DE102019123392B3 - LINEAR TRANSMISSION DEVICE WITH WIRELESS POWER SUPPLY - Google Patents

Abstract

A linear transmission device with wireless power capability includes a transmission mechanism and a wireless power supply module. The transmission mechanism includes an elongated shaft part and a moving part. The elongated shaft part defines an axis. The moving part is provided on the elongated shaft part such that the moving part is movable along the axis. The wireless power supply module includes a magnet providing part provided on the elongated shaft part to provide a magnetic field and an induction coil provided on the moving part. A direction of the magnetic field is parallel to the axis. A normal induction coil vector is parallel to the direction of the magnetic field. when the moving part is moved along the axis, a current being induced in the induction coil by changing the magnetic field.

Description

BACKGROUND OF THE INVENTION

Field of invention

The present disclosure relates to a linear transmission device, and more particularly to a linear transmission device with wireless power supply capability.

Description of the prior art

A linear transmission device, such as a linear guide, a lifting-rotating module, and a shaft guide that is secured against rotation play an important role in automation. To increase the stability of the automation equipment, linear transmission devices are being developed in the direction of intelligent field devices. By installing sensors on the linear transmission device, parameters of the linear transmission device can be obtained and monitored, and a corresponding correction can be made in accordance with the parameters in order to avoid errors. For example, fixed parameters can be monitored in order to know the degree of wear of the components in order to replace them before the components are damaged. As another example, vibration parameters can be monitored to control the operating speed of the components so as to avoid the components becoming wedged due to excessively high operating speed.

For example, a cable can be provided to supply power to the sensors installed on a moving part of the linear transmission device. The above solution for powering the sensors can become difficult when the cable is to be added to the existing circuit layout for automation (such as an injection molding machine with a complex and dense circuit layout moving part, which brings drawbacks such as fatigue, breakage or leakage of the cable, and it is therefore disadvantageous for monitoring the linear transmission device.

The Chinese patent publication CN 1 01 326 706 A discloses a wireless actuator wherein the wireless actuator supplies power to a consumer (such as a drive component and a radio receiver section) located on a movable table by means of a non-contact power component. The non-contact power supply component includes a primary coil provided on a base and a secondary coil provided on the movable table. The primary coil is driven by alternating current to generate a magnetic field, and a direction of the magnetic field is perpendicular to a longitudinal direction of the web. By changing the direction of the magnetic field of the primary coil, a current is induced in the secondary coil. Thus, the non-contact power supply component can supply power to the load provided on the moving table by a wireless method, and the disadvantage that the cable may be pulled during the moving operation of the moving table can be prevented. However, the primary coil and the secondary coil must be arranged in one area to cover the displacement distance of the moving table along the lengthwise direction of the path (for example, multiple primary coils may be required along the lengthwise direction of the path so that the total length of the plurality of primary coils is greater than or equal to the displacement distance of the moving table along the lengthwise direction of the track; alternatively, a single large primary coil is placed along the lengthwise direction of the track so that the length of the primary coil is greater than or equal to the offset -Distance of the moving table is along the longitudinal direction of the track). Thus, when the movable table moves along the base, the secondary coil can be opposite at least one of the primary coils. If the area in which the primary coil is to be provided is to be reduced, a second battery must be provided to connect the secondary coil so that the secondary coil can be powered by the second battery when the secondary coil far from the primary coil. As a result, more materials are required in the wireless actuator, which inevitably increases manufacturing costs and makes manufacturing difficult.

The Chinese patent publication CN 1 03 659 791 A discloses a wireless power device and direct drive system including the device. The Chinese patent CN 1 02 931 735 B discloses a contactless power system and method for moving a mobile device along the track. The arrangement of the primary coil and the secondary coil of the CN 1 03 659 791 A and CN 1 02 931 735 B are however comparable to that of CN 1 01 326 706 A and therefore also have the disadvantage of higher production costs and more difficult manufacture. The DE 101 25 059 A1 discloses a linear transmission device having an elongated member, a moving part provided on the elongated member, and a wireless power module having a magnetic and an induction coil. It will moving part moves along the axis, then a current is induced in the induction coil by changing the magnetic field. The U.S. 3,693,033 A discloses a key operated electrical pulse generator comprising a housing of non-magnetic material carrying a push-button key at one end, a coil at the other end, and a body of magnetic material spaced from the coil. A permanent magnet is mounted in the housing for movement between the magnet body and the coil and is magnetically attracted by the magnet body.

The development of a new linear transmission device with the ability to wirelessly supply power to a load placed on a moving part is therefore preferably used in automated equipment (such as an injection molding machine) with complex and dense circuit layouts, and avoids the disadvantages of a wired method of power supply such as fatigue, breakage or leakage of the cable, reduces manufacturing costs and manufacturing problems, and has become an important target for the industry concerned.

SUMMARY OF THE INVENTION

According to an embodiment of the present disclosure, a linear transmission device capable of wireless power supply includes a transmission mechanism and a wireless power supply module. The transmission mechanism includes an elongated shaft part and a moving part. The elongated shaft part defines an axis. The moving part is arranged on the elongated shaft part such that the moving part is movable along the axis. The wireless power supply module contains a magnet providing part, an induction coil and a storage element for electrical energy. The magnet providing part is provided on the elongated shaft part to provide a magnetic field, a direction of the magnetic field being parallel to the axis. The induction coil is provided on the moving part, and a normal vector of the induction coil is parallel to the direction of the magnetic field. If the moving part is moved along the axis, a current is induced in the induction coil by changing the magnetic field. The electric energy storage element is provided on the moving part and is electrically connected to the induction coil.

These and other features of the present invention will no doubt become apparent to those skilled in the art upon reading the following detailed description of the preferred embodiment shown in the various figures and drawings.

Figure list

• 1 Fig. 13 is a three-dimensional diagram showing a linear transmission device.
• 2 Figure 13 is a functional block diagram illustrating a wireless power module of 1 shows that supplies electricity to a consumer.
• 3 Figure 12 is a functional block diagram showing a wireless power module that provides power to a consumer, according to an embodiment of the present disclosure.
• 4th FIG. 13 is a three-dimensional diagram showing a linear transmission device according to another embodiment of the present disclosure.
• 5 FIG. 13 is a plan diagram showing a linear transmission device according to still another embodiment of the present disclosure.
• 6th Fig. 13 is a three-dimensional diagram showing a moving part according to still another embodiment of the present disclosure.
• 7th Fig. 13 is a three-dimensional diagram showing a moving part according to still another embodiment of the present disclosure.
• 8th FIG. 13 is a floor plan diagram showing a machine according to still another embodiment of the present disclosure.
• 9 FIG. 13 is another floor plan diagram showing the apparatus of FIG 8th shows.

DETAILED DESCRIPTION

In 1 becomes a three-dimensional diagram of a linear transmission device 100 shown in accordance with an embodiment of the present disclosure. The linear transmission device 100 can deliver electricity wirelessly. The linear transmission device 100 contains a transmission mechanism 110 and a wireless power module 140 . The transmission mechanism 110 contains an elongated shaft part 120 and a moving part 130 . The elongated shaft part 120 defines an axis D. The moving part 130 is on the elongated shaft part 120 provided so that the moving part 130 is movable along the axis D. In the embodiment, the elongated shaft part is 120 a screw shaft, the moving part 130 is a Screw nut wherein at least one roller member (not shown) such as a ball or a roller may be provided between the screw shaft and the screw nut. In other words, the transmission mechanism 110 be a ball screw or a worm screw. In another embodiment, the transmission mechanism 110 , but not limited to, a linear guide or a ball spline shaft. For example, if the transmission mechanism 110 the linear guide is the elongated shaft part 120 a running track, and the moving part 130 be a sliding block; when the transmission mechanism 110 is the ball spline shaft, then the elongated shaft part 120 a splined shaft and the moving part 130 be a spindle nut.

The wireless power supply module 140 contains a part providing a magnet 150 and an induction coil 160 . The part providing a magnet 150 is on the elongated shaft part 120 provided to provide a magnetic field, and a direction B of the magnetic field runs parallel to the axis D. In particular, includes the part providing the magnet 150 a coil 151 in which the coil 151 parallel to the induction coil 160 is arranged. The sink 151 can be connected to a power source (not shown) by means of a cable (not shown) to be supplied with power for generating the magnetic field. Will the coil 151 provided with a clockwise current, then the direction of the current is in the direction of arrow C, in which one side of the part providing the magnet 150 that is on the moving part 130 shows is a north pole, and one side of the magnet providing part 150 that away from the moving part 130 shows there is a south pole. I.e. the direction B of the magnetic field of the part providing the magnet 150 is on that the moving part 130 directed and parallel to the axis D. Will the coil 151 supplied with a current in the counterclockwise direction (the direction of the current is against the direction of arrow C), then the side of the part providing the magnet 150 that is on the moving part 130 shows a south pole while the side of the magnet providing part 150s that away from the moving part 130 is, is a north pole. That is, the direction B of the magnetic field of the part providing the magnet 150 orients itself away from the moving part 130 and runs parallel to the axis D. In another embodiment, the part providing the magnet can be a permanent magnet and the direction of the magnetic field of the permanent magnet can be oriented towards or away from the moving part and runs parallel to the axis D.

The induction coil 160 is on the moving part 130 intended. A normal induction coil vector 160 is parallel to the direction B of the magnetic field. Becomes the moving part 130 moved along the axis D, then a current is generated in the induction coil 160 induced by changing the magnetic field. Below is the one in the induction coil 160 induced current can also be referred to as induced current. In the embodiment, the coil is 151 of the part providing the magnet 150 parallel to the induction coil 160 arranged. Thus, the magnetic flux flowing through the induction coil 160 is amplified, so that the efficiency of generating the induced current is increased.

The change in the magnetic field can be achieved by changing the magnetic flux that passes through the induction coil 160 reached, which is achieved by the relative movement between the induction coil 160 and the part providing the magnet 150 is effected. If the part providing the magnet 150 the sink 151 contains, then the change in the magnetic field can also be achieved by changing the direction B of the magnetic field of the part providing the magnet 150 can be achieved by the coil 151 of the part providing the magnet 150 is supplied with alternating current. In addition, the wire diameter, the coil diameter and the number of turns of the induction coil 160 adjusted to increase the intensity of the induced current.

In 1 , is the part providing the magnet 150 at one * 121 of the elongated shaft part 120 intended. This can influence the original work cycle of the moving part 130 be avoided.

In 1 contains the moving part 130 an end surface 131 and a depression 133 . The depression 133 is on the final surface 131 concave and the induction coil 160 is in the deepening 133 intended. Thus, the original size of the moving part 130 can be obtained, thereby influencing the original work cycle of the moving part 130 can be avoided.

In 1 can use the wireless power supply module 140 selectively a distance sensor 152 include, on the side of the part providing the magnet 150 may be provided that the moving part 130 opposite. To display the position of the distance sensor 152 , is the distance sensor 152 indicated with dashed line. The distance sensor 152 is used to detect the distance L between the part providing the magnet 150 and the induction coil 160 . Reaches the distance L between the part providing the magnet 150 and the induction coil 160 a certain distance, then becomes the coil 151 of the part providing the magnet 150 powered to create a magnetic field. Thus, the part providing the magnet can 150 can only be powered within the range of the specified distance, which is advantageous for saving electrical energy and thermal energy. The determined distance can be greater than 0 cm and less than or equal to 30 cm. The distance sensor 152 may be, but is not limited to, an optical sensor (such as a laser radar) or an ultrasonic sensor.

2 Figure 8 shows as a functional block diagram the wireless power module 140 the 1 that a consumer 190 powered. In particular, the induction coil 160 with the consumer 190 be electrically connected. The one in the induction coil 160 induced current can be sent directly to the consumer 190 to be delivered.

3 is a functional block diagram showing a wireless power supply module 240 According to another embodiment of the present disclosure, showing a consumer 290 powered. The wireless power supply module 240 contains a part providing a magnet 250 , an induction coil 260 , a rectifier unit 270 and a memory element 280 for electrical energy. The rectifier unit 270 is between the induction coil 260 and the storage element 280 intended for electrical energy to convert the induced current from alternating current to direct current. The storage element 280 for electrical power is provided on the moving part and with the induction coil 260 through the rectifier unit 270 electrically connected. The storage element 280 for electrical power can be provided on the moving part removably. It is therefore advantageous to use the energy storage element 280 to replace. The storage element 280 for electrical energy can be, but is not limited to, a capacitor or a rechargeable battery. The rechargeable battery can be, but is not limited to, a rechargeable button battery or a flexible lithium battery. The storage element 280 for electrical energy can with the consumer 290 be electrically connected. The one in the induction coil 260 induced current can first be in the storage element 280 for electrical energy are stored, whereupon the storage element 280 for electrical energy the electricity to the consumer 290 supplies. It is thus beneficial to the consumer 290 to be continuously supplied with electricity. For example, the part providing the magnet becomes 250 powered only when the distance between the part providing the magnet 250 and the induction coil 260 which is the certain distance. Is the distance between the part providing the magnet 250 and the induction coil 260 not the certain distance, then the consumer can 290 continuously by means of the storage element 280 powered for electrical energy.

Other details of the wireless power module 240 can be identical to those of the wireless power supply module 140 , if there is no contradiction, and are not repeated here.

4th is a three-dimensional diagram showing a linear transmission device 300 according to yet another embodiment of the present disclosure. The linear transmission device 300 contains a transmission mechanism 310 and a wireless power supply module 340 . The transmission mechanism 310 contains an elongated shaft part 320 and a moving part 330 . The wireless power supply module 340 contains two parts providing magnets 350 and two induction coils 360 (only one induction coil 360 is shown). The parts providing two magnets 350 are at two end areas 321 and 322 of the elongated shaft part 320 arranged. Each of the parts providing magnets 350 contains a coil 351 . The moving part 330 contains two end surfaces 331 and 332 and two indentations wherein one indentation (not shown) is from the end surface 331 is concave, and the other recess 334 from the end surface 332 is concave. The two induction coils 360 are in the recess of the end surface 331 or the deepening 334 the end surface 332 intended. The spools 351 are parallel to the induction coil 360 arranged. The sink 351 may be connected to a power source (not shown) by a cable (not shown) to be energized to generate a magnetic field.

In 4th can use the two induction coils 360 be electrically connected to an identical consumer (not shown). Thus the two induction coils 360 induced currents are supplied to the identical consumer. Alternatively, the two induction coils 360 be electrically connected to two consumers (not shown). Ie the one in the two induction coils 360 induced currents are supplied to the two consumers. when the two induction coils 360 are electrically connected to the identical loads, wherein the two induction coils 360 can be connected in series or in parallel. The orientation of the direction of the magnetic field of the parts providing the two magnets 350 with the arrangement (connection in series or parallel) of the two induction coils 360 is well known in the art and is not listed here.

Other details of the linear transmission device 300 can be identical to those of the linear transmission device 100 , if there is no contradiction, and are not repeated here.

5 Figure 13 is a floor plan diagram showing a linear transmission device 400 according to yet another embodiment of the present disclosure. The linear transmission device 400 contains a transmission mechanism 410 and a wireless power supply module (not marked). The transmission mechanism 410 contains an elongated shaft part 420 and a moving part 430 . The elongated shaft part 420 contains two end regions 421 and 422 . The moving part 430 includes an end surface 432 and a recess (not shown). The recess is from the end surface 432 concave. The wireless power supply module includes a part providing a magnet 450 and an induction coil (not shown). The induction coil is in the recess of the end surface 432 intended. The part providing the magnet 450 is at the end 422 of the elongated shaft part 420 intended. The wireless power supply module can furthermore be a carrier part 470 include. The carrier part 470 serves to carry the part providing the magnet 450 . The part providing the magnet 450 can be attached to the carrier part 470 be attached by adhesive bonding or screwing. The carrier part 470 is at the end 422 and is connected to a machine (not shown). A distance between the part providing the magnet 450 and the induction coil can be made using the support part 470 can be set with different thickness. As a result, the intensity of the induced current can be adjusted.

6th is a three-dimensional diagram showing a moving part 530 according to yet another embodiment of the present disclosure. The linear transmission device can be a parameter detecting module 590 include. The module acquiring the parameter 590 can with the induction coil 560 be electrically connected, that is, the parameter-detecting module 590 is a consumer that works with the induction coil 560 connected is. The module acquiring the parameter 590 is used to acquire a parameter of the linear transmission device. For example, the module that records a parameter 590 detect the operating speed of the elongated shaft part of the linear transmission apparatus, thereby avoiding the situation that the elongated shaft part is stuck due to damage to other elements caused by an excessively high operating speed. The one by the one parameter-capturing module 590 detected parameters can be transmitted wirelessly to a receiving unit (not shown), such as a computer or a smartphone. Thus, the linear transmission device can be monitored in real time. The one parameter acquisition module 590 can, without being limited thereto, be a sensor for detecting the parameters of vibration, temperature or a sound signal.

In 6th the wireless power module can be a storage element 580 be for electrical energy. The storage element 580 for electrical energy is with the induction coil 560 electrically connected. A rectifier unit (not shown) can be between the storage element 580 for electrical energy and the induction coil 560 be arranged. The one in the induction coil 560 induced current can first be in the storage element 580 for electrical energy are stored, whereupon the storage element 580 for electrical energy, current to the parameter-taking module 590 supplies. In other words, it is the parameter acquiring module 590 with the induction coil 560 through the storage element 580 electrically connected for electrical energy.

The moving part 530 includes an end surface 531 and a depression 533 . The depression 533 is on the final surface 531 concave. The depression 533 contains a first recording area 533a and a second receiving area 533b . The induction coil 560 is in the first recording area 533a intended. The storage element 580 for electrical energy and the parameter-recording module 590 are in the second recording area 533b intended. Thus, it is advantageous the original size of the moving part 530 to maintain.

7th is a three-dimensional diagram showing a moving part 630 according to yet another embodiment of the present disclosure. In comparison with 6th contains the moving part 630 an end surface 631 and a protruding area 635 . The protruding area 635 stands from the end surface 631 emerged. The protruding area 635 contains two surfaces, one top surface 635a or a side surface 635b are. The side surface 635b connects the top surface 635a with the end surface 631 . The induction coil 660 is on the top surface 635a intended. The Storage element 680 for electrical energy and the parameter-recording module 690 are on the side surface 635b intended. It is thus advantageous to keep the circumferential dimensions of the moving part 630 to maintain. In another embodiment, the induction coil 660 on the side surface 635b be provided and the memory element 680 for electrical energy and the parameter-recording module 690 can on the induction coil 660 be provided. Details of the storage element 680 for electrical energy and the parameter-recording module 690 can refer to the storage element 280 for electrical energy, the storage element 580 for electrical energy and the parameter-recording module 590 relate and are not repeated here.

In the 8th and 9 , 8th is a floor plan diagram depicting a machine 700 according to yet another embodiment of the present disclosure. 9 is another floor plan diagram showing the machine 700 from 8th shows. In 8th and 9 is the machine 700 an injection molding machine. In 8th is the machine 700 in a clamped state. In 9 is the machine 700 in an open and ejected state. The linear transmission device 100 is in the machine 700 provided and the machine 700 has a normal work cycle. The machine listed here 700 , an injection molding machine, is only mentioned as an example, and the present disclosure is not limited thereto. The machine 700 , which has a normal working cycle, is suitable the linear transmission device 100 to move. For example, the machine can 700 also be a pressure injection machine or a pipe bending machine.

In 1 is that the linear transmission device 100 simultaneously with a drive motor 730 the machine 700 through the end area 122 and with a first connection 710 the machine 700 by the moving part 130 connected. The drive motor 730 drives the elongated shaft part 120 to rotate around the moving part 130 to make it move along the axis D so that the first connection 710 and the second connection 720 are actuated, the mold 740 to bring about repeated clamping and opening. When combining the wireless power supply module 140 with the transmission mechanism 110 can the existing normal work cycle of the machine 700 be used to create a relative movement between the part providing the magnet 150 and the induction coil 160 to generate the current in the induction coil 160 to induce. Thus, no additional power source is required for the relative movement between the part providing the magnet 150 and the induction coil 160 to produce what is useful to provide wireless power capability while conserving power and simplifying elements. In addition, it is difficult when the machine 700 has a complex and dense circuit layout, attaching cables to the existing circuit layout, to the consumer who is on the moving part 130 is arranged to be powered by a wired method. According to the present disclosure, the in the induction coil 160 that is on the moving part 130 is provided, induced currents can be generated by a wireless method, whereby the difficulty of attaching cables of a wired method can be solved.

According to the present disclosure, the term “parallel” or “perpendicular” denotes an element that is configured parallel or perpendicular relative to another element. Due to manufacturing tolerances or other factors, the element is not exactly perpendicular relative to the other element. In the present disclosure, the term “parallel” or “perpendicular” therefore includes the meaning of the phrase “substantially parallel” or “substantially perpendicular”. For example, a deviation of a desired angle between two elements in the range of -10 degrees to 10 degrees is within the scope of the present disclosure.

In accordance with the present disclosure, the term "electrically connected" means that two elements can transmit electrical energy through a direct, indirect, wired, or wireless method.

Compared to the prior art, the wireless power module of the linear transmission device of the present disclosure can wirelessly induce current in the induction coil located on the moving part to supply a load (such as a parameter-sensing module) connected to the induction coil is electrically connected, which is advantageously used in the automated equipment (such as an injection molding machine) with complex and dense circuit layout, in order to avoid disadvantages of a wired method of power supply such as fatigue , Breakage or leakage of the cable, and therefore it is advantageous for the development of the linear transmission device in the intelligent field. Furthermore, according to the linear transmission apparatus of the present disclosure, regardless of whether the storage element is provided for electric power or not, the area where the magnet providing part is provided does not require the displacement distance of the moving part along the elongated Shaft part covers, which is advantageous for reducing the manufacturing cost and manufacturing difficulty.

It will be readily apparent to those skilled in the art that numerous modifications and changes can be made in the apparatus and method while holding to the teachings of the invention. The above disclosure is therefore to be interpreted in such a way that it is only limited by the scope and limits of the appended claims.

Claims (9)

A linear transmission device (100) capable of wireless power supply, comprising: a transmission mechanism (110) comprising: an elongated shaft portion (120) defining an axis; and a moving part (130) provided on the elongated shaft part (120) so that the moving part (130) is movable along the axis; and a wireless power supply module (140) comprising: a magnet providing member (150) disposed on the elongated shaft member (120) for providing a magnetic field wherein a direction of the magnetic field is parallel to the axis; an induction coil (160) provided on the moving part (130), wherein a normal vector of the induction coil (160) is parallel to the direction of the magnetic field; wherein when the moving part (130) is moved along the axis, a current is induced in the induction coil (160) by changing the magnetic field; and an electric energy storage element (280) provided on the moving part (130) and electrically connected to the induction coil (160). Linear transmission device (100) according to Claim 1 wherein the magnet providing part (150) is provided at an end portion of the elongated shaft part (120). Linear transmission device (100) according to Claim 1 wherein the moving part (130) is a screw nut and the elongated shaft part (120) is a screw shaft. Linear transmission device (100) according to Claim 1 wherein the linear transmission device is provided in a machine, and the machine has a regular working cycle. Linear transmission device (100) according to Claim 1 wherein the moving member (130) includes an end surface and a recess, wherein the recess is concave on the end surface, and wherein the induction coil is provided in the recess. Linear transmission device (100) according to Claim 1 wherein the moving member (130) includes an end surface and a protruding portion, wherein the protruding portion protrudes from the end surface, and wherein the induction coil (160) is provided on one surface of the protruding portion. Linear transmission device (100) according to Claim 6 wherein the electric power storage element (280) is detachably provided on the moving part (130). Linear transmission device (100) according to Claim 1 wherein the magnet providing part (150) comprises a coil, wherein the wireless power supply module (140) further comprises a distance sensor for detecting a distance between the magnet providing part (150) and the induction coil (160) wherein when the distance between the magnet providing part (150) and the induction coil (160) reaches a certain distance, the coil of the magnet providing part (150) is energized to provide the magnetic field in which the certain distance is greater than 0 cm and less than or equal to 30 cm. Linear transmission device according to Claim 1 further comprising a parameter sensing module electrically connected to the induction coil (160), wherein the parameter sensing module is for sensing a parameter of the linear transmission device (110).

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