JP2020188336A - Imaging device, shooting lens, and accessory - Google Patents

Abstract

To improve operability when an accessory member such as an interchangeable lens unit (shooting lens) is attached and detached to and from the main body of an imaging device.SOLUTION: An imaging device 10 includes a movable portion to which a shooting lens 50 is detachably attached and a main body 30 that movably supports the movable portion, and a lens detection unit 205 detects that a shooting lens is attached to the movable portion. A first regulation unit 305 regulates the rotation of the movable portion in the pan direction, and a second regulation unit 208 regulates the rotation of the movable portion in the tilt direction. When the lens detection unit detects that the shooting lens is attached, a control unit 207 controls the first regulation unit and the second regulation unit to regulate the rotation angle of the movable portion within a predetermined range.SELECTED DRAWING: Figure 2

Description

The present invention relates to an image pickup device, a photographing lens, and an accessory, and more particularly to an image pickup device in which an accessory member such as an interchangeable lens unit can be attached to and detached from the image pickup device main body.

In recent years, video distribution services using communication networks such as the Internet have become widespread. The data processing capacity of the information communication terminal has been improved, and the environment is such that high-quality video content can be easily used.

In such an environment, there is an increasing demand for higher image quality for image pickup devices that capture moving images. In such an image pickup device, for example, a large solid-state image sensor is mounted so that high-quality moving images can be recorded by combining a large-diameter interchangeable lens unit.

By the way, in digital cameras and the like, various accessories such as an interchangeable lens unit and a grip (grip member) can be attached to and detached from the camera body to enable various shooting and video recording according to the user's request. It is known (Patent Document 1).

In Patent Document 1, for example, the gripping member is held between a first posture in which the handle portion of the gripping member is located below the camera body and a second posture in which the handle portion is located above the camera body. It can be displaced with respect to the camera body. As a result, it is possible to switch between high-angle shooting and low-angle shooting to support various shooting styles without having to change the gripping member.

JP-A-2015-207886

However, in the image pickup apparatus described in Patent Document 1 described above, for example, when the interchangeable lens unit is replaced while the handle portion is gripped, the mount portion of the camera body connected to the interchangeable lens unit is attached to the gripping member. There is a risk that it will move relatively. That is, in the image pickup apparatus described in Patent Document 1, it may not be possible to replace the interchangeable lens unit while grasping the handle portion, and it takes time to replace the lens.

Therefore, an object of the present invention is to provide an imaging device, a photographing lens, and an accessory capable of improving operability when attaching / detaching an accessory member such as an interchangeable lens unit (photographing lens) to the image capturing apparatus main body. It is in.

In order to achieve the above object, the imaging device according to the present invention is an imaging device in which the photographing lens is interchangeable, and the movable portion to which the photographing lens is detachably attached and the movable portion are movably supported. A main body portion, a lens detection unit that detects that the photographing lens is attached to the movable portion, a first regulating portion that regulates the rotation of the movable portion in the pan direction, and a tilt direction of the movable portion. When the mounting of the photographing lens is detected by the second regulating unit that regulates the rotation and the lens detecting unit, the rotation of the movable portion is controlled by controlling the first regulating unit and the second regulating unit. It is characterized by having a control unit that regulates an angle within a predetermined range.

According to the present invention, it is possible to improve the operability when attaching / detaching an accessory member such as an interchangeable lens unit (shooting lens) to / from the image pickup apparatus main body.

It is a perspective view which shows the appearance of the image pickup apparatus according to embodiment of this invention. It is a block diagram which shows an example about the structure of the image pickup apparatus shown in FIG. It is a perspective view which shows the movable part shown in FIG. 1 in an exploded manner. It is sectional drawing which shows the structure of the tilt rotation regulation part shown in FIG. It is a figure for demonstrating the structure of the fixed part shown in FIG. It is a figure for demonstrating the structure of the pan rotation regulation part shown in FIG. It is a figure which shows the relationship between the position of the hinge torque operation part shown in FIG. 2, the presence or absence of rotation regulation of a hinge unit, and whether or not a lens unit can be removed. It is a figure for demonstrating the inclination with respect to the tilt rotation axis in the image pickup apparatus shown in FIG.

An example of the image pickup apparatus according to the embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a perspective view showing the appearance of an image pickup apparatus according to an embodiment of the present invention. FIG. 1A is a perspective view seen from the front side, and FIG. 1B is a perspective view seen from the back side.

The illustrated image pickup device 10 includes an image pickup device main body having a movable portion 20 and a fixed portion (main body portion) 30. The movable portion 20 is attached to the fixed portion 30 by the hinge unit (connecting portion) 40, and the position of the movable portion 20 with respect to the fixed portion 30 can be changed by the hinge unit 40. An interchangeable lens unit (hereinafter, simply referred to as a lens unit) 50 is detachably attached to the movable portion 20.

The lens unit (photographing lens) 50 is attached to the movable portion 20 by, for example, a so-called bayonet type attachment structure. That is, the bayonet claw portion 507 is formed on the lens unit 50, and the lens mount 211 is formed on the movable portion 20.

When attaching the lens unit 50 to the movable portion 20, first, the protruding portion of the bayonet claw portion 507 is aligned with the notch formed inside the lens mount 211. Then, the lens unit 50 is inserted into the movable portion 20, and the lens unit 50 is rotated around the optical axis of the lens unit 50 and attached to the movable portion 20.

Further, the lens mount 211 is formed with a movable pin (not shown) that is a part of the lens rotation restricting portion 204 protruding. By engaging the movable pin with the recess 508 formed in the lens unit 50, the lens rotation regulating portion 204 regulates that the lens unit 50 is removed from the state in which the lens unit 50 is mounted on the movable portion 20.

On the other hand, when the lens unit 50 is removed from the movable portion 20, the hinge torque operating portion (hereinafter, also simply referred to as the operating portion) 202 is operated to retract the movable pin inward so that the bayonet claw portion 507 and the lens mount 211 are connected. Disengage.

When the lens unit 50 is attached to the movable portion 20, the interface portion provided with the movable portion 20 (IF: not shown in FIG. 1) and the interface portion provided with the lens unit 50 (not shown with FIG. 1). Is electrically connected. As a result, as will be described later, the lens unit 50 and the movable portion 20 can communicate with each other.

The movable portion 20 is held by the hinge unit 40. The hinge unit 40 is a biaxial hinge having a tilt rotation hinge 401 and a pan rotation hinge 402. The tilt rotation hinge 401 is rotatably fixed to the movable portion 20 on the rotation axis T. Further, the pan rotation hinge 402 is rotatably fixed to the fixing portion 30 on the rotation shaft P.

As a result, the movable portion 20 and the lens unit 50 can be changed to various postures with respect to the fixed portion 30 by rotating the tilt rotation hinge 401 and the pan rotation hinge 402.

The fixing unit 30 is provided with a display unit 303. The display unit 303 is, for example, an LCD (Liquid Crystal Display) or an organic EL (Electro-luminescence) display. The display unit 303 displays an image obtained by shooting, a screen for setting shooting conditions, and the like. The display unit 303 may be a display having a touch panel function.

The fixing portion 30 is provided with a grip portion 304. The grip portion 304 is formed at the end of the fixing portion 30, and its surface is formed of an elastic material. For example, ethylene propylene diene rubber (EPDM) or silicone rubber is used as a surface material.

The user can take pictures from various angles by freely rotating the lens unit 50 and the movable portion 20 with the other hand while holding the grip portion 304 with one hand. The movable portion 20 is provided with an accessory shoe 209, and an external accessory other than the lens unit is attached to the accessory shoe 209. For example, the accessory shoe 209 is equipped with a video light, an external microphone, or the like as an external accessory.

The accessory shoe 209 is provided with an accessory detection unit (not shown in FIG. 1) inside the accessory shoe 209, and when the accessory is attached to the accessory shoe 209, information indicating the type of the accessory is shown as described later. Can be obtained.

FIG. 2 is a block diagram showing an example of the configuration of the image pickup apparatus shown in FIG.

The lens unit 50 includes a photographing optical system 501, and the photographing optical system 501 includes a plurality of lenses, a holder for holding these lenses, a zoom lens mechanism, a focus lens mechanism, and a shake correction lens mechanism.

Further, the lens unit 50 has an aperture unit 502, and as the aperture unit 502, for example, a glow aperture unit that drives a plurality of thin light-shielding sheets to change the size of an aperture defined around the optical axis. Used.

The lens driving unit 503 includes a zoom lens mechanism, a focus lens mechanism, a shake correction lens mechanism, and an actuator for driving the aperture unit 502. The actuators used for each of these mechanisms and units are appropriately selected in consideration of the thrust, speed, stroke, stopping accuracy, power consumption, manufacturing cost, etc. required for driving. For example, as the actuator, a DC motor, a stepping motor, a USM (Ultrasonic Motor), or the like is used.

The lens control unit 504 has a motor driver IC, and drives and controls various actuators provided in the lens drive unit 503. By electrically connecting the lens unit 50 and the movable unit 20 by the interface units (IF) 506 and 205, the lens control unit 504 and the central control unit 207 can communicate with each other.

The lens unit 50 further includes a runout detection unit (posture detection unit) 505, and as the runout detection unit 505, for example, a gyro sensor or an acceleration sensor is used. The runout detection result, which is the output of the runout detection unit 505, is sent to the lens control unit 504. Then, the lens control unit 504 sends the runout detection result as an analog signal or digital data to the central control unit 207 via the IF 506 and 205. As a result, the central control unit 207 can know the inclination of the lens unit 50.

The movable unit 20 is provided with an imaging unit 201. The image pickup unit 201 includes an image pickup element such as a CCD (Charge Coupled Device) sensor or a CMOS (Complementary MOS) sensor, and also has a low-pass filter. The low-pass filter blocks the incidence of infrared rays and prevents the occurrence of color moiré. An optical image is formed on the image sensor via the photographing optical system 502 and a low-pass filter, and the image pickup unit 201 outputs an image signal corresponding to the optical image.

The central control unit 207 has a CPU (Central Processing Unit) that controls the entire image pickup device 10. The image signal output from the image pickup unit 201 is sent to the central control unit 207, and the central control unit 207 performs predetermined image processing to generate image data. The predetermined image processing includes electronic vibration isolation processing by image cropping and rotation processing.

The central control unit 207 records the above image data in the recording unit 210. At this time, the central control unit 207 records the shooting date and time, the setting conditions of the imaging device 10 at the time of shooting, and the like.

The operation unit 202 is a member operated by the user when the lens unit 50 is removed from the movable unit 20, and can transition between a plurality of positions. The operation unit position detection unit 203 detects the position of the operation unit 202. For example, the operation unit position detection unit 203 detects the position of the operation unit 202 by a transmissive photo interrupter or the like whose output signal changes according to the amount of received light. The position detection result obtained by the operation unit position detection unit 203 is sent to the central control unit 207. Further, by operating the operation unit 202, the tilt rotation regulation unit 204 and the pan rotation regulation unit 305 operate as described later.

As described above, the movable portion 20 is rotatably held by the hinge unit 40, and the hinge unit 40 has a tilt rotation hinge 401 and a pan rotation hinge 402. The tilt rotation hinge 401 is provided with a tilt rotor 403 mounted around the rotation shaft T. The tilt rotor 403 is arranged inside the movable portion 20 and is fixed to the tilt rotation hinge 401.

Further, the movable portion 20 is provided with a tilt rotation restricting unit 208, which is arranged at a position facing the tilt rotor 403 and is rotatably held together with the movable portion 20 with respect to the rotation axis T. .. As the tilt rotation regulating unit 208, for example, a linear solenoid actuator that slides the movable pin back and forth by electronic control is used.

Under the control of the central control unit 207, the tilt rotation control unit 208 reciprocates between a position where the movable pin is pressed against the surface of the tilt rotor 403 and a position where the movable pin is retracted from the surface of the tilt rotor 403.

In the position where the movable pin presses the surface of the tilt rotor 403, the frictional load for rotating the movable portion 20 with respect to the tilt rotation hinge 401 increases, and the movable portion 20 does not easily rotate.

On the other hand, in the position where the movable pin is retracted from the surface of the tilt rotor 403, the friction load is reduced and the movable portion 20 is smoothly rotated with a predetermined amount of dynamic torque.

In the position where the movable pin is retracted from the surface of the tilt rotor 403, the hinge unit 40 has a predetermined amount of holding force in a state where the tilt rotation hinge 401 and the pan rotation hinge 402 are stopped. The holding force is set to be higher than the static torque at which the hinge unit 40 maintains the stopped posture while receiving the weight of the lens unit 50 and the movable portion 20.

Therefore, in this position, when the user points the lens unit 50 at the subject and stops the rotation of the hinge unit 40, the lens unit 50 and the movable portion 20 can maintain their postures as they are.

The movable unit 20 is provided with a tilt angle detection unit (angle detection unit) 243 that detects the rotation angle of the tilt rotor 403. The central control unit 207 can know the angle of the movable unit 20 with respect to the hinge unit 40 according to the detection result of the tilt angle detection unit 243.

The pan rotation hinge 402 is provided with a pan rotor 404 mounted around the rotation shaft P. The pan rotor 404 is arranged inside the fixing portion 30 and is fixed to the pan rotating hinge 402.

Further, the fixing portion 30 is provided with a pan rotation regulating portion 305. The pan rotation restricting portion 305 is arranged at a position facing the pan rotor 404, and is fixedly held by the fixing portion 30. As the pan rotation regulating unit 305, a linear solenoid actuator or the like is used as in the tilt rotation regulating unit 208.

Under the control of the central control unit 207, the pan rotation regulation unit 305 reciprocates in the same manner as the tilt regulation unit 208. Specifically, the pan rotation regulating unit 305 reciprocates the pressing member that regulates the movement of the pan rotor 404 by driving the solenoid actuator. Here, the pan rotation regulating unit 305 reciprocates between the position where the pressing member presses the surface of the pan rotor 404 and the position where the pressing member retracts from the surface of the pan rotor 404.

In the position where the pressing member presses the surface of the pan rotor 404, the frictional load for rotating the pan rotation hinge 402 with respect to the fixed portion 30 increases, and the movable portion 20 does not easily rotate.

On the other hand, in the position where the pressing member is retracted from the surface of the pan rotor 404, the frictional load is reduced and the movable portion 20 is in a state of smoothly rotating.

The fixing portion 30 is provided with a pan angle detecting portion 321 for detecting the rotation angle of the pan rotor 404. The central control unit 207 can know the angle of the movable unit 20 with respect to the fixed unit 30 according to the detection result of the pan angle detecting unit 321.

The central control unit 207 controls the tilt rotation control unit 208 and the pan rotation control unit 305 according to the position detection result which is the output of the operation unit position detection unit 203. The control method will be described later.

The movable portion 20 is further provided with a runout detecting portion 206. As the runout detection unit 206, for example, a gyro sensor or an acceleration sensor is used. The runout detection result, which is the output of the runout detection unit 206, is sent to the central control unit 207 as an analog signal or digital data.

The central control unit 207 can know the inclination of the movable unit 20 according to the runout detection result sent from the runout detection unit 206. By providing the movable portion 20 with a shake detecting portion, it is possible to detect the inclination of the movable portion 20 even when the lens unit 50 is not attached.

As described above, the fixing portion 30 is provided with the grip portion 304. The grip portion 304 is formed at the end portion of the fixing portion 30, and an elastic material is used for the surface thereof. Then, the operation unit 301 is arranged at a position where the user can operate the grip unit 304 while holding the grip unit 304.

Further, the fixing unit 30 is provided with a power supply unit 302 and a display unit 303. As described above, the display unit 303 displays an image obtained by shooting, a screen for setting shooting conditions, and the like. As the power supply unit 302, for example, a battery pack equipped with an alkaline secondary battery or a lithium ion secondary battery is used. Then, the power supply unit 302 is electrically connected to the central control unit 207 via a wire harness or the like wired inside the hinge unit 40 to supply power to the image pickup apparatus 10.

The fixed portion 30 is provided with a runout detecting portion 322 like the movable portion 20. Then, for example, a gyro sensor or an acceleration sensor is used as the runout detection unit 322. The runout detection result, which is the output of the runout detection unit 322, is sent to the central control unit 207 as an analog signal or digital data. The central control unit 207 can know the inclination of the fixing unit 30 according to the runout detection result sent from the runout detection unit 322.

FIG. 3 is a perspective view showing the movable portion shown in FIG. 1 in an exploded manner.

The lens mount 211 is fixed to the base member 212 by screws 215a to 215d. The base member 212 includes metal die-cast parts, and for example, magnesium alloy die-cast or aluminum alloy die-cast is used. Further, the base member 212 includes a lens rotation regulation unit 204 and an interface unit (lens detection unit) 205.

The interface portion 205 has a plurality of contact pins, an urging member such as a coil spring, and a resin case containing these, and the plurality of contact pins project from the opening of the resin case. The contact pin is constantly urged from the back side by an urging member (not shown). Further, the contact pin can be slid inward from the surface of the resin case.

A flexible printed circuit board 214 is connected to the interface unit 205, and the conductive pattern wired inside the flexible printed circuit board and the contact pins are electrically conductive according to the protruding positions of the contact pins. By pushing the contact pin inward from the surface of the resin case by a predetermined amount, the contact pin and the conductive pattern are electrically conductive.

The movable portion 20 is provided with a side cover 213. The accessory shoe 209 is fixed to the side cover 213 by two screws 216. Then, the screws 217a and 217b are fastened to the base member 212 from the screw holes formed in the accessory shoe 209 through the escape holes of the side cover 213. As a result, the side cover 213 is fixed to the base member 212.

After that, the imaging unit 201 is fixed to the base member 212 by screws 223a to 223c. As described above, the image pickup unit 201 has an image sensor and a low-pass filter. Further, the image pickup unit 201 includes an image pickup element and has a rigid package electrically connected to the image pickup element. Then, the hard package is mounted on the printed circuit board, various electronic components are mounted on the printed circuit board, and the hard package is adhesively fixed to the metal plate in advance.

As the hard package, for example, a multilayer substrate having a ceramic base material is used, and a conductor pattern is formed inside the hard package. A part of the conductor pattern is connected to an electrode terminal exposed on the surface, and a part of the electrode terminal and the image sensor are electrically connected by a method such as wire bonding.

Further, the electrode terminals of the hard package are mounted on the printed circuit board together with various electronic components by reflow soldering or the like. The metal plate is a member for attaching the imaging unit 201 to the base member 212, and after aligning the hard package with the metal plate, the side surface of the hard package and the end face of the metal plate are adhesively fixed. As the adhesive used for adhesive fixing, for example, an ultraviolet curable resin that cures in response to light energy due to irradiation with ultraviolet rays is used.

The image pickup unit 201 and the base member 212 are fixed by screws with coil springs 222a to 222c sandwiched between them. As a result, the imaging unit 201 is supported by the base member 212 so as to be slightly displaceable in the optical axis direction. Then, by adjusting the tightening amount of the screws 223a to 223c, the inclination of the imaging surface of the imaging unit 201 with respect to the base member 212 is adjusted. When the adjustment is completed, the metal plate and each screw are adhesively fixed to prevent the screws 223a to 223c from loosening.

The tilt rotation hinge 401 described above is provided with two arm portions fixed to the movable portion 20. Then, the holder 218 is rotatably held on one arm portion around the rotation axis T with respect to the arm portion. The holder 219 is rotatably held on the other arm portion around the rotation axis T with respect to the arm portion. The arm portion that holds the holder 219 has a hollow structure inside, and the harness 405 is inserted through the hollow portion and wired inside the pan rotation hinge 402.

The harness 405 is further wired from the inside of the pan rotation hinge 403 to the inside of the fixing portion 30, and is electrically connected to the operation unit 301, the power supply unit 302, the display unit 303, the pan rotation regulation unit (first regulation unit) 305, and the like. Connected to.

A tilt rotation regulating portion (second regulating portion) 208 is joined to the holder 218. As the tilt rotation regulating unit 208, as described above, a linear solenoid actuator or the like that slides the movable pin back and forth by electronic control is used. Then, a harness is connected to the actuator terminal.

Screw fastening holes are formed in the holders 218 and 219, respectively, and the holder 218 is fixed to the base member 212 by the screws 220a and 220b, and the holder 219 is fixed to the base member 212 by the screws 221a and 221b.

A plurality of screw fastening holes are formed in the chassis 224, and the chassis 224 is fixed to the side cover 213 by the screws 225a and 225b. Further, the printed circuit board 226 is fixed to the chassis 224 by screws 228a to 228c.

Various electronic components are mounted on the printed circuit board 226 by reflow soldering or the like. For example, a runout detection unit 206, a central control unit 207, and a recording unit 210 are mounted on the printed circuit board 226. Further, a plurality of connectors are mounted on the printed circuit board 226, and the flexible printed circuit board 214, the harness 405, and the tilt rotation regulating unit 208 are electrically connected to the printed circuit board 226.

One end of the flexible printed circuit board 227 is connected to the printed circuit board 226, and the other end is connected to the printed circuit board mounted on the imaging unit 201. As a result, the image pickup unit 201 and the printed circuit board 226 are electrically connected.

The back cover 229 is provided with an operation unit 202. A flexible printed circuit board 230 extends to the operation unit 202, and after connecting the operation unit 202 to a connector mounted on the printed circuit board 226, the side cover 213 and the back cover 229 are engaged with each other.

The back cover 229 is formed with a plurality of engaging claws for engaging with the side cover 213. The side cover 213 is formed with a groove to which the engaging claw is attached at a position facing the engaging claw. When the back cover 229 is assembled to the side cover 213, the engaging claws engage with the groove portion and act as a stopper. In order to more reliably prevent the covers from coming off, the engaging portions may be appropriately adhered and fixed.

FIG. 4 is a cross-sectional view showing the structure of the tilt rotation restricting portion shown in FIG. FIG. 4A is a cross-sectional view showing a state in which the plunger retracts from the surface of the tilt rotor, and FIG. 4B is a view showing a state in which the plunger is pressed against the surface of the tilt rotor.

As described above, the tilt rotation restricting unit 208 is arranged at a position facing the tilt rotor 403 and is held rotatably with respect to the rotation axis T. In the illustrated example, the tilt rotation regulating unit 208 is a linear solenoid actuator that slides and drives the plunger 208c back and forth by electronic control.

A fixed iron core 208b, a plunger 208c, a coil spring 208d, a bobbin 208e, and a coil 208f are housed in the case 208a. The fixed iron core 208b is a member that attracts the plunger 208c when a magnetic field is generated by passing an electric current through the coil 208f. The fixed iron core 208b is adhesively fixed to the bottom of the case 208a.

The plunger 208c is a driving component of a solenoid using a movable iron core. By inserting the coil spring 208d between the plunger 208c and the fixed iron core 208b, the plunger 208c is always urged toward the center of rotation of the rotation shaft T. A coil 208f is wound around the bobbin 208e, and the bobbin 208e is fixed in the case 208a. The case 208a is then sealed by the lid 208g.

The tilt rotation regulating unit 208 can reciprocate between the state shown in FIG. 4A and the state shown in FIG. 4B. A sliding sheet 208h is inserted between the plunger 208c and the tilt rotor 403. The sliding sheet 208h is formed of a material having high wear resistance. At the position where the plunger 208c presses the surface of the tilt rotor 403 via the sliding seat 208h, the frictional load that rotates the movable portion 20 with respect to the tilt rotation hinge 401 increases, and the movable portion 200 does not easily rotate.

On the other hand, in the position where the movable pin is retracted from the surface of the tilt rotor 403, the frictional load is reduced and the movable portion 200 rotates smoothly. The frictional load can be adjusted according to the material used for the sliding sheet 208h, and as the material for the sliding sheet 208h, for example, a polyacetal (POM) sheet, a nylon sheet, or a rubber sheet is appropriately used.

FIG. 5 is a diagram for explaining the structure of the fixed portion shown in FIG. 5 (a) and 5 (b) are perspective views showing the fixed portion in an exploded manner.

The fixed portion 30 includes a fixed portion front cover 306 and a fixed portion side cover 307.
The display portion 303 is held by the fixed portion side cover 307. The exterior is defined by the fixed portion front cover 306, the fixed portion back cover 307, and the grip portion 304.

A pan rotation regulating portion 305 that regulates the rotation of the pan rotor 404 is arranged in the fixing portion 30. Then, the pan rotation control unit 305 is held by the base holder 308 and the gear cover 309. The pan rotor 404 is fixed to the pan rotation hinge 402 by four screws 310. The base holder 308 is screwed to the fixed portion back cover 307 with screws 311.

The pan rotor 404 includes a gear portion 404a, and the gear portion 404a meshes with the pan angle detection gear 312. The pan angle detection gear 312 is pivotally supported by holes formed in the base holder 308 and the gear cover 309. The shaft portion of the pan angle detection gear 312 is provided with a half-moon shaped shaft portion 312a. A half-moon-shaped hole is similarly formed in the rotatable shaft provided in the angle detection element 313, and the shaft portion 312a of the pan angle detection gear is inserted into the hole.

In the illustrated example, a rotary potentiometer is used as the angle detection element 313, and when the pan angle detection gear 312 rotates, the slider rotates in the potentiometer. As a result, the slider slides on the resistor and the resistance value of the resistor changes. Then, the rotation angle of the pan rotation hinge 402 can be detected according to this resistance value.

The pan rotation hinge 402 does not rotate beyond a predetermined angle (predetermined angle range). Here, the convex portion 308a provided on the base holder 308 moves with respect to the groove portion 404b provided on the pan rotor 404, and the end of the groove portion 404b and the convex portion 308a come into contact with each other at a predetermined angle. As a result, the pan rotation hinge 402 cannot rotate any further. In this way, it is possible to prevent disconnection of the internal wiring due to excessive rotation of the pan rotation hinge 402.

The angle detection element 313 is mounted on the fixed portion flexible printed circuit board 315 and connected to the fixed portion printed circuit board 316. A solenoid actuator 314 used for pan rotation torque control is soldered to the fixed portion flexible printed circuit board 315. Then, the electric power required for driving is supplied to the solenoid actuator 314 via the fixed portion printed circuit board 316.

The fixed portion printed circuit board 316 and the movable portion printed circuit board 226 are electrically connected to the central control unit 207 by a wire harness 405 or the like wired in the hinge unit 40. The fixed portion printed circuit board 316 is fixed to the fixed portion back cover 307 with four screws 317. A pressing member 319 is attached to the central portion of the arm 318, and an elastic member is used as the pressing member 319.

FIG. 6 is a diagram for explaining the structure of the pan rotation regulating portion shown in FIG. FIG. 6A is a cross-sectional view showing a first state of the pan rotation regulating portion, and FIG. 6B is a cross-sectional view showing a second state of the pan rotation regulating portion. Further, FIG. 6C is a cross-sectional view showing a third state of the pan rotation regulation unit.

In the state shown in FIG. 6A, the hinge rotation torque is the smallest, and there is no rotation regulation by the regulating member. The arm 318 is fixed to the base holder 308 by the rotation shaft 318a and rotates about the axis. A coil spring 320 is locked to the other end of the rotating shaft 318a.

The coil spring 320 is locked to the arm 318 and the hook portion 308b provided on the base holder 308, and is urged in the direction in which the arm 318 and the pan rotor 404 are separated from each other. Then, the solenoid actuator 314 is screwed to the base holder 308. The plunger 314a is connected to the arm 318 via a hook member 314b.

When the plunger 314a is sucked by the drive of the solenoid actuator 314, the arm 318 rotates as shown in FIG. 6B. Then, the pressing member 319 attached to the arm 318 and the pan rotor 404 slide, and the rotational torque of the pan rotation hinge 402 increases. When the plunger 314a is returned to the state where there is no rotation restriction, the plunger 314a is returned to the protruding state by the coil spring 320.

The state shown in FIG. 6C shows a state in which a current is further passed through the solenoid actuator 314. Here, the engaging convex portion 318b provided on the arm 318 engages with the gear portion 404a to regulate the rotation.

A so-called self-holding solenoid is used as the solenoid actuator 314. Therefore, when the power is off, the plunger 314a is attracted and held by the permanent magnet in the solenoid actuator 314. At this time, the attractive force of the permanent magnet is set to be larger than the spring force of the coil spring 320. Therefore, even when the power of the image pickup apparatus is turned off, the rotation regulation can be maintained.

In this way, the pan rotation regulating unit 305 can change and maintain the rotational torque of the hinge stepwise.

FIG. 7 is a diagram showing the relationship between the position of the hinge torque operation unit shown in FIG. 2, the presence / absence of rotation restriction of the hinge unit, and the possibility / removal of the lens unit.

When the position of the hinge torque operation unit 202 is the position A1, the tilt rotation regulation unit 208 and the pan rotation regulation unit 305 move in the direction in which the regulation member (plunger) retracts from the tilt rotor 403 and the pan rotor 404, respectively, and are stopped. At this time, the hinge unit 40 operates smoothly with less frictional load applied to the tilt rotation hinge 401 and the pan rotation hinge 402.

When the positions of the hinge torque operation unit 202 are the positions A2 and A3, the tilt rotation regulation unit 208 and the pan rotation regulation unit 305 move in the direction in which the regulation member presses against the tilt rotor 403 and the pan rotor 404, respectively. At this time, the frictional load applied to the tilt rotation hinge 401 and the pan rotation hinge 402 increases, and the hinge unit 40 is in a locked state in which it does not operate with a small operating force.

When the positions of the hinge torque operation unit 202 are positions A1 and A2, the movable pin 204b is held at a position exposed from the through hole of the lens mount 211. Therefore, when the positions of the hinge torque operation unit 202 are the positions A1 and A2, the rotation of the lens unit 50 is restricted and the lens unit 50 cannot be removed.

When the position of the hinge torque operation unit 202 is the position A3, the movable pin 204b is held at a position where it retracts into the through hole of the mount 211. Therefore, when the position of the hinge torque operation unit 202 is A3, the rotation of the lens unit 50 is not restricted and the lens unit 50 can be removed.

When replacing the lens unit 50 in the image pickup apparatus 10, the user moves the position of the hinge torque operation unit 202 to the position A3. Here, the position before moving to the position A3 is always set to the position A2. Then, even when moving from the position A1 to the position A3, it is configured to pass through the position A2. Therefore, when replacing the lens unit 50, the hinge unit 40 can be locked before the lens unit 50 can be removed.

Here, the operation when the lens unit 50 is attached will be described.

In the image pickup apparatus 10, the tilt hinge 401 and the pan hinge 402 are in the locked state when the lens unit 50 is removed. By locking the hinge, the hinge does not move carelessly when the lens unit 50 is attached, and the lens unit 50 can be easily attached. Further, since the lens unit 50 can be mounted without the hinge rotating even when the grip portion 304 is gripped, the user can smoothly change the lens.

When the lens unit 50 is mounted, the lens unit 50 is brought into contact with the lens mount 211 in a state of being aligned with the marks provided on both the lens unit and the lens mount. At this time, the movable pin 204b is pushed by the lens unit 50 and retracted.

When the lens unit 50 is rotated, the bayonet claw portion 507 of the lens unit 50 and the lens mount 211 are engaged with each other. Then, when the lens unit 50 is rotated by a predetermined angle, the movable pin 204b engages with the recess 508 provided on the lens unit 50 side, and the rotation of the lens unit 50 is restricted.

When the lens unit 50 is attached to the movable portion 20, the interface portion 205 and the interface portion 506 are electrically connected, and when the attachment of the lens unit 50 is detected, the focal length and weight of the lens unit 50 are determined. Information (lens information) is sent to the central control unit 207. That is, the central control unit 207 acquires lens information.

Subsequently, the release of the hinge lock will be described.

If the image pickup device main body is held so that the pan rotation axis P is vertical and the tilt rotation axis T is horizontal when the hinge lock is released, the hinge may rotate due to the weight of the lens unit 50. Whether or not the hinge rotates is determined for each lens unit to be mounted. That is, whether or not the hinge rotates depends on the weight and size of the lens unit, and in the case of a zoom lens, the amount of extension of the lens barrel during zooming. Therefore, the weight of each lens unit and the like are stored in the lens unit for each lens unit as hinge lock release availability information. Then, the hinge lock release availability information is sent to the central control unit 207 by mounting the lens unit.

When the mounted lens unit 50 can unlock the hinge, the central control unit 207 unlocks the pan hinge 401 and the tilt hinge 402. For example, in the case of a single focus lens having a light weight and a short overall length, the hinge lock is released because the hinge does not rotate. As described above, when the lens unit 50 is mounted, the hinge is locked, so that the lens unit 50 can be easily mounted. Further, when the lens unit 50 is attached, the hinge lock is automatically released, so that the shooting can be smoothly performed.

If the hinge lock cannot be released, the central control unit 207 does not unlock the tilt hinge 402, but only the pan hinge 401. As a result, it is possible to prevent the tilt hinge 402 from rotating due to the weight of the lens unit 50 immediately after the lens unit 50 is attached. Since the rotation restriction of the pan hinge 401 is released, the user can smoothly shift to shooting.

Next, the release of the hinge lock according to the posture of the imaging device will be described.

As described above, when the lens unit 50 is attached, the central control unit 207 confirms the hinge lock release availability information. If the hinge lock can be released, the central control unit 207 releases the hinge lock. On the other hand, when the hinge lock cannot be released, the central control unit 207 maintains the locked state of the tilt hinge 401 and the pan hinge 402 immediately after the lens unit is attached.

After that, the central control unit 207 determines to unlock the tilt hinge 401 and the pan hinge 402. First, the central control unit 207 confirms how much the tilt rotation axis T is tilted with respect to the horizontal according to the detection results of the runout detection units 206 and 322, the tilt angle detection unit 243, and the pan angle detection unit 321. ..

FIG. 8 is a diagram for explaining the inclination with respect to the tilt rotation axis in the image pickup apparatus shown in FIG. 8 (a) is a view of the image pickup device from the back side, and FIG. 8 (b) is a view of the image pickup device from the side view. Further, FIG. 8C is a view of the image pickup apparatus from the upper surface side.

The angle θ1 is the inclination of the tilt rotation axis T with respect to the horizontal, and the central control unit 207 confirms the angle θ1. First, the tilt angle detection unit 243 detects the tilt angle θ2 shown in FIG. 8B. Further, the pan angle detection unit 321 detects the pan angle θ3 shown in FIG. 8 (c). The central control unit 207 determines whether or not the pan hinge rotates due to the weight of the lens unit based on the tilt angle θ2 and the pan angle θ3.

For example, when the angles θ1, θ2, and θ3 are all 0 degrees, it is assumed that the user holds the grip portion 304 in a substantially vertical position. At this time, the pan hinge does not rotate due to the weight of the lens unit 50. Therefore, it is determined that the lens unit 50 will not rotate unnecessarily even if the lock of the pan hinge 402 is released, and the central control unit 207 unlocks the pan hinge 402. However, the locked state of the tilt hinge 402 is maintained.

Next, when the angle θ1 is around 90 degrees and θ2 is 0 degrees, it is assumed that the user holds the image pickup device 10 sideways when the lens unit is attached. In this case, since the pan hinge 402 is rotated by the weight of the lens unit 50, the central control unit 207 does not unlock the pan hinge 401. On the other hand, since a rotating force does not act on the tilt hinge 402, the central control unit 207 unlocks the tilt hinge 402.

In addition, if it is determined that a rotational force acts on both the tilt hinge and the pan hinge according to the angles θ1, θ2, and θ3, the central control unit 207 does not unlock the tilt hinge and the pan hinge.

Here, another method of unlocking the tilt hinge will be described.

Here, the tilt hinge 401 is unlocked by manually rotating the pan hinge 402 by a predetermined angle or more while only the pan hinge 402 is unlocked by the hinge angle determination. In this case, the central control unit 207 determines that the user holds the lens unit 50 and rotates the pan hinge 402, and does not carelessly move the lens unit 50.

In this way, the operability can be improved by making it possible to immediately perform both pan and tilt operations even in a large lens unit in which the hinge lock cannot be released.

On the other hand, if the tilt hinge 401 is manually rotated by a predetermined angle or more while only the tilt hinge 401 is unlocked by the hinge angle determination, the central control unit 207 unlocks the pan hinge 402. That is, by operating a hinge other than the locked hinge, the hinge in the locked state can be released. As a result, the user can quickly move the lens unit without having to take his / her hand off the lens unit to operate the operation unit 202.

Further, after determining the orientation of the lens unit, the hinge lock can be performed again by operating the hinge torque operation unit 202. During the hinge lock, the user can recognize the hinge lock state by turning on and off the LED light emitting unit (not shown) provided in the fixed portion 30.

By the way, when a lens unit in which the hinge lock release availability information is not recorded is attached, the central control unit 207 does not automatically release the hinge lock. For example, even if a heavy lens unit is attached, the process is performed so that the hinge is not inadvertently rotated. If the body cap is attached to the lens mount 211 when the lens unit is not attached, the central control unit 207 does not detect the attachment of the lens unit, so that the hinge lock is maintained.

Even when the power of the image pickup apparatus 10 is off, the central control unit 207 detects that the lens unit 50 is attached via the interface unit 205. When the mounting of the lens unit 50 is detected, the central control unit 207 turns on the power and performs hinge control as described above.

When an external microphone, video light, or the like is attached to the accessory shoe 209 shown in FIG. 2, the central control unit 207 provides information (accessory information) related to the attached accessory from the accessory detection unit (accessory detection unit) 242. obtain. Then, the central control unit 207 determines whether or not to release the hinge lock according to the combination of the lens unit 50 mounted on the lens mount 211 and the accessory. According to this determination, when a large video light or the like is attached in a state where the hinge lock is released, the hinge lock is performed and the lens unit 50 can be prevented from tilting.

A case will be described in which the image pickup apparatus 10 includes a mechanism (not shown) that can rotate in the roll direction, that is, with respect to the optical axis, in addition to the tilt direction and the pan direction. Since the configuration of the imaging device is the same as that of the pan hinge 402, the description thereof will be omitted.

When the lens unit 50 is attached / detached, the lens unit 50 is rotated with respect to the optical axis, but when the lens unit 50 can be rotated in the roll direction, the movable portion 20 rotates together with the lens unit 50 when the lens unit 50 is attached / detached. Resulting in. Therefore, when the lens unit 50 is attached or detached, the central control unit 207 restricts the rotation in the roll direction, and after the lens unit 50 is attached, the restriction is released.

Although the hinge is locked when the rotation is regulated, the rotatable angle may be regulated according to the length and weight of the lens unit 50 without completely locking the hinge. .. Further, the rotational torque at the hinge may be increased to make it difficult to rotate without locking so that the hinge does not move completely.

By performing the control as described above, the hinge does not move carelessly when the lens unit 50 is attached, and the work when the lens unit 50 is attached becomes easy.

Further, after the lens unit 50 is attached, in the case of a relatively light lens unit, the hinge lock is released and the lens unit can be quickly directed in a desired direction. Further, even if a heavy lens unit such as a telephoto lens is attached, the hinge tilts due to the weight of the lens, and the lens unit can be prevented from collapsing.

As described above, in the embodiment of the present invention, it is possible to improve the operability when attaching / detaching an accessory member such as a lens unit to / from the image pickup apparatus main body.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited to these embodiments, and various modifications and modifications can be made within the scope of the gist thereof.

10 Imaging device 20 Moving part 30 Fixed part (main body part)
40 Hinge unit (connection part)
50 Lens unit (shooting lens)
202 Operation unit 207 Central control unit 208 Tilt rotation regulation unit 209 Accessory shoe 305 Pan rotation regulation unit

Claims (10)

An imaging device with interchangeable shooting lenses
A movable part to which the shooting lens is detachably attached, and
A main body that movably supports the movable part,
A lens detection unit that detects that the photographing lens is attached to the movable unit, and
The first regulating part that regulates the rotation of the movable part in the pan direction and
A second regulating unit that regulates the rotation of the movable portion in the tilt direction,
When the lens detection unit detects that the photographing lens is attached, the control unit controls the first regulation unit and the second regulation unit to regulate the rotation angle of the movable unit within a predetermined range. ,
An imaging device characterized by having. The control unit is characterized in that the range of the rotation angle of the movable portion regulated by the first regulation unit is made larger than the range of the rotation angle of the movable portion regulated by the second regulation unit. The imaging apparatus according to 1. Further, a posture detection unit for detecting the posture of the image pickup device is provided.
When the lens detection unit detects the mounting of the photographing lens, the control unit determines the first regulation unit and the second regulation unit according to the posture of the image pickup device detected by the attitude detection unit. The imaging apparatus according to claim 1 or 2, wherein the range of the rotation angle of the movable portion is changed by the portion. Lens information related to the photographing lens is stored in the photographing lens.
When the photographing lens is attached to the movable portion, the control unit acquires the lens information and determines whether or not the regulation by the first regulating unit and the second regulating unit is released based on the lens information. The imaging apparatus according to any one of claims 1 to 3, wherein the image pickup apparatus is characterized in that the image is determined. An angle detecting unit for detecting the rotation angle of the movable portion in the pan direction and the tilt direction is provided.
In a state where the rotation of the movable portion is restricted in either the pan direction or the tilt direction, the rotation angle detected by the angle detection unit in the other of the pan direction and the tilt direction is equal to or greater than a predetermined angle. The imaging device according to any one of claims 1 to 4, wherein the control unit releases the regulation by the first regulation unit or the second regulation unit corresponding to the one. Any one of claims 1 to 5, wherein the main body portion is provided with a connecting portion that supports the movable portion on the main body portion and enables the position of the movable portion to be changed with respect to the main body portion. The imaging apparatus according to claim 1. An accessory shoe to which external accessories can be attached,
It has an accessory detection unit that detects that the external accessory is attached to the accessory shoe.
When the accessory detection unit detects that the external accessory is attached, the control unit is regulated by the first regulation unit and the second regulation unit according to the lens information and the accessory information related to the external accessory. The imaging device according to claim 4, wherein it is determined whether or not to release the image. An imaging device with replaceable accessories
A movable part to which the accessory is detachably attached,
A main body that movably supports the movable part,
An accessory detection unit that detects that the accessory is attached to the movable unit,
The first regulating part that regulates the rotation of the movable part in the pan direction and
A second regulating unit that regulates the rotation of the movable portion in the tilt direction,
When the accessory detection unit detects the attachment of the accessory, the control unit controls the first regulation unit and the second regulation unit to regulate the rotation angle of the movable unit within a predetermined range.
An imaging device characterized by having. A photographing lens mounted on the imaging device according to any one of claims 1 to 7. An accessory attached to the imaging device according to claim 8.

Images