JP2005273754A - Dual type coupling and its application device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a dual type coupling having deflection property and rigidity and provide a device as application of the coupling. <P>SOLUTION: The input side 101 is formed as a transmitting structure of rotational movement energy, while the output side 102 is formed as a transmitting structure of rotational movement energy. A deflective transmitting device 103 comprises an eddy current coupling, a fluid coupling, a power generation effect coupling or autonomous rotation part and a passive rotation part and consists of a coupling structure so that the two generate a rotational motion energy to perform transmission or a coupling equipped with a similar function, wherein the autonomous rotation part is connected with the input part 101 while the passive rotation part is connected to the output side 102. A single-way transmission device 104 is formed as a conventional one-way clutch or a transmission device to make transmission while it makes rotation only in one direction, in which one side is connected to the input side 101 and the other end is connected to the passive rotation part of the deflective transmitting device 103. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a dual coupling having flexibility and rigidity and an application device thereof. In particular, it refers to the coupling of rotational kinetic energy with a special function. It accelerates the kinetic energy of rotation from the input side to exhibit the flexibility with a rotation difference and transmits it to the output side, and non-rigid transmission with a rotation difference is generated according to the change of the load. In the opposite case, the rotational kinetic energy fed back from the output side to the input side has the characteristic of rigid transmission with no rotational difference. This flexible and rigid dual coupling is a shock-type load that stores energy, a press, a drive device for unstable flow stress, a flow stress generator, a ventilation fan that is driven by flow stress, and a device that stores the energy of the flywheel Or it can be applied to other loads.

  Conventional couplings are usually divided into two types. One of them is a flexible coupling with a rotational difference. For example, when rotational kinetic energy is transmitted between the input side and the output side of an eddy current coupling, fluid coupling, or power generation effect coupling, non-rigid transmission with a rotational difference occurs according to a change in load. Another type is a rigid coupling. That is, when rotational kinetic energy is normally transmitted between the input side and output side of a friction clutch driven by mechanical, electromagnetic force, force against flow, mechanical force or centrifugal force, the two are synchronous and there is no rotational difference. Therefore, when it is used, it is often limited.

  A main object of the present invention is to provide a dual coupling having flexibility and rigidity and an apparatus for applying the same. It is for the first time a mechanical kinetic energy coupling with an input side and an output side. Specifically, when rotational kinetic energy is transmitted from the input side, it has a kinetic energy transmission characteristic that exhibits a flexible acceleration with a rotational difference, and has a non-rigid transmission with a rotational difference according to a change in load. The rotational kinetic energy fed back from the output side to the input side from the opposite direction has a rigid transmission with no rotational difference.

  The present invention relates to mechanical kinetic energy coupling with an input side and an output side for the first time. Specifically, when rotational kinetic energy is transmitted from the input side, it has a kinetic energy transmission characteristic that exhibits a flexible acceleration with a rotational difference, and has a non-rigid transmission with a rotational difference according to a change in load. The rotational kinetic energy fed back from the output side to the input side from the opposite direction has a rigid transmission with no rotational difference.

FIG. 1 is an explanatory view of the structural principle of a flexible and rigid dual coupling and its application apparatus according to an embodiment of the present invention. Its main components include the following.
Input side 101: It is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures. Thereby, it is connected to one side of the unidirectional transmission 104. Moreover, it is connected with the spontaneous rotation part of the flexible transmission 103 by it.

  Output side 102: It is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures. Thereby, it is connected to the passive rotating part of the flexible transmission 103. It also connects to the other side of the unidirectional transmission 104.

  Flexible transmission device 103: it has an eddy current coupling, a fluid coupling, a power generation coupling or a voluntary rotating part and a passive rotating part, both of which have a rotational difference according to a change in load, a non-rigid rotational kinetic energy Or a coupling having other similar functions. The spontaneous rotation unit is connected to the input side 101. The passive rotating unit is connected to the output side 102 and is connected to one end of the unidirectional transmission device 104.

  Single-direction transmission 104: A conventional single-direction clutch or other one-way transmission is configured to rotate and transmit in the other direction, but in the other direction, the transmission is idle. One end thereof is connected to the input side 101. The other end is connected to the passive rotating portion of the flexible transmission device 103.

  With the structure described above, rotational kinetic electrical energy is transmitted from the input side 101 to the output side 102 through the flexibility of non-rigid transmission. In the opposite case, the rotational kinetic energy fed back from the output side 102 to the input side 101 through the unidirectional transmission device 104 performs rigid transmission with no rotational difference.

FIG. 2 is an example of a dual coupling constructed by combining the eddy current coupling of FIG. 1 with a unidirectional transmission. Its main components include the following.
Input side 201: It is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures. Thereby, one side of the unidirectional transmission 204 is connected. Thereby, it is connected to the spontaneous rotation part of the spontaneous rotation part 2031 of the eddy current coupling.

  Output side 202: It is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures. Thereby, it is connected to the passive rotating part 2032 of the eddy current coupling. It also connects to the other side of the unidirectional transmission 204.

  Eddy current coupling 203: selected because it has two types of structure. The structure that forms a magnetic field by exciting a coil with a permanent magnet or an electric current is a spontaneous rotating unit 2031 for eddy current coupling, but a passive rotating unit 2032 for eddy current coupling is formed by an eddy current conductor. ing. Alternatively, it includes another eddy current coupling structure that has the same function but has a fixed magnetic field structure and is provided with an intermediate magnetic path that can rotate. Further, the structure of the intermediate magnetic path is the spontaneous rotating part 2031 of the eddy current coupling, and the passive rotating part 2032 of the eddy current coupling is constituted by the eddy current conductor, so that the spontaneous rotating part of the eddy current coupling is formed. When 2031 rotates by being driven by the input side 201, the two cause a relative rotational speed difference according to the change of the load through the eddy current effect, and further interlocks the passive rotating part 2032 of the eddy current coupling by a flexible transmission. Then, the output side is driven. The relationship of connecting the spontaneous rotator 2031 of the eddy current coupling to the input side 201 and the relationship of connecting the passive rotator 2032 of the eddy current coupling to the output side 202 are represented by the spontaneous rotation unit 2031 of the eddy current coupling. May be changed to a relationship of connecting the output side 202 to the output side 202 and a relationship of connecting the passive rotator 2032 of the eddy current coupling to the input side 201.

  Single-direction transmission device 204: a conventional single-direction clutch or a transmission device that rotates and transmits only in one direction, while the other direction is idle. One end thereof is connected to the input side 201. The other end is connected to the passive rotating part 2032 of the eddy current coupling.

FIG. 3 is an example of a dual coupling constructed by combining the fluid coupling of FIG. 1 with a unidirectional transmission. The main components are as follows.
Input side 301: It is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures. Thereby, one side of the unidirectional transmission 304 is connected. Thereby, it is connected to the spontaneous rotating part 3031 of the fluid coupling.

  Output side 302: It is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures. Thereby, it is connected to the passive rotating part 3032 of the fluid coupling. It also connects to the other side of the unidirectional transmission 304.

  Fluid coupling 303: A fluid coupling voluntary rotating part 3031 with a vane that produces a moving flow stress is connected to the input side 301. Further, by having a fluid coupling passive rotation unit 3032 and a case that are driven by fluid stress, when the fluid coupling spontaneous rotation unit 3031 is driven by the input side 401 and rotates, it transmits gas or liquid. Transmits kinetic energy as a medium. Thereby, according to the change of load, a relative rotational speed difference is produced and a flexible transmission is performed to drive the passive rotating part 3032 and the output side 302 of the fluid coupling. The relationship of connecting the spontaneous rotation unit 3031 of the fluid coupling to the input side 301 and the relationship of connecting the passive rotation unit 3032 of the fluid coupling to the output side 302 are the same as the relationship of connecting the spontaneous rotation unit 3031 of the fluid coupling to the output side. The relationship of connecting to 302 and the relationship of connecting the passive rotating part 3032 of the fluid coupling to the input side 301 may be changed.

  Single-direction transmission device 304: a conventional single-direction clutch or a transmission device that rotates and transmits only in one direction, while the other direction is idle. One end thereof is connected to the input side 301. The other end is connected to a passive rotating part 3032 of the fluid coupling.

FIG. 4 is an example of a dual coupling constructed by combining the electromagnetic coupling of FIG. 1 with a unidirectional transmission. The main components are as follows.
Input side 401: It is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures. Thereby, it is connected to one side of the unidirectional transmission 404. Thereby, it is connected to the spontaneous rotation part 4031 of the power generation effect coupling.

  Output side 402: It is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures. Thereby, it is connected to the passive rotating part 4032 of the power generation effect coupling. It also connects to the other side of the unidirectional transmission 404.

  Power generation effect coupling 403: It constitutes the spontaneous rotation part 4031 of the power generation effect coupling with a magnetic field formed by exciting a coil with a permanent magnet or current. A passive rotating part 4032 of the power generation effect coupling is constituted by the electric pivots rotating relative to each other. Further, the spontaneous rotation part 4031 of the power generation effect coupling is connected to the input side 401, and the passive rotation part 4032 of the power generation effect coupling is connected to the output side 402. Both control the generated power output from the power generation effect coupling 403 to the load 406 by the power generation load control device 405. In addition, when the power generation coupling spontaneous rotation part 4031 is rotated and driven on the input side 401, a relative rotation speed difference is generated according to a change in load, and the power generation coupling is passively rotated with non-rigid flexibility. By driving the unit 4032, it is driven and output to the output side 402. The relationship between the spontaneous rotation part 4031 of the power generation effect coupling connected to the input side 401 and the relationship of connecting the passive rotation part 4032 of the power generation effect coupling to the output side 402 are referred to as the spontaneous rotation part 4031 of the power generation effect coupling. May be changed to a relationship of connecting to the output side 402 and a relationship of connecting the passive rotating portion 4032 of the power generation effect coupling to the input side 401.

  Single-directional transmission 404: A conventional single-directional clutch or other one-way transmission is configured to rotate and transmit in the other direction, while the other direction is a non-spinning transmission. One end thereof is connected to the input side 401. The other end is connected to the passive rotating part 4032 of the power generation effect coupling.

Power generation load control device 405: It is composed of a mechanical or solid electronic electric circuit, and controls the power generated by the power generation coupling 403.
Load 406: It is comprised by the load which moves a load with an electrical resistance or other electrical energy, and shall be the power generation load of the power generation effect coupling 403.

  The present invention relates to a flexible and rigid binary coupling and its application device. It is possible to perform mixing control by a dual coupling having flexibility and rigidity and its application device by providing a clutch which can be controlled on the output side. FIG. 5 is an explanatory diagram of a structure provided with a clutch that can be controlled on the output side or the input side of the embodiment of FIG. Its main composition includes the following.

  Input side 101: It is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures. Thereby, it is connected to one side of the unidirectional transmission 104. Moreover, it is connected with the spontaneous rotation part of the flexible transmission 103 by it.

  Output side 102: It is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures. Thereby, it is connected to the passive rotating part of the flexible transmission 103. It also connects to the other side of the unidirectional transmission 104.

  Flexible transmission device 103: it has an eddy current coupling, a fluid coupling, a power generation coupling or a voluntary rotating part and a passive rotating part, both of which have a rotational difference according to a change in load, a non-rigid rotational kinetic energy Or a coupling having other similar functions. The spontaneous rotation unit is connected to the output side 101. The passive rotation unit is connected to the output side and is connected to one end of the unidirectional transmission device 104.

  Single-direction transmission 104: A conventional single-direction clutch or other one-way transmission is configured to rotate and transmit in the other direction, but in the other direction, the transmission is idle. One end thereof is connected to the input side 101. The other end is connected to the passive rotating portion of the flexible transmission device 103.

  Controllable clutch 501: Whether the input side 101 controls the transmission relationship to the outside by performing the function of closing and disconnecting the transmission by controlling with human force, mechanical force, electromagnetic force or flow response force, The output side 102 controls the transmission relationship to the outside. The controllable clutch 501 is provided on the input side 101 or the output side 102 as required.

  As described above, the dual coupling having flexibility and rigidity and its application device are provided with the transmission characteristics of flexibility and rigidity in the input and output directions for the first time, respectively, so that an impact load, press, non Since it can be applied to a stable flow stress driving device, a flow stress generator, a ventilation fan driven by a flow stress, a device for storing energy of a flywheel, or other loads, the idea is new and the function is reliable.

It is a schematic diagram showing the structural principle of a dual coupling and its application device according to an embodiment of the present invention. It is a schematic diagram which shows the state comprised by combining the eddy current coupling of the dual coupling by one Example of this invention, and the unidirectional transmission. It is a schematic diagram which shows the state by which the fluid coupling of the dual coupling by one Example of this invention and the unidirectional transmission were comprised. It is a schematic diagram which shows the state comprised combining the electromagnetic effect coupling of the dual coupling by one Example of this invention, and the unidirectional transmission. It is a schematic diagram which shows the state in which the clutch which can be controlled in the output side or input side of the binary coupling by one Example of this invention is provided.

Explanation of symbols

  101 input side, 102 output side, 103 flexible transmission device, 104 unidirectional transmission device, 201 input side, 202 output side, 203 eddy current coupling, 204 unidirectional transmission device, 301 input side, 302 output Side, 303 fluid coupling, 304 unidirectional transmission device, 401 input side, 402 output side, 403 power generation coupling, 404 unidirectional transmission device, 405 power generation load control device, 406 load, 501 controllable clutch , 2031 Spontaneous rotating part of eddy current coupling, 2032 Passive rotating part of eddy current coupling, 3031 Spontaneous rotating part of fluid coupling, 3032 Passive rotating part of fluid coupling, 4031 Spontaneous power generation coupling Rotary part, 4032 passive rotary part of power generation coupling

Claims (5)

This is a dual coupling with flexibility and rigidity, and its application device, which accelerates the kinetic energy of rotation from the input side to the flexibility with a rotational difference and transmits it to the output side to transmit the load. Non-rigid transmission with a difference in rotation occurs according to the change.
The input side (101) is composed of a shaft shape, a wheel shape, a disk shape, or other various rotational kinetic energy transmission structures, and is connected to one side of the unidirectional transmission device (104) to provide a flexible transmission device ( 103) voluntary rotating part,
The output side (102) is composed of a shaft shape, wheel shape, disk shape, or other various rotational kinetic energy transmission structures, and is connected to the passive rotating portion of the flexible transmission device (103) to transmit in a single direction. Connected to the other side of the device (104),
The flexible transmission device (103) has an eddy current coupling, a fluid coupling, a power generation coupling, or a spontaneous rotating portion and a passive rotating portion, both of which have a rotational difference according to a change in load, and a non-rigid rotational motion. It consists of a coupling that generates energy and transmits it, or a coupling with other similar functions. The spontaneous rotation part is connected to the input side (101), and the passive rotation part is connected to the output side (102). Connected to one end of the transmission (104)
The unidirectional transmission device (104) is configured by a conventional unidirectional clutch or a transmission device that rotates in only one direction, but the other direction is an idle transmission, and one end is on the input side (101). The other end is connected to the passive rotating part of the flexible transmission (103),
With the structure described above, rotational kinetic electrical energy is transmitted from the input side (101) to the output side (102) through the flexibility of non-rigid transmission, and conversely, from the output side (102) to the unidirectional transmission device (104 ) Through which the kinetic energy of the rotation fed back to the input side (101) performs rigid transmission without a difference in rotation, and its application device. It is a dual coupling constructed by combining an eddy current coupling with a flexible coupling function with a unidirectional transmission,
The input side (201) is composed of a shaft shape, a wheel shape, a disk shape, or other various rotational kinetic energy transmission structures, and is connected to one side of the unidirectional transmission device (204) for eddy current coupling. Connected to the spontaneous rotation part of the spontaneous rotation part (2031),
The output side (202) is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures, and is connected to the passive rotating portion (2032) of the eddy current coupling to transmit in a single direction. Connected to the other side of the device (204),
The eddy current coupling (203) is selected because it has two types of structures, and a structure that forms a magnetic field by exciting a coil with a permanent magnet or current is used as a spontaneous rotating part (2031) of the eddy current coupling. However, an eddy current conductor constitutes a passive rotating part (2032) of eddy current coupling, or has another same function, the structure of the magnetic field is fixed, and a rotatable intermediate magnet Including an eddy current coupling structure provided with a path, and the structure of the intermediate magnetic path is a spontaneous rotating part (2031) of the eddy current coupling, and the passive rotating part (2032) of the eddy current coupling with an eddy current conductor. ), When the spontaneous rotating part (2031) of the eddy current coupling is driven to rotate on the input side (201), the relative rotational speed difference according to the change of load through the eddy current effect Then, the passive rotating part (2032) of the eddy current coupling is interlocked with the flexible transmission to drive the output side, and the spontaneous rotating part (2031) of the eddy current coupling is connected to the input side (201 ) And the connection of the passive rotating part (2032) of the eddy current coupling with the output side (202), and the spontaneous rotating part (2031) of the eddy current coupling with the output side (202). And the relationship of connecting the passive rotating part (2032) of the eddy current coupling to the input side (201),
The unidirectional transmission device (204) is configured by a conventional unidirectional clutch or a transmission device that rotates by rotating in only one direction, and the other direction is idle, and one end thereof is connected to the input side (201). The dual coupling according to claim 1, wherein the other end is connected to a passive rotating part (2032) of the eddy current coupling. It is a dual coupling constructed by combining an eddy current coupling with a flexible coupling function with a unidirectional transmission,
The input side (301) is composed of a shaft shape, a wheel shape, a disk shape, or other various rotational kinetic energy transmission structures, and is connected to one side of a unidirectional transmission device (304) for spontaneous fluid coupling. Connected to the central rotating part (3031),
The output side (302) is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures, and is connected to the passive rotating portion (3032) of the fluid coupling to transmit a unidirectional transmission device. (304) Connect to the other side,
The fluid coupling (303) connects the spontaneous rotation part (3031) of the fluid coupling with the vane that generates the moving flow stress to the input side (301), and the passive of the fluid coupling that is driven by the fluid stress. When the spontaneous rotation part (3031) of the fluid coupling is driven and rotated by the input side (401), the kinetic energy is transmitted using gas or liquid as a transmission medium. , Thereby producing a relative rotational speed difference according to a change in load, performing a flexible transmission to drive the passive rotating part (3032) and the output side (302) of the fluid coupling, The connection of the spontaneous rotation part (3031) to the input side (301) and the passive rotation part (3032) of the fluid coupling to the output side (302) The connection is changed to a relationship in which the spontaneous rotation part (3031) of the fluid coupling is connected to the output side (302) and a relation in which the passive rotation part (3032) of the fluid coupling is connected to the input side (301). Well,
The unidirectional transmission device (304) is configured by a conventional unidirectional clutch or a transmission device that rotates by rotating in only one direction and the other direction is an idle rotation, and one end thereof is connected to the input side (301). The dual coupling according to claim 1, wherein the other end is connected to a passive rotating part (3032) of the fluid coupling. It is a dual coupling constructed by combining an eddy current coupling with a flexible coupling function with a unidirectional transmission,
The input side (401) is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures, and is connected to one side of the unidirectional transmission device (404) to Connected to the spontaneous rotation part (4031),
The output side (402) is composed of a shaft shape, a wheel shape, a disk shape or other various rotational kinetic energy transmission structures, and is connected to the passive rotating portion (4032) of the power generation effect coupling to transmit in a single direction. Connected to the other side of the device (404),
The power generation effect coupling (403) comprises a spontaneous rotation part (4031) of a power generation effect coupling by a magnetic field formed by exciting a coil with a permanent magnet or an electric current, and a power generation effect cup with an electric pivot that rotates relative to the power generation coupling. The passive rotating part (4032) of the ring is configured, the spontaneous rotating part (4031) of the power generation coupling is connected to the input side (401), and the passive rotating part (4032) of the power generation coupling is output. Connected to the side (402), both control power generation power output from the power generation coupling (403) to the load (406) by the power generation load control device (405), and the power generation coupling on the input side (401). When the voluntary rotating part (4031) is driven to rotate, a relative rotational speed difference is generated according to a change in the load, and the non-rigid flexible and power generation effect coupling By driving the dynamic rotating part (4032), it drives to the output side (402) and outputs it, and the relation of connecting the spontaneous rotating part (4031) of the power generation effect coupling to the input side (401) and power generation The relationship of connecting the passive rotation part (4032) of the power coupling to the output side (402), the relationship of connecting the spontaneous rotation part (4031) of the power generation coupling to the output side (402), and the power generation coupling. The passive rotation part (4032) of the above may be changed to a relationship connecting to the input side (401),
The unidirectional transmission device (404) is configured by a conventional unidirectional clutch or a transmission device that rotates by rotating in only one direction, but the other direction is idle, and one end thereof is the input side (401). The other end is connected to the passive rotating part (4032) of the power generation coupling,
The power generation load control device (405) is constituted by a mechanical or solid electronic electric circuit, and controls the power generated by the power generation effect coupling (403).
The dual cup according to claim 1, wherein the load (406) comprises a load that moves the load with electric resistance or other electric energy, and serves as a power generation load of the power generation effect coupling (403). Ring and its application equipment. Add a controllable clutch on the output side, perform mixing control with a dual coupling with flexibility and rigidity and its application device,
The input side (101) is composed of a shaft shape, a wheel shape, a disk shape, or other various rotational kinetic energy transmission structures, and is connected to one side of the unidirectional transmission device (104) to provide a flexible transmission device ( 103) voluntary rotating part,
The output side (102) is composed of a shaft shape, wheel shape, disk shape, or other various rotational kinetic energy transmission structures, and is connected to the passive rotating portion of the flexible transmission device (103) to transmit in a single direction. Connected to the other side of the device (104),
The flexible transmission device (103) has an eddy current coupling, a fluid coupling, a power generation coupling, or a spontaneous rotating portion and a passive rotating portion, both of which have a rotational difference according to a change in load, and a non-rigid rotational motion. It is composed of a coupling that generates energy or a transmission that has a similar function, and the spontaneous rotation unit is connected to the output side (101), the passive rotation unit is connected to the output side, and a unidirectional transmission device Connected to one end of (104),
The unidirectional transmission device (104) is constituted by a conventional unidirectional clutch or a transmission device that rotates only in one direction, but the other direction is idle, and one end thereof is the input side (101). The other end is connected to the passive rotating part of the flexible transmission (103),
The controllable clutch 501 is controlled by human force, mechanical force, electromagnetic force, or flow response force, and the transmission side is closed and separated and disconnected, so that the input side (101) has a transmission relationship to the outside. The control side or the output side (102) controls the transmission relationship to the outside, and the controllable clutch 501 is provided on the input side (101) or the output side (102) as necessary. 2. The dual coupling according to 1, and an application device thereof.

Images