JP2008298973A - Imaging apparatus and portable telephone set - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an imaging apparatus that is impact-resistant, vibration-resistant, and dust-resistant. <P>SOLUTION: The imaging apparatus is configured so that a lens holding part 201 with a lens holding part 201 fixed thereto is slidable. The imaging apparatus includes: the lens holding part 201; an acceleration sensor 26 for detecting the acceleration of the imaging apparatus; and a locking mechanism for fixing the lens holding part 201 on the basis of the detection result of the acceleration detection sensor 26 so as to prevent sliding of the lens holding part 201. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an image pickup apparatus, and more particularly to an image pickup apparatus that is built in a mobile phone and a digital camera, reduces noise generated by a lens driving device during autofocusing and zooming, and has dust resistance. .

  An imaging device built in a mobile phone and a digital camera that performs autofocus and zooming records sound during shooting in the movie mode that is the function of the imaging device, so an imaging device that reduces noise generated when an actuator is driven is known. It has been.

  As a lens driving device that reduces generated noise, there are a device that suppresses noise of a stepping motor (for example, see Patent Document 1) and a device that moves a lens by expansion and contraction of a piezoelectric element (for example, see Patent Document 2).

  The apparatus that suppresses the noise of the stepping motor shown in Patent Document 1 uses a stepping motor 102 as an actuator, as shown in FIG. 11, and attaches the stepping motor 102 to a mounting plate 104 via a connecting plate 103. When the mounting plate 104 is fixed to the lens barrel 109, a vibration damping material 113 is sandwiched between the mounting plate 104 and the lens barrel 109 and fixed by screws 114.

  As shown in FIG. 12, the apparatus configured to move the lens by expansion and contraction of the piezoelectric element disclosed in Patent Document 2 is a sliding fitting portion 72a of a support 72 that supports a lens barrel 71 that is a driven member. 72b are slidably and frictionally engaged with the drive shaft 73. The drive shaft 73 is supported by the support portions 75 and 76 of the frame 77 so as to be displaceable. One end of the piezoelectric element 78 that is displaced in the thickness direction is fixed to the axial end of the drive shaft 73, and the lens barrel is moved by making the displacement in the thickness direction of the piezoelectric element 78 into a blaze waveform. .

JP-A-5-281447 JP-A-4-069070

  By the way, there is a possibility that a part inside the imaging apparatus may be damaged by an impact or vibration caused by a user's unexpected drop or the like. However, Patent Documents 1 and 2 do not sufficiently consider the impact resistance against an impact caused by an unexpected drop or the like and the vibration resistance against vibration. In particular, since the lens support to which the lens is attached is configured to be slidable on the drive shaft according to the distance to the subject, sufficient consideration is given to impact resistance etc. in order to prevent damage to the lens, for example. There is a need to.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide an imaging device and a mobile phone device having shock resistance, vibration resistance, and dust resistance.

  In order to achieve the above object, a first imaging device of the present invention is an imaging device in which a lens support to which a lens is fixed is slidable, and detects acceleration of the lens support and the imaging device. And a fixing means for fixing the lens support so as not to slide based on the detection result of the acceleration detecting means.

With this configuration, it is possible to prevent scratches on the lens surface attached to the lens support as a driving body, and to prevent flare due to scratches on the lens surface in terms of optical performance.
In particular, when there are multiple lens supports, dust resistance is improved by preventing interference between the lens supports, and it is possible to deal with dust problems due to pixel size reduction, which has become a more recent issue in cameras. It has become a thing.

  In the second imaging device of the present invention, one end of the lens support is slidable, and the fixing means is connected to the other end of the lens support by an applied voltage based on a detection result by the acceleration detection means. And the other end of the lens support can be fixed.

  With this configuration, even if one end of the lens support is slidable, the other end is fixed so as not to slide, and it is possible to increase the strength against impact and vibration caused by unexpected drops, etc. is there.

  In the third image pickup apparatus of the present invention, the fixing unit includes a spring that is extended by the applied voltage and presses the lens support.

  With this configuration, for example, when the acceleration exceeds a predetermined speed due to, for example, an unexpected drop, the spring is pressed against the lens support by the applied voltage so that it does not slide. It is possible to increase the strength.

  In the fourth imaging apparatus of the present invention, the constituent material of the fixing means includes a material whose spring constant of the constituent material changes according to the applied voltage.

  With this configuration, the spring constant changes depending on the applied voltage according to the acceleration detection result in the imaging device.For example, when the voltage is not applied, the spring constant is adjusted so that the lens support is not locked and the voltage is applied. The lens support can be adjusted to lock.

  In the fifth imaging device of the present invention, the constituent material of the fixing means includes a material whose shape changes depending on the applied voltage.

  With this configuration, the shape of the material (shape memory alloy, etc.) constituting the fixing means changes depending on the applied voltage according to the acceleration detection result in the imaging device. For example, when no voltage is applied, the lens support is not locked. Thus, the shape of the constituent material of the fixing means can be adjusted, and when the voltage is applied, the shape of the constituent material of the fixing means can be adjusted to lock the lens support.

  In the sixth image pickup apparatus of the present invention, the fixing means adjusts the fixing strength when fixing the lens support so as not to slide based on the applied voltage.

  With this configuration, for example, different applied voltages are generated based on the acceleration detection result, whereby the fixing strength when the lens support is locked can be adjusted. In order to adjust the fixing strength, for example, the spring constant is made different for each applied voltage, or the constituent material of the fixing means is made different for each applied voltage.

  The seventh imaging apparatus of the present invention has a plurality of lens supports, and the fixing means can be fixed so that the plurality of lens supports do not slide simultaneously.

  With this configuration, the dust support is improved by preventing the interference between the lens supports, and it is possible to cope with the dust problem due to the reduction in pixel size, which has become a more recent issue in cameras. .

  In the eighth imaging apparatus of the present invention, the acceleration detection unit is an acceleration sensor.

  With this configuration, for example, when the acceleration exceeds a predetermined speed due to an unexpected drop, etc., the lens support can be locked so as not to slide, and the strength against impact and vibration caused by the unexpected drop can be increased. It is.

  The first mobile phone terminal of the present invention has a configuration in which the imaging device is mounted.

With this configuration, it is possible to prevent scratches on the lens surface attached to the lens support as a driving body, and to prevent flare due to scratches on the lens surface in terms of optical performance.
In particular, when there are multiple lens supports, dust resistance is improved by preventing interference between the lens supports, and it is possible to deal with dust problems due to pixel size reduction, which has become a more recent issue in cameras. It has become a thing.

  The present invention can prevent a lens support for fixing a lens as a driving body from being damaged when dropped, and can maintain optical performance and improve dust resistance. Further, when a plurality of lens supports are provided, interference between the lens holding portions can be prevented.

  In addition, when it is necessary to prevent noise, such as when recording external sound during movie mode shooting, the input voltage from the electrical signal input unit is turned on to reduce the rigidity of the pressure contact fixing unit, and the drive mechanism Vibration transmission from the camera to the camera fixing portion can be attenuated, and noise due to the resonance can be reduced. Also, when it is not necessary to prevent noise such as when the camera is not driven or when sound recording is not necessary, turn off the input voltage from the electrical signal input unit, and the drive source fixing frame and camera fixing unit The pressure-fixing rigidity of the actuator is increased, the strength against shocks and vibrations caused by unexpected drops, etc. is increased, and the actuator can be prevented from being damaged. Can have impact and vibration resistance.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

First, an overall image of an imaging apparatus according to an embodiment of the present invention will be described.
FIG. 1 is an example of a cross-sectional view of an imaging apparatus according to an embodiment of the present invention. As illustrated in FIG. 1, the imaging apparatus includes one or more lens holding units 201, a driving mechanism 202 that moves the lens holding unit 201 in the optical axis direction, a lens holding unit 201, the driving mechanism 202, a pressure contact mechanism, and a lock. A case 203 (so-called lens barrel) in which the mechanism is installed is provided, and an image processing unit 204 that converts an optical signal input via a lens into an electrical signal. As an example of the pressure contact mechanism, there are pressure contact mechanisms 206, 306, and 406, which will be described later. Examples of the lock mechanism include lock mechanisms 507 and 607 described later.

  The lens holding unit 201 is an example of a “lens support”. The lock mechanisms 507 and 607 are examples of “fixing means”.

The image processing unit 204 includes a three-dimensional circuit board 204a mounted on the main body substrate 205, and a solid-state image sensor 204b attached to the three-dimensional circuit board 204a. The solid-state imaging element 204b is a photoelectric conversion element that is integrated into an integrated circuit using a semiconductor element manufacturing technique, and includes photodiodes that detect light and generate charges.
Hereinafter, the main part of the imaging device in the embodiment of the present invention will be described.

(First embodiment)
FIG. 2 is an example of a fragmentary sectional view of the imaging apparatus 200 according to the first embodiment of the present invention. As described above, the imaging apparatus 200 is provided in the case 203 (not shown in FIG. 2), the lens holding unit 201 that holds the lens 4, the drive mechanism 202 that moves the lens in the optical axis direction, and the imaging apparatus. A pressing mechanism 206 that changes the pressing force according to the operating state, and a lock mechanism for fixing the lens holding unit 201 are provided. Examples of the lock mechanism include lock mechanisms 507 and 607 described in later embodiments.

  As shown in FIG. 2, the lens holding unit 201 is disposed on one end side of the lens 4 and the lens holding unit 201, holds the lens 4 inside, and slides with respect to the drive shaft 1 of the drive mechanism 202. The holding member 3 is fitted to a possible (slidable) degree. The lens 4 is, for example, a convex lens whose central portion is thicker than the edge portion, and guides light incident through the opening of the case 203 to the light receiving portion of the solid-state imaging device 202b.

  In FIG. 2, the two lens holding portions 201 are provided. However, the present invention is not limited to this, and the number may be one or three or more. When there are a plurality of lens holding portions 201, the holding member 3 of any lens holding portion 201 is fitted so as to be slidable with respect to the drive shaft 1, and the other end of each lens holding portion 201 is a locking mechanism. Are arranged in parallel to face each other.

  The drive mechanism 202 is configured by the drive shaft 1 and the piezoelectric element 2 described above. For example, the drive shaft 1 is formed by aligning long carbon fibers in the axial direction, and hardening with epoxy resin as a binder to improve wear resistance. The piezoelectric element 2 is formed by stacking (depositing) piezoelectric elements made of lead zirconate titanate (hereinafter, PZT), for example.

  Thus, the drive mechanism 202 is a device that utilizes the high-speed response and friction of the piezoelectric element 2, and the holding member 3 is moved along the drive shaft 1 by applying a drive voltage such as a sawtooth wave by the drive circuit. It can be moved.

  The pressure contact mechanism 206 includes a case fixing portion 5 fixed to the case 203, a driving mechanism fixing portion 6 to which the driving mechanism 202 is fixed, and a moving plate 10 connected to the driving mechanism fixing portion 6 via the vibration damping material 7. A pressing means fixing portion 12 on which one end of a spring 11 connected to the moving plate 10 is fixed, and an electric circuit for controlling the operation of the electromagnetic magnet 9 by inputting an electric signal to the electromagnetic magnet 9. 13.

  Examples of the vibration damping material 7 include a rubber cushion material and a gel cushion material.

  The case fixing portion 5 has a pressure contact surface 8, and the pressure contact surface 8 and one surface of the drive mechanism fixing portion 6 are in contact with each other through the vibration damping material 7. Further, the other surface of the drive mechanism fixing portion 6 and one surface of the moving plate 10 are in contact with each other via the vibration damping material 7.

  A spring 11 is connected between the other surface of the moving plate 10 and the pressure contact means fixing portion 12. In addition, an electromagnetic magnet 9 a is installed on the other surface side of the moving plate 10, and the electromagnetic magnet 9 b is installed at a position facing the electromagnetic magnet 9 a on the press contact means fixing portion 12. Further, the press contact means fixing portion 12 is fixed to the case 203 (lens) similarly to the case fixing portion 5.

(Pressure contact state)
As shown in FIG. 2, the imaging apparatus 200 configured as described above has a spring 11 whose one end is fixed to the press contact means fixing portion 12 when the input signal from the electric circuit 13 is not present. It is in the state pushed to the fixed part 5 side. That is, the moving plate 10 is fixed in pressure contact with the case fixing portion 5 side through the vibration damping material 7. Similarly, the drive mechanism fixing portion 6 installed between the moving plate 10 and the case fixing portion 5 is fixed in pressure contact with the case fixing portion 5 via the vibration damping material 7. In other words, the driving mechanism 202 is pressed against the case 203 with high rigidity by the pressing mechanism 206.

  By bringing the image pickup apparatus 200 into the pressure contact state in this way, the drive mechanism 202 is pressed and fixed to the case 203 with high rigidity, so that the resistance to shocks and vibrations due to unexpected drops and the like is improved, and the drive mechanism 202 Damage can be avoided.

(Pressure release state)
FIG. 3 is an example of a diagram for explaining a state where the pressure contact state in the imaging apparatus 200 is released. As shown in FIG. 3, in the imaging apparatus 200, when a signal is input from the electric circuit 13, a force acts in a direction in which the electromagnetic magnet 9 a and the electromagnetic magnet 9 b attract each other. Since this force is designed to be greater than the force by which the spring 11 pushes the moving plate 10 toward the case fixing portion 5, the electromagnetic magnet 9a and the electromagnetic magnet 9b approach or come into contact with each other.

  Then, as compared with the above-described pressure contact state, the position of the moving plate 10 where the electromagnetic magnet 9a is installed moves to the pressure contact means fixing portion 12 side where the electromagnetic magnet 9b is installed.

  In this way, the pressure contact state between the movable plate 10 and the case fixing portion 5 is relaxed (released), and at the same time, the pressure contact state between the case fixing portion 5 and the drive mechanism fixing portion 6 is also relaxed (released). ) That is, the driving mechanism 202 is brought into pressure contact with the case 203 by the pressure contact mechanism 206 with lower rigidity than the above pressure contact state.

  Thus, by setting the imaging device 200 in the pressure contact released state, the vibration generated by the operation of the drive mechanism 202 can be attenuated by the vibration damping material 7, and the vibration transmitted to the case fixing portion 5 can be reduced. it can. Therefore, it is possible to prevent the case 203 from resonating and generating noise.

  Note that the timing at which the electronic circuit 13 controls the operation of the electromagnetic magnet, that is, the timing at which the pressure contact state and the pressure contact release state are switched may be determined in consideration of the operation state of the electronic device in which the imaging device 200 is mounted.

  For example, when the electronic device on which the imaging apparatus 200 is mounted is a video camera and the video camera is an operation for recording moving image data including sound data, the imaging apparatus 200 is set in the disengaged state from the viewpoint of noise prevention. Just do it.

  Further, in a mode in which the video camera does not operate the imaging device 200 or a mode in which sound recording is not performed, the imaging device 200 may be brought into a pressure contact state from the viewpoint of impact resistance.

(Second Embodiment)
FIG. 4 is an example of a cross-sectional view of a main part of an imaging apparatus 300 according to the second embodiment of the present invention.
In the following description, the same reference numerals are given to the same components as those described above, and a part of the description will be omitted.

  In the image pickup apparatus 200, the spring 11 and the electromagnetic magnet 9 are used in the pressure contact mechanism 206. However, in the image pickup apparatus 300, they are not used in the pressure contact mechanism 306, and the elastic force (spring constant) changes depending on the presence or absence of an input voltage. The point which uses the fixed board 14 comprised by is different from 1st Embodiment. As an example of the lock mechanism of the present embodiment, there are lock mechanisms 507 and 607 described in later embodiments.

  The pressure contact mechanism 306 includes a case fixing portion 5 fixed to the case 203, a driving mechanism fixing portion 6 to which the driving mechanism 202 is fixed, and a fixing plate 14 connected to the driving mechanism fixing portion 6 through a vibration damping material 7. The pressure contact means fixing portion 12 is connected to the fixing plate 14 via the vibration damping member 7, and the electric circuit 313 is used to input an electric signal to the fixing plate 14 to control the elastic force of the fixing plate 14.

  The case fixing portion 5 has a pressure contact surface 8, and the pressure contact surface 8 and one surface of the drive mechanism fixing portion 6 are connected via a vibration damping material 7. Further, the other surface of the drive mechanism fixing portion 6 and one surface of the fixing plate 14 are connected via a vibration damping material 7. Further, the fixing plate 14 is installed on the other surface of the fixing plate 14 and the pressure contact means fixing portion 12 via the vibration damping material 7. Further, the pressure contact means fixing portion 12 is fixed to the case 203 (lens barrel) in the same manner as the case fixing portion 5.

  The fixed plate 14 is formed using a material whose elastic force (spring constant) changes depending on the presence or absence of an input voltage, and is made of, for example, a shape memory polymer material. Here, a description will be given assuming that a material whose elastic force is reduced when there is an input voltage is used.

(Pressure contact state)
As shown in FIG. 4, the imaging apparatus 300 configured as described above is in a state where the elastic force of the fixing plate 14 is large when there is no input signal from the electric circuit 313. At this time, the fixing plate 14 presses and fixes the drive mechanism fixing portion 6 to the case fixing portion 5 side via the vibration damping material 7. In other words, the driving mechanism 202 is pressed against the case 203 with high rigidity by the pressing mechanism 306.

  By bringing the image pickup apparatus 300 into the pressure contact state in this way, the drive mechanism 202 is pressed and fixed to the case 203 with high rigidity, so that the resistance to shocks and vibrations caused by unexpected drops and the like is improved, and the drive mechanism 202 Damage can be avoided.

(Pressure released state)
In addition, when there is an input signal from the electric circuit 313, the imaging device 300 is in a state where the elastic force of the fixing plate 14 is small. Therefore, the pressure contact state between the fixing plate 14 and the drive mechanism fixing portion 6 is relaxed (released), and at the same time, the pressure contact state between the case fixing portion 5 and the drive mechanism fixing portion 6 is also relaxed (released). The That is, the drive mechanism 202 is brought into pressure contact with the case 203 by the pressure contact mechanism 306 with lower rigidity than the above pressure contact state.

  Thus, by setting the imaging apparatus 300 in the pressure-released state, the vibration generated by the operation of the drive mechanism 202 can be attenuated by the vibration damping material 7, and the vibration transmitted to the case fixing unit 5 can be reduced. it can. Therefore, it is possible to prevent the case 203 from resonating and generating noise.

(Third embodiment)
FIG. 5 is an example of a fragmentary sectional view of an imaging apparatus 400 according to the third embodiment of the present invention. FIG. 6 is an example of a diagram illustrating a state where the pressure contact state of the imaging apparatus 400 is released. In the following description, the same reference numerals are given to the same components as those described above, and a part of the description will be omitted.

  In the first embodiment, the electromagnetic magnet 9 is used in the pressure contact mechanism 206 of the image pickup apparatus 200, but the pressure contact mechanism 406 of the image pickup apparatus 400 is not used, and a shape memory alloy whose shape changes depending on the presence or absence of an input voltage is used. Different from form. As an example of the lock mechanism of the present embodiment, there are lock mechanisms 507 and 607 described in later embodiments.

  The pressure contact mechanism 406 includes a case fixing unit 5 fixed to the case 203, a driving mechanism fixing unit 6 to which the driving mechanism 202 is fixed, and a moving plate 10 connected to the driving mechanism fixing unit 6 via the vibration damping material 7. The shape memory alloy 15 is installed and one end of a spring 11 connected to the moving plate 10 is fixed, and the shape memory alloy 15 is controlled by inputting an electric signal to the shape memory alloy 15. And an electric circuit 413.

  The case fixing portion 5 has a pressure contact surface 8, and the pressure contact surface 8 and one surface of the drive mechanism fixing portion 6 are connected via a vibration damping material 7. Further, the other surface of the drive mechanism fixing portion 6 and one surface of the moving plate 10 are in contact with each other via the vibration damping material 7.

  A spring 11 is connected between the other surface of the moving plate 10 and the pressure contact means fixing portion 12. Further, a shape memory alloy 15 is provided on the surface of the pressure contact means fixing portion 12 that faces the moving plate 10. The tip of the shape memory alloy 15 is in contact with the other surface of the movable plate 10. Further, the press contact means fixing portion 12 is fixed to the case 203 (lens) similarly to the case fixing portion 5.

  The shape memory alloy 15 changes its shape depending on the presence or absence of an input voltage, and is made of, for example, Ti—N or an alloy-based shape memory alloy. Here, the shape memory alloy 15 has the first shape (large shape) shown in FIG. 5 when there is no input voltage, and deforms into the second shape (small shape) shown in FIG. 6 when there is an input voltage. It will be described as being.

(Pressure contact state)
As shown in FIG. 5, in the imaging apparatus 400 configured in this way, when there is no input signal from the electric circuit 413, the shape memory alloy 15 has the first shape, and the movable plate 10 is placed on the case fixing unit 5 side. Press to. In the imaging apparatus 400, the length of the spring 11 is designed so that the spring 11 having one end fixed to the press contact means fixing portion 12 exerts a force in a direction in which the moving plate 10 is pulled toward the press contact means fixing portion 12 side. The shape of the shape memory alloy 15 is not changed by the elastic force of the spring 11, and the movable plate 10 is pressed against the case fixing portion 5 by the shape memory alloy 15.

  Therefore, the moving plate 10 pressed by the tip portion of the shape memory alloy 15 is fixed in pressure contact with the case fixing portion 5 via the vibration damping material 7. Similarly, the drive mechanism fixing portion 6 installed between the moving plate 10 and the case fixing portion 5 is fixed in pressure contact with the case fixing portion 5 via the vibration damping material 7. In other words, the driving mechanism 202 is pressed against the case 203 with high rigidity by the pressing mechanism 406.

  By bringing the imaging device 400 into the pressure contact state in this way, the drive mechanism 202 is pressed and fixed to the case 203 with high rigidity, so that the resistance to shocks and vibrations caused by unexpected drops and the like is improved, and the drive mechanism 202 Damage can be avoided.

(Pressure released state)
FIG. 6 is an example of a diagram for explaining a state where the pressure contact state in the imaging apparatus 400 is released. As shown in FIG. 6, in the imaging apparatus 400, when a signal is input from the electric circuit 413 to the shape memory alloy 15, the shape of the shape memory alloy 15 becomes a reduced shape (second shape). Then, the moving plate 10 is moved to the press contact means fixing portion 12 side by the elastic force of the spring 11 as compared with the position in the press contact state described above.

  In this way, the pressure contact state between the movable plate 10 and the case fixing portion 5 is relaxed (released), and at the same time, the pressure contact state between the case fixing portion 5 and the drive mechanism fixing portion 6 is also relaxed (released). ) That is, the drive mechanism 202 is brought into pressure contact with the case 203 by the pressure contact mechanism 406 with lower rigidity than the above pressure contact state.

  Thus, by setting the imaging apparatus 400 to the pressure release state, vibration generated by the operation of the drive mechanism 202 can be attenuated by the vibration damping material 7, and vibration transmitted to the case fixing unit 5 can be reduced. it can. Therefore, it is possible to prevent the case 203 from resonating and generating noise.

(Fourth embodiment)

  FIG. 7 is an example of a fragmentary sectional view of an imaging apparatus 500 according to the fourth embodiment of the present invention. In the following description, the same reference numerals are given to the same components as those described above, and a part of the description will be omitted. As an example of the pressure contact mechanism of this embodiment, there are the pressure contact mechanisms 206, 306, and 406 described in the previous embodiment.

  The imaging apparatus 500 has a lock mechanism 507. The lock mechanism 507 is fixed to the spring 21, the case 203, the electromagnetic magnet 23 is installed on one surface, and one end of the spring 21 connected to the lens fixing buffer plate 25 is fixed to the lock mechanism fixing portion 22. , An electromagnetic circuit 23, an electric circuit 24 for controlling the operation of the electromagnetic magnet 23 by inputting an electric signal to the electromagnetic magnet 23, and a spring that is installed on one surface and connected to the lock means fixing portion 22. 21 has a lens fixing buffer plate 25 to which the other end of the lens 21 is fixed, and an acceleration sensor 26 disposed on one surface of the lens fixing buffer plate 25 and capable of detecting an impact by detecting acceleration, for example. Composed. The acceleration sensor 26 is an example of “acceleration detecting means”. The spring 21 is an example of “a constituent material of the fixing means”.

  Here, there are a plurality of electromagnetic magnets 23, the electromagnetic magnet 23 a is installed on one surface of the locking means fixing portion 22, and the electromagnetic magnet 23 b is installed on one surface of the lens fixing buffer plate 25. The electromagnetic magnets 23a and 23b are installed at positions facing each other.

(Not locked)
As shown in FIG. 7, the imaging apparatus 500 configured as described above acts so that the electromagnetic magnet 9 a and the electromagnetic magnet 9 b attract each other when there is no input signal from the electric circuit 24. Since this force is designed to be greater than the force with which the spring 21 pushes the lens fixing buffer plate 25 toward the lens holding portion 201, the electromagnetic magnet 9a and the electromagnetic magnet 9b come close to or in contact with each other. Yes. Accordingly, the lens fixing buffer plate 25 and the other end of the lens holding portion 201 (the upper side of the lens holding portion 201 in FIG. 7) are not in contact with each other, and the lens holding portion 201 is not fixed. It is locked.

  In the unlocked state, for example, when there is no risk of damage to the imaging apparatus 500 due to, for example, an unexpected drop, the lens holding unit 201 can be slid along the drive shaft 1, and autofocus and zooming can be performed. Such operations can be performed smoothly, and the optical performance can be maintained.

(Locked state)
FIG. 8 is an example of a diagram illustrating a locked state of the imaging apparatus 500. As shown in FIG. 8, in the imaging apparatus 500, when a signal is input from the electric circuit 24, the spring 21 whose one end is fixed to the lock means fixing portion 23 causes the lens fixing buffer plate 25 to move the lens holding portion 201. The force works to push. This force becomes larger than the force that the electromagnetic magnet 9a and the electromagnetic magnet 9b attract each other. Accordingly, the lens fixing buffer plate 25 moves to the lens holding portion 201 side. The other end of the lens holding portion 201 is pressed against the other surface of the lens fixing buffer plate 25, and the lens holding portion 201 is in a locked state in which the driving mechanism 202 cannot slide.

  The input of the signal from the electric circuit 24 is generated when, for example, the acceleration detected by the acceleration sensor 26 exceeds a predetermined threshold. As a result, it is possible to increase the strength against an impact or vibration caused by an unexpected drop or the like, and to prevent damage to the lens.

  Moreover, as a signal input from the electric circuit 24, for example, a different signal input may be generated according to the magnitude of the acceleration detected by the acceleration sensor 26. By changing the elastic force of the spring 21, for example, by changing the elastic force of the spring 21, the lock strength when the lens holding unit 201 is locked can be adjusted, and the durability of the lens holding unit 201 at the time of impact is improved. It becomes possible.

  Further, in FIG. 8, the other end of the plurality of lens holding portions 201 is shown in a locked state by being pressed by one lens fixing buffer plate 25. One lens fixing buffer plate 25 may be provided. That is, one lock mechanism 507 may be provided for one lens holding unit 201. However, in this case, the plurality of lock mechanisms 507 are controlled to be locked at the same time so that the lens holding portions 201 do not interfere with each other due to, for example, a sudden drop or the like and damage the lens. Is preferred.

In such a locked state, since the lens holding part 201 is fixed so as not to slide,
It is possible to prevent a decrease in optical performance such as flare due to prevention of scratches on the lens surface. Further, when a plurality of lens holding portions 201 are provided, it is possible to prevent the lenses from being buffered and to improve dust resistance.

(Fifth embodiment)
FIG. 9 is an example of a fragmentary sectional view of an imaging apparatus 600 according to the fifth embodiment of the present invention. In the following description, the same reference numerals are given to the same components as those described above, and a part of the description will be omitted. Moreover, as an example of the pressure contact mechanism of this embodiment, there are the pressure contact mechanisms 206, 306, and 406 described in the previous embodiment.

  In the lock mechanism 507 of the imaging device 500, the electromagnetic magnet 23 is used, but in the lock mechanism 607 of the imaging device 600, the shape memory alloy 27 whose shape changes depending on the presence or absence of an input voltage is used. Different from the device 500.

  As shown in FIG. 9, the lock mechanism 607 is fixed to the spring 21 and the case 203, the shape memory alloy 27 is installed on one surface, and one end of the spring 21 connected to the lens buffer plate 25 is fixed. The lock means fixing portion 22, the electric circuit 24 for controlling the shape of the shape memory alloy by inputting an electric signal to the shape memory alloy 27, the lens fixing buffer plate 25 to which the other end of the spring 21 is fixed, and the lens fixing For example, an acceleration sensor 26 that is arranged on one surface of the buffer plate 25 and can detect an impact by detecting acceleration and a shape memory alloy 27 are configured. The shape memory alloy 27 is an example of “constituent material of the fixing means”.

  The shape memory alloy 27 changes its shape depending on the presence or absence of an input voltage, and is made of, for example, Ti—N or an alloy-based shape memory alloy. Here, the shape memory alloy 27 has the first shape (small shape) shown in FIG. 9 when there is no input voltage, and the second shape (large shape) shown in FIG. 10 when there is no input voltage. It will be explained as a thing.

(Not locked)
As shown in FIG. 9, in the imaging device 600, when there is no input signal from the electric circuit 24, the shape of the shape memory alloy 27 is the first shape. In the imaging apparatus 600, the force by which the spring 21 pulls the buffer plate 25 for fixing the lens toward the lock unit fixing portion 22 and the force by which the first shape memory alloy 27 presses one surface of the buffer plate 25 for fixing the lens are equal. In this case, the lens fixing buffer plate 25 and the lens holding portion 201 are designed not to contact each other. That is, in this case, the other surface of the lens fixing buffer plate 25 does not come into contact with the other end of the lens holding portion 201 and is in a slidable state so that the lens holding portion 201 is not fixed. ing.

  In the unlocked state, when there is no risk of damage to the imaging apparatus 600 due to, for example, an unexpected drop, the lens holding unit 201 can be slid along the drive shaft 1, and autofocusing and zooming can be performed. Thus, the optical performance can be maintained.

(Locked state)
FIG. 10 is an example of a diagram illustrating the locked state of the imaging apparatus 600. In the imaging apparatus 600, when a signal is input from the electric circuit 24, the shape of the shape memory alloy 27 becomes an enlarged shape (second shape). Then, the lens fixing buffer plate 25 is pressed toward the lens holding portion 201 side. In this case, the force with which the second shape memory alloy 27 pushes the lens fixing buffer plate 25 is greater than the force with which the spring 21 pulls the lens fixing buffer plate 25 toward the locking means fixing portion 22. Accordingly, the lens fixing buffer plate 25 moves to the lens holding portion 201 side. Then, the lens holding part 201 is brought into pressure contact with the lens fixing buffer plate 25 and is in a locked state in which the driving mechanism 202 cannot slide.

  For example, the signal input from the electric circuit 24 is generated when the acceleration detected by the acceleration sensor 26 exceeds a predetermined threshold. As a result, it is possible to increase the strength against an impact or vibration caused by an unexpected drop or the like, and to prevent damage to the lens.

  Further, as a signal input from the electric circuit 24, for example, a different signal input may be generated depending on the magnitude of the acceleration detected by the acceleration sensor 26. For example, by changing the elastic force of the spring 21 or the shape (size, etc.) of the shape memory alloy 27 according to the input signal, the lock strength when the lens holding unit 201 is locked can be adjusted. The durability of the lens holding part 201 at the time of impact can be improved.

  FIG. 10 shows that the other end of the plurality of lens holding portions 201 is brought into a locked state by being pressed by one lens fixing buffer plate 25. One lens fixing buffer plate 25 may be provided. That is, one lock mechanism 607 may be provided for one lens holding unit 201. However, in this case, the plurality of locking mechanisms 607 are controlled to be locked at the same time so that the lenses are not damaged due to, for example, an unexpected drop. Is preferred.

  In such a locked state, the lens holding portion 201 is fixed so as not to slide, so that a decrease in optical performance such as flare due to prevention of scratches on the lens surface can be prevented. Further, when a plurality of lens holding portions 201 are provided, it is possible to prevent the lenses from being buffered and to improve dust resistance.

  INDUSTRIAL APPLICABILITY The present invention is useful for an imaging device, a cellular phone terminal, and the like having shock resistance, vibration resistance, and dust generation resistance.

An example of a cross-sectional view of the imaging apparatus according to the first embodiment of the present invention An example of a cross-sectional view of a main part of the imaging apparatus according to the first embodiment of the present invention An example of a diagram for explaining a press-contact release state in the first embodiment of the present invention Example of principal part sectional drawing of the imaging device in the 2nd Embodiment of this invention Example of principal part sectional drawing of the imaging device in the 3rd Embodiment of this invention An example of a diagram for explaining a press-release state in the third embodiment of the present invention Example of principal part sectional drawing of the imaging device in the 4th Embodiment of this invention An example of a diagram for explaining a locked state in a fourth embodiment of the present invention Example of principal part sectional drawing of the imaging device in the 5th Embodiment of this invention An example of a diagram for explaining a locked state in a fifth embodiment of the present invention Sectional drawing of the imaging device of patent document 1 Sectional drawing of the imaging device of patent document 2

Explanation of symbols

200, 300, 400, 500, 600 Imaging device 1 Drive shaft 2 Piezoelectric element 3 Holding member 4 Lens 5 Case fixing portion 6 Drive mechanism fixing portion 7 Vibration damping material 8 Pressure contact surface 9 Electromagnetic magnet 10 Moving plate 11 Spring 12 Pressure contact means fixing Part 13 Electric circuit 14 Fixing plate 15 Shape memory alloy 21 Spring 22 Locking means fixing part 23 Electromagnetic magnet 24 Electric circuit 25 Lens fixing buffer 26 Acceleration sensor 27 Shape memory alloy 201 Lens holding part 202 Drive mechanism 203 Case 204 Image processing unit 205 Main body substrate 206 Pressure contact mechanism 207 Lock mechanism

Claims (9)

An imaging device in which a lens support to which a lens is fixed is slidable,
The lens support;
An acceleration detector for detecting the acceleration of the imaging device;
Based on the detection result by the acceleration detecting means, a fixing means for fixing the lens support so as not to slide;
An imaging apparatus having The imaging apparatus according to claim 1,
One end of the lens support is slidable,
The imaging device is capable of fixing the other end of the lens support by pressing the other end of the lens support with an applied voltage based on a detection result by the acceleration detection unit. The imaging apparatus according to claim 2,
The image pickup apparatus, wherein the fixing unit includes a spring that is extended by the applied voltage and presses the lens support. The imaging apparatus according to claim 3,
An imaging apparatus in which the constituent material of the fixing unit includes a material in which a spring constant of the constituent material changes according to the applied voltage. The imaging apparatus according to claim 2,
The imaging device includes a constituent material of the fixing unit including a material whose shape changes depending on the applied voltage. The imaging apparatus according to claim 4 or 5, wherein
The fixing device adjusts a fixing strength when fixing the lens support so as not to slide based on the applied voltage. The imaging apparatus according to any one of claims 1 to 6,
A plurality of the lens supports;
The fixing device is an imaging device that can be fixed so that the plurality of lens supports do not slide simultaneously. The imaging apparatus according to any one of claims 1 to 7,
The said acceleration detection part is an imaging device which is an acceleration sensor.   A mobile phone terminal equipped with the imaging device according to claim 1.

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