JP2009198645A - Driving module and electronic equipment comprising the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable good driving of a driving module and electronic equipment comprising it even under a high temperature environment and miniaturizing the driving module and electronic equipment. <P>SOLUTION: This driving module 1 includes a support body having a lens frame 4 to which a guide projection 4D is provided, a module under plate 8 which positions the lens frame to a reference position, and a module frame 5 which movably accommodates the lens frame 4, an upper-plate spring 6 and under-plate spring 7 which are fixed extending in the direction orthogonal to the driving direction between the lens frame 4 and the support body and which are arranged in parallel facing to each other in a non-load state, a shape memory alloy wire 10 stretched and laid to the cylindrical outer periphery parts of the module frame 5 and locked at the guide projection 4D at the middle, a compression coil spring 40 provided so as to apply a spring force to the guide projection 4D in the direction to extend the shape memory alloy wire 10 at the end and shape-memorized so as to increase the spring force accompanying the temperature rising, and a cover 11 for supporting the other end. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a drive module and an electronic apparatus including the drive module. For example, the present invention relates to a drive module that is suitable for adjusting the focal position by driving an optical system or a movable member, or using the actuator as an actuator, and an electronic apparatus including the drive module.

2. Description of the Related Art Conventionally, in a small electronic device such as a mobile phone with a camera function, an apparatus using a drive module that drives a driven body such as a photographing lens unit with a shape memory alloy wire is known.
As such a drive module and electronic device, in Patent Document 1, a first lens frame having a lens group assembled thereto, and the first lens frame are fixed and movably attached to a guide shaft along the drive direction. The second lens frame, the shape memory alloy wire that is locked to the second lens frame and contracts when the current is applied and biases the second lens frame in the driving direction, and the second lens frame is shaped A lens driving device including a compression coil spring that urges along a guide shaft to press against a memory alloy wire, and an imaging device including the same are described.
JP 2007-57581 A

However, the conventional drive module as described above has the following problems.
In the lens driving device described in Patent Document 1, a sliding load is generated because the second lens frame is driven using the guide shaft. For example, in order to obtain good driving characteristics such as increasing the focusing speed, it is necessary to reduce the urging force by the compression coil spring that leads to an increase in the driving load of the shape memory alloy wire. Therefore, in Patent Document 1, in a non-energized state of the shape memory alloy wire, the shape memory alloy wire is slightly stretched by the biasing force of the compression coil spring, or the shape memory alloy wire has a slight slack, The protrusion of the second lens frame is brought into contact with the head of the screw so as to be stationary. As a result, at the start of energization, the urging force from the shape memory alloy wire is very small or no urging force is applied, and smooth driving can be performed even if the guide shaft is loaded to some extent. Yes.
By the way, since shape memory alloy has a hysteresis characteristic with respect to the strain amount with respect to temperature, in order to perform accurate driving, it is cooled to the transformation start temperature or lower after each driving and returned to the driving reference position. Therefore, it is necessary to drive in one direction.
In a conventional lens driving device such as Patent Document 1, although the operation works without problems when the environmental temperature is equal to or lower than the transformation start temperature of the shape memory alloy, when the environmental temperature reaches the temperature within the transformation region of the shape memory alloy, The temperature does not fall below the transformation start temperature. For this reason, even when the energization is stopped, the shape memory alloy wire does not extend to the length at the start of driving. The shape memory alloy wire is stretched to some extent by the biasing force of the compression coil spring. However, the biasing force of the compression coil spring becomes very small in the vicinity of the drive reference position, and cannot be fully stretched. Accordingly, there is a problem that accurate driving cannot be performed under a high temperature environment because a position error of the driving reference position occurs.

  The present invention has been made in view of the above problems, and provides a drive module that can perform good driving even in a high-temperature environment and can be downsized, and an electronic apparatus including the drive module. Objective.

In order to solve the above-described problems, in the invention described in claim 1, the object is provided with a protrusion that protrudes to the side of the columnar body, the columnar body having an axis line arranged along the driving direction. A driver,
A support body having an abutting support portion for positioning the driven body at a reference position in the driving direction, and a cylindrical portion that movably accommodates the driven body in the driving direction; and the driven body A pair of parallel leaf springs that are attached to extend in a direction perpendicular to the driving direction between the support plate and the support member, and are arranged to face each other so as to be parallel to each other in an unloaded state, and a cylindrical outer peripheral portion of the support member And a shape memory alloy wire having an intermediate portion engaged with the protrusion of the driven body, and the protrusion of the driven body at one end as the environmental temperature increases. A shape memory alloy actuator that is deformed so as to move and moves the driven body to the reference position against the shape memory alloy wire when not energized and locked to the protrusion. And the other end of the shape memory alloy actuator A structure comprising a support portion for supporting.
According to the present invention, the driven body is elastically supported by the parallel leaf spring pair disposed so as to be parallel to each other in a no-load state with respect to the support body. It is supported so as to be movable along the driving direction without using a means for generating a dynamic load.
Also, one end of the protrusion of the driven body is deformed so as to urge the protrusion as the environmental temperature rises, and resists the shape memory alloy wire that is not energized and is locked to the protrusion. Since the shape memory alloy actuator that has been memorized so as to move the driven body to the reference position is provided, the ambient temperature becomes equal to or higher than the transformation end temperature when the temperature of the shape memory alloy wire drops, and the shape memory alloy wire If the shape memory alloy wire does not extend even when the current is turned off, the biasing force of the shape memory alloy actuator acting on the protrusion increases and the shape memory alloy wire is extended. Can be returned to.
As a result, only when the environmental temperature rises, an urging force for extending the shape memory alloy wire can be applied, and it is not necessary to preload the driven body with a parallel leaf spring pair or the like. In addition, the thickness of the device in the driving direction can be reduced. Moreover, manufacture and assembly of a parallel leaf spring pair can be facilitated.
The columnar body of the driven body is used in a broad sense including all forms whose outer shape is substantially columnar. Therefore, it is not limited to a solid columnar body, and includes, for example, a cylindrical body provided with a through-hole in the center. Further, an assembly such as a lens assembly is included as long as the outer shape is substantially columnar.

According to a second aspect of the present invention, in the drive module according to the first aspect, the shape memory alloy actuator and the shape memory alloy wire have a transformation start temperature and a transformation end temperature when the temperature of the shape memory alloy actuator rises. Tss and Tse (where Tss <Tse) are set, and the transformation end temperature and transformation start temperature when the temperature of the shape memory alloy wire is lowered are Twe and Tws (where Twe <Tws), respectively. Tw0 (where Twe <Tw0 ≦ Tws) is selected from the temperatures in the transformation region at the time of the temperature drop, and the shape memory at which the deformation strain at the time of temperature rise of the shape memory alloy actuator is the constant temperature Tw0. When the temperature equal to the transformation strain when the temperature of the alloy wire falls is Ts0, the following equation is satisfied. Configuration to that.
Tss ≦ Twe <Tse (a)
Ts0 ≦ Tw0 (b)
According to the present invention, when the environmental temperature T that determines the temperature of the shape memory alloy wire and the shape memory alloy actuator when the temperature is lowered when no current is supplied rises from the temperature lower than the temperature Tw0 to the temperature Tw0, the environmental temperature T The amount of deformation of the shape memory alloy wire and the shape memory alloy actuator is determined according to the amount of distortion of the corresponding transformation. According to the conditional expressions (a) and (b), at the temperature Tw0 or lower, the deformation strain of the shape memory alloy actuator exceeds the deformation strain of the shape memory alloy wire. Therefore, in proportion to these strain amounts. Due to the acting force relationship, the shape memory alloy is elongated and the driven body is reliably moved to the reference position.

According to a third aspect of the present invention, in the drive module according to the second aspect, the upper limit temperature of the transformation linear region at the time of temperature rise of the shape memory alloy actuator is that of the transformation at the time of temperature fall of the shape memory alloy wire. It is set as the structure which is below the minimum temperature of a linear area | region.
According to the present invention, the upper limit temperature of the transformation linear region when the temperature of the shape memory alloy actuator rises is larger than the lower limit temperature of the transformation linear region when the temperature of the shape memory alloy wire is lower than Tw0. Since the difference between the deformation strain when the shape memory alloy actuator temperature rises in the temperature range and the deformation strain when the shape memory alloy wire temperature falls, the biasing force of the shape memory alloy actuator is relatively reduced To do. Therefore, it is possible to relatively reduce the driving load when driving the driven body by energizing the shape memory alloy wire.

According to a fourth aspect of the present invention, in the drive module according to the third aspect, the amount of transformation distortion at the time of temperature rise generated in the shape memory alloy actuator at the constant temperature Tw0, and the shape memory alloy wire The strain amount of transformation at the time of temperature drop is equal, the lower limit temperature of the linear region of transformation at the time of temperature rise of the shape memory alloy actuator, and the lower limit temperature of the linear region of transformation at the time of temperature fall of the shape memory alloy wire Are equal to each other.
According to the present invention, in the linear region of the transformation at a constant temperature Tw0 or less, the amount of transformation strain when the temperature of the shape memory alloy wire falls and the amount of transformation strain when the temperature of the shape memory alloy actuator rises match. As compared with the case where the amount of transformation distortion at the time of temperature rise of the shape memory alloy actuator exceeds, the urging force against the protrusion of the shape memory alloy actuator can be further reduced and generated without excess or deficiency. Therefore, it is possible to further reduce the driving load when driving the driven body by energizing the shape memory alloy wire.

According to a fifth aspect of the present invention, in the drive module according to any one of the first to fourth aspects, the shape memory alloy actuator comprises a compression coil spring that is attached by being compressed along the drive direction, One end is configured to be in contact with a position facing the locking position of the shape memory alloy wire in the protrusion.
According to this invention, since the shape memory alloy actuator is brought into contact with the position facing the locking position of the shape memory alloy wire, the resultant force of the shape memory alloy wire and the biasing force from the shape memory alloy actuator are substantially straight. Since they act on the wire, the moment to the driven body due to the driving force of the shape memory alloy wire can be reduced, so that stable driving can be performed.
In addition, the shape memory alloy actuator can be easily arranged and downsized as compared with the case where a tensile shape memory alloy spring is used as the shape memory alloy actuator.

According to a sixth aspect of the present invention, in the drive module according to any one of the first to fifth aspects, the shape memory alloy actuator is disposed between the parallel leaf spring pairs in the drive direction. .
According to this invention, since the shape memory alloy actuator is disposed between the parallel leaf spring pairs in the driving direction, the shape memory alloy actuator does not protrude in the driving direction, so that a compact device can be configured.

According to a seventh aspect of the present invention, an electronic device includes the drive module according to any one of the first to sixth aspects.
According to this invention, since the drive module is provided, the same operation as that of any one of claims 1 to 6 is provided.

  According to the drive module of the present invention and the electronic apparatus including the drive module, the shape memory alloy capable of supporting the driven body along the driving direction by the parallel leaf spring pair and increasing the urging force as the environmental temperature increases. Since the shape memory alloy wire can be extended by the actuator, it is possible to perform good driving even in a high temperature environment, and it is possible to reduce the size.

  Embodiments of the present invention will be described below with reference to the accompanying drawings. In all the drawings, even if the embodiments are different, the same or corresponding members are denoted by the same reference numerals, and common description is omitted.

[First Embodiment]
The drive module according to the first embodiment of the present invention will be described.
FIG. 1 is a schematic perspective exploded view for explaining a mounting state of a drive module according to a first embodiment of the present invention on a substrate. FIG. 2 is a schematic perspective exploded view showing a schematic configuration of the drive module according to the first embodiment of the present invention. FIG. 3A is a plan view of FIG. 1A. FIG. 3B is a schematic BB cross-sectional view of FIG. FIG. 4 is a schematic perspective view showing the internal configuration of the assembled state of the drive module according to the first embodiment of the present invention. FIG. 5 is a cross-sectional view taken along line CC in FIG. FIG. 6 is a schematic perspective view showing a part of a driven body used in the drive module according to the first embodiment of the present invention. FIGS. 7A and 7B are a plan view of D view and a back view of E view in FIG. 6, respectively. FIG. 8A is a schematic perspective view of a module frame used in the drive module according to the first embodiment of the present invention. FIG. 8B is a rear view of FIG. 8A viewed from F. FIG. 9 is a plan view of a leaf spring member used in the drive module according to the first embodiment of the present invention. FIG. 10 is a schematic perspective view of a module lower plate used in the drive module according to the first embodiment of the present invention. FIG. 11 is a plan view of a power supply member used in the drive module according to the first embodiment of the present invention. FIG. 12 is a back view of a cover used in the drive module according to the first embodiment of the present invention. FIG. 13 is a schematic graph showing the temperature strain characteristics of the shape memory alloy wire and the shape memory alloy actuator used in the drive module according to the first embodiment of the present invention. The horizontal axis represents the temperature T of the shape memory alloy, and the vertical axis represents the strain (the same applies to FIGS. 15 and 16).
In some of the drawings, for the sake of clarity, for example, components such as the lens unit 12 are omitted as appropriate.

As shown in FIG. 1, the drive module 1 of this embodiment is formed in a box shape as a whole. The drive module 1 is assembled and completed, and is provided in an electronic device or the like. The drive module 1 can be fixed on the drive module 1 by being fitted on or bonded to a substrate 2 that supplies a control signal or power. .
On the upper surface of the substrate 2, a pair of land portions 3 that are connected to a power supply member of the drive module 1 to be described later and supply electric power, and an image sensor 30 are provided.

As shown in FIGS. 1 and 2, the driving module 1 forms a lens frame 4 (driven body), a lens unit 12 (driven body, see FIG. 1), a module frame 5 (supporting body), and a parallel leaf spring pair. Upper plate spring 6 and lower plate spring 7, module lower plate 8 (support), power supply member 9, shape memory alloy (hereinafter abbreviated as SMA) wire 10, cover 11, and compression coil spring 40 ( The shape memory alloy actuator) is a main constituent member, and these constituent members are laminated together to constitute one actuator.
In the assembled state of these constituent members, as shown in FIG. 3B, the lens frame 4 into which the lens unit 12 is screwed is inserted into the module frame 5, and the upper plate spring 6 and the lower plate spring are inserted. 7 is a state in which the lens frame 4 and the module frame 5 are sandwiched from above and below in the figure and fixed by caulking. From the lower side of the figure, the module lower plate 8 and the power supply member 9 are laminated in this order, A cover 11 that is fixed together by caulking from below the frame 5 and covers these laminates from above is fixed to the module lower plate 8.
The compression coil spring 40 is held in a compressed state between the cover 11 and the lens frame 4.

In addition, the symbol M in the figure is a virtual axis line of the drive module 1 that coincides with the optical axis of the lens unit 12 and indicates the drive direction of the lens frame 4. In the following, for the sake of simplicity of explanation, in the explanation of each disassembled component member, the position and direction may be referred to based on the positional relationship with the axis M at the time of assembly. For example, even when there is no clear circle or cylindrical surface in the component, unless there is a risk of misunderstanding, the direction along the axis M is simply the axial direction, the radial direction of the circle centering on the axis M, and the circumferential direction. It may be simply referred to as a radial direction, a circumferential direction, or a radial direction with respect to the axis M and a circumferential direction.
Further, unless otherwise specified, the vertical direction refers to the vertical direction in the arrangement when the axis M is arranged in the vertical direction and the mounting surface of the drive module 1 is vertically downward.

Among these components, the lens frame 4 is formed in a cylindrical shape as a whole as shown in FIGS. 2 and 6, and penetrates through the center thereof and is formed in a coaxial shape with the axis M. A female screw is formed on the inner peripheral surface 4F of the housing portion 4A. Then, a lens unit 12 (see FIGS. 3B and 5) holding an appropriate lens or lens group held in a lens barrel having an external thread formed on the outer peripheral portion is screwed into the housing portion 4A. It can be done.
In a state where the lens unit 12 is fixed to the lens frame 4, the lens unit 12 and the lens frame 4 constitute a driven body of a columnar body.
The outer wall surface 4B of the lens frame 4 is provided with a projecting portion 4C projecting radially outward at an angle of 90 degrees in the circumferential direction, extending in the axial direction, and an upper end portion of each projecting portion 4C, End surfaces 4a and 4b made of a plane orthogonal to the axis M are formed at the lower end and in the vicinity thereof. On the end faces 4a and 4b, there are provided four upper fixing pins 13A and four lower fixing pins 13B respectively protruding upward and downward along the axis M.
The upper fixing pin 13A is for holding the upper leaf spring 6, and the lower fixing pin 13B is for holding the lower leaf spring 7.

The positions of the upper fixing pin 13A and the lower fixing pin 13B in plan view may be different from each other, but in the present embodiment, the upper fixing pin 13A and the lower fixing pin 13B are arranged in a positional relationship coaxial with four axes parallel to the axis M. Yes. For this reason, the insertion positions of the upper fixing pin 13A and the lower fixing pin 13B in the upper plate spring 6 and the lower plate spring 7 are made common.
Further, the radial center positions of the upper fixing pin 13A and the lower fixing pin 13B may be different in distance from the axis M, but are arranged on the same circumference in the present embodiment. For this reason, the respective center positions are arranged in a square lattice pattern (see FIGS. 7A and 7B).

  On the radially outer side of the lens frame 4, a guide protrusion 4 </ b> D (protrusion part) is provided so as to protrude radially outward from the lower end side in the vicinity of one protrusion part 4 </ b> C. The protruding direction of the guide protrusion 4D is an angle θ from an integer multiple of 90 degrees (where θ is an acute angle) with respect to the angular position in the circumferential direction around the axis M of each upper fixing pin 13A and each lower fixing pin 13B. It is set to a positional relationship shifted by a certain amount. That is, when the guide protrusions 4D are arranged along the square diagonal, the upper fixing pins 13A and the lower fixing pins 13B are all arranged at positions deviated from the square diagonal by a fixed angle θ. It has become.

A tip key portion 4D1 having a right isosceles triangle shape in a plan view is provided at the tip of the guide projection 4D, and is arranged so as to be vertically movable along a corner portion on the inside of the cover 11 described later. As shown in FIGS. 3B and 4, in the assembled state, the SMA wire 10 is locked to the lower surface of the guide protrusion 4D from below.
As shown in FIG. 3B, a locking projection 4f is provided on the tip side of the projection upper surface 4d, which is the upper surface of the guide projection 4D. The position of the locking projection 4f may be shifted in the radial direction with respect to the axis M with respect to the locking position of the SMA wire 10, but in the present embodiment, is substantially coincident with the locking position of the SMA wire 10.
The outer diameter of the locking projection 4f can be inserted into the inner peripheral portion of the compression coil spring 40, and the base end portion is sized so as to be substantially inscribed in the inner peripheral portion of the compression coil spring 40. Accordingly, the compression coil spring 40 is inserted into the locking projection 4f from above, so that the end of the compression coil spring 40 abuts on the projection upper surface 4d, and the compression coil spring 40 is rotated around the axis M. It is possible to position in the direction.

Further, as shown in FIGS. 6, 7 </ b> A, and 7 </ b> B, a protruding piece shape extending in the circumferential direction from the side portion of each protruding portion 4 </ b> C along the lower portion of the outer wall surface 4 </ b> B of the lens frame 4. 4E is provided for each degree. However, the contact portion 4E of the protrusion 4C having the guide protrusion 4D in the vicinity also serves as the base end portion of the guide protrusion 4D.
Each contact portion 4E has a smooth contact surface 4e on its upper surface, and the position of the contact surface 4e in the axial direction is above the lens frame 4 along the axis M (FIG. 3B and FIG. 5). When the user tries to move more than a certain distance in the direction of arrow (A), the position is set to a position that contacts a receiving portion 5E (see FIG. 8B) of the module frame 5 described later.
Further, in the present embodiment, the lens frame 4 is integrally formed with a thermoplastic resin capable of thermal caulking or ultrasonic caulking, such as polycarbonate (PC), liquid crystal polymer (LCP) resin, or the like.

As shown in FIGS. 2, 8A, and 8B, the module frame 5 has a generally rectangular outer shape in plan view, and is formed coaxially with the axis M at the center thereof. It is a cylindrical member in which an accommodating portion 5A (cylindrical portion) composed of a through hole is formed, and the lens frame 4 is accommodated in the accommodating portion 5A.
At the upper and lower corners of the module frame 5 are formed end faces 5a and 5b which are planes orthogonal to the axis M, and the upper fixing pin 14A is directed upward from the end face 5a and is lowered downward from the end face 5b. Four side fixing pins 14B are provided.
The upper fixing pin 14A is for holding the upper leaf spring 6, and the lower fixing pin 14B is for holding the lower leaf spring 7, the module lower plate 8, and the feeding member 9.
The distance between the end surfaces 5a and 5b is set to the same distance as the distance between the end surfaces 4a and 4b of the lens frame 4.

  A notch 5B having a size in which the groove width in a plan view is fitted to the guide projection 4D of the lens frame 4 so as to be movable in the axial direction is formed at a lower portion of one corner of the module frame 5. The notch 5B penetrates the guide projection 4D of the lens frame 4 in a state in which the lens frame 4 is inserted and accommodated in the module frame 5 from below, and the tip key portion 4D1 of the guide projection 4D is inserted into the diameter of the module frame 5. This is for projecting outward in the direction and positioning the lens frame 4 in the circumferential direction.

In this embodiment, since the notch 5B is provided at such a position, as shown in FIG. 8B, the lower fixing pin 14B in the vicinity of the notch 5B avoids the notch 5B, and the axis M It is formed at a position away from the line connecting the point Q1 that is the intersection of the corners of the outer shape. On the other hand, the other three lower fixing pins 14B are provided on or close to the line connecting the axis M and the intersection of the corners of the outer shape, and are arranged along the outer shape of the module frame 5. It is arranged in a letter shape. Accordingly, the four lower fixing pins 14B are arranged at asymmetric positions in plan view.
On the other hand, the position of the upper fixing pin 14A in plan view may be different from the arrangement of the lower fixing pin 14B, but in this embodiment, the positional relationship is coaxial with each of the four axes parallel to the axis M. Is arranged. For this reason, the insertion positions of the upper fixing pin 14A and the lower fixing pin 14B in the upper leaf spring 6 and the lower leaf spring 7 are made common.

  As shown in FIG. 8B, when the intersections of the side surfaces of the module frame 5 are Q1, Q2, Q3, and Q4 in plan view, the axial centers of the upper fixing pins 14A and the lower fixing pins 14B are Are arranged in the vicinity of the points Q1, Q2, Q3, Q4 and on or near the lines K1, K2, K3, K4 connecting the points Q1, Q2, Q3, Q4 and the axis line M, respectively. . That is, the line segments k1, k2, k3, k4 connecting the axis centers of the upper fixing pins 14A and the lower fixing pins 14B and the axis line M overlap with the line segments K1, K2, K3, K4, or 30 degrees or less. Crossed at a shallow angle.

Further, as shown in FIG. 8A, the SMA wire 10 is connected to the two corners adjacent to the notch 5B of the module frame 5 on the side surface in the same direction as the corner where the notch 5B is provided. A pair of locking grooves 5C for attaching the wire holding members 15A and 15B (see FIGS. 2 and 4) to be held are provided. In the present embodiment, the wire holding member 15 </ b> A is provided on a side surface on the side where the pair of terminal portions 9 </ b> C of the power supply member 9 protrudes from the drive module 1, and the wire holding member 15 </ b> B is a pair of the power supply member 9 from the drive module 1. The terminal portion 9C is provided on the side surface on the side where it does not protrude.
The wire holding members 15A and 15B are conductive members such as a key-like metal plate formed by caulking the ends of the SMA wires 10 at the ends, and are fitted into the locking grooves 5C from the side. The end portion of the SMA wire 10 is positioned and held.
As shown in FIG. 4, the wire holding members 15 </ b> A and 15 </ b> B are provided with a piece-like terminal portion 15 a on the side opposite to the crimping position of the SMA wire 10, and the terminal portion 15 a is attached to the module frame 5 when attached to the module frame 5. It protrudes slightly below the module lower plate 8 stacked below.
Further, the SMA wire 10 held at both ends by the pair of wire holding members 15A and 15B is locked from below to the front end key portion 4D1 of the guide projection 4D of the lens frame 4 protruding from the notch 5B of the module frame, The lens frame 4 is urged upward by the tension of the SMA wire 10 via the distal end key portion 4D1.

As shown in FIGS. 8A and 8B, the housing 5A of the module frame 5 is formed radially outward from the inner wall surface 5D and is formed from the lower end side to the upper end side intermediate portion in the axial direction. A receiving portion 5E that is a concave portion is provided in such a shape that each portion 4E of the lens frame 4 can be inserted from below. However, the contact receiving portion 5E corresponding to the contact portion 4E that also serves as the guide protrusion 4D is also used by the groove bottom portion of the notch 5B.
The contact receiving portion 5E has a receiving surface 5E1 that can contact the contact surface 4e of the contact receiving portion 4E on the lower side in the axial direction. As a result, when the lens frame 4 moves upward by a predetermined distance along the axis M, the receiving surface 5E1 of the receiving portion 5E is contacted with the contacting surface 4e of the receiving portion 4E. The upward movement of the lens frame 4 is restricted. That is, the contact receiving portion 5E constitutes a position restricting portion that restricts the upward movement range of the lens frame 4, and the contact receiving portion 4E is a cover provided so as to be able to contact the position restricting portion of the module frame 5. A position restricting unit is configured.
In the present embodiment, the position of the receiving portion 5E in the plan view is formed at the corner of the rectangular outer shape of the module frame 5 from the center (axis M) of the housing portion 5A as shown in FIG. 8B. It is provided at a position including line segments K1, K2, K3, and K4 toward the section.

With such a configuration, even if a large impact is applied from the outside, for example, by dropping the drive module, the lens frame 4 moves upward beyond the position of the receiving surface 5E1 of the receiving portion 5E. I can't do it.
In this embodiment, such a restriction position is such that the lens frame 4 does not collide with the cover 11 and the deformation of the upper leaf spring 6, the lower leaf spring 7, and the compression coil spring 40 is, for example, an elastic limit or winding. It is set to be smaller than the deformation limit such as the contact length.
Further, since the contact receiving portion 5E is provided at a position including line segments K1, K2, K3, K4 from the center of the housing portion 5A toward the corners of the rectangular outer shape of the module frame 5, the module frame 5 , The radial region from the accommodating portion 5A to the corner of the rectangular outer shape can be used effectively.
For this reason, even if the receiving portion 5E is provided inside the module frame 5, the outer shape of the module frame 5 can be prevented from increasing, so that the size and weight can be reduced.

  Further, in the present embodiment, the module frame 5 is integrally formed of a thermoplastic resin capable of thermal caulking or ultrasonic caulking, for example, polycarbonate (PC), liquid crystal polymer (LCP) resin, or the like, similarly to the lens frame 4. .

As shown in FIG. 5, the module frame 5 and the lens frame 4 inserted into the module frame 5 are respectively provided with an upper leaf spring on the end surface 5a of the module frame 5 and the end surface 4a of the lens frame 4, respectively. 6, lower leaf springs 7 are laminated on the end surface 5 b of the module frame 5 and the end surface 4 b of the lens frame 4, respectively.
In the present embodiment, as shown in FIG. 9, the upper leaf spring 6 and the lower leaf spring 7 are flat plate spring members punched in the same shape, and have a spring property such as a stainless steel (SUS) steel plate, for example. It consists of a metal plate.

As shown in FIG. 9, the shape of the upper leaf spring 6 (lower leaf spring 7) is such that the outer shape in plan view is a substantially rectangular shape similar to the upper (lower) end of the module frame 5, and the center portion A circular opening 6C (7C) that is coaxial with the axis M and slightly larger than the inner peripheral surface 4F of the lens frame 4 is formed in a ring shape as a whole.
At the three corners of the upper leaf spring 6 (lower leaf spring 7) and in the vicinity of one corner, an upper fixing pin 14A (lower fixing pin 14B) formed near the corner of the module frame 5 and one corner. ) Is provided with four through holes 6B (7B) that can be respectively inserted into the upper fixing pins 14A (lower fixing pins 14B). In the present embodiment, one of the through holes 6B (7B) through which the upper fixing pins 14A (lower fixing pins 14B) formed at the corners corresponding to the points Q2 and Q4 in FIG. The circular hole and the other are oblong holes, and positioning within a plane perpendicular to the axis M with respect to the module frame 5 is possible.

Further, the upper plate spring 6 (lower plate spring 7) has upper fixing pins 13A (lower fixing pins) corresponding to the positions of the upper fixing pins 13A (lower fixing pins 13B) formed on the lens frame 4. Four through-holes 6A (7A) that can be respectively inserted into the pins 13B) are provided.
That is, in this embodiment, each through-hole 6A (7A) is formed at a position shifted by an angle θ from an integral multiple of 90 degrees with respect to the straight line L1 corresponding to the line segment K1 in FIG. Yes. And the part in which these through-holes 6A (7A) were provided is connected with the circumferential direction by the annular part 6F (7F) along opening 6C (7C).
In this embodiment, by setting the angle θ to an appropriate value in such an arrangement, the diameter of the circle centering on the axis M where the through hole 6A (7A) is located and the through hole 6B (7B) The respective arrangement positions can be set so that the difference in diameter from the circle diameter of the circle centered on the arranged axis M is smaller than that in the case where the angle θ is 0 degrees. .

Further, on the outer side in the radial direction of the opening 6C (7C), four slits 6D extending in a substantially semicircular arc shape in the circumferential direction from a position in the vicinity of the through-hole 6A (7A) opposing each other diagonally across the axis M. (7D) is formed on the outer side in the radial direction of the annular portion 6F (7F) so as to be overlapped in the radial direction by substantially quadrants.
Thereby, four spring parts 6E (7E) extended from the rectangular frame outside the upper leaf | plate spring 6 (lower leaf | plate spring 7) to the substantially quadrant arc shape one each through-hole 6A ( 7A) A leaf spring member extending in the vicinity is formed. That is, a leaf spring member in which the annular portion 6F (7F) is elastically supported uniformly at four locations by the four spring portions 6E (7F) is formed on the rectangular frame.

As shown in FIG. 2, the module lower plate 8 allows the lower fixing pins 14 </ b> B of the module frame 5 to pass through the through holes 7 </ b> B of the lower plate spring 7, and the lower frames of the lens frames 4 housed in the module frame 5. In a state in which the side fixing pin 13B is passed through the through hole 7A of the lower leaf spring 7, the lower leaf spring 7 is stacked between the module frame 5 with the lower leaf spring 7 sandwiched from below, and the rectangular outer shape of the lower leaf spring 7 is obtained. The frame is fixed in close contact with the end surface 5 b of the module frame 5.
As shown in FIG. 10, the module lower plate 8 is a plate-like member having a rectangular outer shape substantially the same as the outer shape of the module frame 5, and a substantially circular opening 8 </ b> A centering on the axis M at the center. Are formed penetrating in the thickness direction.
The opening 8A extends from the upper surface 8a where the lower leaf spring 7 is laminated to a position corresponding to the position where each lower fixing pin 13B of the lens frame 4 is disposed, and is thick from the upper surface 8a to the lower surface side. Four U-shaped relief portions 8d penetrating in the vertical direction are formed. Thereby, interference with the caulking portion of the lens frame 4 to be described later can be avoided.
The inner diameter of the circular portion of the opening 8A is equal to or smaller than the inner diameter of the opening 7C of the lower leaf spring 7, and the upper surface 8a is a plane on which the spring portion 7E and the annular portion 7F of the lower leaf spring 7 can also abut. Is configured. For this reason, the guide protrusion 4 </ b> D is brought into contact with the lower plate spring 7. Thus, the module lower plate 8 constitutes an abutting support portion, and constitutes a support body together with the module frame 5 constituting the cylindrical portion.
In addition, through holes 8C through which the lower fixing pins 14B are inserted are formed at the corners located on the periphery of the module lower plate 8 corresponding to the positions of the lower fixing pins 14B of the module frame 5. ing.

  Further, the lower surface 8b of the module lower plate 8 is formed with a convex portion 8D that protrudes downward along the opening 8A. The end surface 8c of the convex portion 8D constitutes an attachment surface that is brought into contact with the substrate 2 and has a function of a positioning spacer for positioning in the axis M direction relative to the substrate 2, that is, the optical axis direction. The level difference between the end surface 8c and the lower surface 8b of the convex portion 8D is set to a height that protrudes downward from the caulked portion when the power supply member 9 is assembled by caulking the lower surface 8b.

In the present embodiment, the module lower plate 8 is made of a synthetic resin having electrical insulation.
For this reason, the module lower plate 8 is an insulating member that fixes the power supply member 9 to the lower plate spring 7 in an electrically insulated state. Moreover, it is also an insulating member which maintains an electrical insulation state with respect to the board | substrate 2 which the end surface 8c contact | abuts.

As shown in FIG. 11, the power supply member 9 includes a pair of electrodes 9 a and 9 b each formed of a plate-like metal plate in the present embodiment.
Each of the electrodes 9a and 9b includes a substantially L-shaped wiring portion 9B that follows the outer shape of the module lower plate 8, and a terminal portion 9C that protrudes outside the outer shape of the module lower plate 8 from the end of the wiring portion. It consists of a polygonal metal plate. And in each wiring part 9B, two lower sides which adjoin along the external shape of the module lower board 8 among the lower side fixing pins 14B of the module frame 5 which protrude below from the lower surface 8b of the module lower board 8 Two through holes 9A for positioning the electrodes 9a and 9b with respect to the module frame 5 by inserting the fixing pins 14B, respectively, are provided.
In this embodiment, as shown in FIGS. 1 and 3A, the terminal portions 9C of the electrodes 9a and 9b are radially outward from the side surface of the module frame 5 where the wire holding member 15A is attached. It is provided so as to protrude in parallel.
For this reason, the electrode 9a is conductively cut in a concave shape to electrically connect the terminal portion 15a of the wire holding member 15A to the side surface on the wiring portion 9B between the through hole 9A and the terminal portion 9C. A connecting portion 9D is provided.
In addition, the electrode 9b is provided with a conductive connection portion 9D that is notched in a concave shape in order to electrically connect the terminal portion 15a of the wire holding member 15B to the side surface on the wiring portion 9B between the two through holes 9A. It has been.
As means for electrically connecting each conductive connection portion 9D to the terminal portion 15a, for example, soldering or adhesion using a conductive adhesive can be employed.

As shown in FIGS. 1 and 12, the cover 11 has a side wall portion 11D extending from the outer edge portion of the upper surface 11E to the lower side so as to cover the module frame 5 so that the module frame 5 can be fitted, and a rectangular opening 11C is formed on the lower side. The formed member is provided with a circular opening 11A centered on the axis M at the center of the upper surface 11E. The size of the opening 11A is set so that the lens unit 12 can be taken in and out.
Further, on the back surface side of the upper surface 11E, as shown in FIG. 12, interference with a caulking portion 16 (to be described later) is caused at a position corresponding to the arrangement position of each upper fixing pin 13A of the lens frame 4 in the circumferential direction of the opening 11A. Four U-shaped concave portions 11B are formed for avoidance.
The depth of the recess 11B is set to a depth at which the caulking portion 16 and the cover 11 do not come into contact with each other even when the contact surface 4e and the receiving surface 5E1 are in contact with each other. The recess 11B may be a recess that protrudes above the upper surface 11E, but in this embodiment, the thickness of the recess 11B is thin, and the outer surface of the upper surface 11E is flat.

At one corner on the back side of the upper surface 11E, in the assembled state, as shown in FIG. 3 (b), the compression coil is positioned at the same height as the surface of the upper leaf spring 6 attached to the module frame 5. A trapezoidal coil spring support portion 11a (support portion) that supports the end portion of the spring 40 is formed.
On the end surface 11a, a locking protrusion 11b protruding toward the opening 11C is formed at a position corresponding to the locking protrusion 4f of the lens frame 4 in the assembled state.
The outer diameter of the locking projection 11b can be inserted into the inner peripheral portion of the compression coil spring 40, and the base end portion is sized so as to be substantially inscribed in the inner peripheral portion of the compression coil spring 40. As a result, the compression coil spring 40 is inserted into the locking projection 11b from below, so that the end of the compression coil spring 40 is brought into contact with the coil spring support portion 11a. Positioning in the circumferential direction is possible.

The compression coil spring 40 is an SMA actuator in which a shape in which the spring length is extended on the high temperature side is stored by processing a wire made of SMA into a coil shape and heat-treating it.
Here, with reference to FIG. 13, the temperature distortion characteristic of SMA used for the compression coil spring 40 is demonstrated with the temperature distortion characteristic of SMA used for the SMA wire 10. FIG.
The temperature of the SMA wire 10 when not energized and the compression coil spring 40 when the ambient temperature changes within the operating temperature range t _{min to} t _max that guarantees the operation of the drive module 1 is from T _min to T _max (however, , T _min <T _max ). Here, when the maximum use temperature for the drive module 1 is t _max , the temperature T _max is substantially equal to the SMA wire 10 and the compression coil spring 40 in consideration of a temperature increase due to heat conduction or heat generation in the drive module 1. Maximum ambient temperature during use, generally T _max ≧ t _max . In the following description, for simplicity, T _max is simply referred to as a maximum operating temperature unless there is a risk of misunderstanding. Similarly, T _min is simply referred to as a minimum use temperature.
The maximum use temperature T _max is a constant temperature Tw0 selected from the temperatures in the transformation region when the temperature of the shape memory alloy wire is lowered. As the maximum use temperature T _max , for example, 80 ° C. can be adopted.

The temperature strain characteristic of the SMA wire 10 shows a change represented by a curve αABCDβ when the temperature rises. The magnitudes of the temperatures Tα, T _A , T _B , T _C , T _D , Tβ at each point increase in this order.
The size of the distortion is increased slightly with a constant gradient as the straight line αA in the state before the start of the transformation on the low temperature side, increases to a temperature T _B at a greater rate of change from the transformation start temperature T _A at the time of temperature rise, the temperature Between T _B and T _C , there is a linear change that maintains the slope at temperature T _B , and the rate of change gradually decreases between temperatures T _C and T _D , and is constant between temperatures T _D and Tβ. A change that slightly increases with inclination is shown. Here, T _A is assumed to satisfy the following equation.

T _A ≧ T _max (1)

Therefore, the temperature of the SMA wire 10 by energizing the SMA wire 10 exceeds the temperature T _A, the transformation is started continue to shrink. Therefore, an operation like the curve ABCDβ in FIG. 13 is realized by energizing the SMA wire 10 to generate heat.
If T _A <T _max , the SMA wire 10 contracts before the SMA wire 10 is energized, and normal operation cannot be guaranteed.

Further, the temperature strain characteristic when the temperature of the SMA wire 10 is lowered shows a change represented by a curve βDdcibaα. The magnitudes of the temperatures Tβ, T _D , T _d , T _c , T _i , T _b , T _a , T α at each point decrease in this order. Here, the relationship of the following equation is satisfied.

T _i = T _max (2)
T _a ≦ T _A (3)

The size of the distortion, between the temperature T _d of the temperature Tβ at the high temperature side, linear βD slightly decreased with the same slope and the temperature T _c at a greater rate of change from the start transformation during temperature lowering temperature T _d (Tws) decreased to show a linear change in holding the inclination of the temperature T _c is between a temperature T _c to T _b, between the temperature T _b of transformation during temperature lowering end temperature T _a (Twe), change the rate gradually decreases, indicating a change to a slight decrease in the same slope and the straight line Aα at Tα from the temperature T _a.
Such an SMA wire 10 can be made of, for example, a Ni—Ti alloy containing Ni and Ti at a ratio of approximately 1: 1.

The compression coil spring 40 of the present embodiment is made of a material in which the transformation start temperature is shifted to the low temperature side using the same SMA as that of the SMA wire 10. For example, when a Ni—Ti alloy is used, the transformation start temperature can be shifted to the low temperature side by increasing the Ni content.
In the present embodiment, the temperature strain characteristic when the temperature of the compression coil spring 40 rises shows a change represented by a curve αefjghdβ. Temperature Tα of each _{point, T e, T f, T} j, T g, T h, T d, the size of Tβ are increased in this order. Here, the temperature T _j is a temperature at which the same strain amount as the strain amount at the temperature T _i (Tw0) of the SMA wire 10 is obtained.
The size of the distortion is increased slightly at the same slope as the straight line αA as straight αe in the state before the start of the transformation on the low temperature side, the temperature T _f in a greater rate of change from the transformation start temperature during the temperature rise T _e (Tss) to increase, shows the change in the linear holding the inclination of the temperature T _f is between the temperature T _f to T _g, at a temperature between T _g transformation finish at elevated temperatures from the temperature T _h (Tse), change the rate gradually decreases, the temperature T _h to T [beta, indicating a change to a slight increase at the same rate as the straight line D.beta.
Here, transformation start temperature T _e at elevated temperatures is a temperature lower than the transformation end temperature T _a at a temperature lowering of the SMA wire 10. Also, transformation finish temperature T _h at elevated temperatures has a lower temperature than the transformation start temperature T _d at a temperature lowering of the SMA wire 10.
Therefore, the following equation is satisfied.

T _e <T _a (4a)
T _h <T _d (4b)

  In the present embodiment, the curve abcd is separated from the curve efgh on the high temperature side as a whole. For this reason, the following equation is satisfied.

T _j <T _i (4c)
T _a <T _h (4d)

Here, equation (4a), (4d) _{is, T e, T a, T} h , respectively Tss, Twe, in order to respond to Tse, correspond to the relationship except for equality of the condition (a) . Further, the expression (4c) corresponds to the relationship excluding the equal sign in the conditional expression (b) because T _j and T _i correspond to Ts0 and Tw0, respectively.
In FIG. 13, as an example, although depicted as a _{T h = T max, T h} ≧ T max or conditions, such as T _g ≧ T _max is preferred.
For example, if T _h <T _max , the rate of change in strain is significantly reduced near T _max , the spring length of the compression coil spring 40 is hardly increased, and the spring force of the compression coil spring 40 is greatly increased. In this region, the SMA wire 10 cannot be efficiently stretched.

The SMA wire 10 and the compression coil spring 40 both have a linear region of transformation when the temperature rises and when the temperature falls. That is, the temperatures T _b and T _c are respectively the lower limit temperature and the upper limit temperature of the linear region when the temperature of the SMA wire 10 is decreased, and the temperatures T _f and T _g are respectively the values when the temperature of the compression coil spring 40 is increased. It is the lower limit temperature and the upper limit temperature of the linear region. In the present embodiment, the relationship of the following formula is satisfied.

T _g ≦ T _b (5)

Moreover, the temperature distortion characteristic at the time of the temperature fall of the compression coil spring 40 shows the change represented by the curve βhHGFEα. The magnitudes of temperatures Tβ, T _h , T _H , T _G , T _F , T _E , and Tα at each point decrease in this order. Here, the relationship of the following equation is satisfied.

T _H <T _h (6)
T _E <T _e (7)

The magnitude of strain slightly decreases with the same slope as the straight line βh between the temperature Tβ and the temperature T _H on the high temperature side, and decreases from the transformation start temperature T _H at the time of temperature decrease to the temperature T _G with a larger change rate. shows the linear change to hold the inclination of the temperature T _G in between the temperature T _G to T _F, between a temperature T _F transformation during temperature drop from the end temperature T _E, the rate of change gradually reduced , A change that slightly decreases from the temperature T _E to Tα with the same slope as the straight line eα is shown.

The compression coil spring 40 has an inner diameter that allows the locking projection 4f of the guide projection 4D and the locking projection 11b of the cover 11 to be inserted into the inner peripheral portion, and the locking projections 4f and 11b are inserted at both ends. In this state, the guide protrusion 4D is disposed between the protrusion upper surface 4d and the coil spring support portion 11a of the cover 11.
Natural length of the compression coil spring 40 of the present embodiment, the temperature of the compression coil spring 40 when the transformation start temperature T _e less on the low temperature side at the time of temperature rise, coil spring support portion 11a in the assembled state, the protrusion upper surface 4d The distance is the maximum value H _max (see FIG. 3B) or less.
In this case, the natural length of the compression coil spring 40 may be shorter than H _max as long as it does not deviate from the locking protrusions 4f and 11b at the minimum operating temperature T _min , but the backlash is too large. It is preferable to set the length so that the assembled state does not become unstable.
In addition, when the SMA is, for example, a Ni-Ti alloy at such a low temperature side, it becomes a martensite phase, the elastic modulus is remarkably reduced, and even if compression is applied after mounting, almost no spring force is generated. , H _max may be set.
On the other hand, the natural length on the high temperature side expands to H _max or more at the maximum use temperature T _max and is compressed between the protrusion upper surface 4d and the coil spring support portion 11a in the assembled state, whereby the lens frame 4 The shape is memorized in such a length that a spring force is generated to elongate the SMA wire 10 until the end surface 4b of the SMA contacts the upper surface 8a.
Since the locking projection 4f is provided at a position overlapping the locking position of the SMA wire 10, the point of application of the urging force from the compression coil spring 40 is relative to the point of application of the urging force from the SMA wire 10. It is located on substantially the same straight line parallel to the axis M.

The drive module 1 having such a configuration is assembled in the following procedure.
First, the lens frame 4 is inserted into the housing portion 5A of the module frame 5 from below, and the end surfaces 5a of the module frame 5 and the end surfaces 4a of the lens frame 4 are aligned at the same height. Then, the through holes 6A and 6B of the upper leaf spring 6 are inserted into the upper fixing pins 14A of the module frame 5 and the upper fixing pins 13A of the lens frame 4, respectively.
Thereafter, the tip portions of the upper fixing pins 13A and 14A protruding upward through the through holes 6A and 6B of the upper leaf spring 6 are heat caulked by a heater chip (not shown), and caulked portions 16 and 17 respectively. (See FIGS. 3B, 4 and 5). In the case of using ultrasonic caulking, an ultrasonic vibrator is used instead of the heater chip (the same applies to the following thermal caulking).
Next, the through holes 7A of the lower leaf spring 7 are inserted into the lower fixing pins 13B of the lens frame 4, respectively. At this time, the through holes 7B of the lower plate spring 7, the through holes 8C of the module lower plate 8, and the through holes 9A of the power supply member 9 are inserted into the lower fixing pins 14B of the module frame 5 at the same time. Thereafter, the tip end portion of each lower fixing pin 13B penetrating through each through hole 7A of the lower leaf spring 7 is caulked with a heater chip to form a caulking portion 18 (see FIG. 5). . Since the module lower plate 8 has an escape portion 8 d, the caulking portion 18 does not contact the module lower plate 8.
Next, the lower end portion of each lower fixing pin 14B that protrudes downward through the through holes 7B, 8C, and 9A is caulked with a heater chip to be caulked portion 19 (see FIG. 3B). Form.

  In this way, the upper plate spring 6, the lower plate spring 7, the module lower plate 8, and the power supply member 9 are laminated and fixed to both ends of the lens frame 4 and the module frame 5. At this time, in the no-load state, the spring portions 6E and 7E of the upper leaf spring 6 and the lower leaf spring 7 facing each other are not parallel to each other, and thus are parallel to each other. The annular portion 7F of the lower leaf spring 7 that is in close contact with the end surface 4b is supported in close contact with the upper surface 8a of the module lower plate 8.

Next, the pair of wire holding members 15A and 15B with the SMA wire 10 attached to the tip are respectively locked in the two locking grooves 5C of the module frame 5, and the module is mounted by means such as fitting or adhesion, for example. Hold and fix to the frame 5. At that time, the center portion of the SMA wire 10 is engaged with the distal end key portion 4D1 of the guide protrusion 4D, and the distal end key portion 4D1 is supported so as to be supported from below.
At this time, the terminal portions 15a of the wire holding members 15A and 15B protrude below the module lower plate 8, and are electrically connected 9D of electrodes 9a and 9b, which are power supply members 9 fixed to the module lower plate 8, respectively. Or are located close to each other.
Therefore, for example, each terminal portion 15a is electrically connected to the conductive connection portion 9D by using soldering or a conductive adhesive.

Next, the compression coil spring 40 is extrapolated to the protrusion upper surface 4d, and one end of the compression coil spring 40 is brought into contact with the protrusion upper surface 4d. In this state, the cover 11 is placed from above the module frame 5. Thereby, the latching protrusion 11b is inserted in the inner peripheral part of the other end of the compression coil spring 40, and the compression coil spring 40 is disposed between the protrusion upper surface 4d and the coil spring support part 11a. Therefore, in this embodiment, the compression coil spring 40 is disposed between the upper leaf spring 6 and the lower leaf spring 7.
Next, the side wall part 11D and the module lower plate 8 are joined. For example, an engaging claw or the like is provided on the side wall part 11D and joined by fitting, or the side wall part 11D and the module lower plate 8 are bonded or welded to join.
Thus, the compression coil spring 40 of the present embodiment, the following transformation start temperature T _e at elevated temperatures is assembled without being compressed, in a state of the spring force is not biased to the guide projection 4D. Moreover, even when compressed and assembled by setting the natural length to be longer, the elastic coefficient is remarkably low, so that the spring is hardly assembled.
For this reason, the compression coil spring 40 is easier to assemble than when compressed and assembled in a state where the spring force is larger.
At this time, the caulking portions 16 and 17 are in a state of being separated from the back surface of the upper surface 11E of the cover 11, respectively.
Thus, the assembly of the drive module 1 is completed.

Next, the drive module 1 is mounted on the substrate 2 by aligning the terminal portion 9C of the drive module 1 with the land portion 3 (see FIG. 1) on the substrate 2 as necessary. Then, the terminal portion 9C is electrically connected to the land portion 3 by means such as soldering or a conductive adhesive. The substrate 2 is provided with four relief holes 2a corresponding to the positions of the caulking portions 19 in advance, so that the caulking portions 19 do not interfere with the substrate 2.
For mounting the drive module 1 on the substrate 2, fixing means such as adhesion or fitting can be employed.
The substrate 2 may be an independent member attached to the drive module 1 or a member connected to and disposed on an electronic device or the like.

Next, the lens unit 12 is screwed into the lens frame 4 through the opening 11 </ b> A of the cover 11.
As described above, the lens unit 12 is attached last because the lens of the lens unit 12 is not soiled or dust is attached by the assembling work. For example, the drive module 1 is attached to the lens unit 12. When the product is shipped in a product state where it is attached, or when it is desired to make the opening 11A of the cover 11 smaller than the outer shape of the lens unit 12, for example, when the aperture stop is also used, it is screwed into the lens frame 4 in advance. The above assembly can also be performed.

Next, the operation of the drive module 1 will be described.
FIG. 14 is a schematic cross-sectional view taken along the line BB of FIG. 3A for explaining the operation of the drive module according to the first embodiment of the present invention.

In the drive module 1, the SMA wire 10 is extended in accordance with the environmental temperature in a state where no electric power is supplied to the terminal portion 9 </ b> C and no external force is applied in the drive direction. That is, since the environmental temperature for the SMA wire 10, the compression coil spring 40, the start of the transformation at each temperature increase the temperature T _A, is lower than T _e is the lens frame 4 is not external force is applied, and FIG. 3 (b) As shown in FIG. 4, the end surface 4b of the lens frame 4 to which the lens unit 12 is attached is abutted against the upper surface 8a of the module lower plate 8 via the annular portion 7F, and the upper plate spring 6 and the lower plate spring 7 are It is not deformed.
Thereby, the lens frame 4 is positioned at the drive reference position. In the case of the present embodiment, this reference position is set so that the focal position of the lens unit 12 with respect to the image sensor 30 is at infinity.
Below, operation | movement in case the environmental temperature in the drive module 1 maintains this state first is demonstrated.

When power is supplied from the terminal portion 9C to the power supply member 9, the electrode 9a, the wire holding member 15A, the SMA wire 10, the wire holding portion 15b, and the electrode 9b are electrically connected, so that a current flows through the SMA wire 10. Thus, Joule heat is generated in the SMA wire 10, and temperature increase of the SMA wire 10 exceeds a transformation starting temperature T _A at the time of temperature rise of the SMA wire 10, the temperature distortion during SMA wire 10 temperature rise Shrink to length according to characteristics.

As a result, the lens frame 4 moves upward (direction (A) in the figure).
That is, the spring portions 6E and 7E of the upper leaf spring 6 and the lower leaf spring 7 are deformed, respectively, and an elastic restoring force corresponding to the deformation amount is urged to the lens frame 4 via the annular portions 6F and 7F. The At this time, the upper leaf spring 6 and the lower leaf spring 7 are parallel to each other in an unloaded state, and the spring portions 6E and 7E are deformed while maintaining an equal distance in the direction of the axis M, thus constituting a parallel spring. The lens frame 4 translates along the axis M.
Further, as the guide protrusion 4D moves, the compression coil spring 40 is compressed, and an elastic restoring force corresponding to the amount of compression is biased to the guide protrusion 4D. At this time, the point of application of the urging force from the compression coil spring 40 and the point of application of the urging force from the SMA wire 10 are located on substantially the same straight line parallel to the axis M, so that the moment of force on the lens frame 4 is Since it hardly occurs, even if a force larger than the force by the upper leaf spring 6 and the lower leaf spring 7 is applied, the moving posture of the lens frame 4 is hardly affected. However, ambient temperature of the drive module 1 is lower than the transformation start temperature T _e of the compression coil spring 40, even if the compression coil spring 40 is compressed, as compared to the elastic restoring force of the upper spring 6, the lower plate spring 7 Only a very small spring force is generated.
In this way, the lens frame 4 is translated along the axis M, and the lens frame 4 stops at a position where these elastic restoring forces are balanced with the tension of the SMA wire 10.

  Thus, in the present embodiment, the upper plate spring 6 and the lower plate spring 7 accurately move the lens frame 4 along the axis M without using an axial guide member that generates a sliding load. Can be made. For this reason, it is possible to reduce the number of parts and reduce the size.

Further, when the supply of power is stopped, the lens frame 4 is extended downward (in the (B) direction in the figure) due to the heat radiation from the SMA wire 10 and extending and deforming according to the temperature strain characteristics during cooling of the SMA. Move to the balance position. In this embodiment, it returns to the reference position as shown in FIG.
Thus, the lens frame 4 can be driven in the direction of the axis M by controlling the power supply amount. When driving to a different position, the power supply is stopped, the lens frame 4 is returned to the reference position, and then the power corresponding to the driving amount is supplied again, so that the SMA wire 10 is heated and cooled. In spite of having a hysteresis characteristic, it can be accurately driven to different positions.

Incidentally, the driving module 1, when used under the SMA wire 10 transformation finish during temperature lowering temperature T _a more environmental temperature T of, even when de-energized, the temperature of the SMA wire 10 is lower than the temperature T Therefore, the extension of the SMA wire 10 stops, and the lens frame 4 cannot be returned to the reference position by natural heat dissipation. For this reason, when driving repeatedly, accurate driving cannot be performed.
For example, consider the case where T = T _max as the worst case. In this case, as shown in FIG. 13, as the SMA wire 10 naturally dissipates heat from a higher temperature side, for example, the distortion changes so as to move in this order on a curve passing through points D, d, c, and i. In response to this, it contracts to the length at the temperature T _max and stops.
At this time, as indicated by point h, the compression coil spring 40 has the maximum distortion and extends to the maximum spring length that has been previously memorized in shape, so that the spring force of the compression coil spring 40 causes the guide protrusion 4D to move. The SMA wire 10 is extended until it moves to a position where the tension of the SMA wire 10 and the spring force of the compression coil spring 40 are balanced, that is, the lens frame 4 is moved to the reference position. . Thereby, even if the environmental temperature T becomes the maximum use temperature T _max , the lens frame 4 can be returned to the reference position after the energization of the SMA wire 10 is stopped.
Such an effect is obtained because the temperature strain characteristics of the SMA of the SMA wire 10 and the compression coil spring 40 satisfy the relations of equations (4a), (4d), and (4c), so that the temperature T _max or less. This is because the relationship in which the amount of transformation strain when the temperature of the compression coil spring 40 rises becomes larger than the amount of transformation strain when the temperature of the SMA wire 10 decreases at the ambient temperature T is satisfied.

From the state in which the lens frame 4 has returned to the reference position and, more energized SMA wire 10, the temperature of the SMA wire 10 is heated above T _max, it exceeds the transformation start temperature T _A at the time of temperature rise, 13 The SMA wire 10 contracts in accordance with the temperature strain characteristic of the lens, and the lens frame 4 can be driven according to the value of the current flowing through the SMA wire 10.
At this time, since the compression coil spring 40 tries to maintain the spring length at the environmental temperature T _max , a spring force corresponding to the compression amount acts on the lens frame 4 to be a driving load, but heating by energization is continued. Thus, the tension due to the contraction of the SMA wire 10 is increased, and the lens frame 4 can be driven to a position corresponding to the current value. Therefore, the drive can be performed as described above.

When the environmental temperature T is smaller than T _max , the spring force of the compression coil spring 40 is reduced according to the temperature distortion characteristic of FIG. In this case, since the phase state of the SMA wire 10 also shifts to the low-temperature phase state in proportion to the change in the environmental temperature T, it is possible to return to the reference position with a lower load. Can be returned to the reference position.
In the present embodiment, since the SMA constituting the SMA wire 10 and the compression coil spring 40 has substantially the same inclination in the linear region of the transformation, even if the environmental temperature changes, the SMA wire 10 and the compression coil spring 40 are between the compression coil spring 40 and the SMA wire 10. Is a similar force relationship. For this reason, the lens frame 4 can be smoothly returned to the reference position in any temperature region.

As described above, according to the present embodiment, the compression coil spring 40 is made of SMA, and the spring force is increased as the temperature rises. The temperature strain characteristics of the compression coil spring 40 and the SMA wire 10 are conditional expressions. (4a), (4d), in order to satisfy the (4c), even when the environmental temperature is higher than the transformation end temperature T _a at a temperature lowering of the SMA wire 10, by the spring force of the compression coil spring 40, the SMA wire 10 And the lens frame 4 can be returned to the reference position. For this reason, even if the drive module 1 is used in a somewhat high temperature environment, it can be driven with good positional accuracy.

In this embodiment, the upper leaf spring 6 and the lower leaf spring 7 function as members for maintaining the moving direction and the moving posture of the lens frame 4, and only the compression coil spring 40 is based on the ambient temperature. The lens frame 4 that does not return to the position is provided with a function of returning it to the reference position in response to an increase in environmental temperature.
For example, the compression coil spring 40 may be omitted, and the upper leaf spring 6 and the lower leaf spring 7 may be provided with a preload function for returning the lens frame 4 to the reference position. Since either the spring 6 or the lower leaf spring 7 needs to be deflected, a space is required for deformation in the direction of the axis M, and the thickness of the drive module 1 increases. Further, since the plate thickness and the spring length are less flexible than the coil spring, it is difficult to set the preload and the spring constant without variation.
On the other hand, in the present embodiment, the compression coil spring 40 is connected to the upper leaf spring 6, the lower leaf spring 7, and the like by appropriately setting the condition of the deformation state in which the shape is memorized based on the SMA temperature strain characteristics of the compression coil spring 40. Even if it arrange | positions in the space of between, since the deformation amount of the compression coil spring 40 can be set easily, the drive module 1 can be comprised compactly.

Next, a first modification of the present embodiment will be described.
FIG. 15 is a schematic graph showing the temperature strain characteristics of the shape memory alloy wire and the shape memory alloy actuator used in the drive module according to the first modification of the first embodiment of the present invention.

  In this modification, only the temperature strain characteristic of the SMA used for the compression coil spring 40 of the first embodiment is changed as shown in FIG. 15, and the shape and arrangement of each component are the same as those of the first embodiment. This is the same as the embodiment. Further, in FIG. 15, the same reference numerals as those in FIG. 13 represent the same meaning as in the first embodiment, together with the amount such as the temperature with the suffix, and the description thereof is omitted. Hereinafter, a description will be given centering on differences from the first embodiment.

A compression coil spring 40 of this modification, as shown in FIG. 15, with respect to temperature distortion characteristics of the SMA wire 10, shifting the transformation start temperature T _e when the temperature is increased to the low temperature side, the slope of the linear region of the transformation It is composed of a smaller SMA.
That is, the temperature distortion characteristic at the time of temperature rise of the compression coil spring 40 of the present modification shows a change represented by the curve αef ₁ j ₁ g ₁ h ₁ Dβ. Temperature Tα of each _{point, T e, T f1, T} j1, T g1, T h1, T D, the size of Tβ are increased in this order. Here, the temperature T _j1 is a temperature at which the same strain amount as the strain amount at the temperature T _i of the SMA wire 10 can be obtained.
The size of the distortion is increased slightly at the same slope as the straight line αA as straight αe in the state before the start of the transformation on the low temperature side, increases to a temperature T _f1 at a greater rate of change from the transformation start temperature T _e at elevated temperatures Between the temperature T _f1 and T _g1 , there is a linear change that maintains the slope at the temperature T _f1 , and the rate of change is gradually between the temperature T _g1 and the transformation end temperature T _h1 (Tse) when the temperature rises. It decreased from transformation finish temperature T _h1 to T [beta, indicating a change to a slight increase at the same rate as the straight line D.beta.
Here, the slope of the straight line f ₁ j ₁ g ₁ indicating the linear region of transformation is smaller than the slope of the straight line BC indicating the linear region of transformation when the temperature of the SMA wire 10 rises. And the following formula is satisfied.

T _a <T _h1 (8)
T _f1 <T _b (9)
T _d <T _h1 (10)
T _j1 ≦ T _i = T _max (11)

Since the T _e, T _a, T _h1, respectively Tss, Twe, corresponding to Tse, the formula (4a) to hold as in the first embodiment, the equation (8), the condition This corresponds to the relationship excluding the equal sign in formula (a). Further, the expression (11) corresponds to the conditional expression (b) because T _j1 and T _i correspond to Ts0 and Tw0, respectively.

For this reason, between the temperature _Te and _Tmax , the magnitude of the strain when the temperature of the compression coil spring 40 is increased is equal to or greater than the amount of strain when the temperature of the SMA wire 10 is decreased. A spring force for extending the SMA wire 10 can be generated.
In a temperature region exceeding the point x where the straight line f ₁ g ₁ and the straight line bc intersect, the amount of strain is opposite to the above, so the compression coil spring 40 generates a spring force that extends the SMA wire 10. However, there is no problem in actual use because T _x > T _max .

Moreover, the temperature distortion characteristic at the time of the temperature fall of the compression coil spring 40 of this modification shows the change represented by the curve βh ₁ H ₁ G ₁ F ₁ Eα. The magnitudes of temperatures Tβ, T _h1 , T _H1 , T _G1 , T _F1 , T _E , and Tα at each point decrease in this order. Here, the relationship of the following equation is satisfied.

T _H1 <T _h1 (12)

The magnitude of the strain slightly decreases at the same temperature as the straight line βh ₁ between the temperature Tβ and the temperature T _H1 on the high temperature side, and decreases from the transformation start temperature T _H1 when the temperature decreases to the temperature T _G1 with a larger change rate. and shows a linear change to hold the inclination of the temperature T _G1 in between the temperature T _G1 to T _F1, between the temperature T _F1 of transformation finish temperature T _E during temperature lowering, the rate of change gradually decreases In addition, a change that slightly decreases from the temperature T _E to Tα with the same inclination as the straight line eα is shown.

According to this modification, the temperature distortion characteristics of the compression coil spring 40 and the SMA wire 10 satisfy the conditional expressions (8) to (11), so that the environmental temperature is SMA as in the first embodiment. even if higher than the transformation end temperature T _a at a temperature lowering of the wire 10, the temperature range, by the spring force of the compression coil spring 40, to extend the SMA wire 10, the lens frame 4 can be returned to the reference position It becomes.
And since the inclination of the linear area | region of the temperature distortion characteristic at the time of the temperature rise of the compression coil spring 40 is small compared with the same inclination of the SMA wire 10, compared with the case where each inclination is the same, on the high temperature side of environmental temperature. The driving load can be reduced.

Next, a second modification of the present embodiment will be described.
FIG. 15 is a schematic graph showing the temperature strain characteristics of the shape memory alloy wire and the shape memory alloy actuator used in the drive module according to the second modification of the first embodiment of the present invention.

  In this modification, only the temperature strain characteristic of the SMA used for the compression coil spring 40 of the first embodiment is changed as shown in FIG. 16, and the shape and arrangement of each component are the same as those of the first embodiment. This is the same as the embodiment. Also, in FIG. 16, the same reference numerals as those in FIG. 13 represent the same meaning as in the first embodiment, together with the amount of temperature and the like with the suffixes, and the description thereof is omitted. Hereinafter, a description will be given centering on differences from the first embodiment.

As shown in FIG. 16, the compression coil spring 40 of the present modification is composed of SMA in which the temperature strain characteristic when the temperature rises is the same as the temperature strain characteristic when the temperature of the SMA wire 10 falls.
That is, the temperature distortion characteristic at the time of temperature rise of the compression coil spring 40 of this modification shows a change represented by the curve αe ₂ f ₂ j ₂ g ₂ h ₂ Dβ. This curve overlaps with the curve βDdcibaα indicating the temperature strain characteristic when the temperature of the SMA wire 10 is lowered, and the points e ₂ , f ₂ , j ₂ , g ₂ , h ₂ are points a, b, i, c and d overlap on the graph.
That is, the transformation start temperature T _e2 when the temperature of the compression coil spring 40 rises and the transformation end temperature T _h2 when the temperature rises are respectively the transformation end temperature T _a and the transformation start temperature T _d when the temperature of the SMA wire 10 falls. It agrees and satisfies the relationship of the following formula.

T _e2 = T _a (13a)
T _a <T _h2 (13b)
T _j2 = T _i (13c)

Here, the expressions (13a) and (13d) correspond to the relationship including the equal sign of the conditional expression (a) because T _e2 , T _a , and T _h2 correspond to Tss, Twe, and Tse, respectively. Further, the expression (13c) corresponds to the relation of the equal sign in the conditional expression (b) because T _j2 and T _i correspond to Ts0 and Tw0, respectively.

According to this modification, the magnitude of the strain of the compression coil spring 40 when the temperature rises is always the same as the distortion of the SMA wire 10 when the temperature falls, and the compression coil spring 40 extends the SMA wire 10. The spring force to be generated can be generated without excess or deficiency.
For this reason, it becomes possible to set the drive load by the spring force of the compression coil spring 40 to a required minimum value in the whole use temperature range.

Next, a third modification of the present embodiment will be described.
FIG. 17 is a schematic perspective view showing the internal configuration of the assembled state of the drive module according to the third modification of the first embodiment of the present invention.

In the present modification, a tension coil spring is used as the SMA actuator instead of the compression coil spring 40 of the first embodiment.
As shown in FIG. 17, the drive module of the present modified example is replaced by a tension coil spring 41 (a flexible coil wire 41 a provided on the distal end side instead of the compression coil spring 40 of the first embodiment. SMA actuator). Further, instead of the locking projection 4f of the lens frame 4, a wire locking portion 42a for locking the tip of the pulling wire 41a is provided. And the latching protrusion 80 protruded to the side is provided in the side surface of the module lower board 8 of the position which overlaps with guide protrusion 4D at the time of an assembly. The locking projection 80 is for slidably winding the pull wire 41a and changing the pull direction of the pull wire 41a. Instead of the module frame 5, a module frame 50 (support) provided with a spring housing groove 50 a (support) on the side surface of the module frame 5 on which the SMA wire 10 is stretched is provided.
The tension coil spring 41 engages the tip end of the pull wire 41a with the wire locking portion 42a, and the pull wire 41a is guided by the guide groove on the side surface of the guide projection 4D and is wound around the locking projection 80 to be a module. In a state in which the pulling direction is changed on the side surface side of the frame 5, the module frame 50 is retractably accommodated in the spring housing groove 50 a and fixed to the module frame 50 at the end opposite to the pulling wire 41 a.
The tension coil spring 41 is an SMA in which the shape of the spring length contracted on the high temperature side is memorized by processing the wire made of SMA into a coil shape and heat-treated, and the spring length is extended on the low temperature side of the transformation. Actuator.

In the configuration of the present modification, the tension coil spring 41 is compactly accommodated in the spring accommodating groove 50a on the side of the module frame 50, and with the contraction due to the increase in the environmental temperature, via the tension wire 41a, The guide protrusion 4D is provided so that it can be pulled to the module lower plate 8 side (the lower side in the figure).
The temperature strain characteristic of the tension coil spring 41 is set to have the same characteristics as the SMA used for the compression coil spring 40.

  According to the present modification, the spring force acting on the guide protrusion 4D is the pulling force of the tension coil spring 41, and the operation and effect similar to those of the first embodiment are essentially obtained except that the operation direction is different. Prepare.

[Second Embodiment]
Next, an electronic apparatus according to a second embodiment of the present invention will be described.
18A and 18B are perspective external views of the front and back surfaces of an electronic apparatus according to the second embodiment of the present invention. FIG.18 (c) is GG sectional drawing in FIG.18 (b).

A camera-equipped mobile phone 20 according to the present embodiment shown in FIGS. 18A and 18B is an example of an electronic apparatus including the drive module 1 according to the first embodiment.
The camera-equipped mobile phone 20 includes a known mobile phone device configuration inside and outside the cover 22 such as a reception unit 22a, a transmission unit 22b, an operation unit 22c, a liquid crystal display unit 22d, an antenna unit 22e, and a control circuit unit (not shown). ing.
Then, as shown in FIG. 18B, a window 22A that transmits external light is provided in the cover 22 on the back surface side on which the liquid crystal display unit 22d is provided, and as shown in FIG. The drive module 1 of the first embodiment is installed so that the opening 11A of the drive module 1 faces the window 22A of the cover 22 and the axis M is along the normal direction of the window 22A.
The drive module 1 is mechanically and electrically connected to the substrate 2.
The substrate 2 is connected to a control circuit unit (not shown) so that power can be supplied to the drive module 1.

According to such a configuration, the light transmitted through the window 22 </ b> A can be collected by the lens unit 12 (not shown) of the drive module 1 and imaged on the image sensor 30. Then, by supplying appropriate power from the control circuit unit to the drive module 1, the lens unit 12 can be driven in the direction of the axis M, and the focal position can be adjusted to perform photographing.
According to such a camera-equipped mobile phone 20, since the drive module 1 of the first embodiment is provided, the device can be downsized and manufactured easily, and even when used in a high-temperature environment, it is accurate. Can be focused.

In the above description, the module lower plate 8 and the power feeding member 9 are described as examples. However, these may be omitted depending on circumstances.
For example, when the abutting support portion can be integrally formed with the module frame 5, the module lower plate 8 may be omitted.
Further, the power supply member 9 can be omitted in the case where the wire holding members 15 </ b> A and 15 </ b> B are directly wired or an appropriate power supply member is provided on the side surface of the module frame 5.
For example, when electrical insulation is not required, such as when the power supply member 9 is not stacked on the module lower plate 8, the module lower plate 8 may not be an electrical insulator.

  Further, in the above description, the case where heat caulking or ultrasonic caulking is used for the assembly has been described. However, the upper fixing pins 13A and 14A, the lower fixing pins 13B and 14B, and the like are replaced with screw portions and screwed. Or may be assembled using an adhesive or the like. In this case, the material of the driven body and the support is not limited to a thermoplastic resin that can be caulked.

  In the above description, the module frame 5 has been described as a substantially rectangular member as a whole, but is not limited to a substantially rectangular shape, and may be a polygonal shape. In this case, the rectangular corner can be replaced with a polygonal corner.

  In the above description, the power supply member is described as an example of the case where the power supply member is composed of the electrodes 9a and 9b. However, the power supply member may be a single printed circuit board on which two lines of wiring are formed. .

  In the above description, an example in which the drive module is used for the focal position adjustment mechanism of the lens unit has been described. However, the use of the drive module is not limited to this. For example, you may use for another part as an appropriate actuator which moves a to-be-driven body to a target position. For example, instead of the lens unit 12, a rod member or the like can be screwed, or the lens frame 4 can be changed to another shape and used as an appropriate actuator.

  In the above description, the example of the camera-equipped mobile phone is described as the electronic device using the drive module, but the type of the electronic device is not limited to this. For example, it may be used for an optical device such as a digital camera or a camera built in a personal computer, or may be used as an actuator for moving a driven body to a target position in an electronic device such as an information reading storage device or a printer.

  In addition, the constituent elements of each of the embodiments described above can be appropriately combined and implemented within the scope of the technical idea of the present invention, if technically possible.

It is a typical perspective exploded view for demonstrating the attachment state to the board | substrate of the drive module which concerns on the 1st Embodiment of this invention. It is a typical perspective exploded view showing a schematic structure of a drive module concerning a 1st embodiment of the present invention. FIG. 2 is a plan view of FIG. 1 and a schematic BB cross-sectional view thereof. It is a typical perspective view which shows the internal structure of the assembly state of the drive module which concerns on the 1st Embodiment of this invention. It is sectional drawing which follows the CC line in FIG. It is a typical perspective view which shows a part of to-be-driven body used for the drive module which concerns on the 1st Embodiment of this invention. It is the top view of D view in FIG. 6, and the reverse view of E view. It is the typical perspective view of the module frame used for the drive module concerning a 1st embodiment of the present invention, and the back view of the F view. It is a top view of the leaf | plate spring member used for the drive module which concerns on the 1st Embodiment of this invention. It is a typical perspective view of the module lower board used for the drive module which concerns on the 1st Embodiment of this invention. It is a top view of the electric power feeding member used for the drive module which concerns on the 1st Embodiment of this invention. It is a reverse view of the cover used for the drive module which concerns on the 1st Embodiment of this invention. It is a typical graph which shows the temperature-strain characteristic of the shape memory alloy wire used for the drive module which concerns on the 1st Embodiment of this invention, and a shape memory alloy actuator. It is typical sectional drawing which follows the BB line of Drawing 3 (a) for explaining operation of the drive module concerning a 1st embodiment of the present invention. It is a typical graph which shows the temperature strain characteristic of the shape memory alloy wire used for the drive module which concerns on the 1st modification of the 1st Embodiment of this invention, and a shape memory alloy actuator. It is a typical graph which shows the temperature strain characteristic of the shape memory alloy wire used for the drive module which concerns on the 2nd modification of the 1st Embodiment of this invention, and a shape memory alloy actuator. It is a typical perspective view which shows the internal structure of the assembly state of the drive module which concerns on the 3rd modification of the 1st Embodiment of this invention. It is the surface external appearance of the electronic device which concerns on the 2nd Embodiment of this invention, a perspective external view of a back surface, and its GG sectional drawing.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Drive module 2 Board | substrate 3 Terminal 4 Lens frame (driven body)
4D guide protrusion (protrusion)
4d Projection upper surface 5, 50 Module frame (support)
5A housing part (tubular part)
6 Upper leaf spring (parallel leaf spring pair)
7 Lower leaf spring (parallel leaf spring pair)
8 Module lower plate (support)
8a Upper surface (butting support)
9 Feed Member 10 Shape Memory Alloy (SMA) Wire 11 Cover 11a Coil Spring Support (Support)
12 Lens unit (driven body)
20 Mobile phone with camera (electronic equipment)
40 Compression coil spring (shape memory alloy actuator)
41 Tension coil spring (shape memory alloy actuator)
50a Spring storage groove 50a (support part)
M axis T _max maximum operating temperature (constant temperature Tw0 selected from the temperature in the transformation region when the temperature of the shape memory alloy wire drops)
_Td transformation start temperature (transformation start temperature Tws when temperature of shape memory alloy wire drops)
T _a transformation start temperature (transformation finish temperature Twe at a temperature lowering of the shape memory alloy wire)
_Te , _Te2 transformation start temperature (transformation start temperature Tss when temperature of shape memory alloy actuator rises)
T _h , T _h1 , T _h2 transformation start temperature (transformation end temperature Tse when temperature of shape memory alloy actuator rises)
T _j, T _j2 temperature (temperature Ts0 the amount of strain of the transformation at elevated temperatures of the shape memory alloy actuator is equal to the amount of strain of the transformation at the time of temperature lowering of the shape memory alloy wire at a constant temperature Tw0)

Claims (7)

A driven body comprising a columnar body whose axis is arranged along the driving direction and provided with a protruding portion protruding to the side of the columnar body;
A support body having an abutting support portion that positions the driven body at a reference position in the driving direction, and a cylindrical portion that movably accommodates the driven body along the driving direction;
A pair of parallel leaf springs that are attached between the driven body and the support body so as to extend in a direction orthogonal to the driving direction, and are arranged so as to be parallel to each other in an unloaded state,
A shape memory alloy wire that is stretched around the cylindrical outer periphery of the support and whose intermediate portion is locked to the protrusion of the driven body;
As the environmental temperature rises, the one end is deformed so as to urge the protrusion of the driven body, and against the shape memory alloy wire that is locked to the protrusion when not energized. A shape memory alloy actuator that has a shape memory so as to move the driven body to the reference position;
A drive module comprising: a support portion that supports the other end of the shape memory alloy actuator. The shape memory alloy actuator and the shape memory alloy wire are:
The transformation start temperature and transformation end temperature when the shape memory alloy actuator temperature rises are Tss and Tse (where Tss <Tse), respectively, and the transformation end temperature and transformation start temperature when the shape memory alloy wire temperature falls are respectively Twe, Tws (where Twe <Tws), Tw0 (where Twe <Tw0 ≦ Tws) is selected as the constant temperature selected from the temperature in the transformation region when the temperature of the shape memory alloy wire drops, and the shape memory alloy actuator When the amount of transformation strain at the time of temperature rise is equal to the amount of transformation strain at the time of temperature drop of the shape memory alloy wire at the constant temperature Tw0, Ts0,
The drive module according to claim 1, wherein the following equation is satisfied.
Tss ≦ Twe <Tse (a)
Ts0 ≦ Tw0 (b) The upper limit temperature of the linear region of transformation at the time of temperature rise of the shape memory alloy actuator is
The drive module according to claim 2, wherein the temperature is equal to or lower than a lower limit temperature of a linear region of transformation when the temperature of the shape memory alloy wire is lowered. The amount of transformation strain when the temperature rises in the shape memory alloy actuator at the constant temperature Tw0 is equal to the amount of transformation strain when the temperature of the shape memory alloy wire falls,
The lower limit temperature of the transformation linear region when the temperature of the shape memory alloy actuator is increased is equal to the lower limit temperature of the transformation linear region when the temperature of the shape memory alloy wire is lowered. The described drive module. The shape memory alloy actuator is
Consisting of a compression coil spring that is compressed and mounted along the drive direction;
The drive module according to any one of claims 1 to 4, wherein the one end is in contact with a position facing the locking position of the shape memory alloy wire in the protrusion. The shape memory alloy actuator is
The drive module according to claim 1, wherein the drive module is disposed between the pair of parallel leaf springs in the drive direction.   An electronic apparatus comprising the drive module according to claim 1.

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