JP2013054234A - Optical device, imaging device, power supply device, and lens cap - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve a problem in which: since power receiving coil is provided in a body of a camera in conventional cameras, it has been difficult to align positions of the power receiving coil and a power supply coil of an external charging device in charging power.SOLUTION: An imaging device includes: a body; an imaging element that is provided in the body; a lens that guides a subject image to the imaging element; a lens barrel that protrudes or can protrude from the body, and supports the lens; and a power receiving coil that is provided along an inner peripheral surface of the lens barrel, and charges a rechargeable battery using power supplied from an external power supply coil in a non-contact manner.

Description

  The present invention relates to an optical device, an imaging device, a power feeding device, and a lens cap.

2. Description of the Related Art There is a known camera that uses a magnetic induction action to provide a receiving coil that receives power from an external charging device in a contactless manner, and charges a rechargeable battery that is a power source using the power supplied to the receiving coil.
[Prior art documents]
[Patent Literature]
[Patent Document 1] JP 2010-128219 A

  However, since the power receiving coil is provided in the camera casing in the above-described camera, it is difficult to align the positions of the power receiving coil and the power feeding coil of the external charging device during charging.

  An optical device according to a first aspect of the present invention is provided along a housing, a lens barrel protruding or projectable from the housing, and an inner peripheral surface of the lens barrel, and is not in contact with an external power supply coil And a power receiving coil for charging the rechargeable battery using the power supplied in step (b).

  An imaging device according to a second aspect of the present invention includes the above-described optical device and an imaging element provided in a housing.

  In addition, the power feeding device according to the third aspect of the present invention is configured to receive a power when a lens barrel protruding from the housing of the optical device or the imaging device is insertable, and when the lens barrel is inserted into the recess. A power feeding coil facing the coil.

  The lens cap according to the fourth aspect of the present invention includes a power feeding coil that faces the power receiving coil when the lens cap is mounted on the lens barrel protruding from the housing of the optical device or the imaging device described above.

  It should be noted that the above summary of the invention does not enumerate all the necessary features of the present invention. In addition, a sub-combination of these feature groups can also be an invention.

It is a figure explaining the outline | summary of the charging system which concerns on this embodiment. It is principal part sectional drawing of the camera which concerns on this embodiment. It is a figure explaining an aperture unit. It is principal part sectional drawing of the electric power feeding pad which concerns on this embodiment. It is principal part sectional drawing of the electric power feeding pad which concerns on a 1st modification. It is principal part sectional drawing of the electric power feeding pad which concerns on a 2nd modification. It is a flowchart which shows the electric power feeding process in the electric power feeding pad which concerns on a 2nd modification. It is principal part sectional drawing of the electric power feeding pad which concerns on a 3rd modification. It is principal part sectional drawing of the lens cap which concerns on this embodiment.

  Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the invention according to the claims. In addition, not all the combinations of features described in the embodiments are essential for the solving means of the invention.

  FIG. 1 is a diagram illustrating an outline of a charging system 10 according to the present embodiment. The charging system 10 includes a camera 100 as an optical device and an imaging device, and a power supply pad 200 as a power supply device. As shown in FIG. 1, the camera 100 includes a housing 110, a lens barrel 120 protruding from the housing 110, and a power receiving coil 130 provided along the inner peripheral surface of the lens barrel 120. The power supply pad 200 includes a main body 210, a recess 220 provided in the main body 210, and a power supply coil 230 provided at the bottom of the recess 220.

  The recess 220 of the power supply pad 200 is formed in a shape into which the lens barrel 120 of the camera 100 can be inserted. The lens barrel 120 is guided to the side of the power supply pad 200 and reaches the vicinity of the bottom. The power supply coil 230 of the power supply pad 200 is disposed so as to face the power reception coil 130 of the camera 100 when the lens barrel 120 is inserted into the recess 220.

  The power supply pad 200 excites the power supply coil 230 at a predetermined frequency using power from an external power source in a state where the power supply coil 230 faces the power reception coil 130. Electric power is supplied from the power feeding coil 230 to the power receiving coil 130 in a non-contact manner by electromagnetic induction. The power receiving coil 130 charges the rechargeable battery 140 that is a power source of the camera 100 using the power supplied from the power feeding coil 230.

  Therefore, according to the charging system 10 of the present embodiment, the user can easily align the positions of the power feeding coil 230 and the power receiving coil 130 only by inserting the lens barrel 120 into the recess 220 and placing the camera 100 on the power feeding pad 200. be able to.

  FIG. 2 is a cross-sectional view of a main part of the camera 100 according to the present embodiment. The lens barrel 120 includes a lens 121 and an aperture unit 122 arranged along the optical axis 101. The lens barrel 120 is fixed to the housing 110 in a state of protruding from the housing 110. The lens barrel 120 may be formed integrally with the housing 110. The lens barrel 120 may be detachable from the housing 110. Further, the lens barrel 120 may be a so-called collapsible lens barrel that can project from the housing 110 in the direction of the optical axis 101.

  The lens 121 is a focus lens, for example, and is configured to be movable in the optical axis direction in accordance with a focus adjustment instruction. The lens 121 may be composed of a plurality of lenses such as a focus lens and a zoom lens. The aperture unit 122 is disposed between the imaging element 111 and the power receiving coil 130 in the direction of the optical axis 101.

  The lens 121 and the aperture unit 122 guide the incident subject light flux to the image sensor 111 provided in the housing 110. The imaging element 111 is a photoelectric conversion element such as a CCD or CMOS sensor, and converts an optical image of a subject formed on the light receiving surface into an electrical signal.

  The electrical signal photoelectrically converted by the image sensor 111 is processed into image data by the image processing unit 113 which is a DSP mounted on the main board 112. In addition to the image processing unit 113, a camera system control unit 114, which is an MPU that integrally controls the system of the camera 100, is mounted on the main board 112. The camera system control unit 114 manages the camera sequence and performs input / output processing of each component.

  A display unit 115 such as a liquid crystal monitor is provided on the rear surface of the housing 110, and a subject image processed by the image processing unit 113 on the main board 112 is displayed. The rear display unit 115 displays not only a still image after shooting, but also various menu information, shooting information, and the like.

  The housing 110 is provided with a wireless communication module 116 that performs wireless communication such as infrared communication and Bluetooth (registered trademark) with an external device. The housing 110 houses a detachable rechargeable battery 140 and functions as a power source for the camera 100.

  The power receiving coil 130 is provided along the inner peripheral surface of the lens barrel 120. The power receiving coil 130 is wound around the optical axis 101. In this way, by winding the power receiving coil 130 around the optical axis 101 along the inner peripheral surface of the lens barrel 120, a circular coil can be formed to increase the power supply efficiency.

  In addition, the power receiving coil 130 is disposed on the distal end side of the lens barrel 120, that is, on the side opposite to the coupling side with the housing 110 in the lens barrel 120. Therefore, the user can easily grasp the position of the power receiving coil 130.

  The power receiving coil 130 is connected to the rechargeable battery 140 through a power line. When power is supplied from the power supply pad 200, the power receiving coil 130 supplies power from the power supply pad 200 to the rechargeable battery 140.

  FIG. 3 is a diagram illustrating the aperture unit 122. The aperture unit 122 includes a plurality of aperture blades 123, a stepping motor 124, and a peripheral member 125. The stepping motor 124 functions as an aperture driving unit that drives the plurality of aperture blades 123 in either the opening direction or the minimum aperture direction. The peripheral member 125 supports the plurality of aperture blades 123 in a drivable manner and supports the stepping motor 124.

  An electromagnetic wave shielding sheet made of a material that shields electromagnetic waves such as copper, aluminum, and carbon is attached to the surface of the diaphragm blade 123. An electromagnetic wave shielding sheet is also attached to the surface of the peripheral member 125.

  When the power receiving coil 130 charges the rechargeable battery 140, the camera system control unit 114 transmits a drive signal to the stepping motor 124 so as to close the aperture blade 123 to the minimum aperture. The stepping motor 124 drives the diaphragm blade 123 according to the drive signal from the camera system control unit 114 to shift to the minimum diaphragm state.

  Therefore, during the charging process by the power receiving coil 130, the diaphragm blade 123 and the peripheral member 125 having the electromagnetic wave shielding sheet formed on the surface substantially cover the image sensor 111 when observed from the subject side, as shown in FIG. Therefore, the image sensor 111 can be protected from electromagnetic waves generated by the power receiving coil 130 and the power feeding coil 230 during the charging process.

  When the diaphragm unit 122 can completely close the diaphragm, the camera system control unit 114 causes the stepping motor 124 to completely close the diaphragm blade 123 when the power receiving coil 130 charges the rechargeable battery 140. A drive signal is transmitted to. Further, although the electromagnetic wave shielding sheet is provided on the surface of the diaphragm blade 123, the diaphragm blade 123 itself may be formed of a material that shields electromagnetic waves such as copper, aluminum, and carbon. Similarly, the peripheral member 125 itself may be formed of a material that blocks electromagnetic waves.

  FIG. 4 is a cross-sectional view of a main part of the power supply pad 200 according to the present embodiment. The recess 220 includes a bottom part 221, a side part 222, and an insertion port 223. A groove in which the power feeding coil 230 is disposed is formed in the bottom portion 221. The lens barrel 120 of the camera 100 is inserted into the recess 220 from the insertion port 223. Then, the side portion 222 guides the lens barrel 120 when the lens barrel 120 is inserted into the recess 220.

  The power feeding coil 230 faces the power receiving coil 130 when the tip of the lens barrel 120 reaches the vicinity of the bottom 221. The fact that the power feeding coil 230 faces the power receiving coil 130 refers to a state in which the deviation amount between the central axis of the power feeding coil 230 and the central axis of the power receiving coil 130 is disposed within a predetermined allowable range. Note that the allowable range is determined experimentally or simulationally for a deviation amount that achieves a predetermined power supply efficiency based on specifications such as the size and number of turns of the power feeding coil 230 and specifications such as the size and number of turns of the power receiving coil 130. It is determined in advance by calculation.

  The side portion 222 near the bottom portion 221 is provided with an insertion detection unit 240 that is configured by an infrared sensor or the like and detects insertion into the concave portion 220 of the lens barrel 120. The detection result of the insertion detection unit 240 is output to the power feeding system control unit 251 mounted on the main board 250. The power feeding system control unit 251 is configured by an MPU and integrally controls the system of the power feeding pad 200.

  In addition to the power supply system control unit 251, a power supply circuit 252 that controls power supply of the power supply coil 230 is mounted on the main board 250. When the power supply system control unit 251 determines that the lens barrel 120 has been inserted into the recess 220 from the detection result of the insertion detection unit 240, the power supply system control unit 251 outputs power supply command information for executing power supply processing to the power supply circuit 252. The power feeding circuit 252 starts power feeding by the power feeding coil 230 according to the power feeding command information from the power feeding system control unit 251.

  Specifically, the power supply circuit 252 excites the power supply coil 230 at a predetermined frequency using power from an external power source. Due to the electromagnetic induction action, an electromotive force is generated in the power receiving coil 130 facing the power feeding coil 230. The power receiving coil 130 supplies power generated by the electromagnetic induction action to the rechargeable battery 140 and charges the rechargeable battery 140.

  FIG. 5 is a cross-sectional view of a main part of a power supply pad 300 according to the first modification. In the first modification, the depth of the recess is changed by the biasing force of the spring. In addition, about the same structure as embodiment shown in FIG. 4, the same number is provided and only the changed part is demonstrated.

  The recess 310 of the power supply pad 300 includes a bottom 311, a side 312, and an insertion port 313. A power feeding coil 230 is provided on the bottom 311. Below the bottom portion 311, a spring 320 is provided as a biasing portion that biases the bottom portion 311 toward the insertion port 313. As shown in FIG. 5A, in the initial state where the lens barrel 120 of the camera 100 is not inserted into the recess 310, the bottom 311 is disposed in the vicinity of the insertion port 313 by the spring 320.

  An insertion detection unit 330 that includes an infrared sensor or the like and detects insertion of the lens barrel 120 into the recess 220 is provided on the side portion 312 near the lower side of the bottom portion 311 in the initial state. The detection result of the insertion detection unit 330 is output to the power supply system control unit 251 mounted on the main board 250.

  When the lens barrel 120 is inserted into the recess 310, the bottom 311 moves downward while being in contact with the lens barrel 120 due to the weight of the camera 100. Then, as shown in FIG. 5B, when the housing 110 of the camera 100 comes into contact with the upper surface of the main body 210 of the power supply pad 200, the movement of the bottom 311 is completed. The power feeding coil 230 faces the power receiving coil 130 after the movement of the bottom 311 starts.

  The power feeding system control unit 251 outputs power feeding command information for executing power feeding processing to the power feeding circuit 252 when the bottom 311 crosses the insertion detection unit 330. The power feeding circuit 252 starts power feeding by the power feeding coil 230 according to the power feeding command information from the power feeding system control unit 251. The specific power supply process is the same as the power supply process described with reference to FIG.

  By providing the movable bottom portion 311 and changing the depth from the insertion port 313 to the bottom portion 311 in this way, non-contact charging processing is executed for a plurality of cameras having different lens barrel lengths. be able to. Further, the use of the weight of the camera 100 eliminates the need for a driving device that drives the bottom 311.

  FIG. 6 is a cross-sectional view of a main part of a power supply pad 400 according to the second modification. In the second modification, the depth of the recess is changed by driving the motor. In addition, about the same structure as embodiment shown in FIG. 4, the same number is provided and only the changed part is demonstrated. A second modification will be described using the camera 100 including the retractable lens barrel 120.

  The recess 410 of the power supply pad 400 includes a bottom portion 411, a side portion 412, an insertion port 413, and a tapered portion 414 having a diameter wider than that of the side portion 412 in the vicinity of the insertion port 413. The tapered portion 414 guides the lens barrel 120 into the side portion 412 even if the lens barrel 120 of the camera 100 is placed with being shifted with respect to the center of the insertion port 413.

  A power feeding coil 230 is provided on the bottom portion 411. Below the bottom part 411, a support member 420 that supports the bottom part 411 so as to be movable is provided. As shown in FIG. 6A, in the initial state where the lens barrel 120 of the camera 100 is not inserted into the concave portion 410, the bottom 411 is disposed at the lowermost part in the movable range.

  A rack gear is formed on the support member 420. The motor 430 includes a pinion gear that engages with the rack gear of the support member 420, and functions as a bottom drive unit that moves the bottom 411 and the support member 420 in the depth direction of the recess. In addition to the above-described power supply system control unit 251, a drive circuit 441 that controls driving of the motor 430 is mounted on the main board 440.

  In the main body 210, a wireless communication module 450 that performs wireless communication such as infrared communication and Bluetooth (registered trademark) with an external device is provided. As shown in FIG. 6A, the wireless communication module 116 of the camera 100 in which the lens barrel 120 is housed in the casing 110 transmits protrusion amount information indicating the protrusion amount of the lens barrel 120 by wireless communication. The wireless communication module 450 of the power supply pad 400 functions as a reception unit that receives the protrusion amount information of the lens barrel 120 from the camera 100 in the vicinity of the power supply pad 400.

  When the wireless communication module 450 receives the protrusion amount information of the lens barrel 120, the power supply system control unit 251 determines the depth of the recess 410 for executing the power supply process. For example, the power feeding system control unit 251 determines the protruding amount of the lens barrel 120 as the depth of the concave portion 410. If the lens barrel 120 is projected when the projection amount of the lens barrel 120 is larger than the maximum depth of the recess 410, the lens barrel 120 may strongly collide with the bottom portion 411 and be damaged. Therefore, in this case, the wireless communication module 450 transmits an error signal to the camera 100 and prohibits the lens barrel 120 from protruding.

  The power feeding system control unit 251 outputs information on the determined depth of the recess 410 to the drive circuit 441. The drive circuit 441 calculates the drive amount of the motor 430 for setting the depth of the recess 410 determined by the power feeding system control unit 251. Then, the drive circuit 441 outputs a drive signal indicating the drive amount to the motor 430. The motor 430 drives the bottom 411 and the support member 420 according to the drive signal of the drive circuit 441.

  Further, the power feeding system control unit 251 transmits protrusion command information for instructing the lens barrel 120 to protrude to the camera 100 via the wireless communication module 450. When the camera system control unit 114 of the camera 100 receives the projection command information, the camera system control unit 114 projects the lens barrel 120. Then, when the projection of the lens barrel 120 is completed, the camera system control unit 114 transmits projection completion information to the power supply pad 400 via the wireless communication module 116.

  As shown in FIG. 6B, the power feeding system control unit 251 outputs power feeding command information for executing power feeding processing to the power feeding circuit 252 when the projection of the lens barrel 120 is completed and the movement of the bottom 411 is completed. . The power feeding circuit 252 starts power feeding by the power feeding coil 230 according to the power feeding command information from the power feeding system control unit 251. The specific power supply process is the same as the power supply process described with reference to FIG. Thus, by providing the bottom part 411 in which the depth from the insertion port 413 to the bottom part 411 can be changed, the non-contact charging process can be executed for a plurality of cameras having different lens barrel lengths.

  Further, the power feeding system control unit 251 may determine a value obtained by adding a predetermined gap to the protruding amount of the lens barrel 120 as the depth of the concave portion 410. By performing the power supply process with the lens barrel 120 and the bottom 411 being in non-contact, the load from the bottom 411 to the lens barrel 120 can be eliminated.

  FIG. 7 is a flowchart showing a charging process in the power supply pad 400 of the second modification. This flow is started when, for example, the power supply pad 400 is turned on. The power supply system control unit 251 executes this flow in cooperation with the power supply circuit 252, the drive circuit 441, the wireless communication module 450, and the like. In step S101, the drive circuit 441 outputs to the motor 430 a drive signal that moves the bottom 411 to the lowest position, which is the initial position shown in FIG. When the motor 430 is driven according to the drive signal, the bottom 411 moves to the initial position.

  In step S <b> 102, the power feeding system control unit 251 determines whether the protrusion amount information described above has been received from the camera 100. The process waits until the protrusion amount information is received. When the protrusion amount information is received, the process proceeds to step S103. When the protrusion amount information is received and the protrusion amount of the lens barrel 120 is larger than the maximum depth of the recess 410, the power feeding system control unit 251 transmits an error signal to the camera 100 and ends this flow.

  In step S <b> 103, the power feeding system control unit 251 determines the depth of the recess 410 for executing the power feeding process, and outputs the depth information of the recess 410 to the drive circuit 441. Then, the drive circuit 441 calculates the drive amount of the motor 430 for making the depth of the recess 410.

  In step S104, the drive circuit 441 outputs a drive signal indicating the drive amount calculated in step S103 to the motor 430. The motor 430 is driven by the drive amount indicated by the drive signal to move the bottom portion 411. In step S <b> 105, the power feeding system control unit 251 transmits the protrusion command information described above to the camera 100. In step S <b> 106, the power feeding system control unit 251 determines whether the protrusion completion information described above has been received from the camera 100. The process waits until the protrusion completion information is received. When the protrusion completion information is received, the process proceeds to step S107.

  In step S <b> 107, the power supply system control unit 251 outputs the above-described power supply command information to the power supply circuit 252. The power feeding circuit 252 starts power feeding by the power feeding coil 230 according to the power feeding command information. In step S <b> 108, the power feeding system control unit 251 determines whether or not charging completion information indicating completion of charging has been received from the camera 100. If the charging completion information has not been received, the process proceeds to step S109. If the charging completion information has been received, this flow ends.

  In step S <b> 109, the power supply system control unit 251 determines whether the camera 100 has been removed from the power supply pad 400. For example, the power supply system control unit 251 determines that the camera 100 has been removed from the power supply pad 400 when the wireless communication module 450 has lost communication with the wireless communication module 116 of the camera 100. If the camera 100 is placed on the power supply pad, the process returns to step S107 to continue the power supply process. If the camera 100 is removed from the power supply pad, this flow ends.

  Since the initial position of the bottom part 411 is the lowest part of the movable range, the lens barrel 120 does not collide with the bottom part 411 during the projection of the lens barrel 120 even if the lens barrel 120 is projected first. Therefore, the power feeding system control unit 251 may execute the process of step S105 before steps S103 and S104 or simultaneously with these processes.

  Further, the initial position of the bottom 411 may be the uppermost part or the middle part of the movable range. If the lens barrel 120 is projected before the bottom portion 411 is driven when the uppermost portion and the middle portion are set as the initial positions, the lens barrel 120 can strongly collide with the bottom portion 411 while the lens barrel 120 is projected. There is sex. Therefore, the power feeding system control unit 251 executes step S105 after the driving of the bottom portion 411 is completed in step S104.

  FIG. 8 is a cross-sectional view of a main part of a power supply pad 500 according to the third modification. In the third modified example, unlike the first modified example and the second modified example described above, the bottom of the recess does not move. In the third modification, the protruding amount of the retractable lens barrel 120 is controlled according to the depth of the concave portion defined in advance. In addition, about the same structure as embodiment shown in FIG. 4, the same number is provided and only the changed part is demonstrated.

  The recess 510 of the power supply pad 500 includes a bottom portion 511, a side portion 512, an insertion port 513, and a tapered portion 514 whose diameter is wider than the side portion 512 in the vicinity of the insertion port 513. Similar to the second modification, even if the position of the retractable lens barrel 120 slightly deviates from the side portion 512 when the camera 100 is placed, the tapered portion 514 moves the lens barrel 120 into the side portion 512. invite.

  On the upper surface of the main body 210 of the power supply pad 500, a placement detection unit 520 configured by a load sensor or the like that detects placement on the upper surface of the main body 210 of the camera 100 is provided. The detection result of the placement detection unit 520 is output to the power feeding system control unit 251. The power feeding system control unit 251 determines whether the camera 100 placed on the power feeding pad 500 includes the retractable lens barrel 120 according to the outputs of the insertion detection unit 240 and the placement detection unit 520.

  Specifically, the power supply system control unit 251 detects the retractable lens barrel 120 when the camera 100 is placed on the upper surface of the main body 210 but insertion into the concave portion 510 of the lens barrel 120 is not detected. It is determined that the camera 100 provided with is placed on the power supply pad 500. FIG. 8A shows a state in which the camera 100 including the retractable lens barrel 120 is placed on the power supply pad 500.

  On the other hand, when the camera 100 is detected to be placed on the upper surface of the main body 210 and inserted into the recess 510 of the lens barrel 120 almost simultaneously, the camera 100 from which the lens barrel 120 protrudes is placed on the power supply pad 500. Judge that it was done. In this case, as described with reference to FIG. 4, the power supply system control unit 251 executes the power supply process immediately after the camera 100 is placed on the power supply pad 500.

  In the main body 210, a wireless communication module 530 that performs wireless communication such as infrared communication and Bluetooth (registered trademark) with an external device is provided. When the camera 100 including the retractable lens barrel 120 is placed on the power supply pad 500, the power supply system control unit 251 transmits the protrusion command information for instructing the protrusion of a predetermined protrusion amount to the wireless communication module 530. To the camera 100. The predetermined protrusion amount is, for example, the depth of the recess 220.

  When the camera system control unit 114 of the camera 100 receives the projection command information from the power supply pad 500, the camera system control unit 114 projects the lens barrel 120 by the projection amount indicated by the projection command information. Then, when the projection of the lens barrel 120 is completed, the camera system control unit 114 transmits projection completion information to the power supply pad 500 via the wireless communication module 116.

  FIG. 8B shows a state where the projection of the lens barrel 120 is completed. When the projection of the lens barrel 120 is completed, the power supply system control unit 251 outputs power supply command information for executing power supply processing to the power supply circuit 252. The power feeding circuit 252 starts power feeding by the power feeding coil 230 according to the power feeding command information from the power feeding system control unit 251. By controlling the protruding amount of the lens barrel 120 according to the depth of the recess 220 in this way, the non-contact charging process can be executed for a plurality of retractable cameras having different protruding amounts of the lens barrel. it can.

  Further, the above-described predetermined protrusion amount may be a value obtained by subtracting a predetermined gap from the depth of the recess 220. By performing the power feeding process with the lens barrel 120 and the bottom 221 being in non-contact, the load from the bottom 221 to the lens barrel 120 can be eliminated.

  Next, an embodiment in which a lens cap is used as a power feeding device instead of the above-described power feeding pad will be described. FIG. 9 is a cross-sectional view of a main part of the lens cap 600 according to the present embodiment. The lens cap 600 includes a power feeding coil 610, a mounting detection unit 620, a power feeding circuit 630, and a rechargeable battery 640.

  The feeding coil 610 is provided on the mounting side of the camera 100. The feeding coil 610 faces the power receiving coil 130 in the lens barrel 120 when the lens cap 600 is attached to the lens barrel 120 protruding from the camera 100. The mounting detection unit 620 includes a load sensor or the like, and is disposed on a mounting member with the lens barrel 120. The attachment detection unit 620 detects whether or not the lens cap 600 is attached to the lens barrel 120.

  The power feeding circuit 630 controls power feeding of the power feeding coil 610. Specifically, the power feeding circuit 630 starts power feeding by the power feeding coil 610 using the rechargeable battery 640 when the mounting detection unit 620 detects the mounting of the lens cap 600 on the lens barrel 120. The power feeding process of the power feeding circuit 630 is the same as that of the power feeding circuit 252 described above. The rechargeable battery 640 is detachably attached to the lens cap 600.

  By providing the power supply coil 610 in the lens cap 600 as described above, the positions of the power supply coil 230 and the power reception coil 130 can be easily aligned only by attaching the lens cap 600 to the lens barrel 120. In addition, the rechargeable battery of the camera 100 can be charged while moving while holding the camera 100 with the lens cap 600 attached to the lens barrel 120. Furthermore, the user can charge the camera 100 using the above-described power supply pad at home, and can charge the camera 100 using the lens cap 600 when going out.

  Note that the lens cap 600 may further include a connection portion that connects to an external power source. In this case, the power feeding circuit 630 charges the rechargeable battery 640 using power supplied from an external power source. In addition, the lens cap 600 may include a connection unit that connects to an external power source instead of the rechargeable battery 640. In this case, the power feeding circuit 630 controls power feeding by the power feeding coil 610 using power supplied from an external power source.

  In the above-described embodiment, the contactless charging is performed using the power feeding coil 610 and the power receiving coil 130, but the present invention is not limited thereto, and the charging of the rechargeable battery 640 may be performed on the rechargeable battery 140. Specifically, on the lens cap 600 side, instead of the feeding coil 610, a first connector is provided on a mounting member for the lens barrel 120, and the first connector and the rechargeable battery 640 are connected by a power line. Similarly, on the lens barrel side, a second connector is provided on a mounting member for the lens cap 600 instead of the power receiving coil 130, and the second connector and the rechargeable battery 140 are connected by a power line.

  Then, when the lens cap 600 is attached to the lens barrel 120, the first connector and the second connector are arranged so that the first connector and the second connector are connected. With the first connector and the second connector, when the lens cap 600 is attached to the lens barrel 120, power is supplied from the rechargeable battery 640 of the lens cap 600 to the rechargeable battery 140 of the camera 100. In addition, the lens cap 600 may be provided with a connection portion that is connected to an external power source instead of the rechargeable battery 640. In this case, the first connector is connected to the connection portion by a power line. When the lens cap 600 is attached to the lens barrel 120, power is supplied from the external power source to the rechargeable battery 140 of the camera 100.

  In the above-described embodiment, the power receiving coil 130 is wound around the optical axis 101, but the power receiving coil 130 may be arranged in a state in which its own central axis is deviated from the optical axis 101. Further, the power receiving coil 130 is disposed on the distal end side of the lens barrel 120. However, as long as non-contact charging can be performed, the power receiving coil 130 may be disposed on the center portion of the lens barrel 120 and on the coupling side with the housing 110. Good.

  In the above-described embodiment, the number of power receiving coils is one, but a plurality of power receiving coils may be used. For example, the plurality of power receiving coils are wound around the optical axis of the lens, and are arranged in the lens barrel in order along the optical axis of the lens.

  The plurality of power receiving coils may be disposed along the inner peripheral surface of the lens barrel. The center axis of each power receiving coil arranged along the inner peripheral surface of the lens barrel may be parallel to the optical axis of the lens. In this case, the above-described power supply pad includes at least one power supply coil that faces at least one of the plurality of power reception coils when the lens barrel is inserted into the recess. Further, the center axis of each power receiving coil arranged along the inner peripheral surface of the lens barrel may be perpendicular to the optical axis of the lens. In this case, the above-described power supply pad includes at least one power supply coil that faces at least one of the plurality of power receiving coils when the lens barrel is inserted into the recess, on the side of the recess. The intervals between the plurality of power receiving coils may be equal.

  In the above-described embodiment, the camera system control unit 114 may display information on the charging state on the display unit 115 of the camera 100 during the charging process of the camera 100. For example, the camera system control unit 114 causes the display unit 115 to display an icon indicating a charging state. The user can check the charging state on the display unit 115 and determine whether or not to end the charging.

  In the above-described embodiment, the electromagnetic induction method is used as the non-contact charging method, but other non-contact charging methods may be applied. For example, an electric field coupling method in which an electrode on the power feeding side and an electrode on the power receiving side are opposed to each other and power is fed using an induced electric field generated between the electrodes is used. Specifically, on the lens barrel side, at least one power receiving electrode is provided along the inner peripheral surface of the lens barrel instead of the power receiving coil. In the power supply pad, at least one power supply electrode is provided on the side of the recess instead of the power supply coil.

  The power supply electrode is disposed so as to face the power reception electrode when the lens barrel is inserted into the recess of the power supply pad. In a state where the power feeding electrode and the power receiving electrode face each other, the power feeding circuit of the power feeding pad supplies power to the power feeding electrode. Then, an induction electric field is generated between the electrodes, and power is transmitted from the power supply electrode to the power reception electrode. The power receiving electrode supplies power from the power feeding electrode to the rechargeable battery.

  In the above-described embodiment, the unit of the image sensor 111 is incorporated in the housing 110, but the unit of the image sensor 111 may be detachable. In this case, the remaining part obtained by removing the unit of the image sensor 111 from the camera 100 constitutes an optical device including a housing, a lens barrel, and a power receiving coil. Moreover, although the camera 100 is used as the optical device, the present invention is not limited thereto, and the above-described non-contact charging function may be applied to an optical device such as a telescope, binoculars, and a microscope.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in said embodiment. It will be apparent to those skilled in the art that various modifications and improvements can be made to the above embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

  The order of execution of each process such as operations, procedures, steps, and stages in the apparatus, system, program, and method shown in the claims, the description, and the drawings is particularly “before” or “prior to”. It should be noted that the output can be realized in any order unless the output of the previous process is used in the subsequent process. Regarding the operation flow in the claims, the description, and the drawings, even if it is described using “first”, “next”, etc. for convenience, it means that it is essential to carry out in this order. It is not a thing.

DESCRIPTION OF SYMBOLS 10 Charging system, 100 Camera, 101 Optical axis, 110 Case, 111 Image sensor, 112 Main board, 113 Image processing part, 114 Camera system control part, 115 Display part, 116 Wireless communication module, 120 Lens barrel, 121 Lens 122 aperture unit, 123 aperture blade, 124 stepping motor, 125 peripheral member, 130 power receiving coil, 140 rechargeable battery, 200 power supply pad, 210 main body, 220 recess, 221 bottom, 222 side, 223 insertion port, 230 power supply coil, 240 Insertion detection unit, 250 Main board, 251 Power supply system control unit, 252 Power supply circuit, 300 Power supply pad, 310 Recessed part, 311 Bottom part, 312 Side part, 313 Insertion port, 320 Spring, 330 Insertion detection part, 400 Power supply pad, 410Recessed portion, 411 bottom portion, 412 side portion, 413 insertion port, 414 taper portion, 420 support member, 430 motor, 440 main board, 441 drive circuit, 450 wireless communication module, 500 power supply pad, 510 recessed portion, 511 bottom portion, 512 side portion 513 insertion port, 514 taper part, 520 placement detection part, 530 wireless communication module, 600 lens cap, 610 feeding coil, 620 wearing detection part, 630 feeding circuit, 640 rechargeable battery

Claims (17)

A housing,
A lens barrel protruding or projectable from the housing;
An optical device comprising: a power receiving coil that is provided along an inner peripheral surface of the lens barrel and charges a rechargeable battery using electric power supplied in a non-contact manner from an external power feeding coil.   The optical device according to claim 1, wherein the power receiving coil is wound around an optical axis of a lens supported by the lens barrel.   The optical device according to claim 1, wherein the power receiving coil is disposed on a distal end side of the lens barrel. An optical device according to any one of claims 1 to 3,
An imaging device comprising: an imaging element provided in the housing. At least the surface has an aperture blade formed of a material that blocks electromagnetic waves, and includes an aperture unit supported by the lens barrel,
The imaging device according to claim 4, wherein the aperture unit is disposed between the imaging element and the power receiving coil in an optical axis direction of the lens.   The imaging device according to claim 5, further comprising an aperture driving unit that closes the aperture blade when the power receiving coil charges the rechargeable battery.   The imaging apparatus according to claim 5, wherein the aperture unit includes a peripheral member having at least a surface formed of a material that blocks electromagnetic waves and provided around the aperture blade. A concave portion into which the lens barrel protruding from the housing of the optical device according to any one of claims 1 to 3 or the imaging device according to any one of claims 4 to 7 can be inserted;
A power supply apparatus comprising: the power supply coil facing the power reception coil when the lens barrel is inserted into the recess.   The power feeding device according to claim 8, wherein the power feeding coil is disposed at a bottom of the recess.   The power feeding device according to claim 9, wherein the bottom portion is provided so that a depth from an insertion port of the concave portion to the bottom portion can be changed.   The power feeding device according to claim 10, further comprising an urging portion that urges the bottom portion toward the insertion port. A receiving unit that receives information of a protruding amount of the lens barrel protruding from the housing;
The power feeding device according to claim 10, further comprising: a bottom drive unit that moves the bottom in the depth direction based on the protrusion amount.   The projector according to any one of claims 8 to 12, further comprising: a transmission unit configured to transmit projection command information for commanding a projection amount of the lens barrel from the housing to the imaging device including the lens barrel capable of projecting from the housing. The power feeding device according to claim 1. An insertion detector for detecting insertion of the lens barrel into the recess;
The power supply device according to any one of claims 8 to 13, further comprising a power supply control unit that starts power supply by the power supply coil when insertion of the lens barrel into the concave portion is detected.   When mounted on the lens barrel protruding from the housing of the optical device according to any one of claims 1 to 3 or the imaging device according to any one of claims 4 to 7, A lens cap including the power feeding coil facing the power receiving coil. An attachment detection unit for detecting attachment to the lens barrel;
The lens cap according to claim 15, further comprising: a power supply control unit that starts power supply by the power supply coil when attachment to the lens barrel is detected. Cap side rechargeable battery
The lens cap according to claim 16, wherein the power supply control unit controls power supply by the power supply coil using the cap-side rechargeable battery.

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