JP7091888B2 - Actuator device - Google Patents

Description

The present disclosure relates to an actuator device using an actuator member that deforms based on changes in electrical, photon, chemical, thermal, and other energetic states.

Conventionally, as an actuator member of this type, the actuator member described in Patent Document 1 is known. The actuator member described in Patent Document 1 has a structure in which a single polymer fiber is pre-twisted or a structure in which a plurality of polyma fibers are pre-twisted, and has a characteristic of being deformed by a temperature change based on electric heating or white heating. is doing.

Japanese Unexamined Patent Publication No. 2016-42783

When the actuator member described in Patent Document 1 is once heated and then naturally cooled, the actuator member is deformed in the direction opposite to the deformation direction at the time of heating. That is, the actuator member is deformed based on the change in the state of its thermal energy. If torque can be applied to an arbitrary actuated portion by utilizing the deformation of the actuator member, the actuated portion can be rotationally displaced.

The present disclosure has been made in view of such circumstances, and an object thereof is to provide an actuator device capable of applying torque to a driven portion by using an actuator member that deforms based on a change in energy state. To do.

The actuator device (10) for solving the above problems includes an actuator member (51, 52), a support member (21, 22), a actuated portion (30 ) , an energy adjusting portion (61, 62), and an energy adjusting unit (61, 62 ) . To prepare for. The actuator member is formed in a fibrous shape and is deformed in a direction along a central axis based on a change in energy state. The support member is formed in a rod shape around a predetermined axis. The actuated portion is supported by a support member. The energy adjusting unit adjusts the energy state of the actuator member. The support member is made of an elastic material that is elastically twisted and deformed in the circumferential direction about a predetermined axis based on the deformation of the actuator member. The actuator member is spirally wound around the support member, and when the support member is deformed in a direction along the central axis, the support member is twisted and deformed in the circumferential direction around the predetermined axis to be centered on the predetermined axis. A torque in the circumferential direction is applied to the actuated portion.
Further, other actuator devices (10) for solving the above problems include an actuator member (51, 52), a support member (21, 22,), a actuated portion (30), and an energy adjusting portion (63, 64). And. The actuator member is formed in a fibrous shape and is deformed in a direction along a central axis based on a change in energy state. The support member is formed in a rod shape around a predetermined axis. The actuated portion is supported by a support member. The energy adjusting unit adjusts the energy state of the actuator member. The support member is made of a conductive elastic material that is elastically twisted and deformed in the circumferential direction about a predetermined axis based on the deformation of the actuator member and generates heat based on the supply of electric energy. The actuator member is deformed based on a change in the state of thermal energy, and is spirally wound around the support member. When the actuator member is deformed in a direction along the central axis, the support member is centered on a predetermined axis. By twisting and deforming in the circumferential direction, torque in the circumferential direction around a predetermined axis is applied to the actuated portion. The energy adjusting unit indirectly adjusts the state of the thermal energy of the actuator member by supplying electric energy to the support member.

According to this configuration, when the energy state of the actuator member is adjusted by the energy adjusting unit and the energy state of the actuator member changes, the actuator member is deformed in the direction along the central axis. At this time, since the actuator member is spirally wound around the support member, the actuator member as a whole is deformed in the spiral direction about a predetermined axis. By utilizing this deformation in the spiral direction of the actuator member, it is possible to apply torque in the circumferential direction about a predetermined axis to the actuated portion.

The reference numerals in parentheses described in the above means and claims are examples showing the correspondence with the specific means described in the embodiments described later.

According to the present disclosure, it is possible to provide an actuator device capable of applying torque to a driven portion by using an actuator member that deforms based on a change in energy state.

FIG. 1 is a diagram schematically showing the structure of the actuator device of the first embodiment. FIG. 2 is a cross-sectional view showing a cross-sectional structure taken along the line II-II of FIG. FIG. 3 is a block diagram showing an electrical configuration of the actuator device of the first embodiment. FIG. 4 is a diagram schematically showing the structure of the first modification of the actuator device of the first embodiment. FIG. 5 is a diagram schematically showing the structure of a second modification of the actuator device of the first embodiment. FIG. 6 is a block diagram showing an electrical configuration of the actuator device of the second embodiment. FIG. 7 is a diagram schematically showing the structure of the actuator device of the third embodiment. FIG. 8 is a cross-sectional view showing a cross-sectional structure along the line VIII-VIII of FIG. FIG. 9 is a diagram schematically showing the structure of the actuator device of the fourth embodiment. FIG. 10 is a diagram schematically showing the structure of the actuator device of the first modification of the fourth embodiment. FIG. 11 is a diagram schematically showing the structure of the actuator device of the second modification of the fourth embodiment. FIG. 12 is a diagram schematically showing the structure of the actuator device of the fifth embodiment. FIG. 13 is a block diagram showing an electrical configuration of the actuator device of the fifth embodiment. FIG. 14 is a diagram schematically showing the structure of the actuator device of another embodiment. FIG. 15 is a diagram schematically showing the structure of the actuator device of another embodiment. FIG. 16 is a diagram schematically showing the structure of the actuator device of another embodiment.

Hereinafter, an embodiment of the actuator device will be described with reference to the drawings. In order to facilitate understanding of the description, the same components are designated by the same reference numerals as possible in the drawings, and duplicate description is omitted.
<First Embodiment>
First, a first embodiment of the actuator device will be described. As shown in FIG. 1, the actuator device 10 of the present embodiment includes support members 21 and 22, actuated portions 30, holding members 41 and 42, and actuator members 51 and 52.

The support members 21 and 22 are made of rod-shaped members formed in a columnar shape about a predetermined axis m1. The support members 21 and 22 are made of an elastic material. Elastomer is used as the material of the support members 21 and 22 of the present embodiment. It is also possible to use nylon, rubber, or the like as the material of the support members 21 and 22.

One end portion 21a of the first support member 21 is fixed to one side surface 30a of the actuated portion 30 formed in a cubic shape or a rectangular parallelepiped shape. The other end 21b of the first support member 21 is fixed to a first holding member 41 assembled to a housing or the like (not shown). One end portion 22a of the second support member 22 is fixed to the other side surface 30b of the actuated portion 30. The other side surface 30b is a side surface opposite to one side surface 30a to which one end portion 21a of the first support member 21 is fixed in the actuated portion 30. The other end 22b of the second support member 22 is fixed to a second holding member 42 assembled to a housing or the like (not shown). The support members 21 and 22 support the actuated portion 30. Further, the supported members 21 and 22 are elastically twisted and deformed in the circumferential direction about the axis m1 so that the actuated portion 30 can be rotated. That is, the support members 21 and 22 rotatably support the actuated portion 30 in the circumferential direction about the axis m1.

A sensor device 31 is fixedly provided on the actuated portion 30. The sensor device 31 is a device that detects a predetermined physical quantity such as an infrared sensor.
The first actuator member 51 is composed of a fibrous elongated member spirally wound around the outer peripheral surface of the first support member 21. The first actuator member 51 is made of a non-twisted member that is not twisted in the circumferential direction about the central axis m10. The one end portion 51a of the first actuator member 51 is fixed to the outer peripheral surface of the one end portion 21a of the first support member 21. The other end 51b of the first actuator member 51 is fixed to the outer peripheral surface of the other end 21b of the first support member 21. Regarding the first actuator member 51, an intermediate portion from one end portion 51a to the other end portion 51b may be fixed to the outer peripheral surface of the first support member 21.

The second actuator member 52 is composed of an elongated fibrous member spirally wound around the outer peripheral surface of the second support member 22. The second actuator member 52 is also made of a non-twisted member that is not twisted in the circumferential direction about the central axis m20. The one end 52a of the second actuator member 52 is fixed to the outer peripheral surface of the one end 22a of the second support member 22. The other end 52b of the second actuator member 52 is fixed to the outer peripheral surface of the other end 22b of the second support member 22. Regarding the second actuator member 52, an intermediate portion from one end portion 52a to the other end portion 52b may be fixed to the first support member 21.

The actuator members 51 and 52 are formed of a material that deforms in a direction along the central axes m10 and m20 based on a change in energy state. Specifically, the actuator members 51 and 52 are formed of polymer fibers such as polyamide that are deformed based on changes in the state of their thermal energy.

When the first actuator member 51 transitions from the low temperature state to the high temperature state by being heated, the first actuator member 51 contracts in the direction along the central axis m10, that is, in the spiral direction, as compared with the case of the low temperature state. Due to the contraction deformation of the first actuator member 51 in the spiral direction, the torque in the circumferential direction C1 centered on the axis m1 is applied to the first support member 21 to which the first actuator member 51 is fixed, so that the first support The member 21 is elastically twisted and deformed in the circumferential direction C1. As a result, the torque in the circumferential direction C1 is applied to the actuated portion 30 fixed to the one end portion 21a of the first support member 21, so that the actuated portion 30 and the sensor device 31 are moved from the reference position shown in FIG. It rotates in the circumferential direction C1. At this time, the second actuator member 52 elastically twists and deforms in the circumferential direction C1 following the actuated portion 30, so that the actuated portion 30 is allowed to rotate in the circumferential direction C1. As a result, the actuated portion 30 and the sensor device 31 rotate to the first set position P1 shown by the alternate long and short dash line, which is deviated from the reference position P0 shown by the solid line in FIG. 2 by a predetermined angle θ1 in the circumferential direction C1. ..

Further, when the first actuator member 51 transitions from the high temperature state to the low temperature state due to natural cooling or the like, the first actuator member 51 expands in the direction along the central axis m10 and returns to the original state. That is, since the torque applied to the first support member 21 from the first actuator member 51 disappears, the first support member 21 elastically deforms and returns to the original state. As a result, the actuated portion 30 and the sensor device 31 return to the reference position P0.

Similarly, when the second actuator member 52 also transitions from the low temperature state to the high temperature state, the second actuator member 52 also contracts in the spiral direction along the central axis m20. Due to the contraction deformation of the second actuator member 52 in the spiral direction, the torque in the circumferential direction C2 centered on the axis m1 is applied to the second support member 22 to which the second actuator member 52 is fixed, so that the second actuator member 52 is second. The support member 22 is elastically twisted and deformed in the circumferential direction C2. The circumferential direction C2 is the direction opposite to the direction of the torque applied from the first actuator member 51 to the first support member 21. When the second support member 22 is twisted and deformed in the circumferential direction C2, the torque in the circumferential direction C2 is applied to the actuated portion 30 fixed to one end portion 22a of the second support member 22, so that the actuated portion 30 and the actuated portion 30 The sensor device 31 rotates in the circumferential direction C2 from the reference position shown in FIG. As a result, the actuated portion 30 and the sensor device 31 rotate to the second set position P2 shown by the alternate long and short dash line, which is deviated from the reference position P0 shown by the solid line in FIG. 2 by a predetermined angle θ2 in the circumferential direction C2. .. Further, when the second actuator member 52 is expanded from the high temperature state to the low temperature state due to natural cooling or the like, the second support member 22 returns to the original state, so that the actuated portion 30 and the actuated portion 30 and the actuated portion 30 The sensor device 31 returns to the reference position P0.

Next, the electrical configuration of the actuator device 10 will be described.
As shown in FIG. 3, the actuator device 10 includes a first heating device 61, a second heating device 62, and an ECU (Electronic Control Unit) 70.

The heating devices 61 and 62 are devices for heating the actuator members 51 and 52, respectively. The heating devices 61 and 62 include, for example, coils arranged so as to cover the periphery of the actuator members 51 and 52, and heat the actuator members 51 and 52 by generating heat based on the energization of the coils. In the present embodiment, the heating devices 61 and 62 correspond to the energy adjusting unit that adjusts the state of the thermal energy of the actuator members 51 and 52.

The ECU 70 is mainly composed of a microcomputer having a CPU, ROM, RAM, and the like. The ECU 70 executes a program stored in advance in the ROM to drive the heating devices 61 and 62, thereby executing position control for changing the position of the sensor device 31.
Specifically, when the position of the sensor device 31 is changed in the circumferential direction C1, the ECU 70 transmits a control signal to the first heating device 61 to drive the first heating device 61, thereby driving the first actuator member. 51 is heated. At this time, the ECU 70 controls the heating amount of the first actuator member 51 by including the indicated value of the heating amount of the first actuator member 51 in the control signal. Further, when the sensor device 31 is returned to the reference position P0, the ECU 70 naturally cools the first actuator member 51 by stopping the first heating device 61. Through such thermal energy control of the first actuator member 51, the ECU 70 displaces the sensor device 31 to an arbitrary position in the range from the reference position P0 shown in FIG. 2 to the first set position P1.

Further, the ECU 70 performs the same thermal energy control on the second actuator member 52 through the second heating device 62, so that the sensor device 31 is moved from the reference position P0 shown in FIG. 2 to the second set position P2. Displace to any position in the range.
According to the actuator device 10 of the present embodiment described above, the actions and effects shown in the following (1) and (2) can be obtained.

(1) When the state of the thermal energy of the actuator members 51 and 52 is changed by the heating devices 61 and 62 and the actuator members 51 and 52 are deformed in the direction along the central axes m10 and m20, the entire actuator members 51 and 52 are along the axis. It deforms in the spiral direction centered on m1. The support members 21 and 22 are elastically twisted and deformed in the circumferential directions C1 and C2 by the force applied to the support members 21 and 22 based on the deformation of the actuator members 51 and 52, so that the actuated portion 30 is subjected to the circumferential directions C1 and C2. Rotate to. That is, by utilizing the deformation of the actuator members 51 and 52 in the spiral direction, the torques in the circumferential directions C1 and C2 can be applied to the actuated portion 30.

(2) In order to apply a larger torque to the actuated portion 30, it is necessary to increase the orientation angles φ1 and φ2 of the actuator members 51 and 52 with respect to the central axis m1 of the spiral shown in FIG. As shown in FIG. 1, the orientation angles φ1 and φ2 are acute angles formed by the central axes m10 and m20 of the actuator member with respect to the central axis m1 of the spiral, and are equal to the so-called spiral angle. Since the actuator member described in Patent Document 1 has a structure in which polymer fibers are twisted in advance, if the actuator member is further spirally deformed so that the orientation angle becomes large, the actuator member may be damaged. That is, it is difficult to increase the orientation angle of the actuator member described in Patent Document 1 from the viewpoint of strength, and as a result, it is difficult to apply sufficient torque to the actuated portion. In this respect, since the actuator members 51 and 52 of the present embodiment are untwisted members that are not twisted in the circumferential direction around the central axes m10 and m20, the orientation angles φ1 and φ2 of the actuator members 51 and 52 are φ2. Can be increased. Therefore, the torque applied to the actuated portion 30 can be increased. Further, if the orientation angles φ1 and φ2 can be increased, the torque generation amount of the actuator members 51 and 52 per unit length in the direction along the central axis m1 can be increased. Therefore, since the total length of the actuator device 10 in the direction along the central axis m1 can be shortened, it is possible to reduce the dead space required when mounting the actuator device 10 on the subassembly.

(First modification)
Next, a first modification of the actuator device 10 of the first embodiment will be described.
As shown in FIG. 4, on one side surface 30a of the actuated portion 30 of this modification, one end portion 23a of a shaft member 23 made of metal or the like is provided instead of the first support member 21 and the first actuator member 51. It is fixed. The other end 23b of the shaft member 23 is rotatably supported by a bearing 80 provided on the first holding member 41. Therefore, in the actuator device 10 of this modification, the actuator member 52 is wound only around the support member 22 fixed to one side surface 30b of the actuated portion 30.

According to the actuator device 10 of this modification, the torque in the circumferential direction C2 can be applied to the actuated portion 30 by heating the actuator member 52 by the heating device 62. Further, the torque in the circumferential direction C1 can be applied to the actuated portion 30 by stopping the heating device 62 and naturally cooling the actuator member 52. Therefore, it is possible to obtain an action and effect similar to those of the actuator device 10 of the first embodiment.

(Second modification)
Next, a second modification of the actuator device 10 of the first embodiment will be described.
As shown in FIG. 5, in the actuator device 10 of the present modification, the winding direction of the first actuator member 51 with respect to the first support member 21 is opposite to the winding direction of the first embodiment. Therefore, when the first actuator member 51 is heated by the first heating device 61 and the first actuator member 51 is contracted and deformed, torque in the circumferential direction C2 is applied to the actuated portion 30 and the sensor device 31. That is, in the actuator device 10 of this modification, the direction of the torque applied to the actuated portion 30 and the sensor device 31 due to the contraction deformation of the first actuator member 51 and the actuated portion 30 and the sensor due to the contraction deformation of the second actuator member 52. The direction of the torque applied to the device 31 is the same.

According to such a configuration, even if either one of the first actuator member 51 and the second actuator member 52 is damaged for some reason, the actuated portion 30 and the sensor device 31 are used by using the other undamaged actuator member. Can be torqued. That is, it is possible to redundantly design the means for displacing the actuated portion 30 and the sensor device 31.

<Second Embodiment>
Next, a second embodiment of the actuator device 10 will be described. Hereinafter, the differences from the actuator device 10 of the first embodiment will be mainly described.
In the actuator device 10 of the present embodiment, the first support member 21 and the second support member 22 are made of a conductive elastic material capable of generating heat by energization. As the conductive elastic material, for example, a conductive elastomer can be used.

As shown in FIG. 6, the actuator device 10 includes a first energizing device 63 for energizing the first support member 21 and a second energizing device 64 for energizing the second support member 22. .. When the first support member 21 is energized by the first energizing device 63, the first support member 21 generates heat. When the heat of the first support member 21 is transferred to the first actuator member 51, the first actuator member 51 contracts and deforms, and torque in the circumferential direction C1 is applied to the actuated portion 30 and the sensor device 31. ..

Similarly, when the second support member 22 is energized by the second energizing device 64, the second support member 22 generates heat. When the heat of the second support member 22 is transferred to the second actuator member 52, the second actuator member 52 contracts and deforms, and torque in the circumferential direction C2 is applied to the actuated portion 30 and the sensor device 31. ..

As described above, in the present embodiment, the energizing devices 63 and 64 correspond to the energy adjusting unit that indirectly adjusts the state of the thermal energy of the actuator members 51 and 52 by supplying electric energy to the support members 21 and 22. do.
The ECU 70 controls the energization amount of the first actuator member 51 by transmitting a control signal including an instruction value of the energization amount of the first support member 21 to the first energization device 63. Similarly, the ECU 70 controls the energization amount of the second actuator member 52 by transmitting a control signal including the indicated value of the energization amount of the second support member 22 to the second energization device 64. Through such energization control, the ECU 70 displaces the sensor device 31 to an arbitrary position in the range from the first set position P1 to the second set position P2 shown in FIG.

According to the actuator device 10 of the present embodiment described above, in addition to the action and effect shown in (2) above, the action and effect shown in (3) below can be further obtained.
(3) The state of the thermal energy of the actuator members 51 and 52 is indirectly adjusted by the electric energy applied to the support members 21 and 22 from the energizing devices 63 and 64. When the state of the thermal energy of the actuator members 51 and 52 changes and the actuator members 51 and 52 are deformed in the direction along the central axes m10 and m20, the entire actuator members 51 and 52 are deformed in the spiral direction centered on the axis m1. do. The support members 21 and 22 are elastically twisted and deformed in the circumferential directions C1 and C2 by the force applied to the support members 21 and 22 based on the deformation of the actuator members 51 and 52, so that the actuated portion 30 is subjected to the circumferential directions C1 and C2. Rotate to. That is, by utilizing the deformation of the actuator members 51 and 52 in the spiral direction, the torques in the circumferential directions C1 and C2 can be applied to the actuated portion 30.

<Third Embodiment>
Next, a third embodiment of the actuator device 10 will be described. Hereinafter, the differences from the actuator device 10 of the first embodiment will be mainly described.
As shown in FIG. 7, the actuator device 10 of the present embodiment includes a support member 24 instead of the support members 21 and 22 of the first embodiment. The support member 24 is formed in a columnar shape centered on the axis m1. As shown in FIG. 8, the actuated portion 30 is formed with an insertion hole 30c penetrating from one side surface 30a to the other side surface 30b. A support member 24 is inserted through the insertion hole 30c. Bearings 32 and 33 are provided between the inner peripheral surface of the actuated portion 30 and the outer peripheral surface of the support member 24. The actuated portion 30 is rotatably supported in the circumferential directions C1 and C2 with respect to the support member 24 by these bearings 32 and 33.

The support member 24 is made of a material capable of reducing the frictional force generated between the support member 24 and the actuator members 51 and 52. As the material of the support members 21 and 22 of the present embodiment, metal is adopted. As a result, the actuator members 51 and 52 can be contracted and stretched while sliding on the outer peripheral surfaces of the support members 21 and 22.

As shown in FIG. 7, one end portion 51a of the first actuator member 51 is fixed to one side surface 30a of the actuated portion 30. Further, the other end 21b of the first actuator member 51 is fixed to the first holding member 41. Similarly, one end 52a of the second actuator member 52 is fixed to the other side surface 30b of the actuated portion 30. Further, the other end 52b of the second actuator member 52 is fixed to the second holding member 42. In the present embodiment, the holding members 41 and 42 correspond to members different from the actuated portion 30.

In the actuator device 10 of the present embodiment, when the first actuator member 51 is heated by the first heating device 61 and the first actuator member 51 contracts in the spiral direction, the side surface 30a of the actuated portion 30 is in the circumferential direction. The torque of C1 is directly applied. Due to this torque, the actuated portion 30 and the sensor device 31 rotate in the circumferential direction C1. Further, when the heating of the first actuator member 51 by the first heating device 61 is stopped and the first actuator member 51 is cooled by natural cooling or the like, the first actuator member 51 expands in the spiral direction and is therefore actuated. The unit 30 and the sensor device 31 return to the reference position P0.

Similarly, when the second actuator member 52 is heated by the second heating device 62 and the second actuator member 52 contracts in the spiral direction, the torque in the circumferential direction C2 is directly applied to the other side surface 30b of the actuated portion 30. Is given to. Due to this torque, the actuated portion 30 and the sensor device 31 rotate in the circumferential direction C2. Further, when the heating of the second actuator member 52 by the second heating device 62 is stopped and the first actuator member 51 is cooled by natural cooling or the like, the second actuator member 52 expands in the spiral direction and is therefore actuated. The unit 30 and the sensor device 31 return to the reference position P0.

According to the actuator device 10 of the present embodiment described above, in addition to the action and effect shown in (2) above, the action and effect shown in (4) below can be obtained.
(4) When the state of the thermal energy of the actuator members 51 and 52 is changed by the heating devices 61 and 62 and the actuator members 51 and 52 are deformed in the direction along the central axes m10 and m20, the entire actuator members 51 and 52 are along the axis. It deforms in the spiral direction centered on m1. Based on the deformation of the actuator members 51 and 52, the actuated portion 30 rotates in the circumferential directions C1 and C2. That is, by utilizing the deformation of the actuator members 51 and 52 in the spiral direction, the torques in the circumferential directions C1 and C2 can be applied to the actuated portion 30. Further, torque can be directly applied to the actuated portion 30 from the actuator members 51 and 52. Therefore, a larger torque is applied to the actuated portion 30 as compared with the case where the torque is indirectly applied from the actuator members 51 and 52 to the actuated portion 30 via the support members 21 and 22 as in the actuator device 10 of the first embodiment. It is possible to give it to the department.

<Fourth Embodiment>
Next, a fourth embodiment of the actuator device 10 will be described. Hereinafter, the differences from the actuator device 10 of the first embodiment will be mainly described.
In the case of a configuration in which the first actuator member 51 is heated by the heat generated from the first support member 21, as in the actuator device 10 of the second embodiment, when the first actuator member 51 contracts and deforms due to the heating, the first actuator member 51 is first. The inner peripheral surface of the actuator member 51 is pressed against the outer peripheral surface of the first support member 21. As a result, the contact area between the first actuator member 51 and the first support member 21 increases, and as a result, the heat transfer area of the first actuator member 51 with respect to the first support member 21 increases. Therefore, since the amount of heat input to the first actuator member 51 with respect to the first support member 21 increases, the contraction deformation of the first actuator member 51 may be promoted. This causes a factor that lowers the control accuracy of the deformation amount of the first actuator member 51, so that the control accuracy of the rotational position of the actuated portion 30 may deteriorate. Such a problem may occur in the second actuator member 52 as well.

Therefore, in the actuator device 10 of the present embodiment, by adopting a configuration in which the actuator members 51 and 52 are heated from the outer peripheral portions, the inner peripheral portions of the actuator members 51 and 52 are less likely to be pressed against the support members 21 and 22. I have to.
Specifically, as shown in FIG. 9, in the actuator device 10 of the present embodiment, the first heating device 61 that heats the first actuator member 51 from the outer peripheral side and the second actuator member 52 are heated from the outer peripheral side. The second heating device 62 is provided. The first heating device 61 and the second heating device 62 are controlled by the ECU 70 as shown in FIG.

According to the actuator device 10 of the present embodiment described above, the operation and effect shown in the following (5) can be further obtained.
(5) The first heating device 61 heats the outer peripheral portion of the first actuator member 51. According to such a configuration, the temperature of the outer peripheral portion of the first actuator member 51 heated by the first heating device 61 tends to rise. On the other hand, since the inner peripheral portion of the first actuator member 51 is in contact with the first support member 21, the heat of the inner peripheral portion of the first actuator member 51 is dissipated to the first support member 21. As a result, when the first actuator member 51 is deformed, the temperature of the first actuator member 51 becomes higher than the temperature of the first support member 21. As a result, in the first actuator member 51, the amount of contraction deformation of the inner peripheral portion thereof is smaller than the amount of contraction deformation of the outer peripheral portion thereof. Therefore, since the inner peripheral surface of the first actuator member 51 is less likely to be pressed against the outer peripheral surface of the first support member 21, it is possible to suppress an increase in the heat transfer area of the first actuator member 51 with respect to the first support member 21. .. That is, since the amount of heat input from the first support member 21 to the first actuator member 51 is unlikely to change, it is possible to accurately control the amount of deformation of the first actuator member 51. Similar actions and effects can be obtained with respect to the second actuator member 52.

(First modification)
Next, a first modification of the actuator device 10 of the fourth embodiment will be described.
As shown in FIG. 10, in the actuator device 10 of this modification, a plurality of heat radiation fins 101 are formed on the outer peripheral portion of the other end portion 21b of the first support member 21. Further, a plurality of heat radiation fins 102 are also formed on the outer peripheral portion of the other end portion 22b of the second support member 22.

According to such a configuration, the heat radiation of the first support member 21 can be promoted by the heat radiation fin 101, and as a result, the amount of shrinkage deformation of the inner peripheral portion of the first actuator member 51 can be further reduced. .. As a result, the amount of heat input from the first support member 21 to the first actuator member 51 is less likely to change, so that the amount of deformation of the first actuator member 51 can be controlled more accurately.

Further, since the heat radiation fin 102 can promote the heat radiation of the second support member 22, the same operation and effect can be obtained for the second actuator member 52.
(Second modification)
Next, a second modification of the actuator device 10 of the fourth embodiment will be described.

As shown in FIG. 11, in the actuator device 10 of the present modification, the other end portion 21b of the first support member 21 is in contact with the first cooling portion 121 provided on the first holding member 41. The first cooling unit 121 cools the first holding member 41. As the first cooling unit 121, for example, a Pelche element that cools the first holding member 41 by energization, or a cooling water circulation mechanism that cools the first holding member 41 by the cooling water flowing inside can be used. Further, the other end 22b of the second support member 22 is also in contact with the second cooling portion 122 provided on the second holding member 42.

According to such a configuration, heat dissipation of the first support member 21 can be further promoted, and as a result, the amount of shrinkage deformation of the inner peripheral portion of the first actuator member 51 can be further reduced. As a result, the amount of heat input from the first support member 21 to the first actuator member 51 is less likely to change, so that the amount of deformation of the first actuator member 51 can be controlled more accurately.

Further, since the second cooling unit 122 can promote the heat dissipation of the second support member 22, the same operation and effect can be obtained for the second actuator member 52.
<Fifth Embodiment>
Next, a fifth embodiment of the actuator device 10 will be described. Hereinafter, the differences from the actuator device 10 of the second embodiment will be mainly described.

As shown in FIG. 12, the actuator device 10 of the present embodiment includes a first temperature sensor 111 provided on the first actuator member 51 and a second temperature sensor 112 provided on the second actuator member 52. .. The first temperature sensor 111 detects the temperature of the first actuator member 51 and outputs a signal corresponding to the detected temperature. The second temperature sensor 112 detects the temperature of the second actuator member 52 and outputs a signal corresponding to the detected temperature. In the present embodiment, the first temperature sensor 111 and the second temperature sensor 112 correspond to the temperature detection unit.

As shown in FIG. 13, the output signals of the first temperature sensor 111 and the second temperature sensor 112 are taken in by the ECU 70. The ECU 70 acquires the temperature information of the first actuator member 51 based on the output signal of the first temperature sensor 111, and the first support member from the first energizing device 63 based on the acquired temperature of the first actuator member 51. The amount of energization to the 21 is controlled, specifically, the magnitude of the voltage applied to the first support member 21. For example, this energization control is performed as follows.

The rotation angle θ1 of the sensor device 31 shown in FIG. 2 has a correlation with the amount of torsional deformation of the first support member 21. Further, the torsional deformation amount of the first support member 21 has a correlation with the contraction deformation amount of the first actuator member 51, that is, the temperature of the first actuator member 51. Therefore, the rotation angle θ1 of the sensor device 31 has a correlation with the temperature of the first actuator member 51. In the actuator device 10 of the present embodiment, the relationship between them has been obtained in advance by an experiment or the like, and based on the experimental result, the target rotation angle θ * of the sensor device 31 and the target temperature T * of the first actuator member 51 A first map showing the relationship between the above is created in advance, and the first map is stored in the storage device of the ECU 70.

Further, the temperature of the first actuator member 51 has a correlation with the amount of energization from the first energizing device 63 to the first support member 21. In the actuator device 10 of the present embodiment, the relationship between them has been obtained in advance by an experiment or the like, and based on the experimental result, the target temperature T * of the first actuator member 51 and the energization amount indicated value of the first energizing device 63. A second map showing the relationship with P * is created in advance, and the second map is stored in the storage device of the ECU 70.

The ECU 70 sets the energization amount indicated value P * of the first energization device 63 according to the target rotation angle θ * of the sensor device 31 based on the above first map and the second map. That is, the ECU 70 sets the target temperature T * of the first actuator member 51 based on the first map from the target rotation angle θ * of the sensor device 31. Further, the ECU 70 sets the energization amount instruction value P * of the first energization device 63 based on the second map from the target temperature T * of the first actuator member 51.

On the other hand, the ECU 70 calculates the difference value Δ (T * −T) between the temperature T of the first actuator member 51 and the target temperature T * acquired by the first temperature sensor 111, and the difference value Δ (T * −). The energization amount correction value ΔP corresponding to T) is calculated by an arithmetic formula or the like. The energization amount correction value ΔP is set so as to form a positive correlation with the difference value Δ (T * −T). The ECU 70 controls the energization amount from the first energization device 63 to the first support member 21 by using the value “P * + ΔP” obtained by correcting the energization amount instruction value P * by the energization amount correction value ΔP.

Similarly, the ECU 70 acquires the temperature information of the second actuator member 52 based on the output signal of the second temperature sensor 112, and the second energizing device 64 to the second based on the acquired temperature of the second actuator member 52. 2 The amount of electricity supplied to the support member 22 is controlled.
According to the actuator device 10 of the present embodiment described above, the action and effect shown in the following (6) can be further obtained.

(6) The first actuator member 51 is heated by the heat generated from the first support member 21, the first actuator member 51 contracts and deforms, and the inner peripheral surface of the first actuator member 51 becomes the first support member 21. As described above, when pressed, the heat transfer area of the first actuator member 51 with respect to the first support member 21 increases, so that the temperature of the first actuator member 51 tends to rise. Further, as described above, this is a factor that lowers the control accuracy of the deformation amount of the first actuator member 51. In this regard, according to the actuator device 10 of the present embodiment, the temperature of the first actuator member 51 rises above the target temperature T * due to the increase in the heat transfer area of the first actuator member 51 with respect to the first support member 21. In this case, the amount of energization from the second energizing device 64 to the second support member 22 is corrected so that the temperature rise is canceled. As a result, the temperature of the first actuator member 51 can be accurately controlled to the target temperature T *, so that the amount of deformation of the first actuator member 51 can be accurately controlled. Similar actions and effects can be obtained with respect to the second actuator member 52.

<Other embodiments>
In addition, each embodiment can also be carried out in the following embodiments.
In the actuator device 10 of the first embodiment, the first support member 21 is twisted and deformed by the frictional force acting between the first actuator member 51 and the first support member 21 when the first actuator member 51 contracts. If possible, the first actuator member 51 may not be fixed to the first support member 21. Similarly, the second actuator member 52 may not be fixed to the second support member 22.

-In the actuator device 10 of the third embodiment, the configuration of the actuator device 10 of the second embodiment may be adopted as a configuration for heating the actuator members 51 and 52.
As shown in FIG. 14, a heat diffusion layer 24c for increasing the heat transfer efficiency of the actuator members 51 and 52 may be provided on the outer peripheral surface of the support member 24 of the third embodiment. Similarly, a heat diffusion layer may be provided on the outer peripheral surfaces of the support members 21 and 22 of the first embodiment and the second embodiment, respectively.

In the actuator device 10 of the third embodiment, a gap may be formed between the support member 24 and the first actuator member 51, and between the support member 24 and the second actuator member 52.
In the actuator device 10 of the third embodiment, the actuator members 51 and 52 may be arranged inside the support member 24. Specifically, as shown in FIG. 15, a spiral hole 24d into which the first actuator member 51 is inserted and a spiral hole 24e into which the second actuator member 52 is inserted are inside the support member 24. And may be formed.

-The actuator members 51 and 52 are not limited to the spiral structure, but may have a spiral structure. For example, as shown in FIG. 16, the first actuator member 51 is arranged in a spiral shape on the outer periphery of the first support member 25, and the second actuator member 52 is arranged in a spiral shape on the outer periphery of the second support member 26. .. The first support member 25 is formed in a columnar shape about an axis m2 parallel to the axis m1. The first support member 25 is formed in a columnar shape about an axis m3 parallel to the axis m1. One end 51a of the first actuator member 51 is fixed to one side surface 30d of the actuated portion, and the other end 51b of the first actuator member 51 is fixed to the first support member 25. Further, one end 52a of the second actuator member 52 is fixed to one side surface 30e of the actuated portion, and the other end 52b of the second actuator member 52 is fixed to the second support member 26. Even with such a configuration, it is possible to rotate the actuated portion 30 around the axis m1 due to the contraction deformation of the first actuator member 51 and the second actuator member 52.

-As the material of the actuator members 51 and 52, not only the polymer fiber but also an appropriate material that deforms based on changes in electrical, optical, chemical, thermal, and other energetic states can be used. can. Such materials include, for example, shape memory alloys, dielectric elastomers, magnetic gels, conductive polymers and the like. Further, an appropriate energy adjusting unit other than the heating devices 61 and 62 and the energizing devices 63 and 64 may be used according to the material of the actuator members 51 and 52.

-The present disclosure is not limited to the above specific examples. Specific examples described above with appropriate design changes by those skilled in the art are also included in the scope of the present disclosure as long as they have the characteristics of the present disclosure. Each element included in each of the above-mentioned specific examples, and their arrangement, conditions, shape, and the like are not limited to those exemplified, and can be appropriately changed. The combinations of the elements included in each of the above-mentioned specific examples can be appropriately changed as long as there is no technical contradiction.

10: Actuator device 21, 22, 24: Support member 24c: Heat diffusion layer 30: Operated part 51, 52: Actuator member 61, 62: Heating device (energy adjusting part)
63, 64: Energizer (energy adjustment unit)
70: ECU (control unit)
101, 102: Fins 111, 112: Temperature detection unit 121, 122: Cooling unit

Claims (10)

An actuator member (51, 52) that is formed in a fibrous shape and deforms in a direction along the central axis based on a change in energy state.
Support members (21, 22 ) formed in a rod shape around a predetermined axis, and
The actuated portion (30) supported by the support member and
An energy adjusting unit (61, 62 ) for adjusting the energy state of the actuator member is provided.
The support member is made of an elastic material that elastically twists and deforms in the circumferential direction about the predetermined axis based on the deformation of the actuator member.
The actuator member is spirally wound around the support member, and when the support member is deformed in a direction along the central axis, the support member is twisted and deformed in a circumferential direction about the predetermined axis to determine the predetermined size. An actuator device that applies torque in the circumferential direction centered on the axis of the actuated portion to the actuated portion. The actuator member is deformed based on a change in the state of thermal energy.
The actuator device according to claim 1 , wherein the energy adjusting unit adjusts the thermal energy of the actuator member. The actuator device according to claim 2 , wherein the energy adjusting unit comprises a heating device that heats an outer peripheral portion of the actuator member. The actuator device according to claim 3 , wherein the temperature of the actuator member is higher than the temperature of the support member when the actuator member is deformed in a direction along the central axis. The actuator device according to claim 3 or 4 , wherein fins for heat dissipation are formed on the support member. The actuator device according to any one of claims 3 to 5 , further comprising a cooling unit for cooling the support member. An actuator member (51, 52) that is formed in a fibrous shape and deforms in a direction along the central axis based on a change in energy state.
Support members (21, 22) formed in a rod shape around a predetermined axis, and
The actuated portion (30) supported by the support member and
An energy adjusting unit (63, 64) for adjusting the energy state of the actuator member is provided.
The support member is made of a conductive elastic material that elastically twists and deforms in the circumferential direction around the predetermined axis based on the deformation of the actuator member and generates heat based on the supply of electric energy.
The actuator member is deformed based on a change in the state of thermal energy, and is spirally wound around the support member. When the actuator member is deformed in a direction along the central axis, the support member is deformed. By twisting and deforming in the circumferential direction around the predetermined axis, torque in the circumferential direction around the predetermined axis is applied to the actuated portion.
The energy adjusting unit indirectly adjusts the state of heat energy of the actuator member by supplying electric energy to the support member.
Actuator device. A temperature detection unit that detects the temperature of the actuator member, and
The actuator device according to claim 7 , further comprising a control unit that controls the energy adjusting unit based on the temperature of the actuator member detected by the temperature detecting unit. The actuator device according to any one of claims 2 to 8 , wherein a heat diffusion layer (24c) is provided on the outer peripheral surface of the support member. The actuator device according to any one of claims 1 to 9 , wherein the actuator member is a non-twisted member that is not twisted in the circumferential direction about the central axis thereof.

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