JP2021043339A - Image capturing device - Google Patents

Abstract

To provide an image capturing device with a small viewfinder which does not protrude from a camera body when not in use, can be rotated in a protruded state with respect to the camera body while in use, and prevents inadvertent transition to an unintended state while in the protruded state.SOLUTION: In order to achieve the above purpose, an image capturing device of the present invention is configured such that rotation of a rotary unit 41 is restricted when a restricting surface 153 is engaged with a rotation restricting surface 156 while the rotary unit 41 is accommodated inside a holding cover 49.SELECTED DRAWING: Figure6(a)

Description

The present invention relates to an imaging device including an electronic viewfinder. In particular, it concerns digital cameras.

Conventionally, in some cameras equipped with an electronic viewfinder (hereinafter referred to as a finder), the finder eyepiece can be translated in the finder optical axis direction.

In the used state, the finder eyepiece is pulled out in the finder optical axis direction so that the finder optical system is in the used position.

The finder eyepiece has a compact structure by accommodating the finder eyepiece when the finder is not in use.

Further, it is known that the finder can be rotated with respect to the camera body to increase the degree of freedom of the photographer's shooting posture.

Patent Document 1 discloses an image pickup device in which a finder is rotatably provided by using a rotation mechanism.

JP-A-2017-021303

In the configuration described in Patent Document 1, the finder portion is always in a protruding state with respect to the outer shape of the camera.

As a result, it hinders portability, such as hindering shooting operations and carrying around when the camera is not in use.

Therefore, the portability can be improved by making the finder portion not protrude from the camera body when not in use and projecting from the camera body when in use.

That is, when the finder is used, it protrudes from the camera body and further pulls out the finder eyepiece.

Further, by making it rotatable with respect to the camera body in a protruding state, it is possible to make a finder that is compact and has an expanded degree of freedom in the shooting posture of the photographer.

In such a configuration
a) Transition the state of storage and protrusion of the finder with respect to the camera body.
b) Transition between the rotating and non-rotating states of the finder.
c) There is a state transition such as pulling out the used position and the non-used position of the finder eyepiece.

For example, if the finder eyepiece is pulled out during use and the camera body is transitioned from the protruding state to the retracted state, there is a risk that the finder eyepiece will be damaged.

In addition, if the state is inadvertently changed from the protruding state to the stored state, the convenience at the time of use may be impaired.

In view of the above problems, in the present invention, the camera does not protrude from the camera body when not in use, and can rotate in a protruding state with respect to the camera body when in use.

Then, an object of the present invention is to provide an image pickup apparatus having a small finder that prevents a careless transition to an unintended state in a protruding state.

In order to achieve the above object, the image pickup apparatus according to the present invention has an electronic viewfinder unit that is movable in a stored state that is housed with respect to the main body and a protruding state that protrudes with respect to the main body. It ’s a device,
The electronic viewfinder unit includes a rotation unit, a holding cover that rotatably holds the rotation unit about a rotation axis, and a rotation locking member that locks the rotation of the rotation unit. With
The rotating unit is a lens holder that holds an electronic display unit, an eyepiece, an eyepiece window that covers the eyepiece, and a finder lens that guides light flux emitted from the electronic display unit to the eyepiece. And with
The rotation restricting portion of the rotation locking member has a rotation restricting surface.
The eyepiece has a regulatory surface and
It is characterized in that the rotation of the rotating unit is restricted by engaging the restricting surface with the rotation restricting surface in a state where the rotating unit is housed in the holding cover.

According to the present invention, when the finder is not used, it has a small and rotatable finder having no protrusion with respect to the main body of the image pickup apparatus.

Therefore, it is possible to provide an image pickup device that prevents the finder from inadvertently transitioning to an unintended state, which reduces convenience and damages the camera.

It is a perspective view of the image pickup apparatus which concerns on embodiment of this invention. It is a perspective view of the image pickup apparatus which made the finder 20 project. It is a developed perspective view explaining the structure of a finder 20. It is a developed perspective view explaining the structure of a finder 20. It is a developed perspective view explaining the structure of a finder 20. It is a figure explaining the structural details of a finder unit 21. It is a figure explaining the regulation of the rotation operation of a finder unit 21. It is a figure explaining the regulation of the rotation operation of the eyepiece 28 and the finder unit 21. It is a figure explaining the regulation of the rotation operation of the eyepiece 28 and the finder unit 21. It is a figure explaining the regulation of the rotation operation of the eyepiece 28 and the finder unit 21. It is a figure explaining the regulation of the rotation operation of the eyepiece 28 and the finder unit 21. It is a figure explaining the regulation of the rotation operation of the eyepiece 28 and the finder unit 21. It is a figure explaining the structure which suppresses the movement from the protruding state to the retracted state in the rotating operation state of a finder unit 21. It is a block diagram explaining the whole structure in embodiment of this invention.

Hereinafter, examples of the present invention will be described in detail with reference to the drawings. In each figure, the same member is given the same reference number, and duplicate description is omitted.

(Explanation of perspective view of image pickup apparatus 1)
The configuration of the image pickup apparatus 1 which is an example of the image pickup apparatus according to the embodiment of the present invention will be described with reference to FIG.

The image pickup apparatus includes an electronic viewfinder unit 21 that is movable in a stored state that is housed in the main body and a protruding state that protrudes from the main body, and a lens barrel unit 2 that has a photographing optical system.

EVF (electronic viewfinder) refers to an electronic viewfinder.

FIG. 1 is a perspective view of the image pickup apparatus 1. 1 (a) and 1 (b) are a front perspective view and a rear perspective view of the image pickup apparatus 1, respectively.

The image pickup apparatus 1 includes a lens barrel unit 2 including a photographing optical system (not shown). The arrow G indicates the direction of the optical axis of the photographing lens of the imaging device 1.

Further, the image sensor (not shown) is provided to generate image data by photoelectrically converting an optical image of a subject imaged through a plurality of photographing lenses constituting the photographing optical system.

The lens barrel unit 2 is a retractable type, and when retracted, it retracts inside the image pickup apparatus 1.

Further, the image pickup apparatus 1 is composed of a main substrate (not shown), an auxiliary substrate (not shown), and the like on which a processing circuit for converting image data generated by the image pickup element into digital information is mounted.

When the release button 4 is fully pressed, a picture is taken and image data of a subject image is recorded on a recording medium (not shown).

The zoom lever 5 is rotatably held on the outer circumference of the release button 4. When the zoom lever 5 is rotated, the zoom operation is performed.

The power button 6 is pressed by the photographer to switch to an on state (used state) or an off state (non-used state).

The display device 15 is provided on the back surface of the image pickup device 1 and is used for confirming a subject image to be captured and for reproducing and displaying the captured image.

The image pickup apparatus 1 is covered with exterior members of a front cover 9, a rear cover 10, and a top cover 16.

The top cover 16 forms the appearance surface of the upper part of the image pickup apparatus 1 and also forms the opening of the finder 20.

The finder 20 is built in the image pickup device 1, and when stored, the finder 20 is locked while being held inside the image pickup device 1 by a lock mechanism.

A side cover 13 forming a part of the appearance surface is formed on the side surface of the image pickup apparatus 1.

The release lever 14 is held on the side cover 13 so as to be slidable, and by operating the release lever 14, the finder 20 is unlocked and the image pickup device 1 is projected upward.

(Explanation of the block diagram of FIG. 8)
FIG. 8 shows a block diagram showing a configuration example of the image pickup apparatus 1 as an example of the image pickup apparatus of the present invention. The optical system includes a photographing lens 201 and a shutter 202 having an aperture function.

The image pickup unit 203 includes a CCD, a CMOS element, and the like that convert an optical image input through an optical system into an electric signal.

The A / D conversion unit 204 is used when converting the analog signal output from the imaging unit 203 into a digital signal and when converting the analog signal output from the voice control unit 205 into a digital signal.

The lens barrier 206 covers the image pickup unit 203 including the lens 201 of the image pickup apparatus 1 to reduce dirt and damage thereof.

The timing generation unit 207 is controlled by the memory control unit 208 and the system control unit 209, and supplies clock signals and control signals to the image pickup unit 203, the voice control unit 205, the A / D conversion unit 204, and the D / A conversion unit 210. ..

The image processing unit 211 performs predetermined pixel interpolation, reduction, and other resizing processing and color conversion processing on the output data from the A / D conversion unit 204 and the data stored in the memory 212.

Further, the image processing unit 211 performs a predetermined calculation on the captured image data, and the system control unit 209 performs exposure control and distance measurement control based on the obtained calculation result.

As a result, TTL (through-the-lens) AF (autofocus) processing, AE (autoexposure) processing, and EF (flash pre-flash) processing are performed.

The image processing unit 211 further performs a predetermined calculation process using the captured image data, and also performs a TTL-type AWB (auto white balance) process based on the obtained calculation result.

The output data from the A / D conversion unit 204 is written to the memory 212 via the image processing unit 211 and the memory control unit 208, or directly via the memory control unit 208.

The memory 212 stores audio data recorded by the microphone 213, captured still images and moving images, and information incidental to images such as a file header when forming an image file.

The memory 212 has a storage capacity sufficient to store a predetermined number of still images, moving images for a predetermined time, and audio.

The compression / decompression unit 214 compresses / decompresses image data by adaptive discrete cosine transform (ADCT) or the like, and uses the shutter 202 as a trigger to read the captured image stored in the memory 212, perform compression processing, and complete the processing. Write data to memory 212.

Further, the compressed image read into the memory 212 is read from the recording medium 215 or the like, decompression processing is performed, and the processed data is written to the memory 212.

The image data written in the memory 212 by the compression / decompression unit 214 is filed in the file processing unit of the system control unit 209 and recorded on the recording medium 215 via the recording medium I / F 216.

Further, the memory 212 also serves as a memory for displaying an image, and the image data for display written in the memory 212 is displayed by the image display unit 217 via the D / A conversion unit 210.

The voice signal output from the microphone 213 is converted into a digital signal by the A / D conversion unit 204 via the voice control unit 205 composed of an amplifier or the like, and then stored in the memory by the memory control unit 208.

On the other hand, the voice data recorded on the recording medium 215 is read into the memory, and then the signal processed by the voice control unit 205 via the D / A conversion unit 210 is sounded by the speaker 218.

The system control unit 209 controls the entire image pickup apparatus 1. The system memory 219 stores constants, variables, programs, and the like for the operation of the system control unit 209.

The non-volatile memory 220 is a memory that can be electrically erased and recorded, and for example, EEPROM or the like is used.

The shutter switch (SW1), the shutter switch (SW2), and the operation unit 221 are operation means for the user to input various operation instructions to the system control unit 209.

The mode changeover switch 222 is used by the user to switch the operation mode of the system control unit 209 to a still image shooting mode, a continuous shooting (continuous shooting) mode, a moving image mode, a playback mode, and the like.

The shutter switch (SW1) is turned on during the operation (half-pressing) of the shutter button 223 provided in the image pickup apparatus 1.

Then, the start of operations such as AF (autofocus) processing, AE (autoexposure) processing, AWB (auto white balance) processing, and EF (flash pre-flash) processing is instructed.

The shutter switch (SW2) is turned on when the operation of the shutter button 223 is completed (fully pressed), and the recording medium is read from the signal read from the imaging unit 203! Instructs the start of a series of imaging processes until the image data is written to.

The operation unit 203 includes various buttons, a touch panel, and the like.

A specific example is as follows. It consists of an erase button, a menu button, a SET button, and four-way keys arranged in a cross.

When the menu button is pressed, a menu screen on which various settings can be made is displayed on the image display unit 217.

The user can intuitively make various settings by using the menu screen displayed on the image display unit 217 and the four-direction keys and the SET button.

In addition, the display unit detects the contact of the user's finger or pen with the operating member! The icon displayed in may be detected in the same manner as the operation of a switch such as a button or a dial or a dial.

Further, by using an operating member such as a jog dial that can detect rotation, the same operation as the bidirectional key may be performed.

The power button 224 switches between power on and power off.

The power supply control unit 225 includes a battery detection circuit, a DC-DC converter, a switch circuit for switching a block to be energized, and the like, and detects whether or not a battery is installed, the type of battery, and the remaining battery level.

Further, the DC-DC converter is controlled based on the detection result and the instruction of the system control unit 209, and the required voltage is supplied to each unit including the recording medium 215 for a necessary period.

The power supply unit 226 is composed of a primary battery such as an alkaline battery or a lithium battery, a secondary battery such as a NiCd battery, a NiMH battery, or a Li battery, an AC adapter, or the like.

The power supply connector on the camera side and the power supply connector connect the power supply unit 226 and the power supply control unit 225.

RTC227 (Real Time Clock) is a power control unit! Separately, the power supply unit is held inside, and even if the power supply unit 226 is in a down state, the timekeeping is continued.

The system control unit 209 performs timer control using the date and time acquired from RTC227 at the time of startup.

The recording medium attachment / detachment detection unit 228 detects whether or not the recording medium 215 is installed in the recording medium slot.

The communication unit 229 performs various communication processes such as RS232C, USB, IEEE1394, P1284, SCSI, modem, LAN, and wireless communication.

The communication connector 230 (antenna in the case of wireless communication) connects the image pickup device 1 to another device via the communication unit 229.

The detection unit 231 is for detecting whether the finder 20 is pulled out and in a usable state, and a sensor using a mechanical and optical method can be used.

When the detection unit 231 determines that the finder 20 is in a usable state, the image of the image display unit 217 is switched to the finder 20. Then, the user can confirm the image projected on the finder 20.

(Explanation of operation of Finder 20)
Next, the operation of the finder 20 of the present invention shown in FIG. 1 will be described with reference to FIG.

FIG. 2 is a rear perspective view of the image pickup apparatus in which the finder 20 is projected.

FIG. 2A shows a state in which the finder unit 21 protrudes upward from the stored state in the image pickup device 1 by operating the release lever 14 arranged on the side surface of the image pickup device 1 described above.

The eyepiece window 22 is fixed to the eyepiece portion 28. The sensor window 23 is provided on the upper side of the eyepiece window 22.

The sensor window 23 is provided for the optical path of an internal sensor, such as an optical detection sensor.

The internal optical sensor detects that the user, who is the user, has looked into the eyepiece 28, and switches to the display on the electronic viewfinder unit 21.

FIG. 2B shows a state in which the eyepiece 28 of the finder unit 21 is pulled out from the protruding state of the finder unit 21 of FIG. 2A to the back side of the image pickup apparatus 1.

The finder 20 can be used in a state where the eyepiece 28 is pulled out toward the front, and the eyepiece 28 makes it possible to confirm the subject image to be photographed and the reproduced display of the photographed image.

Further, FIG. 2C shows a state in which the finder rotating portion 41 including the eyepiece portion 28 is rotated in the usable state of the finder 20 of FIG. 2B.

In the finder rotating portion 41, the eyepiece portion 28 rotates about 90 degrees to a position parallel to the top cover 16.

That is, the eyepiece window 22 rotates until it faces the top surface of the camera body.

The sensor window 23 is provided above the eyepiece window 22.

In that case, within the range in which the finder rotating unit 41 as the rotating unit is rotated, the internal sensor (not shown) can detect that the user, who is the user, has looked into the eyepiece 28. ..

Therefore, the photographer can also confirm the subject image to be photographed from the upper surface side of the camera and the reproduction display of the photographed image.

The diopter adjustment lever 120 is arranged below the eyepiece portion 28 when viewed from the eyepiece window 22 side in the posture of the image pickup apparatus 1 shown in FIG. 2B.

Therefore, the diopter adjustment lever 120 is exposed in a state where the eyepiece 28 of the finder unit 21 is pulled out and the finder rotating portion 41 is rotated by about 90 degrees.

The user can adjust the diopter of the finder 20 by rotating the diopter adjustment lever 120.

(Explanation of the configuration of the finder 20)
The configuration of the finder 20 will be described with reference to FIG.

As shown in FIG. 3A, the finder 20 includes an electronic viewfinder unit 21 and a vertical movement pop-up mechanism 51 that switches between a stored state and a protruding state.

FIG. 3A is a developed perspective view illustrating the vertical movement pop-up mechanism portion 51 constituting the finder 20.

The base plate 32 as a fixing member is formed of a metal plate, and two guide bars 33 made of a metal material are crimped.

Further, a locking pin 32a is formed on the base plate 32.

The guide bar 33 is formed with a flange-shaped portion 33a so as to be partially enlarged in the radial direction.

The EVF holder 30 is made of a resin material, and two guide bars 33 crimped to the base plate 32 are inserted through the base plate 32 to hold the EVF holder 30 so as to be slidable up and down.

At this time, the flange-shaped portion 33a of the guide bar 33 comes into contact with the EVF holder 30, so that the slide position at the time of protrusion is determined.

The EVF holder 30 is positioned and fixed to the front cover 9 shown in FIG.

The protruding spring 38 is housed inside the EVF holder 30 and urges the guide bar 33 upward.

The spring holder 35 is made of a sheet metal material and is fixed to the EVF holder 30 so as to hold down the end of the protruding spring 38.

The lock lever 36 is rotatably held with respect to the spring holder 35 by the crimping pin 37, and includes a locking claw portion 36a.

One end of the urging spring 34 is locked to the lock lever 36, the other end is locked to the spring holder 35 and held, and the urging spring 34 is configured in a state of urging the lock lever 36 in one direction.

The lock lever 36 is configured to rotate around the crimping pin 37 by operating the release lever 14 shown in FIG.

The finder 20 is held in the stored state by locking the locking pin 32a of the base plate 32 by the locking claw portion 36a of the lock lever 36 during storage.

When the finder 20 is used, the release lever 14 is operated to rotate the lock lever 36 to release the lock of the locking pin 32a, thereby performing a protruding operation.

Next, the configuration of the finder unit 21 will be described.

FIG. 3B is a developed perspective view of the finder unit 21.

The electronic viewfinder unit 21 has a finder rotating portion 41 as a rotating unit and a finder cover 49 that covers the finder rotating portion 41.

The finder unit 21 is provided with a finder top cover 31 that forms an outer surface of the upper surface together with the top cover 16.

Further, the finder cover 49 having two side surfaces 49a parallel to the movable direction in the protruding state is provided.

The side surface 49a of the finder cover 49 has a first side surface located on the left side of the optical axis of the finder lens and a second side surface located on the right side.

The finder rotating portion 41 constituting the finder unit 21 is a lens holder 42 for holding the finder lens, a finder guide cylinder 43 for holding the lens holder 42 so as to be translatable in the optical axis direction of the finder lens, and a flange portion of the finder guide cylinder 43. It has 43a.

The diopter adjusting lever 120 is integrally provided with a cam-shaped portion 121. When the diopter adjustment lever 120 is rotated, the lens holder 42 is translated by the cam shape portion 121 inside the finder guide cylinder 43.

A guide shaft 44 that guides the finder guide cylinder 43 in a linear motion penetrates through the flange portion 43a.

One end of the guide shaft 44 is fixed to the finder fixing cylinder 45.

The eyepiece 28 is locked to the finder guide cylinder 43 by a locking claw 43c provided on the side surface of the finder guide cylinder 43.

By pulling the eyepiece 28 toward the front, the finder guide cylinder 43 pivotally supported by the guide shaft 44 moves in translation with the internal lens holder 42 and becomes usable.

A seal member 43b is provided on the outer periphery of the flange portion 43a of the finder guide cylinder 43. The seal member 43b seals between the finder fixing cylinder 45 and the finder guide cylinder 43 to form a dustproof structure.

The display unit holder 47 holds the electronic display unit 46.

A locking claw 47a is provided on the side surface of the display unit holder 47, and is integrated by a locking portion 45f on the finder fixing cylinder 45 side.

In the display panel urging plate 48, the arm portion 48a is fixed to the finder fixing cylinder 45, and the display unit 46 is urged to the display unit holder 47 side.

The tip 48b of the arm portion 48a also serves as a click portion with respect to the finder guide cylinder 43 that operates integrally when the eyepiece portion 28 is pulled out toward the front. The display panel urging plate 48 rotates together with the finder rotating portion 41.

A substrate base 60 is provided between the vertical movement pop-up mechanism 51 for storage and protrusion at the lower part of the finder unit 21.

The substrate base 60 is fixed to the base plate 32 together with the finder cover 49 by a plurality of fastening screws.

The finder board 24 is fixed to the board base 60.

A flexible substrate (not shown) for transmitting an image signal from the main substrate inside the image pickup apparatus 1 is connected to the finder substrate 24.

Further, the signal is transmitted by the flexible substrate 61 connected to the electronic display unit 46.

The flexible substrate cover 62 is fixed to the substrate base 60. The flexible substrate 61 is arranged in the gap between the connecting surface 49b of the finder cover 49 and the flexible substrate cover 62.

The rotation locking member 130 is urged by the urging spring 132. The rotation locking shaft 131 penetrates the rotation locking member 130 and is held by the substrate base 60.

That is, the rotation locking member 130 is a member that rotates with respect to the rotation locking shaft 131. The rotation locking shaft 131 may be integrally formed with the rotation locking member 130.

The rotation locking member 130 locks the finder fixing cylinder 45.

The rotation locking member 130 is arranged on the optical axis side of the finder lens with respect to the surface 49a of the finder cover 49 in a state where the finder fixing cylinder 45 is locked.

As a result, the rotation locking member 130 can prevent interference with the surrounding members until the finder unit 21 transitions from the state of being housed in the image pickup apparatus 1 to the state of protruding upward.

Therefore, the finder rotating unit 41 is securely locked without transitioning to an inadvertent state until the finder unit 21 transitions from the state of being housed in the image pickup apparatus 1 to the state of protruding upward. To.

The cam shape portion 121 is integrated with the diopter adjusting lever 120. The cam-shaped portion 121 integrated with the diopter adjusting lever 120 is slidably fitted to the finder guide cylinder 43.

When the diopter adjustment lever 120 is rotated, the lens holder 42 is translated by the cam shape portion 121 inside the finder guide cylinder 43. Therefore, by rotating the diopter adjustment lever 120, the user can adjust the diopter of the finder 20.

(Explanation of finder rotation operation)
Next, the finder rotation operation will be described with reference to FIG. 3 (c).

FIG. 3C is a diagram showing the relationship between the finder cover 49 and the finder fixing cylinder 45.

The finder cover 49 includes a first surface and a second surface 49a that are parallel to the optical axis direction of the finder lens and parallel to the movable direction of the finder unit 21.

The rotating shaft 50 is held by holes 49c provided in the first surface 49a and the second surface 49a.

The finder unit rotation shaft 50 is divided into two bodies, a first shaft penetrating the first surface and a second shaft penetrating the second surface.

The finder unit rotation shaft 50 is divided into two members, but a single member may be used.

The first surface and the second surface 49a are connected by a third surface 49b located closer to the subject than the first surface and the second surface 49a.

The first surface, the second surface 49a, and the third surface 49b have a substantially U-shape in a cross section F orthogonal to the movable direction V between the stored state and the protruding state.

The finder unit rotating shaft 50 is rotatably fitted with a shaft hole portion 45b provided in the fixed cylinder 45 constituting the finder rotating portion 41, and is formed on the first surface and the second surface 49a of the finder cover 49. It is being held.

The finder unit rotating shaft 50 can secure strength as a rotating shaft by being coupled to the rigid finder cover 49.

In the finder fixing cylinder 45, a part of the finder unit rotating shaft 50 is rotatably fitted to the shaft hole portion 45b.

The finder unit rotation shaft 50 is provided on the side opposite to the eyepiece 28 with respect to the optical axis of the finder lens with reference to the lens holder 42, and on the side where the finder unit 21 protrudes from the optical axis of the finder lens.

Therefore, the finder fixing cylinder 45 can rotate with respect to the finder cover 49. Further, the finder cover 49 is provided with a rotation stopper portion 49d.

The finder fixing cylinder 45 has a configuration in which the contact portion 45d comes into contact with the rotation stopper portion 49d when rotated by about 90 degrees.

The finder rotating unit 41 can rotate between 0 and 90 degrees, where the optical axis of the finder lens is substantially parallel to the optical axis of the photographing optical system.

The rotating unit 41 is a lens that holds an electronic display unit 46, an eyepiece 28, an eyepiece window 22 that covers the eyepiece, and a finder lens that guides the light flux emitted from the electronic display unit to the eyepiece 28. It includes a holder 42 and.

A locking portion 145 is provided on the outside of the finder fixing cylinder 45.

The rotation locking member 130 is urged by an urging spring 132 on the finder fixing cylinder 45 side.

The rotary locking member 130 engages with the locking portion 145 provided on the finder fixing cylinder 45 by the urging force of the urging spring 132.

Here, the rotation locking member 130 is arranged diagonally with respect to the finder unit rotation shaft 50 when viewed from a direction perpendicular to the surface 49a of the finder cover 49.

Therefore, the finder fixing cylinder 45 is locked at the farthest position with respect to the finder unit rotation shaft 50.

As a result, the finder fixing cylinder 45 is securely locked.

Therefore, the finder 20 is securely locked with the finder rotating unit 41 until the finder 20 transitions from the state of being housed in the image pickup apparatus 1 to the state of protruding upward.

(Detailed description of the configuration of the finder unit 21)
Next, the configuration details of the finder unit 21 will be described with reference to FIG.

FIG. 4A is a view of the finder 20 in which the finder unit 21 inside the image pickup apparatus 1 is housed in the image pickup apparatus 1 and the lens barrel unit 2 as viewed from the rear side of the image pickup apparatus 1. Is.

The finder 20 is arranged on the left side of the lens barrel unit 2 and is adjacent to each other.

Further, in a state where the finder unit 21 is housed in the image pickup apparatus 1, the lens barrel unit 2 is arranged on the lower right side of the eyepiece 28.

Further, as described with reference to FIG. 2, the sensor window 23 is provided on the upper side of the eyepiece window 22.

FIG. 4B is a diagram illustrating a finder guide cylinder 43 constituting the finder rotating portion 41.

The guide shaft 44 that guides the finder guide cylinder 43 in a linear motion penetrates the upper left corner of the flange portion 43a provided on the finder guide cylinder 43.

The lens holder urging spring 146 is arranged at the upper right corner of the lens holder 42 that translates inside the finder guide tube 43.

That is, the guide shaft 44 and the lens holder urging spring 146 are arranged at different upper corners of the finder guide cylinder 43.

The locking claw 43c provided on the finder guide cylinder 43 locks the eyepiece 28 and the finder guide cylinder 43. The locking claws 43c are arranged on the lower left and right sides of the finder guide cylinder 43.

The diopter adjustment lever 120 is arranged on the lower surface side of the eyepiece portion 28 when viewed from the eyepiece window 22 side, and is slidably fitted to the finder guide cylinder 43.

The surface of the finder guide cylinder 43 to which the diopter adjusting lever 120 is slidably fitted is adjacent to the surface on which the locking claw 43c is provided.

That is, the positional relationship between them is described with the finder lens as the center when viewed from the eyepiece window 22 side.

The lens holder urging spring 146 is located at the upper right corner of the lens holder 42, the guide shaft 44 is located at the upper left corner of the finder guide cylinder 43, and the locking claws 43c are located on the lower left and right sides of the finder guide cylinder 43.

Here, as described with reference to FIG. 4A, a lens barrel unit is placed on the lower right side of the eyepiece 28 in a state where the finder unit 21 is housed in the image pickup device 1 when viewed from the eyepiece window 22 side. It is a relationship in which 2 is arranged.

Further, as described with reference to FIG. 3C, the finder fixing cylinder 45 is optimally on the diagonal side with respect to the finder unit rotation shaft 50.

Therefore, the locking means for restricting the rotation of the finder rotating portion 41 shown in FIG. 3B has a rotating locking member 130 on the lower left corner side of the finder rotating portion 41 when viewed from the eyepiece window 22 side. Deploy.

As a result, the finder rotating unit 41 can be reliably locked without increasing the size of the image pickup apparatus 1 and without transitioning to an inadvertent state.

(Explanation of regulation of rotational operation of electronic viewfinder unit 21)
Next, with reference to FIG. 5, the regulation of the rotational operation of the electronic viewfinder unit 21 after the protruding state will be described.

FIG. 5 shows the electronic viewfinder unit 21 in which the eyepiece 28 is in the retracted state.

In FIG. 5A, the grip portion 157 is a portion to be gripped in order to pull out the eyepiece portion 28. Therefore, the grip portion 157 is partially thickened as compared with the other portions of the eyepiece portion 28.

The regulated shape portion 153 is integrally provided with the eyepiece portion 28. The regulated shape portion 153 is thinner than the grip portion 157. The rotation locking member 130 is inside the regulated shape portion 153 when the eyepiece portion 28 is in the retracted state.

FIG. 5B is a cross section orthogonal to the finder optical axis of FIG. 5A.

In the cross section orthogonal to the rotation shaft 131, the rotation locking member 130 has a locking contact surface 154, an invitation surface 155, and a rotation restriction surface 156.

The locking contact surface 154 is in contact with the locking portion 145 provided on the fixed cylinder 45. Therefore, the finder rotating portion 41 constituting the finder unit 21 is locked in a state parallel to the finder lens optical axis and the image pickup lens (not shown).

When the eyepiece 28 is in the retracted state, the rotation locking member 130 is inside the regulated shape portion 153 provided on the eyepiece 28.

Therefore, even if the rotation locking member 130 tries to rotate against the urging force of the urging spring 132, the rotation restricting surface 156 is restricted from rotating due to interference with the regulation shape portion 153. There is.

That is, when the eyepiece 28 is in the retracted state, the fixed cylinder 45 cannot be rotated because the locked state is not released.

When viewed from the surface 49a of the finder cover 49 as the holding cover, the intersection P of the invitation surface 155 as the tapered surface and the rotation restricting surface 156 is within the projection of the grip portion 157.

The grip portion 157 is a thick portion for ensuring strength. Therefore, even if the rotation restricting surface 156 interferes with the regulated shape portion 153, the regulated shape portion 153 does not elastically deform.

Therefore, when the eyepiece 28 is in the retracted state, the fixed cylinder 45 is securely locked, and the finder rotating portion 41 does not inadvertently rotate to change the state.

(Explanation of Rotation Locking Member 130)
FIG. 6A shows the finder unit 21 in which the eyepiece 28 is pulled out to the position of use.

FIG. 6B is a cross section orthogonal to the finder optical axis of FIG. 6A.

FIG. 6C shows a state in which the rotating portion 41 starts rotating from the state in which the eyepiece portion 28 shown in FIG. 6A is pulled out to the used position.

FIG. 6D is a cross section orthogonal to the optical axis direction G of the photographing lens of the image pickup apparatus 1 of FIG. 6C.

In FIG. 6A, the regulated shape portion 153 integrally provided with the eyepiece 28 is provided with a notch shape 158 at the extension portion of the eyepiece 28 in the optical axis direction of the finder.

Since the notch shape 158 is present in the state where the eyepiece 28 is pulled out to the use position, the rotation restricting surface 156 is exposed from the eyepiece 28.

Therefore, the rotation restricting surface 156 provided on the rotation locking member 130 avoids interference with the restricted shape portion 153.

Next, FIG. 6C shows a state in which the rotation locking member 130 has started rotation. The locking contact surface 154 is pushed and rotated in the direction opposite to the urging direction by the locking portion 145 provided on the fixed cylinder 45.

Since there is a notch shape 158, when the rotation locking member 130 starts to rotate, the rotation regulation surface 156 avoids interference with the regulation shape portion 153.

Therefore, the rotation locking member 130 can rotate against the urging force of the urging spring 132.

FIG. 6 (d) is a cross section of FIG. 6 (c) orthogonal to the optical axis direction G of the photographing lens of the imaging device 1.

As shown in FIG. 6D, the rotation locking member 130 rotates around the rotation locking shaft 131 as the fixed cylinder 45 rotates.

The intersection P of the invitation surface 155 as the tapered surface and the rotation restriction surface 156 moves outward from the outermost shape of the eyepiece portion 28.

Therefore, the locking contact surface 154 of the rotary locking member 130 is separated from the locking portion 145 provided on the fixed cylinder 45, and the locking is released.

That is, the fixed cylinder 45 can rotate to a predetermined angle.

FIG. 6E shows a cross section orthogonal to the finder optical axis of the finder unit 21 during the transition from the state in which the fixed cylinder 45 is rotated by a predetermined angle to the stored state of 0 degrees.

The rotation locking member 130 is urged by the urging force of the urging spring 132.

When the fixed cylinder 45 transitions from the state of being rotated by a predetermined angle to the state of being stored at 0 degrees, the invitation surface 155 comes into contact with the locking portion 145 as shown in FIG. 6 (e).

The rotation locking member 130 rotates about the rotation locking shaft 131 in the direction opposite to the urging direction by the locking portion 145 on the invitation surface 155.

That is, the locking portion 145 rotates the rotating locking member 130.

The invitation surface 155 as the tapered surface returns to the state shown in FIG. 6 (c) while contacting the locking portion 145.

Therefore, the electronic viewfinder unit 21 transitions from the state of being rotated by a predetermined angle to the stored state of 0 degrees, and is locked again.

The locking contact surface 154, the invitation surface 155, and the rotation control surface 156 are adjacent to each other. Therefore, the rotation locking member 130 can be miniaturized. As a result, the rotation locking member 130 can lock the fixing cylinder 45 inside the finder cover 49.

Therefore, when the finder unit 21 is in a protruding state, the eyepiece 28 is pulled out and put into a usable state, so that the finder unit 21 can rotate.

Further, when the eyepiece 28 is in the retracted state, the rotation locking member 130 is regulated so as not to be easily rotated by the regulation shape portion 153 provided on the eyepiece 28, and the finder rotation part 41 carelessly moves. It is possible to suppress the state transition.

Consider the case where the electronic viewfinder unit 21 is projected from the main body and viewed from the eyepiece window 22 side.

The rotation of the rotation unit 41 is locked on the side opposite to the rotation axis 50 of the rotation unit 41 around the optical axis of the finder lens and on the side opposite to the lens barrel unit 2 around the optical axis of the finder lens. The rotation locking member 130 is arranged.

The electronic viewfinder unit 21 can be translated into a stored state in which it is stored in the main body and a protruding state in which it protrudes from the main body.

The rotating unit 41 includes a guide cylinder 43 for holding the lens holder 42, and a diopter adjusting lever 120 for shifting the lens holder 42 to the optical axis of the finder lens inside the guide cylinder 43.

Further, the rotating unit 41 includes a detection sensor for switching the display to the display unit 15 of the image pickup apparatus 1, and a sensor window 23 provided in the optical path of the detection sensor.

When viewed from the eyepiece window 22 side, the sensor window 23 is arranged on the rotation shaft 50 side of the rotation unit 41 with the eyepiece window 22 as the center in the translation direction of the electronic viewfinder unit 21.

The diopter adjustment lever 120 is arranged on the side opposite to the rotation shaft 50 of the rotation unit 41 with the eyepiece window 22 as the center in the translation direction of the electronic viewfinder unit 21.

The rotating unit 41 includes a fixed cylinder 45 that houses the guide cylinder 43 in a linear motion on the optical axis of the finder lens.

The eyepiece 28 is locked to the guide cylinder 43, and moves in translation with the guide cylinder 43 in the optical axis direction of the finder lens.

Consider the case of viewing from the eyepiece window 22 side.

The guide cylinder 43 is an urging spring that urges the guide shaft 44 and the lens holder 42 that guide the lens holder 42 toward the rotation shaft 50 side of the rotation unit 41 around the eyepiece window 22 in the translational direction of the electronic viewfinder unit 21. 146 is provided.

When viewed from the eyepiece window 22 side, the guide cylinder 43 has a plurality of eyepiece portions 28 on the side opposite to the rotation axis 50 of the rotation unit 21 about the eyepiece window 22 in the translational direction of the electronic viewfinder unit 21. A locking claw 43c is provided.

The holding cover 49 includes two surfaces 49a in which a flat plate extends in a direction parallel to the optical axis direction G of the photographing optical system and parallel to the movable direction of the retracted state and the protruding state with respect to the main body of the imaging device 1. ing.

The rotating unit 41 is rotatably supported in the holding cover 49 by the rotating shaft 50 of the rotating unit 41 in the protruding state.

The rotation locking member 130 is arranged diagonally with respect to the rotation shaft 50 of the rotation unit 21 with the fixed cylinder 45 as the center when viewed from a direction perpendicular to the surface 49a of the holding cover 49.

The fixed cylinder 45 is provided with a locking portion 145 with the rotating locking member 130.

Further, a substrate 60 to be fixed to the fixing member 32 together with the holding cover 49 is provided.
The rotation locking member 130 is pivotally supported by the substrate 60, and the rotation locking member 130 is rotatable about a rotation axis extending in the optical axis direction of the finder lens.

The rotary locking member 130 is urged by the urging spring 132 on the side that comes into contact with the locking portion 145.

When viewed from the eyepiece window 22 side, the rotation locking member 130 is located closer to the optical axis of the finder lens than the surface 49a of the holding cover 49 in a state where the locking portion 145 of the fixed cylinder 45 is locked. It is located in.

The rotation locking member 130 restricts the electronic viewfinder unit 21 from moving to the stored state with respect to the main body 1 when the rotation unit 41 is rotating.

The rotation locking member 130 is pivotally supported by the fixing member 32 to which the holding cover 49 is fixed by the rotation locking shaft 131 extending in the optical axis direction of the finder lens.

The rotation locking member 130 is urged by the urging spring 132.

The rotation locking member 130 moves in the rotation direction of the rotation unit 41 to a regulated position that restricts the movement of the electronic viewfinder unit 21 to the retracted state.

After that, the rotation locking member 130 can rotate in the order of the locking position for locking the rotation operation of the rotation unit 41 and the releasing position for releasing the locking of the rotation operation of the rotation unit 41.

At the restricted position, an abutting portion 137 that engages with the main body portion 1 is formed at one end of the rotation locking member 130.

The other end of the rotation locking member 130 is provided with a contact surface 154 that is locked to the rotation unit 41 to regulate the rotation operation.

When viewed from the eyepiece window 22 side, the contact surface 154 and the abutting portion 137 are formed on opposite sides of the rotation locking shaft 131.

The rotation restricting portion having the contact surface 154 at one end of the rotation locking member 130 has a tapered surface 155 for returning the rotation unit 41 from the state in which the rotation unit 41 is rotating to the locking position.

(Explanation of slide prevention mechanism)
Next, with reference to FIG. 7, a slide prevention mechanism to the stored state position during the rotation operation of the electronic viewfinder unit 21 will be described.

FIG. 7A is a cross-sectional view showing the configuration of the rotation locking member 130 in a state where the finder rotation portion 41 is rotated.

FIG. 7B is an enlarged view showing a detailed portion of the rotation locking member 130.

In FIG. 7A, the finder rotating portion 41 shows a state of being rotated 90 degrees as shown in FIG. 2C described above, and the rotation locking member 130 is centered on the rotation locking portion shaft 131. It is rotated by the urging spring 132 and stopped in a state of being in contact with the substrate base 60.

The rotation locking member 130 shown in FIG. 7B has a locking contact surface 154 that is locked to the fixed cylinder 45 to regulate the rotation operation, and sandwiches the rotation locking portion shaft 131. On the opposite side, a main body storage abutting portion 137 is formed.

In FIG. 7, the rotation locking member 130 is urged from a locking position (state of FIG. 5B) that regulates the rotation operation of the finder unit 21.

Therefore, it is rotated to the further rotated overstroke position.

At this time, the main body storage abutting portion 137 provided in a part of the rotation locking member 130 also rotates further from the locking position (state of FIG. 5B) and rotates to the outside of the locking position. It is stopped.

As described with reference to FIG. 3A, the spring holder 35 is fixed to the EVF holder 30 (described in FIG. 3A) described above.

The abutting portion 35a is provided on the spring holder 35 so as to face the main body storage abutting portion 137 when the rotation locking member 130 is stopped at the overstroke position.

As a result, the finder unit 21 tends to move to the stored state with respect to the image pickup apparatus main body 1 in the rotating state.

In that case, the main body storage abutting portion 137 comes into contact with the abutting portion 35a of the spring holder 35 to prevent the slide movement to the stored state.

In this way, the rotation locking member 130 is urged from the locking position and rotates to the overstroke position.

Then, the main body storage abutting portion 137 comes into contact with the abutting portion 35a of the spring holder 35 to prevent the slide movement to the stored state.

The rotation locking member 130 is a single member that locks the rotation of the fixed cylinder 45 to suppress the rotation operation of the finder unit 21 and to suppress the movement of the finder unit 21 in the retracted state direction. It is possible.

That is, the finder unit 21 is prevented from inadvertently transitioning to an unintended state with a small number of parts.

As a result, the finder unit 21 is inadvertently lowered toward the retracted state after the rotation operation of the finder unit 21 when the camera is used, and there is no problem that the finder display image cannot be visually recognized.

As described above, the locking contact surface 154 provided on the rotary locking member 130 is in contact with the locking portion 145 provided on the fixed cylinder 45.

When the eyepiece 28 is in the retracted state, the rotation locking member 130 is restricted from rotating by the rotation restricting surface 156 provided on the rotation locking member 130 by the restricted shape portion 153 provided on the eyepiece 28. Has been done.

Therefore, the finder rotating portion 41 constituting the finder unit 21 is locked in a state parallel to the finder lens optical axis and the image pickup lens (not shown).

Further, the main body storage abutting portion 137 provided on the rotation locking member 130 abuts on the abutting portion 35a of the spring holder 35 to prevent the slide movement to the stored state.

Depending on the state of the eyepiece 28, the finder 20 can prevent a decrease in convenience due to a careless transition to an unintended state and damage to the camera.

As another embodiment, another member may have a function of suppressing the rotational movement of the finder unit 21 and a function of suppressing the movement of the finder unit 21 in the stored state direction.

The rotation restricting portion of the rotation locking member 130 has a rotation restricting surface 156, and the eyepiece 28 has a restricting surface 153.

In a state where the rotating unit 41 is housed in the holding cover 49, the rotation of the rotating unit 41 is restricted by engaging the restricting surface 153 with the rotation restricting surface 156.

A notch 158 is formed on the regulation surface 153, and the rotation regulation surface 156 of the rotation locking member 130 is notched in the optical axis direction of the finder lens in a state where the eyepiece 28 is pulled out to the use position. It is located in part 158.

Therefore, the regulation surface 153 does not engage with the rotation regulation surface 156.

The rotating unit 41 includes a guide cylinder 43 for holding the lens holder 42, and a fixed cylinder 45 for accommodating the guide cylinder 43 so as to be linearly movable on the optical axis of the finder lens.

At the locking position for locking the rotational operation of the rotating unit 41, the contact surface 154 comes into contact with the locking portion 145 provided on the fixed cylinder 45.

The tapered surface 155 comes into contact with the locking portion 145 provided on the fixed cylinder 45 when the rotating unit 41 is returned from the rotating state to the locking position.

When viewed from the eyepiece window side, the tapered surface 155 and the rotation restricting surface 156 are adjacent to each other, and the tapered surface 155 and the contact surface 154 are adjacent to each other.

The holding cover 49 includes two surfaces 49a in which a flat plate extends in a direction parallel to the optical axis direction G of the photographing optical system and parallel to the movable direction of the retracted state and the protruding state with respect to the main body of the imaging device 1. ing.

The intersection P formed on the extension of the adjacent tapered surface 155 and the rotation restricting surface 156 is within the projection of the thick portion of the restricting surface 153 when viewed from the surface 49a side of the holding cover 49.

The thick portion of the regulation surface 153 is a grip portion 157 that is gripped to pull out the eyepiece portion 28.

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.

1 Image pickup device 9 Front cover 16 Top cover 14 Release lever 20 Finder 21 Finder unit 22 Eyepiece window 28 Eyepiece 31 Finder Top cover 35a Butt part 41 Finder rotation part 44 Guide shaft 45 Finder fixing cylinder 45b Shaft hole part 49 Finder Cover 50 Finder unit Rotating shaft 51 Vertical movement mechanism 130 Rotating locking member 131 Rotating locking shaft 132 Biasing spring 137 Main body storage abutment part 145 Locking part 153 Restricted shape part 154 Locking contact surface 155 Inviting surface 156 Rotation control surface 157 Grip

Claims (6)

An imaging device having an electronic viewfinder unit that is movable in a stored state that is stored in the main body and a protruding state that protrudes with respect to the main body.
The electronic viewfinder unit includes a rotation unit, a holding cover that rotatably holds the rotation unit about a rotation axis, and a rotation locking member that locks the rotation of the rotation unit. With
The rotating unit is a lens holder that holds an electronic display unit, an eyepiece, an eyepiece window that covers the eyepiece, and a finder lens that guides light flux emitted from the electronic display unit to the eyepiece. And with
The rotation restricting portion of the rotation locking member has a rotation restricting surface.
The eyepiece has a regulatory surface and
An imaging device characterized in that the rotation of the rotating unit is restricted by engaging the restricting surface with the rotation restricting surface in a state where the rotating unit is housed in the holding cover. A notch is formed on the regulation surface,
In a state where the eyepiece is pulled out to the use position, the rotation restricting surface of the rotation locking member is located at the notch in the optical axis direction of the finder lens, so that the regulation surface is rotated. The imaging device according to claim 1, wherein the image pickup device does not engage with a motion control surface. The rotating unit includes a guide cylinder for holding the lens holder and a fixed cylinder for accommodating the guide cylinder so as to be linearly movable on the optical axis of the finder lens.
At the locking position for locking the rotational operation of the rotating unit, the contact surface abuts on the locking portion provided on the fixed cylinder.
According to claim 1 or 2, the tapered surface comes into contact with a locking portion provided on the fixed cylinder when the rotating unit is returned from the rotating state to the locking position. The imaging apparatus described. The aspect according to any one of claims 1 to 3, wherein when viewed from the eyepiece window side, the tapered surface and the rotation restricting surface are adjacent to each other, and the tapered surface and the contact surface are adjacent to each other. The imaging device described. The holding cover has two surfaces in which a flat plate extends in a direction parallel to the optical axis direction of the photographing optical system and parallel to the movable direction of the retracted state and the protruding state with respect to the main body of the imaging device.
The intersection formed on the extension of the adjacent tapered surface and the rotation restricting surface is within the projection of the thick portion of the restricting surface when viewed from the surface side of the holding cover. Item 4. The imaging apparatus according to item 4. The imaging device according to claim 5, wherein the thick portion of the regulation surface is a grip portion that is gripped to pull out the eyepiece portion.

Images