and a rotating body that generates a set of generated torque as a whole in the rotating body by driving each of the driving coil arrays corresponding to each phase of the multiphase driving. It is good also as what mixes a generation | occurrence | production mechanism part.
[0023]
Further, the rotating mechanism of the electric energy converter according to the present invention includes a fixed shaft planted in a fixed housing, and a plurality of rotating bodies supported by the fixed shaft so as to be independently rotatable, directly or indirectly. It is also possible for the rotating body to integrally have output shafts that can output a rotational force.
[0024]
In this case, it is preferable to provide a support member for supporting the other end of the fixed shaft, which has an opening for taking out the rotational force, on the other end side of the fixed shaft.
[0025]
The electrical energy converter according to the present invention further includes a rotational speed detection means for detecting the rotational speed of the rotating body,
Based on the output of the rotation speed detection means, the current supply source has a rotation speed control means for controlling the rotation speed to be kept constant even when the load of the rotation body fluctuates while the rotation body is rotating. It is desirable that
[0027]
In the electrical energy converter according to the present invention, the plurality of magnetism generating mechanism portions may be separated from each other with respect to the rotating body of the rotating mechanism portion, or in a state where both the integral facing and the separated facing are mixed. It can be provided.
[0028]
Here, “the state of separation facing each other with respect to the rotating body” means that each of the plurality of magnetism generating mechanism parts is assembled so as to be separable from the rotating mechanism part, and is opposed to the rotating body in the rotating mechanism part with a magnetic gap therebetween. It means the state that was done. On the other hand, “a state of facing the rotating body integrally” means that each of the plurality of magnetism generating mechanism sections is assembled integrally with the rotating mechanism section (cannot be separated) and the rotating body in the rotating mechanism section. And the state of being opposed to each other with a magnetic air gap therebetween, and the “mixed state of an integral facing and a separated facing with respect to the rotating body” means a state in which the two are mixed, that is, a plurality of At least one of the magnetism generating mechanism parts is assembled so as to be separable from the rotating mechanism part and the rest is assembled integrally with the rotating mechanism part (cannot be separated), and each magnetism generating mechanism part is magnetically coupled to the rotating body in the rotating mechanism part. It means that they are arranged opposite to each other with a specific gap therebetween.
[0029]
In addition, the rotating body of the electric energy converter according to the present invention is provided with a plurality of notches in a state where dynamic balance is maintained,
A plurality of sensors for detecting the presence or absence of notch portions, each of which is disposed at a position where it is not simultaneously detected that the magnetism generating mechanism portion is the notched portion when the rotating mechanism portion is mounted on the magnetism generating mechanism portion. Shall have,
It is desirable that the current supply source has a driving stop means for stopping driving of the driving coil on the assumption that the rotation mechanism portion is not mounted when all the outputs of the sensor indicate the cutout portion. .
[0030]
In addition, the rotating body of the electric energy converter according to the present invention is removed by being built or fitted integrally on the surface of a member having a function other than rotation, for example, the bottom surface, the top surface, the outer surface, the inclined surface, and the inner surface. It shall be installed freely,
The magnetism generating mechanism section may be arranged to face the rotating body with a magnetic gap therebetween.
[0031]
Further, the main magnetic circuit of the magnetic generation mechanism part of the electric energy converter according to the present invention is formed of a soft magnetic ferrite member such as Mn—Zn, Ni—Zn, and the drive constituting the magnetic generation mechanism part. It is desirable that the winding of the coil is a stranded wire in which a number of thin wires are bundled so that the magnetism generating mechanism can be driven at a high frequency. Here, the “high frequency” is a frequency range of about 5 kHz to 30 kHz.
[0032]
Further, the current supply source of the electric energy converter according to the present invention is provided with switching means for selectively generating a rotating magnetic field and a high-frequency alternating magnetic field for induction heating,
The rotating body may be induction-heated by the high frequency alternating magnetic field when the high frequency alternating magnetic field is generated. In particular, the rotating body is also combined with a member having excellent heating characteristics.
[0033]
Moreover, the electrical energy converter according to the present invention is a rotating mechanism unit including a plurality of rotating bodies,
The current supply source is provided with means capable of simultaneously generating a rotating magnetic field and a high-frequency alternating magnetic field for induction heating, and the rotating magnetic field and the high-frequency wave are independently generated from a magnetic generating mechanism disposed opposite to a plurality of rotating bodies. The alternating magnetic field can be generated simultaneously or selectively.
[0034]
Here, “independently and simultaneously generating a rotating magnetic field and a high-frequency alternating magnetic field” means that a combination of a rotating magnetic field and a high-frequency alternating magnetic field is free, and both may be generated simultaneously, or selectively. It means that it may be generated. For example, in the case of a combination having two rotating bodies, a “combination” applies a rotating magnetic field to both, a high-frequency alternating magnetic field to both, a rotating magnetic field to one, and the other to the other. On the other hand, a high frequency alternating magnetic field is applied. “Selectively generating” means that the generation of a rotating magnetic field or a high-frequency alternating magnetic field can be alternately turned on and off independently.
[0035]
The rotating mechanism of the electric energy converter according to the present invention includes a fixed shaft planted in a fixed housing, a rotating body rotatably supported around the fixed shaft, and a part of the rotating body. And a planetary gear that meshes with the gear, and a planetary gear meshing with the gear, and a fixed shaft that is formed integrally with the output portion of the reduction mechanism and is rotatably supported by a fixed shaft. It is desirable that the output shaft be provided. A large number of such configurations may be stacked in the axial direction of the fixed shaft.
[0036]
In addition, the support shaft or tripod of the crane which has the opening part for taking out the rotational force of this output shaft on the side of the output shaft supported and should hold the other end of a fixed shaft firmly in a housing | casing It is preferable to provide a mechanical support member.
[0037]
The electric energy converter according to the present invention includes a current supply source that outputs a current of a predetermined frequency, a magnetism generating mechanism that is driven by the current supply source to generate a rotating magnetic field, and a good soft magnetic material that is freely rotatable. A rotating magnetic field generated from the magnetism generating mechanism section, the magnetism generating mechanism section and the rotating mechanism section being assembled so as to be separable from each other with a magnetic gap therebetween. An electric energy converter that rotates the rotating body by acting on the rotating body,
The rotation mechanism unit includes a fixed shaft planted in a fixed housing, and a plurality of rotating bodies supported by the fixed shaft so as to be independently or directly rotatable.
The rotating body may include an output shaft capable of outputting a rotational force independently and integrally.
[0038]
The electric energy converter according to the present invention includes a current supply source that outputs a current of a predetermined frequency, a magnetism generating mechanism that is driven by the current supply source to generate a rotating magnetic field, and a good soft magnetic material that is freely rotatable. A rotating magnetic field generated from the magnetism generating mechanism section, the magnetism generating mechanism section and the rotating mechanism section being assembled so as to be separable from each other with a magnetic gap therebetween. An electric energy converter that rotates the rotating body by acting on the rotating body,
It is further provided with a rotation speed detecting means for detecting the rotation speed of the rotating body,
Based on the output of the rotation speed detection means, the current supply source has a rotation speed control means for controlling the rotation speed to be kept constant even when the load of the rotation body fluctuates while the rotation body is rotating. It can be made up of.
[0040]
The electric energy converter according to the present invention includes a current supply source that outputs a current of a predetermined frequency, a magnetism generating mechanism that is driven by the current supply source to generate a rotating magnetic field, and a good soft magnetic material that is freely rotatable. A rotating magnetic field generated from the magnetism generating mechanism section, the magnetism generating mechanism section and the rotating mechanism section being assembled so as to be separable from each other with a magnetic gap therebetween. An electric energy converter that rotates the rotating body by acting on the rotating body,
The rotating body is formed with a plurality of notches in a state where dynamic balance is maintained,
A plurality of sensors for detecting the presence or absence of a notch portion, wherein the magnetism generating mechanism portion is disposed at a position where it is not simultaneously detected that the rotation mechanism portion is mounted on the magnetism generating mechanism portion. For example, a magnetic sensor)
The current supply source may include driving stop means for stopping driving of the driving coil by assuming that the rotating mechanism portion is not mounted when all the outputs of the sensor indicate the cutout portion. .
[0041]
Further, this sensor can also serve as a rotational speed detection means for detecting the rotational speed of the rotating body.
[0042]
The electric energy converter according to the present invention includes a current supply source that outputs a current of a predetermined frequency, a magnetism generating mechanism that is driven by the current supply source to generate a rotating magnetic field, and a good soft magnetic material that is freely rotatable. A rotating magnetic field generated from the magnetism generating mechanism section, the magnetism generating mechanism section and the rotating mechanism section being assembled so as to be separable from each other with a magnetic gap therebetween. An electric energy converter that rotates the rotating body by acting on the rotating body,
The rotating body of the rotating mechanism is assumed to be detachably mounted on the surface of a member having a function other than rotation,
The magnetism generating mechanism portion may be arranged to face the rotating body with a magnetic gap therebetween.
[0043]
The electric energy converter according to the present invention includes a current supply source that outputs a current of a predetermined frequency, a magnetism generating mechanism that is driven by the current supply source to generate a rotating magnetic field, and a good soft magnetic material that is freely rotatable. A rotating magnetic field generated from the magnetism generating mechanism section, the magnetism generating mechanism section and the rotating mechanism section being assembled so as to be separable from each other with a magnetic gap therebetween. An electric energy converter that rotates the rotating body by acting on the rotating body,
A rotating mechanism unit having a plurality of rotating bodies,
The current supply source is provided with means capable of simultaneously generating a rotating magnetic field and a high-frequency alternating magnetic field for induction heating. The rotating magnetic field and the high-frequency alternating are independently provided from a plurality of magnetism generating mechanism units arranged opposite to the plurality of rotating bodies. The magnetic field can be generated simultaneously or selectively.
[0044]
Here, “independently and selectively generating a rotating magnetic field and a high-frequency alternating magnetic field” and “selectively generating” have the same meaning as described above.
[0045]
The electric energy converter according to the present invention includes a current supply source that outputs a current of a predetermined frequency, a magnetism generating mechanism that is driven by the current supply source to generate a rotating magnetic field, and a good soft magnetic material that is freely rotatable. A rotating magnetic field generated from the magnetism generating mechanism section, the magnetism generating mechanism section and the rotating mechanism section being assembled so as to be separable from each other with a magnetic gap therebetween. An electric energy converter that rotates the rotating body by acting on the rotating body,
A fixed shaft planted in a fixed housing, a rotating body rotatably supported around the fixed shaft, and a gear integrally formed coaxially with a part of the rotating body A reduction mechanism having a planetary gear meshing with the gear, and an output shaft that is integrally formed with an output portion of the reduction mechanism and is rotatably supported by a fixed shaft; can do.
[0046]
In addition, the support shaft or tripod of the crane which has the opening part for taking out the rotational force of this output shaft on the side of the output shaft supported and should hold the other end of a fixed shaft firmly in a housing | casing It is preferable to provide a support member.
[0047]
【The invention's effect】
According to the electrical energy converter of the present invention, the drive coils are arranged on the circumferences having different diameters, that is, they are arranged in multiple layers, so that a small magnetism generating mechanism portion can be formed, and the same generated torque amount can be obtained. This can be realized with a small device. As a result, for example, it is possible to fit the size of a separate electric energy converter with an output power of about 500 W or less into the size of a product that can be easily handled by a person with both hands (one side of the cube is about 30 cm at the maximum). It is possible to provide a device with excellent matching properties.
[0048]
In addition, if the drive coils are driven so that each generated torque corresponding to each drive coil array compensates for the valley of the generated torque by the other drive coil arrays, the average generated torque can be increased or torque unevenness can be reduced. In particular, it can greatly contribute to the improvement of the minimum generated torque.
[0049]
Also, if each of the drive coil arrays is driven corresponding to each phase of the multiphase drive to generate a set of generated torque as a whole in the rotating body, the conventional single-position current supply source can be used as it is. Thus, multiple drive coils can be arranged.
[0050]
Further, by providing a plurality of torque generating mechanisms for the independent ring pair and a plurality of torque generating mechanisms for the deformed ring pair, or mixing them, it is possible to easily further increase the torque. In addition, since the change between the independent ring pair and the deformed ring pair can be easily done by changing the connection mode of the rotating plate and the drive coil, the torque generating mechanisms can be freely combined according to the required machine output characteristics. it can.
[0051]
In addition, if each rotating body having an independent output shaft is supported on a fixed shaft so as to be independently rotatable, a small-sized electric energy converter having a multi-axis output configuration can be obtained (such a configuration is referred to as “multi-axis Output mechanism ”).
[0052]
In this case, if a support member having an opening for taking out rotational force is provided on the other end side of the fixed shaft, and a support member that supports the other end of the fixed shaft is provided, as the rotating body rotates. There is no possibility that the other end of the fixed shaft vibrates or falls.
[0053]
In addition, if the rotational speed of the rotating body is detected and controlled so as to keep the rotational speed constant at all times, the rotational body can always be rotated at a constant rotational speed without being affected by load fluctuations. A constant number control mechanism).
[0054]
In addition, if the rotating bodies having unique output shafts are independently arranged on both sides of the magnetism generating mechanism section, the rotational power self-adjusted and set according to the load of each rotating body is supplied from each output shaft. For example, an electric three-wheel bicycle in which the rotating plate itself also serves as a disc brake can be realized by adopting a twin rotor configuration with two rotating bodies.
[0055]
  At this time, to ensure power matchingOrThus, a small-sized device having sufficient driving ability (for example, an electric three-wheel bicycle) can be configured.
[0056]
Further, if the plurality of magnetism generating mechanism parts are provided in any state of separation facing or a mixture of integral facing and separation facing with respect to the rotating body of the rotating mechanism part, For example, a soft magnetic metal plate having a one-turn coil chain array of two rotating bodies is bonded together to form a rotating mechanism section having one rotating body, and two magnetism generating mechanism sections on both sides of the rotating body. It is also possible to adopt a twin stator configuration in which As a result, for example, the rotation mechanism portion arranged in a hidden door or the like can have a lock function, and the separated magnetism generation mechanism portion (stator) can have a key function.
[0057]
In addition, with the dynamic balance maintained, a plurality of notches are provided in the rotating body, and a plurality of sensors are provided at positions that do not detect the notches simultaneously when the rotating mechanism is mounted. If the drive coil is stopped when indicating that it is a notch, it is possible to prevent the device from being destroyed by driving the drive coil when the rotation mechanism is not mounted. Protection mechanism). If a magnetic sensor is used as the sensor, it is possible to reliably detect the presence or absence of mounting of a rotating mechanism having a rotating plate that is a metal object even without contact. Further, if this sensor also serves as the rotational speed detection means, it is not necessary to separately provide the rotational speed detection means.
[0058]
Further, if the rotating body is mounted on the surface of a member having a function other than the rotation, and the magnetism generating mechanism portion is disposed to face the rotating body with a magnetic gap therebetween, for example, a disk-shaped or belt-shaped 1 The turn coil chain can be sandwiched between the bottom, slope, side, etc. of pans, dishes, funnels, etc., and the drive coil can be divided into multiple faces so as to face it, making it possible to increase the functionality of the members (Such a configuration is called “mounting mechanism”). Specifically, when a rotating plate is inserted into a funnel and rotated integrally in water, the funnel can be operated. When the pan or the like is a non-magnetic member, a one-turn coil chain with a magnetic metal plate is used.
[0059]
Further, if the main magnetic circuit of the magnetism generating mechanism part is formed of a soft magnetic ferrite member such as Mn—Zn or Ni—Zn so that high frequency driving is possible, the electric energy converter according to the present invention can be reduced to a millimeter size. It becomes possible to apply to the machine.
[0060]
In addition, if the current supply source is generated by switching between a rotating magnetic field and a high-frequency alternating magnetic field for induction heating, the rotating body itself can be switched between being driven to rotate or induction heated. Since it can do, for example, a rotary cooking appliance can be used as it is as a heating cooking appliance. In particular, the heating effect can be further enhanced by using a rotating body that is composed of a member having excellent heating characteristics.
[0061]
In addition, a rotating mechanism unit having a plurality of rotating bodies and a magnetism generating mechanism unit capable of generating a rotating magnetic field and a high-frequency alternating magnetic field at the same time, independently generating a rotating magnetic field and a high-frequency alternating magnetic field simultaneously or selectively. In this way, each rotating body can perform induction rotation action and induction heating action independently, and the application range of the electric energy converter can be expanded. It can also be dedicated mainly to the heating main configuration (such a configuration is called an “independent rotating body mechanism”). For example, when a rotating magnetic field is applied to one rotating body and an alternating magnetic field is applied to the other rotating body, it can be utilized for thermal polishing, deburring polishing, and the like.
[0062]
Further, a fixed shaft is planted in a fixed housing, and a rotating body is rotatably supported around the fixed shaft, and a gear is integrally formed coaxially with a part of the rotating body. If the planetary gears are engaged with each other to reduce the speed, and the output shaft formed integrally with the output portion is rotatably supported around the fixed shaft, the torque can be further increased. , An electric energy converter with extremely strong force can be obtained (such a configuration is referred to as a “deceleration mechanism”).
[0063]
For example, by extracting the output output of the high torque and low rotation through the opening of the support member through the output gear of the output gear that has been decelerated in multiple stages on the output side of the rotating shaft that is firmly supported at both ends of the rotating mechanism unit housing, It can be used as a power source for an underwater auxiliary chair for bathing physically disabled people.
[0064]
Moreover, it is also possible to combine with the above-mentioned “multi-axis output mechanism”, so that the application range of the electric energy converter can be further expanded.
[0065]
The effects of the present invention described above all relate to those applied to an electrical energy converter based on a multi-arrangement of drive coils, but various improvements applied to the multi-arrangement include electrical energy of a multi-arrangement configuration. It is not limited only to the converter. In particular, the above-mentioned “multi-axis output mechanism”, “rotational speed constant control mechanism”, “double rotor configuration”, “double stator configuration”, “non-mounting protection mechanism”, “mounting mechanism”, “independent rotating body The “mechanism” and the “deceleration mechanism” can be applied to any type of electric energy converter as long as it is a separation-type electric energy converter, and the above-described effects can be similarly exhibited.
[0066]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0067]
The separation type electric energy converter according to the present invention is such that the magnetism generating mechanism section has a drive coil array composed of a plurality of drive coils respectively arranged on the circumferences having different diameters. In other words, the drive coil is arranged in multiple. First, a basic configuration example for sin / cos two-phase driving in which driving coils are arranged in a double manner will be described.
[0068]
FIG. 1 to FIG. 5 are plan views (A) of a drive coil of a magnetic generation mechanism used in an induction motor that is an aspect of an electric energy converter according to an embodiment of the present invention, and corresponding rotations. It is the top view (B) of the rotating plate as a rotary body of a mechanism part, and the electrical connection figure (C) of a drive coil.
[0069]
FIG. 1 shows an embodiment in which the total number of drive coils is 8, and the number of electrical angles, that is, the number p of magnetic poles, is 2 for one mechanical angle per phase. Similarly, FIG. 2 shows a mode with 8 drive coils in total and 1 electrical angle, FIG. 3 shows a mode with 12 drive coils in total, and 3 electrical angles, and FIG. 4 shows a mode with 16 drive coils in total and 4 electrical angles. FIG. 5 shows a mode in which the total number of drive coils is 16, 2 electrical angles.
[0070]
Hereinafter, basic items common to these will be described. In FIG. 1 to FIG. 5, equivalent elements are denoted by the same reference numerals, and descriptions thereof are collectively performed.
[0071]
The magnetic generation mechanism unit 100 has a magnetic core 104, and a drive coil 103 wound around a bobbin is concentrically arranged on a magnetic pedestal 101 embedded in the bottom surface of the magnetic generation mechanism unit casing. Distribute evenly to form a row. Circles formed on the inside and outside indicated by thin lines in the figure are referred to as circles R1 and R2, respectively.
[0072]
Specifically, the drive coils 103 that are half of the total number of coils are equally arranged in the inner circle R1. The outer circle R2 is shown in a radial pattern in the figure passing through the valleys of the drive coils 103 arranged in the inner circle R1, that is, between the drive coils 103 adjacent from the center (substantially intermediate in this example). The drive coils 103 are arranged so as to be close to the drive coils 103 on the inner chain line R1 and on the inner circle R1. The diameters of the drive coil 103 and the magnetic core 104 arranged in the outer circle R2 are preferably the same as or slightly smaller than those arranged in the inner circle R1 in order to obtain the same generated torque. One drive coil array formed by connecting the drive coils 103 arranged in both circles alternately and continuously inside and outside is called a deformed circle R0 (see FIGS. 1, 3 and 4). Note that the drive coil 103 shown in the figure is given a coil number indicated by a small Roman letter starting from a on the deformation circle R0 in the counterclockwise direction.
[0073]
As described above, according to the present invention, since the drive coil 103 is arranged separately for the inner circle R1 and the outer circle R2, compared to the conventional arrangement in which all the drive coils are arranged on the same circumference. Since the required diameter can be reduced, the magnetism generating mechanism can be reduced in size, and the entire electrical energy converter can be reduced in size.
[0074]
As a result, the size of products that humans can easily handle with both hands (up to about 30 cm on each side of the cube) and the limited size of the separable electric energy converter given by the required gap length due to separation (realizable) Convenient size (about φ100mm to φ300mm), and a good match (size matching) can be given as a result, and equipment suitable for man-machine interface is provided. It becomes possible to do.
[0075]
  In this example, the same number of drive coils are arranged in the inner circle R1 and the outer circle R2 so as to be close to each other between the valleys.Have.
[0076]
Thus, depending on the structure of the drive coil 103 disposed on both the circles R1 and R2, the structure of the rotating plate 111 disposed so as to be magnetically coupled thereto, and the connection mode of the drive coil 103, the following two types are provided. The torque generating action by the combination can be obtained. That is, the inner and outer drive coil arrays jointly perform one action and generate a set of torque as a whole (in the case of FIGS. 1, 3 and 4), and the inner and outer drive coil arrays are mutually connected. It is a non-interference type (in the case of FIGS. 2 and 5) that acts on the rotating plate 111 independently without interfering and adds the generated torque generated by each to the shaft output of the rotating mechanism. Each will be described below.
[0077]
In the case of the interference type shown in FIGS. 1, 3, and 4, a magnetic flux train (inner magnetic flux chain train) emitted from each drive coil 103 arranged on the inner side and a magnetic flux train emitted from each drive coil 103 arranged on the outer side. The radius is different from that of the outer magnetic flux chain train. This is hereinafter referred to as “the two magnetic flux chain trains have an arrangement position difference” (the same applies to FIGS. 2 and 5).
[0078]
A one-turn coil in which magnetic flux generated from the drive coil 103 is linked to the rotating plate 111 is arranged corresponding to each drive coil. The one-turn coil is generally formed by providing a hole or hole in the rotating plate 111. The hole 112 formed in the rotating plate 111 corresponds to each time when the driving coil 103 of the inner circle R1 corresponds, or when one driving coil 103 of the outer circle R2 adjacent to the coil corresponds. The area of the perforations is determined so that one induction magnetic pole is formed by interlinking with the magnetic flux generated from each drive coil 103. Then, a single one-turn coil row (one-turn coil chain row) corresponding to one deformation circle R0 is formed so as to absorb the arrangement position difference of the magnetic flux chain rows as a whole. The total number of one-turn coils is the same as the total number of drive coils 103 (see (B) in FIGS. 1, 3 and 4).
[0079]
Thus, in the case of the interference type, both the magnetic flux chain trains formed by the inner and outer drive coil trains on the deformation circle R0 and the one-turn coil chain train that absorbs the arrangement position difference between the two magnetic flux chain trains are in the axial direction. (In the case of a flat type induction motor), a deformed ring pair (a deformed one ring pair) that is arranged with a magnetic air gap therebetween, and both chain rows interfere with each other to form a pair of upper and lower chain rows. Is formed.
[0080]
In the case of the deformed one ring pair, the inner drive coils 103 are connected in series so that the directions of the generated magnetic fluxes are alternately reversed. Similarly, the directions of the generated magnetic fluxes are alternately reversed in the outer drive coils. Connect in series so that Each of the series-connected drive coil arrays is used as one phase for two-phase driving, one is connected to the sin side and the other is connected to the cos side, and two-phase driving is performed by the inverter circuit 120 (see FIGS. 1, 3 and 4). (See each (C)).
[0081]
By this two-phase drive, a rotating magnetic field is generated in the magnetic gap between the magnetism generating mechanism unit 100 and the rotating mechanism unit. This rotating magnetic field has a variation component in the radial direction in the same manner as the arrangement position difference of the magnetic flux chain train. However, since the one-turn coil chain of the opposing rotating plate 111 absorbs the arrangement position difference of the magnetic flux chain train, 1 The induction magnetic pole formed in the turn coil does not change due to the fluctuation component of the rotating magnetic field.
[0082]
In the case of this interference type, the connection mode of the drive coils is the same as the conventional one in which all the drive coils are arranged on the same circumference, and the generated torque is substantially the same. Therefore, according to this interference type, when the total number of drive coils to be used is the same, the generated torque can be made the same while reducing the size of the device. In other words, when the device sizes are the same, the generated torque can be increased, that is, the torque can be increased by increasing the number of drive coils (multipolarization).
[0083]
On the other hand, in the case of the non-interference type shown in FIGS. 2 and 5, the drive coil arrays inside and outside the magnetism generating mechanism section operate independently without interfering with each other as described above. , R2) are formed inside and outside.
[0084]
The rotating plate 111 is provided with a one-turn coil in which the magnetic flux generated from the driving coil 103 is linked to each driving coil 103. At this time, it is preferable that independent one-turn coil rows (one-turn coil chain rows) corresponding to the inner and outer two drive coil rows are formed in a double manner in the radial direction. For example, a composite rotating plate 111 in which rotating plates 111a and 111b are arranged in an inner and outer double is used (see (B) in FIGS. 2 and 5). Of course, the total number of inner and outer doubles of the one-turn coil is the same as the total number of drive coils 103.
[0085]
The drive coil 103 is connected in series so that the direction of the generated magnetic flux is alternately reversed using every other drive coil 103 for each circle. As a result, two series connections of the drive coils are formed both inside and outside. The starting points are sequentially adjacent to the drive coils (the starting points in this example are a, b, c, and d). Two inner drive coil arrays connected in series are each used as one phase of two-phase drive, one is connected to the sin side and the other is connected to the cos side. Similarly, the two outer drive coils connected in series Each column also has one phase for two-phase driving, and one is connected to the sin side and the other is connected to the cos side. That is, the inner and outer sin sides and the cos sides are connected in parallel so that the rotation directions of the rotating magnetic fields generated by the respective drive coil arrays are the same (see (C) in FIGS. 2 and 5). Therefore, each drive coil row is independently driven in two phases, and the electrical angle is ½ of the interference type.
[0086]
By the two-phase drive, a rotating magnetic field is generated in the magnetic gap between the magnetism generating mechanism unit 100 and the rotating mechanism unit, but the magnetic flux generated by the inner drive coil array is chained only with the inner one-turn coil chain array. In addition, by providing an induction electromagnetic path in which the magnetic flux generated by the outer drive coil array is linked only to the outer one-turn coil chain array, induction magnetic poles that do not interfere with each other are formed. That is, each magnetic flux chain train formed by the inner and outer drive coil trains and the inner and outer one-turn coil train trains are arranged with a magnetic gap in the axial direction (in the case of a flat type induction motor), and two upper and lower chain trains are arranged. Two independent ring pairs forming one pair independently are formed (collectively referred to as “independent two ring pairs”). As a result, two sets of electrical angles are 180 ° out of phase, and a torque generation mechanism is formed that compensates for the valley of the generated torque in the angular direction, and the generated torque generated by each is added to the shaft output. The In addition, this greatly contributes to an increase in average generated torque and a reduction in torque unevenness, particularly an improvement in the minimum generated torque.
[0087]
Therefore, according to this interference type, it is possible to simultaneously increase the generated torque and reduce the torque unevenness while reducing the size of the apparatus. In other words, when the apparatus sizes are the same, it is possible to simultaneously increase the torque and reduce torque unevenness.
[0088]
As the above-mentioned rotating plate 111, any material can be used as long as the material is used for a conventional rotating plate such as iron. In order to generate a secondary magnetic pole by inducing eddy current due to electromagnetic induction with low resistance while suppressing heat generation, it is particularly preferable to use an aluminum perforated plate using aluminum. Further, each of them may be subjected to an insulation treatment such as anodizing to laminate a plurality of sheets to form a several turn coil. Then, the generated torque can be improved. In this case, as a means for serializing several-turn coils, a one-turn coil having a notch is vertically connected when stacked.
[0089]
In order to operate the non-interference type configuration more reliably, it is important to prevent the two ring pairs from being magnetically coupled. For this purpose, it is preferable that each ring pair has an independent closed magnetic circuit configuration by actively utilizing the magnetic anisotropy of the air gap and the material.
[0090]
Specifically, the magnetic flux of the drive coil 103 (for example, N pole) generated by the interlinked magnetic generation mechanism unit 100 enters the one-turn coil of the rotating plate 111 and effectively counters the drive coil 103 (in the case of the previous example). In this case, a composite plate in which a soft magnetic metal plate that is guided to the drive coil 103 to be a S pole and constitutes a closed magnetic circuit is laminated on the rotating plate 111 may be used.
[0091]
As long as the soft magnetic metal plate completely covers the hole 112 of the rotating plate 111, the shape thereof is not limited, and may be, for example, a polygonal shape. The material is preferably an SPC material or a silicon steel plate having good soft magnetic properties and good conductor.
[0092]
Further, when the rotating plate 111 and the soft magnetic metal plate are laminated to form a closed magnetic circuit configuration, the maximum driving frequency is required in relation to the required mechanical output characteristics and the driving frequency and the eddy current resistance of the rotating plate 111. It is desirable to select the material and shape of both so that the number of rotations can be obtained. Specifically, considering the time variation of the skin effect, the magnetic Reynolds number due to motion, and the composite state thereof, the material of the rotating plate 111, the shape of the perforated cage, etc., so that the driving frequency is in a practical frequency range It is desirable to select a hollow area. Furthermore, in order to adjust the magnetic resistance and the electric resistance with respect to the driving frequency, the soft magnetic metal plate is optimized. For example, silicon steel, soft magnetic ferrite and a composite material thereof may be used, or a punching process may be performed. Further, if the Mn—Zn ferrite cylinder with a protruding edge is used as the drive coil 103 used for the magnetic core 104, a closed magnetic circuit can be configured more easily and effectively.
[0093]
Note that the method of using the closed magnetic circuit configuration in this way is not limited to the non-interference type, and may be applied to an interference type.
[0094]
The above description is for a two-phase drive compatible with a double drive coil array. However, the present invention is not limited to this, and a multi-phase drive compatible with a three-phase drive can be used. Of course, it is possible to multiplex more than double. A method for dealing with these changes will be briefly described.
[0095]
The deformation ring configuration is as follows. When the number of electrical angles is n and the number of drive phases is m, the number of drive coils k forming each row is 2n. The number of multiplexing, that is, the number of coil arrays is equal to the number m of drive phases. For each row, the drive coils are connected in series so that the directions of the magnetic flux generated by the drive coils are alternately reversed. Then, the drive coils connected in series are each connected to the output terminal of each phase of the inverter circuit as one phase. The configuration of the rotating plate is according to the above example. Thereby, it can be set as m phase drive, n electrical angle, and a deformation | transformation 1 ring pair structure.
[0096]
For independent ring pairs: When the number of electrical angles is j and the number of drive phases is m, the number of drive coils k forming each row is 2jm. The number of multiplexing, that is, the number of coil arrays is equal to the number m of drive phases. For each row, every (m−1) drive coils are used and connected in series so that the direction of the generated magnetic flux is alternately reversed. Then, the drive coils connected in series are each connected to the output terminal of each phase of the inverter circuit as one phase. This is similarly performed for the other columns. The configuration of the rotating plate is according to the above example. Thereby, it can be set as m phase drive, j electric angle, and a pure independent m ring pair structure.
[0097]
Here, in the case of the independent m-ring pair configuration, the “genuine” is referred to as described above. When the rotating plates corresponding to the respective rows are integrally formed as described above, each of the torque generating mechanisms formed by the respective rows. This is because it is considered that the generated torque generated by the above is added at the shaft output and, as a result, forms one torque generating mechanism.
[0098]
Therefore, if an output shaft is provided independently for each rotating plate without integrally forming a rotating plate corresponding to each row, the rotation output by the generated torque generated by each torque generating mechanism formed by each row is generated. It can also be taken out independently. Further, it is possible to combine a part of the rotating plates corresponding to each row. Furthermore, if the connection with the inverter circuit is reversed, the direction of rotation can be reversed.
[0099]
For example, in the case of three-phase drive, instead of configuring one genuine independent three ring pair, configure three independent one ring systems, or one independent one ring system and one independent two ring system. You can also. Of course, in the case of the above-described two-phase driving, two independent one ring systems can be configured. In the case of four-phase driving, two independent two-ring systems can be configured.
[0100]
Furthermore, although the above description has explained that each column is driven by the same number of electrical angles and phases, the present invention is not limited to this. That is, the number of drive phases and the number of electrical angles may be different for each column.
[0101]
In this way, when the number of drive coils is increased, the drive coils can be easily arranged by arranging the drive coils in multiple layers, and also by arranging the high-density drive coils that alternately complement each other in position and angle. This is very convenient for constructing a “flat” electrical energy converter. The drive coil can be multipolarized without causing a significant increase in cost, and the torque generating mechanism can be arbitrarily selected according to the required mechanical output characteristics.
[0102]
If today's digital inverter technology is used, it is not difficult to generate a multi-phase from a single phase, but the more the multi-phase, the more complicated the inverter circuit and the electric motor, and the higher the cost. On the other hand, in the separation type electric energy conversion according to the present invention, there are restrictions due to separation, but for example, multi-axis output and provision of a speed reduction mechanism (described later) without causing a significant increase in cost. It is possible to realize a variety of responses, etc., and provide value compounding (described later) at a low cost to the consumer sector rather than industrial use, and also apply it to special fields (described later). In view of the above, it is preferable to employ a multipolar configuration based on two-phase driving.
[0103]
Here, what is important in the configuration in which drive coils such as interference type or non-interference type are arranged in multiple is important for the torque generating mechanism unit consisting of a conventional single drive coil array and a corresponding rotating plate. The invention is the same in the total number of drive coils, but, for example, by forming a torque generation mechanism having a simple configuration such as a deformed one ring pair or an independent two ring pair, if the device size is the same in any configuration, This means that high torque can be achieved. However, when the drive coils are connected in parallel to achieve multi-polarization, the output terminal of the inverter circuit and the terminals of a large number of drive coils must be connected, and terminal processing becomes complicated. It is preferable to increase the number of poles by connecting drive coils in series.
[0104]
In addition, it is also a feature of the present invention that each of the torque generation mechanisms having a simple configuration can be handled as one conversion unit. Furthermore, since it is possible to easily add the conversion units exclusively or mixedly on the same surface or in a multifaceted manner, higher torque can be achieved without causing a significant increase in cost. Moreover, since it is a separation type, replacement and replacement thereof is extremely easy. Here, “dedicated” means that only one modified ring pair is present, or only one independent ring pair is plural. “Mixed” means that a modified 1 ring pair and an independent ring pair are combined.
[0105]
Such conversion unitization is a concept that is useful when the rotating mechanism itself forms a member mold, utilizing one major feature of an electric energy converter having a separation function, and the surface of the member (for example, This is extremely effective when adding conversion units to side surfaces (including slopes) and ceiling surfaces other than the bottom surface.
[0106]
Further, the difference between the deformed one ring pair and the independent ring pair is the connection method of the drive coil and the shape of the hole portion forming the one-turn coil of the rotating plate, and the change between them is called the changing of the connecting method and the rotating plate. An extremely simple process is sufficient. Therefore, according to the required machine output characteristics such as high rotation direction or high torque direction, it is possible to recombine with an optimum and high-efficiency rotation mechanism part, for example, for the purpose of doubling the deformation 1 ring pair as an independent ring pair. On the contrary, it has the characteristic effect that the conventional torque generating mechanism part does not have, such as easy modification of the machine output characteristics, such as the purpose of increasing the torque by changing the independent ring pair to a deformed one ring pair. The role played by the present invention is very large. Here, “double speed” means that the rotation speed is twice that of the deformation 1 ring pair.
[0107]
A configuration example in which two torque generation mechanisms are provided based on the above-described idea is shown in FIG. In this example, eight drive coils are connected to the magnetism of the magnetism generating mechanism unit 100 so as to form four drive coil arrays concentrically (circles formed are circles R1, R2, R3, and R4 from the inside). A combination of the two torque generation mechanisms of the drive coil rows R1 and R2 and the drive coil rows R3 and R4, each of which has 16 drive coils 103, which are equally arranged on the pedestal 101. is there. Each torque generating mechanism may be configured as either a modified 1 ring pair or an independent 2 ring pair.
[0108]
  When the two torque generating mechanisms are provided, the drive coil 103 on the other circle is arranged between the adjacent drive coils 103 on the adjacent circle (substantially intermediate in this example). Further, the diameter of the drive coil 103 arranged in the circle R2 is smaller than that arranged in the circle R1, so that the drive coil 103 is arranged in high density, and the one arranged in the circle R3 is more than that arranged in the circle R1.bigIn addition, it is preferable that the arrangement in the circle R4 is smaller than that in the circle R3.
[0109]
The rotation mechanism unit (not shown) is provided with an inner rotation plate so as to be magnetically coupled to the drive coils disposed on the circles R1 and R2 of the magnetism generation mechanism unit, and the drive disposed on the circles R3 and R4. An outer rotating plate is disposed so as to be magnetically coupled to the coil. These two rotating plates may be for either the above-described modified one ring pair or independent two ring pair.
[0110]
The driving coils arranged on the circles R1 and R2 correspond to the inner rotating plate, and the driving coils arranged on the circles R3 and R4 correspond to the outer rotating plate, respectively, as shown in FIG. ) Or in series as shown in FIG. That is, when both the inner rotating plate and the outer rotating plate are for the modified one ring pair, they are connected in series according to FIG. Thereby, it can be set as the thing of a deformation | transformation 2 ring pair and 4 electrical angles as a whole. When both the inner rotating plate and the outer rotating plate are for independent two-ring pairs, they are connected in series according to FIG. Thereby, it can be set as the thing of independent 4 ring pair and 2 electrical angles as a whole. Further, one rotating plate is for a modified one ring pair and connected in series according to FIG. 1 (C), and the other rotating plate is for an independent two ring pair and is connected in series according to FIG. 2 (C). It is good also as a structure which connected and mixed the deformation | transformation 1 ring pair and the independent 2 ring pair.
[0111]
Next, using a magnetic generation mechanism section, a rotation mechanism section, and a current supply source based on the above idea, a speed reduction mechanism, a rotational speed control, a configuration that gives a regeneration gain (feedback) from the rotation mechanism section to the magnetic generation mechanism section, etc. A more specific aspect of the separated induction motor will be described.
[0112]
FIG. 7 is a diagram showing a total number of drive coils of 16, two-phase drive, independent two ring pairs, and two electrical angle magnetism generating mechanism part 200 (φ232 mm × h43 mm), each showing a plan view showing the arrangement of the drive coils (A) ), A side sectional view (B) in the direction of the XY arrow. The side sectional view (B) shows only the right half. In the magnetism generating mechanism 200, the total number of drive coils that can be practically arranged on the same plane and on the same circumference is about 20 in total, and in consideration of an inexpensive current drive source, two-phase drive and the same circle The total number of coils arranged on the circumference is 20 or less, and an effective and high-density drive coil arrangement is designed in consideration of increasing torque and reducing torque unevenness. In addition, since it is necessary to keep a sufficient pitch length between the poles in the same phase under a long magnetic gap length, when the magnetic gap length is 6 mm, the shortest drive coil of the magnetism generation mechanism unit 200 in free space. The design target value is designed so that the pitch between the electrodes is 5 cm or more.
[0113]
As is clear from FIG. 7A, the arrangement of the drive coils 203 (the inner arrangement is 203a and the outer arrangement is 203b) in the magnetism generation mechanism 200 is the same as that shown in FIG. That is, the inner drive coil array R1 (eight of the coil symbols b, d, f, h, j, l, n, and p) and the outer drive coil are arranged on the outer side as shown in the figure. The outer drive coil row R2 (eight of the coil symbols a, c, e, g, i, k, m, and o) is brought close to the valleys of the drive coils adjacent to each other in the row R1 so as to suppress an increase in radius. Arrange.
[0114]
As shown in FIG. 5C, the drive coils 203 are connected every other column. That is, the drive coils 203a-1 (b, f, j, n) of the inner drive coil array R1 are connected in series so that the directions of magnetic fluxes generated by the respective drive coils 203a-1 are alternately reversed. Similarly, the drive coils 203a-2 (d, h, l, p) are connected in series so that the directions of magnetic fluxes generated by the respective drive coils 203a-2 are alternately reversed. Also for the outer drive coil row R2, the drive coil 203b-1 (a, e, i, m) and the drive coil 203b-2 (c, g, k, o) are respectively provided in the same manner as the inner drive coil row R1. Connect in series.
[0115]
The drive coil 203a-1 of the inner drive coil row R1 and the drive coil 203b-1 of the outer drive coil row R2 are connected to the same phase (sin phase). Similarly, the drive coil 203a-2 and the drive coil 203b-2 are connected to the same phase (cos phase). As a result, the drive coils 203 constituting the inner and outer drive coil arrays are completely independent of each other and are driven in two phases with two electrical angles.
[0116]
These drive coil arrays R1 and R2 are arranged on the upper surfaces of two independent magnetic pedestal disks 206 (inner side 206a and outer side 206b) embedded in the bottom surface of the magnetism generating mechanism unit 200. The magnetic pedestal 206 has a ring shape formed by spirally winding a 0.3 mm thick silicon steel plate. The magnetic pedestal disk 206 is not limited to a circle but may be a polygon.
[0117]
The magnetism generating mechanism 200 is made of a molded resin and the like, and as the top plate 207 constituting its upper surface, a heat-resistant, shock-resistant and non-water-absorbing fluororesin compound material is suitable. Note that air holes (not shown) for heat dissipation are provided on the bottom and side surfaces of the housing.
[0118]
  FIG. 8 shows a rotating mechanism 210 (φ226 mm) corresponding to the magnetism generating mechanism 200.,h1 = 35 mm, h2 = 50 mm), a plan view focusing on the rotating plate 211 used in the rotating mechanism unit 210 (A), and a side sectional view of the rotating mechanism unit 210 in the XY arrow direction (B). It is. The plan view (A) and the side sectional view (B) show only the right half.
[0119]
The rotation mechanism unit 210 has a fixed shaft type planetary gear speed reduction mechanism, and has a fixed shaft 221 planted in a fixed housing (in this example, the bottom plate 220), and rotates around the fixed shaft 221. A rotating plate 211 that is freely supported, a gear 222 that is integrally formed coaxially with a part of the rotating plate 211 (in the vicinity of the fixed shaft 221 in this example), and a planetary gear 231 that meshes with the gear 222. And an output shaft (output gear) 240 that is integrally formed with the output portion (in this example, the outer ring gear 234) of the speed reduction mechanism and is rotatably supported by the fixed shaft 221. ing.
[0120]
This speed reduction mechanism includes four planetary gears 231 (see the four circles indicated by dotted lines in FIG. 1A) arranged uniformly around the circumference from a gear 222 formed integrally with a rotating plate 211 that generates torque. ), A one-stage gear reduction mechanism that transmits the reduced speed to the outer ring gear 234 disposed on the outermost periphery is formed. The reduction ratio is about 1 / 3.8. Note that the number of planetary gears 231 is not limited to four, and may be three, for example.
[0121]
The rotating plate 211 is formed by integrally forming an aluminum perforated cage disk 212 and a soft magnetic metal disk 213 corresponding to the inner and outer coil rows independently.
[0122]
The aluminum perforated cage disk 212 has a one-turn coil chain array corresponding to two sets of independent drive coil arrays R1 and R2 inside and outside the magnetism generating mechanism section 200 at the same radial position. It consists of two sets of independent car disks 212a and 212b. Two sets of independent soft magnetic metal disks 213a and 213b are provided on the opposite surfaces of the cage disks 212a and 212b as viewed from the drive coil so as to completely cover the respective aluminum hole cages. The soft magnetic metal disks 213a and 213b are not limited to the disk shape but may be polygonal.
[0123]
The rotating plate 211 is integrally formed while maintaining a complete division so that two sets of aluminum perforated cage disks 212 and two sets of soft magnetic metal disks 213 can independently generate rotational torque. The configuration is as follows.
[0124]
A tripod-type support having a tripod divided into three equal circumferences and three openings (not shown) of the output gear 240 close to about 100 ° on the upper surface of the output gear 240 of the casing 210a of the rotation mechanism 210. The plate 241 is attached to the upper end surface of the fixed shaft 221 by screwing, and is configured to fix and support the casing 210a and the upper end portion of the fixed shaft 221. The tripod support plate 241 may be a monopod like a crane neck.
[0125]
When the rotating mechanism 210 is fitted to the top plate 207 of the magnetism generating mechanism 200 so that the bottom plate 220 is overlapped and the respective driving coils 203 are driven, the rotating plate 211 is rotated. The rotational force of the rotating plate 211 generated thereby is reduced to about 1 / 3.8 by the reduction mechanism, and is mechanically output (rotated output) via the output gear 240.
[0126]
It should be noted that the present invention is not limited to the speed reduction mechanism using the planetary gear as described above, and it is also possible to use a speed reduction mechanism (for example, a speed reduction mechanism manufactured by Harmonic Drive, Inc.) in which the number of teeth of the internal teeth and the external teeth is shifted by one. In this case, it is also possible to adopt a configuration in which the internal teeth themselves are also used as a rotating plate.
[0127]
FIG. 9 is a diagram showing a total number of drive coils of 16, two-phase drive, a deformed one ring pair, and a magnetic generation mechanism section 250 (φ232 mm × h43 mm) for four electrical angles, and a plan view showing the arrangement of the drive coils, respectively (A ), A side cross-sectional view (B) in the XY arrow direction. The side sectional view (B) shows only the left half.
[0128]
As is clear from FIG. 9A, the arrangement of the drive coil 253 in the magnetic generation mechanism section 250 is the same as the arrangement in the magnetic generation mechanism section 200 shown in FIG.
[0129]
Each drive coil 253 is connected as shown in FIG. That is, the drive coils 253a (b, d, f, h, j, l, n, p) of the inner drive coil array R1 are set so that the directions of magnetic fluxes generated by the respective drive coils 253a are alternately reversed. Connect in series. Also, the outer drive coil array R2 is connected in series with the drive coils 253b (a, c, e, g, i, k, m, o) in the same manner as the inner drive coil array R1. The inner drive coil row R1 is connected to the cos phase, and the outer drive coil row R2 is connected to the sin phase. As a result, the inner and outer drive coil arrays form one deformed coil array and are driven with four electrical angles.
[0130]
The inner and outer drive coil arrays are disposed on the upper surface of a magnetic pedestal disk 256 embedded in the bottom surface of the magnetism generating mechanism portion 250. The magnetic pedestal disk 256 is not limited to a circle but may be a polygon.
[0131]
  FIG. 10 shows a rotating mechanism 260 (φ226 mm) corresponding to the magnetism generating mechanism 250.,h1 = 57 mm, h2 = 72 mm, h3 = 110 mm), a plan view focusing on the rotating plate 261 used in the rotating mechanism 260 and a side cross section of the rotating mechanism 260 in the XY arrow direction. It is a figure (B). The plan view (A) and the side sectional view (B) show only the left half.
[0132]
The rotation mechanism 260 has a fixed shaft type two-stage planetary gear reduction mechanism in which another rotation gear reduction mechanism is added to the rotation mechanism 210 described above. Another difference is that the fixed shaft 271 extends to the bottom surface of the magnetism generating mechanism 250 in order to maintain a sufficient bearing distance. As a result, the fixed shaft 271 of the rotating mechanism portion 260 is fitted into the bottom surface of the magnetism generating mechanism portion 250 so that the distance between the bearings is sufficiently maintained and the load bearing capacity is improved.
[0133]
The first stage of the rotating mechanism 260 has the same configuration as the gear reduction mechanism of the rotating mechanism 210 described above (each component member is given the same reference number as above), and the second stage is a first stage. The output gear 240 of the eye is used as its inner ring gear, and a gear reduction mechanism (planetary gear 281, outer ring gear 284) having the same configuration as that of the first stage is formed. Rotation output). The reduction ratio is about 1 / 3.8 per stage, and is about 1/14 as a whole.
[0134]
As described above, according to the present invention, the rotation mechanism portion is set to the shaft fixed system, so that the unitized planetary gear speed reduction mechanism can be made in one stage or two stages (and can be further multistaged) without being multipolarized. As a result, the torque can be increased, the range of torque increase methods can be selected, and the application range of the electric energy converter can be expanded.
[0135]
The rotating plate 261 includes an aluminum perforated cage disk 262 and a soft magnetic metal disk 263 that integrally correspond to the drive coil array (deformation ring) that generates one rotating magnetic field of the magnetism generating mechanism 250. Is formed.
[0136]
The aluminum perforated cage disk 262 has a one-turn coil chain array arranged so as to absorb the radial position difference between the two inner and outer drive coil arrays. A soft magnetic metal disk 263 (which may be a polygon) is provided on the opposite surface of the aluminum perforated cage disk 262 as viewed from the drive coil so as to completely cover each aluminum perforated cage portion.
[0137]
The deformed drive coil arrays R1 and R2 and the aluminum perforated cage disk 262 form a pair with two upper and lower rings separated by a magnetic gap, and four pole pairs within one mechanical angle (one rotation angle). In other words, the modified 1 ring is driven by 4 electrical angles.
[0138]
Similar to the one-stage configuration, the upper surface of the output gear 290 of the casing 260a of the rotation mechanism 260 has a tripod equally divided into three circumferences, and an opening (approximately 100 °) of the output gear 290 ( A tripod support plate 291 having three openings (not shown) is attached. A monopod may be used like a crane's neck.
[0139]
When the rotation mechanism 260 is fitted to the top plate 257 of the magnetism generation mechanism 250 so that the bottom plate 270 is overlapped with each other and the drive coils 253 are driven, the rotation plate 261 rotates. The rotational force of the rotating plate 261 generated thereby is reduced to about 1/14 by the two-stage reduction mechanism, and is mechanically output (rotated output) through the output gear 290.
[0140]
Thus, if it has a deceleration mechanism, it can be made into an electric energy converter with extremely strong power, and can be applied, for example, as an underwater power source for an auxiliary chair for taking a disabled person in the bathroom. become able to.
[0141]
Note that any rotation mechanism portion is provided with a convection hole (not shown) for guiding heat generation to the outside around the casing. The energy transmitted to the rotating plate of the rotating mechanism section is divided into a power component and a heat generating component, but the ratio varies depending on the load torque situation. Taking advantage of the feature that this induction motor is a separated type, for example, a rotating mechanism part is arranged in hot water to make a stirring action, and the heat generated by this rotating mechanism part is transmitted to hot water through a convection hole, Can be used for heat insulation. In this case, the bearing is subjected to a waterproofing treatment with a magnetic fluid (not shown).
[0142]
Next, a current supply source for driving the magnetic generation mechanism units 200 and 250 will be described. The current supply source 300 of this example drives the magnetism generating mechanism while maintaining and monitoring the operating state of the induction motor having the total number of drive coils of 16, and adopts an inverter system as a basic configuration. A block diagram of the current supply source 300 is shown in FIG. Hereinafter, the current supply source 300 is referred to as an “inverter circuit 300”. Of course, the inverter circuit 300 can be used not only in the induction motor having the total number of drive coils of 16 described above but also in an electric energy converter of another aspect according to the present invention.
[0143]
This inverter circuit 300 is supplied with a single-phase 100 V, 50/60 Hz commercial voltage, and outputs a double voltage rectified two-system DC voltage V1, V2, and a digital signal processing for performing various controls described later. Unit (DSP) 320, an output unit 340 that outputs a sine signal and a cosine signal of a predetermined frequency to the magnetism generation mechanism units 200 and 250, and a switch 351 that forms part of the drive stop unit 350. This is an AC to DC, DC to AC converter, that is, an AC-AC inverter, which performs phase conversion and frequency conversion on the phase signal and outputs a low voltage, large current sine wave signal.
[0144]
The power supply unit 310 includes a voltage doubler rectifier circuit 311 and a power factor correction circuit 312. The power supply unit 310 is supplied with the commercial voltage AC100V and the activation signal S1. The voltage doubler rectifier circuit 311 doubles the commercial voltage AC100V and outputs DC voltages V1 and V2. The power factor correction circuit 312 suppresses harmonics so that harmonic noise does not occur in the commercial power supply, and improves the power factor.
[0145]
The DSP unit 320 includes a processor (CPU) 321, a drive frequency variable oscillator 322, an F / V converter 323, an output comparison circuit 324, a triangular wave oscillation circuit 325, a π / 2 phase shift circuit 326, pulse width modulation circuits 327 and 328, and A sine wave signal having a predetermined frequency output from the drive frequency variable oscillator 322 is converted into a two-phase signal (sin signal, cos signal), and each of the two-phase signals is converted into a high-frequency triangular wave. The pulse width modulation is performed to output a PWM wave to the output unit 340.
[0146]
The DSP unit 320 is provided with a determination circuit 352 that forms part of the drive stop unit 350 that determines whether or not the rotation mechanism unit is mounted on the magnetism generation mechanism unit.
[0147]
The output unit 340 includes half-bridge type output circuits 341 and 342 and filter circuits 343 and 344 that remove PWM carrier waves, and switches the double voltage rectified DC voltages V1 and V2 with the input two-phase PWM waves. A drive output is obtained, a PWM carrier wave included in the drive output is removed, and a two-phase signal having a phase difference of 90 ° is supplied to each drive coil of the magnetism generating mechanism 200, 250.
[0148]
Output impedance Z of inverter circuit 300_OUTEffective part of Real (Z_{O UT}) (Effective resistance) is dominated by the ON resistance of the output current control transistors (not shown) of the half-bridge type output circuits 341 and 342 at a driving frequency of 1 kHz or less, and is generally about 1Ω to 3Ω.
[0149]
  The inverter circuit 300 is connected with a magnetic circuit mainly composed of the drive coils of the magnetism generating mechanism sections 200 and 250 and the rotating plates 111 and 261 of the rotating mechanism sections 210 and 260 as load circuits.Be.
[0150]
By the way, effective power (effective power) such as motive power and heat generation is a resistance component of the rotating plates 211 and 261 of the rotating mechanism units 210 and 260 (hereinafter, these rotating plates are generally referred to as “rotating bodies”). Is the power consumed only by it. The other electric power functions as a so-called magnetic flux carrier that transmits the effective electric power to the rotating body without impairing the large magnetic gap. In other words, the magnetic flux carrier is made up of reactive power (referred to as reactive power or apparent power), and this reactive power reciprocates between the power supply of the inverter circuit 300 and the load circuit, and sends the active power to the rotating body. It can be interpreted that it plays the role of a magnetic flux carrier that is carried and not consumed by the load circuit. This reactive power is not used as motive power or heat generation, and has no true consumption, but its value is larger than that of active power.
[0151]
The inverter circuit 300 needs to supply this large reactive power to the load circuit in addition to the active power. In particular, when the rotation mechanism section is not mounted, the value is about 2 kVA, and therefore it is necessary to pay attention to the withstand voltage and current resistance handled by the inverter circuit 300.
[0152]
Next, conditions for efficiently transmitting the power supplied by the inverter circuit 300 to the rotation mechanism units 210 and 260 will be considered.
[0153]
Two-terminal impedance Z for one phase on the side of the magnetic generation mechanism when the rotation mechanism is not mounted on the magnetic generation mechanism_S0Effective part of Real (Z_S0) (Effective resistance) is the output impedance Z of the inverter circuit 300_outEffective resistance of Real (Z_OUT) It is important to make the value sufficiently lower than 1Ω to 3Ω.
[0154]
If the drive frequency f ≦ 1 kHz, the inverter circuit 300 can supply power to the rotation mechanism unit without waste through the magnetic coupling between the magnetism generation mechanism unit and the rotation mechanism unit. That is, part of the power supplied by the inverter circuit 300 is effective resistance Real (Z_S0) And the remaining power is consumed by the rotating mechanism. Therefore, in order to efficiently transmit the power supplied from the inverter circuit 300 to the rotation mechanism unit, the effective resistance Real (Z_S0) Value is sufficiently small, that is, it is desirable to thoroughly reduce the AC resistance including the DC resistance of the magnetism generating mechanism at the driving frequency within a feasible range. Can be suppressed, and the efficiency can be improved.
[0155]
By the way, the applicant, as the relationship between the size of the electric motor of this example and the drive frequency becomes smaller, the efficiency in separation decreases, and conversely, an integrated configuration is required. Confirmed to move to a higher one.
[0156]
As a countermeasure to shift the drive frequency to the higher one, first, the wire material of the drive coil is a stranded wire bundled with many thin wires, and the main magnetic circuit of the magnetism generation mechanism section (more preferably also the rotation mechanism section), It is preferable to form Mn—Zn or Ni—Zn soft magnetic ferrite known as an audio magnetic head, or a composite material thereof to reduce the AC resistance at the high frequency driving frequency. In addition, since the shape of a ferrite material is concerned with a ferrite baking ability, it is good to use the polygon etc. which combined the block piece with easy baking.
[0157]
As a result, high-frequency driving becomes possible, and electric energy conversion according to the present invention can be applied to a millimeter-size machine or the like.
[0158]
Further, the design method for reducing the AC component resistance corresponding to the high frequency driving can be applied to the case where a high frequency alternating magnetic field for induction heating described later is generated.
[0159]
Furthermore, this design method can be applied to any configuration as long as it is not only a multiple arrangement configuration of electrical energy converters but also a separate type electrical energy converter.
[0160]
In the inverter circuit 300 in this example, proximity sensors 150 and 151 (other methods may be used) described later are used as the rotation speed detection means, and the output is sent to the processor 321 as indicated by a dotted line in the figure. The driving frequency can be controlled so that the rotation speed is maximized. In this case, the output of the drive frequency variable oscillator 322 is directly input to the pulse width modulation circuit 327 and the phase shift circuit 326 as a sin phase signal without passing through the output comparison circuit 324 (see FIG. Middle dotted line). The sin phase signal is delayed by 90 ° by the phase shift circuit 326 to be a cos phase signal, which is input to the pulse width modulation circuit 328.
[0161]
The dynamic response of the motor is about 6 to 8 seconds due to a high moment of inertia and a low regenerative gain. In other words, the cut-off frequency is about 0.1 Hz. In order to improve the cut-off frequency to about 10 Hz by performing the above-described speed control on the motor having such dynamic response, generation of rotation information of 100 pulses / rotation or more, that is, control information density It is necessary to increase. For this purpose, it is preferable to provide a dedicated means for detecting rotation information (number of rotations) of 100 pulses / rotation or more using the proximity sensors 150 and 151 as described above. For example, 100 notches are provided in the vicinity of the outer edge of the rotating body, and this is detected.
[0162]
The electric energy converter according to the present invention is of a separated type, and for example, an electric cordless and robust rotating mechanism is placed in a special environment such as underwater, in the sea, or in sewage where light does not pass. In addition, the rotation mechanism can be easily replaced. Therefore, when providing the rotation information detection means, it is required to reliably detect the rotation information during operation without any electrical or optical work on the rotation mechanism section from the magnetism generation mechanism section. In view of this, it is preferable to use, for example, a magnetic sensor (such as a proximity sensor described later) that can detect the presence or absence of metal in the rotating body even under a long magnetic gap. This magnetic sensor mainly detects a change in inductance due to the presence or absence of metal.
[0163]
For example, the proximity sensors 150 and 151 (other methods may be used) are used as the rotational speed detection means, and the outputs of the proximity sensors 150 and 151 are input to the F / V conversion circuit 323 to perform the F / V conversion. A speed control loop (constant speed control loop; not shown) for controlling the voltages V1 and V2 by comparing the output of the circuit 323 with the set voltage may be provided. Thereby, responsiveness can be improved to several Hz.
[0164]
In addition, in order to improve the start-up characteristics of the motor, the overvoltage at startup (about 1.5 times the rated voltage) is set by the load (this value is given as program data with a maximum of 3 minutes as a guide) ) After the elapse of time, it is preferable to provide an electrical forced kick start function for returning to steady voltage application and continuously rotating. By adding this kick start function, the rotating body can be raised to a predetermined number of revolutions in a short time. In this case, in order to prevent burning of the drive coil when the rotating body is constrained for some reason, a method for restricting the application time of overvoltage to the drive coil (hereinafter referred to as “forced short-time overvoltage application acceleration method”). It is good to adopt. Also, as one of the means for emergency stop of this high speed, high moment of inertia rotating body, the drive coil is switched to the reverse rotation mode and this overvoltage is applied (hereinafter referred to as “forced overvoltage application braking method”). Good. In this case, the application of overvoltage is cut off when the rotation speed pulse is equal to or less than a predetermined set pulse number. In this example, the rotation braking circuit 329 shown in FIG. 11 functions as this forced overvoltage application braking method.
[0165]
In addition, when the aluminum perforated cage disk of the one-turn coil chain of the rotating body is changed to a semi-hard magnetic material of about 50 to 300 oerste (Oe), such as alnico material, the speed control for maintaining the above-mentioned rotational speed constant. Even without forming a loop, a self-synchronized constant-speed synchronous motor can be easily configured.
[0166]
However, in this case, it is desirable to have a magnetizing function at the time of startup. For this purpose, the program built in the processor part of the inverter circuit applies a DC overvoltage to the drive coil at the start-up to magnetize the rotating body of Alnico, and after the rotating body is stopped, the function of demagnetizing as necessary This can be realized by providing This motor has a large feature that the magnetism generating mechanism section has a large current capacity and has a low impedance up to about 20 kHz, so that a magnetization demagnetizing function can be easily added to the inverter circuit 300. Moreover, when it is necessary to restrain and hold the rotating body after the rotating body is stopped, the DC voltage can be applied to the drive coil.
[0167]
The inverter circuit 300 is provided with functions other than the drive frequency control and speed control described above. Hereinafter, other functions will be described.
[0168]
As described above, when the rotation mechanism portion is not mounted on the magnetism generation mechanism portion, it is necessary to pay attention to the withstand voltage and current resistance handled by the inverter circuit 300. In this example, safety measures are taken.
[0169]
First, a plurality of notches are provided in a part of the rotating body in a state where dynamic balance is maintained. In this example, three small cutout portions 129 are provided on the outermost periphery of the rotating body at the position where the circumference is divided into three equal parts in the area where the magnetic metal plate of the closed magnetic path material is not provided on the back surface ( FIG. 8 and FIG. 10).
[0170]
Next, a plurality of sensors for detecting the presence or absence of the notch portion 129 are provided in the magnetism generating mechanism portion. The arrangement positions are such that they are not simultaneously detected as the cutout portions 129. That is, when the rotation mechanism is mounted, at least one sensor is arranged so as to be positioned in the notch. In this example, the magnetic induction type proximity sensors 150 and 151 that can detect the presence or absence of metal by the cutout portion 129 without contact are divided into two equal parts on the circumference and arranged at positions where they contact the cutout portion 129 of the rotating body. (See FIGS. 7 and 9).
[0171]
When the determination circuit 352 of the drive stopping means 350 provided in the inverter circuit 300 indicates that all outputs are the cutout portions 129 based on the output status of the proximity sensors 150 and 151, the switch 351 is turned off. .
[0172]
When the outputs of the proximity sensors 150 and 151 indicate notches, it indicates that the rotating mechanism is not mounted on the magnetism generating mechanism (non-mounted), so the switch 351 is turned off. Thus, in this state, the power is not turned on, that is, the drive coil is stopped in the non-mounted state, in other words, the device can be safety-equipped so that the main power can be turned on only after being mounted. .
[0173]
As described above, while the rotating body is rotating, the outputs of the proximity sensors 150 and 151 can be used as signals indicating the number of rotations.
[0174]
However, the proximity sensors 150 and 151 may mistakenly recognize that the rotation mechanism is in a mounted state when a metal object (for example, a spoon) is placed on the top plates 207 and 257. In order to avoid power-on malfunction due to this, the detection by the electric switch that is pushed in only after the rotation mechanism is actually mounted and the detection by the proximity sensors 150 and 151 described above are combined, that is, mechanically. It is preferable to provide a double safety mechanism (detection and magnetic detection) and take reliable safety measures (fail-safe system).
[0175]
In this way, the method for taking safety measures when the rotation mechanism unit is not mounted is not limited to the electric energy converter of the multiple arrangement configuration, and is similarly applied to the separated electric energy converter of other configurations. Can do.
[0176]
Various processes such as the drive frequency control and the speed control described above can be performed by digital signal processing except for the output circuits 341 and 342 and the filter circuits 343 and 344, and in particular, are manufactured by Texatsu Instruments (TI). By effectively utilizing a motor control DSP or the like, it is possible to provide an inverter with a program that optimizes the processing process. These can also be linked to a home computer and perform an agent function.
[0177]
  In the field of small electric motors with an output of 500 W or less, considering the power supply situation in the home, the electric motor of this example is considered in consideration of the fact that the basic restrictions as an electric motor are the heat generation and temperature rise of the magnetism generation mechanism.Magnetic generation mechanismAre designed to have a temperature rise value of 60 ° C. or less.
[0178]
In addition, the size of the magnetism generation mechanism is φ232mm, which makes it possible to reduce the overall size of the device to φ300mm or less, and the size of products that can be easily handled by humans with both hands (up to about 30cm on each side of the cube) Conveniently, a good agreement was shown, and as a result, a good consistency was given.
[0179]
Next, a rotation mechanism unit having a multi-axis output configuration that has a plurality of rotating plates that are fixed to the shaft and each provided with an output shaft independently will be described.
[0180]
FIG. 12 is a view showing the rotation mechanism portion of this multi-axis output configuration, and is a side sectional view (A) and a sectional view in the XY arrow direction (B). The corresponding magnetism generating mechanism unit shown in FIG. 6 is used. In addition, the rotating plate to be used is not limited to the one for an electric energy converter having a multiple arrangement structure such as the above-described independent ring pair or deformed ring pair, and may be any type. Of course, a magnetism generating mechanism and a current supply source having a configuration corresponding thereto are used.
[0181]
First, the fixed shaft 402 is planted in the housing (the bottom plate 401 in this example) to which the rotation mechanism unit 400 is fixed.
[0182]
Inside the rotation mechanism unit 400, an inner rotation plate 410 is arranged so as to be magnetically coupled to the drive coils arranged on the circles R1 and R2 of the corresponding magnetism generation mechanism unit (see FIG. 6), and the circles R3 and R4. The outer rotating plate 411 is disposed so as to be magnetically coupled to the driving coil disposed above. These two rotating plates may be for either the above-described modified one ring pair or independent two ring pair. Each of the two rotating plates is provided with dedicated output shafts 420 and 421 extending in the center and rising in the vicinity of the fixed shaft.
[0183]
An output shaft (inner output shaft) 420 of the inner rotary plate 410 is supported by the inner bearing portion 430 so as to be rotatable with respect to the fixed shaft 402. The output shaft (outer output shaft) 421 of the outer rotating plate 411 is supported by the outer bearing portion 431 so as to be rotatable with respect to the inner output shaft 420. In the figure, reference numeral 440 denotes a tripod type fixed shaft support plate.
[0184]
Thereby, if a rotating magnetic field is independently given so that both rotary plates may rotate independently, a rotational output can be obtained individually from two output shafts, or a differential output can be obtained. For example, it is possible to configure a rotating mechanism portion having two different target mechanical output characteristics, that is, a modified 1 ring pair and an output shaft of 4 electrical angles and an independent 2 ring pair and an output shaft of 2 electrical angles.
[0185]
It is also possible to combine this multi-axis output configuration and the above-described configuration in which the above planetary gear reduction mechanisms are stacked in multiple stages, which can further expand the application range of the electric energy converter.
[0186]
Note that the multi-axis output configuration technique as described above can be applied not only to a multiple arrangement configuration of electric energy converters but also to a separate type electric energy converter of another configuration.
[0187]
Next, the rotation mechanism part which provided the rotary body which can rotate independently on both sides of a magnetism generation mechanism part is demonstrated. Note that the above-described one in which the rotating body is arranged on one side of the magnetism generating mechanism section is referred to as a rotating mechanism section having a single rotor configuration.
[0188]
The rotation mechanism unit having such a configuration can be applied as a twin-rotor configuration having two rotating plates, for example. In order to obtain a rotating mechanism section having this twin-rotor configuration, for example, a magnetic base provided in the magnetism generating mechanism section is replaced with a rotatable rotating body and incorporated in the rotating mechanism section. The structure may have two rotating bodies on both sides.
[0189]
In this way, one large magnetic gap length necessary for separation is divided into two rotors so as to be divided into two magnetic gap lengths, and an integrated configuration is provided, and each rotor has its own output shaft. With the two-output shaft configuration, the rotational power that is self-adjusted and set according to the load of each rotor can be extracted independently from each output shaft.
[0190]
As a result, particularly when the casing is bent, the inherent advantage of the induction machine that automatically adjusts the difference between the rotational speeds of the inner and outer wheels is utilized. For example, an electric three-wheel bicycle in which the rotating body itself also serves as a disc brake It can be applied to.
[0191]
It should be noted that the rotating body used in the rotating mechanism portion arranged on both sides is not limited to the one for the electric energy converter having a multi-arrangement configuration such as the above-described independent ring pair or deformed ring pair. May be. Of course, a magnetism generating mechanism and a current supply source having a configuration corresponding thereto are used.
[0192]
Of course, it is effective to perform drive frequency control and speed control in order to effectively exhibit this configuration.
[0193]
Next, a description will be given of a structure in which a plurality of magnetism generating mechanism portions are provided in any state of separation facing, integral facing, and a mixture thereof with respect to the rotating body.
[0194]
As such a configuration, for example, a soft magnetic metal plate having a one-turn coil chain array of two rotating bodies is bonded to form one rotating body, and a rotating mechanism section is provided on both sides of the rotating body. On the other hand, both of them can be separated, or one of them can be integrated and the other can be separated, and can be applied as a twin stator structure in which two magnetic generation mechanisms are arranged.
[0195]
This twin stator configuration can be used, for example, before a lock. In this case, the rotation mechanism part and one of the magnetism generation mechanism parts are separated, and the one magnetism generation mechanism part is regarded as a portable free key of the size of a cigarette, and the rotation mechanism part and the other magnetism generation mechanism part are integrated. The two magnets are embedded in the inside of a non-metallic door or box, and one of the key magnetism generating mechanisms is almost fitted to the rotating mechanism through a non-metallic door and the rotating body is rotated. The doors can be unlocked and the other integrated magnetism generating mechanism can be operated to automatically lock the doors simultaneously, for example, while in the living room at bedtime. Needless to say, only the separated rotating mechanism portion can be used as a power source for locking and unlocking by arranging the rotating body inside a non-metallic door or box.
[0196]
In the above description, the magnetism generating mechanism section generates a rotating magnetic field, and the induction motor that induces and rotates the rotating body by applying the rotating magnetic field to the rotating body has been described. The electric energy converter is not necessarily limited to such an induction motor, and the magnetism generating mechanism section generates an alternating magnetic field, and induction heating can be performed by the alternating magnetic field. In this case, it is desirable that the magnetism generating mechanism section includes switching means for selectively generating a rotating magnetic field and an alternating magnetic field.
[0197]
In this way, one magnetic generation mechanism unit can be used for both rotating magnetic field generation and alternating magnetic field generation, and can be used by switching between induction rotation and induction heating, for example, electric cordless rotary cooking It is possible to provide a new kitchen cooking table that can be used in combination with an appliance (such as a mixer or a juicer) and another metal cooking pan.
[0198]
In this case, an alternating magnetic field generated by the magnetism generating mechanism section may be applied to the rotating body of the rotating mechanism section so that the rotating body itself is induction-heated, or the magnetizing mechanism section, the rotating mechanism section, The metal cooking pan may be placed on the magnetism generating mechanism portion instead of the rotating mechanism portion so that the cooking pan is induction-heated.
[0199]
In addition, when this induction heating is performed, local concentration of heating can be avoided and heat generation is dispersed and uniformed because the drive coil rows of the magnetism generating mechanism section are arranged in the radial direction, which is preferable for cooking and the like. .
[0200]
In addition, when the magnetism generating mechanism is also used for induction heating in addition to induction rotational power, a frequency outside the audible frequency range of 20 to 30 kHz is generally used as the induction heating drive frequency. On the other hand, it is desirable that the magnetic generation mechanism unit has a sufficiently low loss, and the design method corresponding to the above-described high frequency driving may be applied. That is, the wire material of the drive coil is a stranded wire bundled with many thin wires, and the magnetic core and magnetic pedestal of the drive coil have a Mn—Zn system that can sufficiently reduce loss with respect to the high frequency drive frequency. It is preferable to use a Ni—Zn-based soft magnetic ferrite material.
[0201]
In addition, a rotating mechanism section having a plurality of rotating bodies and a magnetism generating mechanism section capable of generating a rotating magnetic field and a high-frequency alternating magnetic field at the same time, independently generating a rotating magnetic field and a high-frequency alternating magnetic field simultaneously or selectively. It is also possible to make it. Then, for example, when a rotating magnetic field is applied to one rotating body and an alternating magnetic field is applied to the other rotating body, it can be utilized for thermal polishing, deburring polishing, and the like. In addition, the range of use of the electric energy converter can be further expanded, for example, each rotating body can be rotated in opposite directions, or one or both can be induction-heated as necessary. Such a method is not limited to the electric energy converter having the multiple arrangement, but can be applied to the separated electric energy converters having other configurations.
[0202]
Next, a description will be given of the addition of a new function of the electric energy converter according to the present invention, that is, another use mode (application development). Needless to say, the addition of the new function of the electric energy converter can be applied not only to the electric energy converter having the multiple arrangement configuration but also to the separated electric energy converter having another configuration. Although the new function to be given is mainly given to the rotation mechanism part, the magnetism generation mechanism part may be given a function to assist it. And this new function may be given in a rotating state, and rotation and a new function may be performed alternately.
[0203]
  As an idea of adding this new function,
    1) Co-Generation (heat)Movement(Joint supply)
    2) Co-Function (multifunctionalization)
    3) Under Special-Environment (in a special environment)
There is a new application as a composite form. Some examples are shown below.
[0204]
“Cogeneration of heat and power” is being put into practical use in a key industry that generates electricity from oil and uses the residual heat. Even in homes, the electric energy converter according to the present invention can be used around the bathroom by not only throwing away the power from the electric power and the heat generated in the separated rotating mechanism part but keeping it warm.
[0205]
The following cases can be considered as applications that make use of the characteristics of the flat / separated configuration. For example, either one of the magnetism generating mechanism part or the rotating mechanism part is embedded where necessary with a non-metallic isolation wall therebetween, and when necessary, the other non-embedded mechanism part is attached to the isolation wall. One function, here, a rotation operation that is practical, can be obtained by sandwiching them together.
[0206]
As a concrete application example, one side is buried inside a beautifully decorated non-metallic wall or door such as wood, glass, pottery, etc., and when necessary, the other is combined and functioned, It is possible to construct a system that can achieve the purpose, an underfloor fan, a ventilator fan or lock system that is used only in hot summer.
[0207]
The following example is shown as “multifunctionalization” in which two functions are realized by one. The shape of the rotating body is not limited to the disk-shaped one like the rotating plate described above, but from a geometric shape such as a cylindrical shape, a hollow shape, a conical shape, a spherical shape, etc., existing products such as tea bowls, dishes, pans and funnels, It can be made into an arbitrary shape, for example, by fitting it to the shape of a commodity such as a bell, and the member can be made multifunctional. Specifically, when a rotating body is inserted into a funnel and rotated integrally in a bathtub, it can function as a hot water circulation pump, or function as a small garbage processor.
[0208]
It is also possible to utilize the features of the cordless, safe, robust and freely removable rotating mechanism, and the rotating mechanism that can be easily maintained, inspected and replaced, and to effectively utilize the heat generated by the rotating body other than the rotational power. it can. One example is “moving signs” and “moving signboards” with snow fog prevention functions outdoors, especially in the snowy and snowy regions. Rotational power may be used for the function to move, heat generated by the rotating plate may be used to prevent snow cover, or induction heating may be performed. Recently, as one of the house glass window cleaning tools, there is an apparatus for cleaning a glass surface that comes into contact with outside air that is out of reach from the room. This device uses a magnet window on the inside (indoor side) or a permanent magnet across a magnetic gap called a glass window to attract soft magnetic metal pieces placed on the outside (outdoor side) with sufficient attractive force so as not to fall. On the other hand, the glass window is cleaned by moving the inner permanent magnet or the like, and sliding the mop or the like mounted and supported on the soft magnetic metal piece arranged on the outer side along with the permanent magnet. By applying the present invention to this apparatus, the magnetism generating mechanism portion is arranged on the indoor side, and a moped rotating plate having a soft magnetic metal piece around the glass is disposed opposite to the magnetism generating mechanism portion with a glass interposed therebetween. The cleaning mop can be made to rotate and slide the rotating plate to clean the glass from the indoor side. Moreover, if it is possible to use a replaceable rotating plate with a mop, it can be used for floor cleaning of buildings and the like. In particular, since the complete isolation from the electrical system is easy, a leakage accident can be reliably prevented.
[0209]
Here, it is very important that when two functions are performed by respective devices, the conversion efficiency as a single product is around 60 to 80%, but the total of the two functions is, for example, 30 to 40%. . The efficiency of this motor is less than 30% due to the mechanical output, but the efficiency of the value mix that is used up to the heat generation is about 50%, which is an inferior value, and it takes advantage of the space-saving and resource-saving flow. It is. However, it is inevitable that the absolute value of each function will be reduced, and it is important to cultivate applications that meet these requirements.
[0210]
  In addition, an electric cordless, safe and robust rotating mechanism is underwater, underwater, in a bathtub, in dirt, in a poisonous drug, in a clean room, in a clean bench, in a food processing machine, thermochemical polishing, deburring, automobile, bicycle In addition to the use of rotational power in “special environments” such as “MovementIt is possible to promote value compositing that is also provided with various functions of "combined supply" and "multifunctionalization".
[0211]
It is also possible to provide a low running cost such that the replacement of the life due to the wear of the rotating mechanism portion can be easily performed at a low cost, such as replacement of a bulb.
[0212]
  As described above, the electric energy converter according to the present invention has an output restriction based on the fact that it is a separated type, and its application field is a small electric motor having an output of about 500 W or less, for example, for 200 W or 500 W. Combination of standard magnetism generating mechanism by rank and standard rotating mechanism by rank that can be freely replaced, the above-mentioned multi-functionality, provision of combined value, and heat at power supply terminalsMovementThrough the provision of co-payments, etc., it has been possible to show good cost performance with saving resources, and in particular, it has become possible to provide value that is combined at low cost in the consumer sector.
[0213]
In addition, according to the electrical energy converter according to the present invention, from application development to household housing equipment, application to underwater use, special sterilization treatment, power source in a clean room, especially machine output characteristics By selecting a torque generation mechanism according to the requirements, incorporating a unitized planetary gear speed reduction mechanism, and supporting multiple output shafts, etc., it is easy to demonstrate on-site adaptability that combines low running costs and easy recyclability. A new platform for energy conversion could be provided.
[Brief description of the drawings]
FIG. 1 is a plan layout view (A) of a drive coil of a magnetism generating mechanism section of an electric energy converter according to the present invention, a plan view (B) of a rotating plate of a rotating mechanism section corresponding thereto, Connection diagram (C): 8 drive coils, 2 electrical angle deformation 1 ring
FIG. 2 is a plan layout view (A) of a drive coil of a magnetism generating mechanism section of an electric energy converter according to the present invention, a plan view (B) of a rotating plate of a rotating mechanism section corresponding thereto, Connection diagram (C): 8 drive coils, 1 electrical angle, 2 independent rings
FIG. 3 is a plan layout view (A) of a drive coil of a magnetism generating mechanism section of an electric energy converter according to the present invention, a plan view (B) of a rotating plate of a rotating mechanism section corresponding to this, and an electrical circuit of the drive coil. Connection diagram (C): 12 drive coils in total, 3 electrical angle deformation 1 ring
FIG. 4 is a plan layout view (A) of a drive coil of a magnetism generating mechanism section of an electric energy converter according to the present invention, a plan view (B) of a rotating plate of a rotating mechanism section corresponding thereto, Connection diagram (C): 16 drive coils in total, 4 electrical angle deformation 1 ring
FIG. 5 is a plan layout view (A) of a drive coil of a magnetism generating mechanism section of an electric energy converter according to the present invention, a plan view (B) of a rotating plate of a rotating mechanism section corresponding thereto, Connection diagram (C): 16 drive coils in total, 2 independent electrical rings
FIG. 6 is a diagram showing a configuration example in which two torque generation mechanisms are provided.
FIG. 7 is a diagram showing a total number of drive coils of 16, two-phase drive, independent two-ring pairs, and a magnetism generating mechanism for two electrical angles; a plan view showing the arrangement of drive coils (A), side in the direction of the XY arrow Sectional view (B)
8 is a view showing a rotation mechanism corresponding to the magnetism generation mechanism shown in FIG. 7; a plan view focusing on the rotation plate (A) and a rotation mechanism having a one-stage gear reduction mechanism in the direction of the XY arrow; Sectional view (B)
FIG. 9 is a diagram showing a total number of drive coils of 16, two-phase drive, a deformed one-ring pair, and a magnetism generating mechanism for four electrical angles; Sectional view (B)
FIG. 10 is a diagram showing a rotating mechanism corresponding to the magnetism generating mechanism shown in FIG. 9; a plan view focusing on the rotating plate (A) and a rotating mechanism having a two-stage gear reduction mechanism in the direction of the XY arrows; Sectional view (B)
FIG. 11 is a block diagram of an inverter circuit (current supply source) that drives a magnetic generation mechanism.
FIG. 12 is a side sectional view (A) and a sectional view in the direction of arrows XY (B) of a rotating mechanism portion of a fixed shaft type, multi-axis output configuration
[Explanation of symbols]
100, 200 Magnetic generation mechanism
103, 203 drive coil
110, 210, 400 Rotation mechanism
111, 211, 410, 411 Rotating plate
120,300 Inverter circuit (current supply source)
129 Notch
150, 151 Proximity sensor (rotational speed detection means)
321 CPU (functions as rotation speed control means and drive frequency control means)
350 Drive stop means

Claims (1)

A multi-phase AC current supply source that outputs a current of a predetermined frequency, a magnetism generating mechanism that is driven by the current supply source to generate a rotating magnetic field, a good conductor of a rotatable one-turn coil group, and a good soft magnetism on the back surface A rotating mechanism having a rotating body made of a material, and the magnetic generating mechanism and the rotating mechanism are assembled so as to be separable from each other. by the action of rotating magnetic field generated in the rotating member an electrical energy converter for rotationally driving the rotation body,
The magnetism generation mechanism unit, have a drive coil array comprising a plurality of drive coils with different circumferentially to each distribution spatial phase arrangements of diameters,
Each of the current supply sources generated between the drive coil array and the one-turn coil chain array in the rotating body directly facing the drive coil array by the rotating magnetic field formed by the magnetic flux generated from each drive coil array The rotation is performed by driving the drive coil so that the generated torque compensates for the torque generated by the other drive coil arrays, or by driving each of the drive coil arrays corresponding to each phase of the multiphase drive. It generates a set of generated torque on the body as a whole,
The electrical energy converter according to claim 1, wherein the rotating mechanism section is formed by independently arranging rotating bodies having inherent output shafts on both sides of the magnetism generating mechanism section .

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