JP2007329726A - Electronic equipment system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electronic equipment system that is advantageous for conducting communication between electronic equipment and external equipment via a cradle in a simple manner, while reducing the size and the cost. <P>SOLUTION: When an imaging device 10 is placed on the cradle 200 and multiconnectors 42, and 202 are connected, data communication terminals are connected with each other, A/V signal terminals are connected with each other, power-supply terminals are connected with each other, and a signal input terminal 4202 and a signal output terminal 242 are connected with each other. When an operation switch 220 is operated and turned on, the signal input terminal 4202, connected to a control unit 1026 of the imaging device 10, undergoes transition from "H" to "L". As a result, the control unit 1026 controls a USB interface part 47 so as to make prescribed data communication executed by a USB, between the imaging device 10 and a personal computer 4 via the USB interface 47. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an electronic device and an electronic device system including a cradle for mounting the electronic device.

When performing data communication between a portable electronic device such as a digital still camera, video camera, or PDA (Personal Digital Assistant) and an external device such as a personal computer, the electronic device and the external device are directly connected with a connection cable. In this case, it is necessary to perform the detachment operation with the connector between the electronic device and the connection cable, and the detachment operation with the connector between the external device and the connection cable, which is inferior in operability.
Therefore, a cradle (mounting table) for placing the electronic device is provided, the cradle and the external device are connected with a dedicated connection cable, and the electronic device and the cradle are attached by a simple operation such as placing the electronic device on the cradle. A system that connects and communicates between an electronic device and an external device via a cradle has been proposed (see Patent Document 1).
JP 2005-33387 A

However, in the above system, the cradle is provided with an interface unit for performing, for example, USB data communication with the electronic device, and a signal indicating whether or not the electronic device is placed on the cradle via this interface unit. When the electronic device detects that the signal has been input, the electronic device performs data communication with the external device.
Therefore, since the cradle requires the interface unit, the configuration is complicated, which is disadvantageous in terms of downsizing and cost reduction.
The present invention has been made in view of such circumstances, and its purpose is to facilitate communication between an electronic device and an external device via a cradle while reducing the size and cost. To provide an advantageous electronic device system.

  In order to achieve the above object, the present invention includes an electronic device and a cradle on which the electronic device is placed, and the electronic device includes a communication control unit, an interface unit connected to the communication control unit, and An electronic device side connector, and the cradle is electrically connected to the cradle side connector and the cradle side connector detachably connected to the electronic device side connector when the electronic device is placed And an external device connector that is detachably connected to the connector of the external device, the electronic device side connector and the cradle side connector are connected, and the external device connector is connected to the external device. By being connected, the electronic device and the external device are connected to the interface unit, the electronic device-side connector, and the cradle-side connector. An electronic device system configured to communicate with an external communication connector, wherein the cradle side connector has a plurality of terminals, and one of the plurality of terminals is a signal output terminal. The electronic device-side connector has a plurality of terminals, and one terminal of the plurality of terminals is directly connected to the communication control unit without the interface unit interposed therebetween, and the electronic device A signal input terminal connected to the signal output terminal when a side connector is connected to the cradle side connector, and the signal by being electrically connected and operated to the signal output terminal to the cradle An operation switch for supplying an operation signal to an output terminal is provided, and the communication control unit supplies the operation signal from the signal output terminal via the signal input terminal. If that is characterized by being configured so as to perform communication between the electronic device and the external device through the interface unit.

  According to the present invention, by operating the operation switch provided in the cradle, the operation signal is directly supplied from the cradle to the communication control unit of the electronic device without interposing the interface unit, and the communication control is performed by the operation signal. Since the unit allows communication between the electronic device and the external device via the cradle, there is no need to provide an interface unit on the cradle, and the electronic device via the cradle can be reduced while reducing the size and cost of the cradle. This is advantageous for easy communication with external devices.

Next, embodiments of the present invention will be described with reference to the drawings.
In this embodiment, the case where the electronic device is an imaging device will be described.
1 and 2 are perspective views of the imaging device 10, FIG. 3 is an exploded perspective view of the imaging device 10, FIG. 4 is a right side view of the imaging device 10, FIG. 5 is a left side view of the imaging device 10, and FIG. FIG. 7 is a rear view of the imaging device 10, FIG. 8 is a plan view of the imaging device 10, and FIG. 9 is a bottom view of the imaging device 10.

As shown in FIGS. 1 and 2, the imaging device 10 is a video camera, and records and reproduces data such as moving images, still images, and sounds using a hard disk device 44 (see FIGS. 3 and 10). .
The imaging apparatus 10 includes a case 12 that forms an exterior, and the case 12 has a length in the front-rear direction and a height in the vertical direction that are larger than the width in the left-right direction. In the present specification, left and right refer to the state in which the imaging device 10 is viewed from the rear, the subject side is referred to as the front in the optical axis direction of the optical system, and the imaging element side is referred to as the rear.
The case 12 has a front surface 12A facing forward, a rear surface 12B facing backward, an upper surface 12C facing upward, a bottom surface 12D facing downward, a left side surface 12E facing left, and a right side facing. Right side surface 12F.
A lens barrel 16 in which the photographing optical system 14 is incorporated extends in the front part at the top of the case 12 so that the front part faces the front surface 12A of the case 12. The photographing optical system 14 has a zoom lens and is configured so that the zoom rate can be continuously varied.
At the rear end of the lens barrel 16, an image sensor 18 (see FIG. 10) that captures a subject image guided by the photographing optical system 14 is provided.
As shown in FIGS. 1 and 2, on the left side of the case 12, a display panel 20 composed of, for example, a liquid crystal display device for displaying a subject image captured by the image sensor 18 is provided so as to be openable and closable. The display panel 20 is superimposed on the left side surface 12E of the case 12 when closed. A speaker 22 is provided on the left side surface 12E of the case 12.
As shown in FIG. 1, a hot shoe 24 to which accessories such as a video light and a flashlight are detachably attached is provided at the front portion of the upper surface 12 </ b> C of the case 12.
As shown in FIGS. 2, 7, and 9, a battery mounting portion 40 for mounting the battery 38 is provided on the rear surface 12 </ b> B of the case 12.
2 and 9, a multi-connector 42 is provided on the bottom surface 12D of the case 12, and the multi-connector 42 places the imaging device 10 on the cradle 200 as shown in FIGS. In this case, it is joined to the multi-connector 202 on the cradle 200 side.
As shown in FIG. 6, a microphone 26 for collecting sound is provided at the lower part of the front surface 12 </ b> A of the case 12.

As shown in FIGS. 1 and 2, the imaging apparatus 10 includes a power operation switch 28, a still image shooting operation switch 30, a zoom operation switch 32, as operation switches for executing various functions related to shooting. A mode switching operation switch 34, a moving image shooting operation switch 36, and the like are provided.
The power operation switch 28, the still image shooting operation switch 30, the zoom operation switch 32, and the mode switching operation switch 34 are provided on the upper surface 12 </ b> C of the case 12.
The moving image shooting operation switch 36 is provided near the right side surface 12F in the middle of the rear surface 12B of the case 12 in the vertical direction.
The power operation switch 28 is used to turn on and off the power of the imaging apparatus 10.
The still image shooting operation switch 30 is for shooting a still image by the image sensor 18.
The zoom operation switch 32 is for changing the zoom ratio of the photographing optical system 14.
The mode switching operation switch 34 is for switching between a still image shooting mode and a moving image shooting mode.
The moving image shooting operation switch 36 is for starting and stopping moving image shooting.

FIG. 10 is a block diagram illustrating a configuration of a control system of the imaging apparatus 10.
As shown in FIG. 10, the imaging apparatus 10 includes a video signal amplification unit 1002, an image data processing unit 1004, an audio signal amplification unit 1006, an audio data processing unit 1008, a display drive unit 1010, a speaker drive unit 1012, and a buffer. Memory 1014, memory control unit 1016, memory card control unit 1018, interface unit 1020, A / V signal generation unit 1022, drive voltage unit 1024, control unit 1026, interface unit 1028, recording / reproducing unit 1030, hard disk device 44, bus 46 A USB interface unit 47 and the like are provided.
The image data processing unit 1004, the audio data processing unit 1008, the display drive unit 1010, the speaker drive unit 1012, the memory control unit 1016, the memory card control unit 1018, the interface unit 1020, the interface unit 1028, and the recording / reproducing unit 1030 are connected to the bus 46. Has been.

The imaging signal generated by the imaging element 18 is amplified by the video signal amplification unit 1002 and supplied to the image data processing unit 1004.
The image data processing unit 1004 generates predetermined moving image data and still image data by performing predetermined signal processing on the image pickup signal, and supplies the generated moving image data and still image data to the recording / reproducing unit 1030.
The audio signal collected by the microphone 26 is amplified by the audio signal amplifying unit 1006, subjected to predetermined signal processing by the audio data processing unit 1008, and supplied to the recording / reproducing unit 1030 as audio data.

The recording / reproducing unit 1030 supplies the moving image data and still image data supplied from the image data processing unit 1004 and the audio data supplied from the audio data processing unit 1008 to the recording / reproducing unit 1030 under the control of the control unit 1026 for recording. The playback unit 1030 records moving image data, still image data, and audio data in the hard disk device 44.
The recording / reproducing unit 1030 also stores the moving image data and still image data supplied from the image data processing unit 1004 and the audio data supplied from the audio data processing unit 1008 into the memory card slot 1019 via the memory card control unit 1018. Recording is performed on the memory card 2 serving as a loaded recording medium.
Further, the recording / reproducing unit 1030 supplies the moving image data and still image data supplied from the image data processing unit 1004 to the display panel 20 via the display drive unit 1010 to display an image.
Further, the recording / reproducing unit 1030 supplies the moving image data and still image data supplied from the memory card 2 via the memory card control unit 1018 to the display panel 20 via the display drive unit 1010 to display an image. In addition, the audio data supplied from the memory card 2 via the memory card control unit 1018 is supplied to the speaker 22 via the speaker drive unit 1012 to output audio.
The recording / reproducing unit 1030 supplies the moving image data and still image data reproduced from the hard disk device 44 to the display panel 20 via the display drive unit 1010 to display an image and reproduces the data from the hard disk device 44. The audio data thus supplied is supplied to the speaker 22 via the speaker drive unit 1012, and audio is output.
The buffer memory 1014 is for reading and writing data including image data or audio data via the memory control circuit 1016 and the bus 46.

The control unit 1026 turns on and off the power of the imaging apparatus 10 by operating the power operation switch 28.
Further, the control unit 1026 records the still image data supplied from the image data processing unit 1004 by giving a command to the image data processing unit 1004 and the recording / reproducing unit 1030 based on the operation of the still image shooting operation switch 30. The still image data is recorded on the hard disk device 44 by being supplied to the reproduction unit 1030.
Further, the control unit 1026 gives a command to a zoom drive unit (not shown) based on the operation of the zoom operation switch 32, and moves the zoom lens of the photographic optical system 14, thereby causing the zoom rate of the photographic optical system 14 to move. To change.
Further, the control unit 1026 gives a command to the image data processing unit 1004 based on the operation of the mode switching operation switch 34, thereby causing the image data processing unit 1004 to generate moving image data, and an image data processing unit. In step 1004, a still image shooting mode for generating still image data is switched.
In the moving image shooting mode, moving image data generated by the image data processing unit 1004 is recorded on the hard disk device 44 or the memory card 2 via the recording / reproducing unit 1030. In the still image shooting mode, generated by the image data processing unit 1004. The still image data thus recorded is recorded on the hard disk device 44 or the memory card 2 via the recording / reproducing unit 1030.
In addition, the control unit 1026 starts and stops recording of moving image data based on the operation of the operation switch for moving image shooting 36. That is, the control unit 1026 gives a command to the image data processing unit 1004 and the recording / reproducing unit 1030 based on the operation of the moving image shooting operation switch 36, whereby the moving image supplied from the image data processing unit 1004 to the recording / reproducing unit 1030 is provided. The operation of recording data in the hard disk device 44 is started or the operation is stopped. In the present embodiment, control unit 1026 is configured by a microcomputer (including a general-purpose microprocessor or DSP).
In the present embodiment, the video signal amplification unit 1002, the image data processing unit 1004, the control unit 1026, the recording / reproducing unit 1030, and the like constitute a signal processing unit as claimed.

  Further, the A / V signal generation unit 1022 converts the moving image (still image) data and audio data supplied from the recording / reproducing unit 1030 or the memory card control unit 1018 via the interface unit 1020 to a predetermined video signal and audio signal. Converted to output.

  The drive voltage unit 1024 adjusts the power supplied from the battery 38 to a predetermined voltage and current and supplies the power to each unit of the imaging device 10 or supplies the power from an external power supply device via the external power supply input terminal 1025. The adjusted electric power is adjusted to a predetermined voltage and current and supplied to each part of the imaging apparatus 10. Further, the battery 38 is charged with electric power supplied from an external power supply device.

The USB interface unit 47 is provided between the bus 46 and the multi-connector 42, and is based on USB between the bus 46 and the external device via the multi-connector 42 and the cradle 200 based on a command from the control unit 1026. Data communication is performed.
That is, the imaging device 10 is configured to communicate with an external device by being placed on the cradle 200. The cradle 200 will be described in detail later.

Next, the hard disk device 44 and its housing structure will be described in detail.
11 is a cross-sectional view taken along line AA of the main part of FIG. 4, and FIG. 12 is a cross-sectional view taken along line BB of the main part of FIG.
FIG. 13 is a right side view of the imaging apparatus 10.
14 to 16 are explanatory views of the mounting operation of the cover 52 in the cross section along the line AA in FIG.
17 to 19 are explanatory views of the mounting operation of the cover 52 in the cross section taken along line BB in FIG.
20 to 23 are explanatory views of the mounting operation of the cover 52. FIG.

The right side surface 12F of the case 12 is provided with a hard disk housing portion 50, a cover 52 for opening and closing the hard disk housing portion 50 is provided, and the outer surface of the cover 52 is closed with the cover 52 closing the hard disk housing portion 50. It constitutes a part of the right side surface 12F (most part in the present embodiment).
As shown in FIG. 3, the hard disk device 44 is configured by incorporating a magnetic disk, a magnetic head, and the like inside a hard disk case 45, and the hard disk case 45 has a flat rectangular plate shape having a thickness smaller than the vertical and horizontal dimensions. And two dampers 54 are mounted around it.
The hard disk housing portion 50 is formed in the vertical, horizontal, and depth dimensions that are larger than the vertical, horizontal, and thickness dimensions of the hard disk case 45. In this example, the hard disk housing portion 50 has a dimension that can accommodate the hard disk case 45 with the damper 54 mounted. It is formed with vertical, horizontal, and depth.
The hard disk housing portion 50 has a rectangular opening 56 on one surface in the depth direction, and the hard disk device 44 extends from the opening 56 in the depth direction of the hard disk housing portion 50 with the damper 54 mounted. Along the way.

As shown in FIG. 3, the first case side mating portion 58 is provided on the portion of the case 12 that includes one of the four edges that border the opening 56, and in the case 12 that includes the upper edge in this example. Is provided.
Further, the second case is aligned with the portion of the case 12 that includes another one of the four edges that border the opening 56, and in this example, the portion of the case 12 that includes the lower edge. A portion 60 is provided.
As shown in FIGS. 3, 11, and 12, the first case side mating portion 58 is provided with a first engagement groove 5802 and a second engagement groove 5804.
The first engagement groove 5802 is provided at the center of the upper edge extending direction that borders the upper portion of the opening 56, and as shown in FIG. 12, the depth in the direction parallel to the depth direction of the hard disk housing portion 50 is provided. It extends along the extending direction of the upper edge and has an open shape on the outer side of the case 12.
As shown in FIG. 3, two second engagement grooves 5804 are provided so as to be located at positions sandwiching the first engagement groove 5802 in the extending direction of the upper edge that borders the upper portion of the opening 56.
As shown in FIG. 11, each second engagement groove 5804 has a depth in a direction perpendicular to the depth direction of the hard disk housing 50 (in the direction perpendicular to the extending direction of the upper edge of the opening 56). Extending along the extending direction of the upper edge.
As shown in FIGS. 11 and 12, the second case side mating portion 60 is formed with a flat outer surface portion 6002 facing downward, and a plurality of screw holes (not shown) are formed in the outer surface portion 6002. Has been.
Further, in this example, screw holes (not shown) are provided in the case 12 in front of the front edge that borders the front portion of the opening 56 and in the case 12 in the rear of the rear edge that borders the rear portion of the opening 56. ) Is formed.

As shown in FIG. 3, the opening 56 is opened and closed by a cover 52, and the cover 52 includes a main body plate portion 62, a first cover side matching portion 64, and a second cover side matching portion 66.
The main plate 62 has a rectangular shape that closes the opening 56.
As shown in FIG. 1, screw insertion holes 6210 are formed in the front part and the rear part of the main body plate part 62, respectively.
As shown in FIGS. 11 and 12, the first cover side mating portion 64 is connected to the upper side of the main body plate portion 62 via a curved portion 63, and the first cover side mating portion 64 is connected to the main body plate portion 62. It protrudes in the intersecting direction (in this example, the orthogonal direction).
The inner surface and the outer surface of the curved portion 63 have an opening 56 closed by the main body plate portion 62, the first cover side matching portion 64 is overlapped with the first case side matching portion 58, and the second cover side matching portion 66 is the second case side. A convex curved surface is formed on the outer side of the hard disk housing 50 in a state of being superimposed on the mating portion 60.
As shown in FIGS. 16 and 19, the first cover side mating portion 64 includes a first plate portion 6402 extending over the entire length of the upper side of the main body plate portion 62 in a direction orthogonal to the main body plate portion 62. In other words, the first cover side mating portion 64 has a first plate portion 6402 that is orthogonal to the main body plate portion 62 via the bending portion 63.
One first engaging convex portion 6410 and two second engaging convex portions 6412 are provided on the first cover side mating portion 64 (on the first plate portion 6402).
In the first engaging convex portion 6410, the opening 56 is closed by the main body plate portion 62, the first cover side aligning portion 64 is overlapped with the first case side aligning portion 58, and the second cover side aligning portion 66 is the second case side. In a state of being overlaid on the mating portion 60, it protrudes parallel to the depth direction of the hard disk housing portion 50 and extends along the extending direction of the first plate portion 6402.
Each of the second engaging convex portions 6412 is provided at a location sandwiching the first engaging convex portion 6410 in the extending direction of the first plate portion 6402.
Each of the second engaging protrusions 6412 protrudes in a direction perpendicular to the depth direction of the hard disk housing portion 50 (a direction perpendicular to the extending direction of the first plate portion 6402 toward the hard disk housing portion 50). The one plate portion 6402 extends along the extending direction.

Then, as shown in FIG. 19, the first engaging convex portion 6410 is formed in a state where the opening 56 is closed by the main body plate portion 62 and the first cover side matching portion 64 is overlapped with the first case side matching portion 58. By engaging the first engaging groove 5802 and the first engaging convex portion 6410 and the first engaging groove 5802 engaging with each other, the cover 52 in the direction perpendicular to the depth direction of the hard disk housing portion 50 is engaged. Movement (movement of the cover 52 in a direction perpendicular to the extending direction of the upper side of the main body plate portion 62 and moving away from the hard disk housing portion 50), that is, in this example, movement of the cover 52 in the vertical direction is prevented. It is formed so that.
Also, as shown in FIG. 16, the two second engaging convex portions 6412 are in a state in which the opening 56 is closed by the main body plate portion 62 and the first cover side matching portion 64 is overlapped with the first case side matching portion 58. Are engaged with the corresponding second engagement grooves 5804, and the second engagement protrusions 6412 and the second engagement grooves 5804 are engaged with each other, so that the direction parallel to the depth direction of the hard disk housing portion 50 is achieved. In this example, the cover 52 is formed so as to be prevented from moving in the left-right direction.

As shown in FIGS. 11 and 12, the second cover side mating portion 66 is connected to the main body plate portion 62 via the bending portion 65 and intersects the main body plate portion 62 (in this example, the orthogonal direction). ).
The inner surface and the outer surface of the curved portion 65 have the opening 56 closed by the main body plate portion 62, the first cover side matching portion 64 is overlapped with the first case side matching portion 58, and the second cover side matching portion 66 is the second case side. A convex curved surface is formed on the outer side of the hard disk housing 50 in a state of being superimposed on the mating portion 60.
As shown in FIGS. 11 and 12, the second cover side mating portion 66 includes a second plate portion 6602 that extends over the entire length of the lower side of the main body plate portion 62 in a direction orthogonal to the main body plate portion 62. ing.
The first cover side mating portion 64 and the second cover side mating portion 66 face each other, that is, the first plate portion 6402 and the second plate portion 6602 face each other.
As shown in FIGS. 11 and 12, the flat inner surface that can contact the outer surface portion 6002 of the second case side mating portion 60 is located at a position where the second cover side mating portion 66 faces the second case side mating portion 60. A portion 6610 is formed.
As shown in FIG. 20, a plurality of screw insertion holes 6010 are provided coaxially with the plurality of screw holes (not shown) at the location of the second plate portion 6602 including the inner surface portion 6610.

As shown in FIGS. 14 to 23, the opening 56 is closed by the main body plate portion 62, and the first and second engaging convex portions 6410 and 6412 are inserted into the first and second engaging grooves 5802 and 5804, respectively. When the outer surface portion 6002 and the inner surface portion 6610 are in contact with each other, the first cover side aligning portion 64 is superimposed on the first case side aligning portion 58 and the second cover side aligning portion 66 is overlapped with the second case side aligning portion. 60 is superimposed.
In this state, as shown in FIG. 23, a screw 6012 that is screwed into the screw hole is fastened through a screw insertion hole 6010, and a screw 6212 is screwed into the screw hole of the case 12 through the screw insertion hole 6210. The cover 52 is attached to the case 12 by these screws 6012 and 6022.
With the cover 52 attached to the case 12 as described above, the outer surface of the first cover side mating portion 64 extends on a virtual surface continuous with the upper surface 12C of the case 12, as shown in FIGS. In addition, the outer surface of the second cover side mating portion 66 extends on a virtual surface continuous with the bottom surface 12D of the case 12, and therefore the cover 52 is only a part of the right side surface 12F of the case 12. In addition, the upper surface 12C and a part of the bottom surface 12D of the case 12 are also configured.
Also, as shown in FIGS. 11 and 12, the damper 54 mounted on the upper side of the hard disk case 45 in the location located near the first cover side mating portion 64 of the damper 54, in this example, has the main body plate portion 62. The inner surface facing the hard disk housing section 50 is sandwiched between a location located near the first cover side mating section 64 and the bottom of the hard disk housing section 50. Further, in the present example, the damper 54 mounted on the lower side of the hard disk case 45 is positioned on the inner surface where the main body plate portion 62 faces the hard disk housing portion 50. It is sandwiched between a location located near the two-cover-side mating portion 66 and the bottom portion of the hard disk housing portion 50. The hard disk device 44 is held and accommodated in the hard disk housing 50 by sandwiching the damper 54 as described above. The configuration of the damper 54 and the sandwiching structure thereof will be described later in detail.

  A grip belt (not shown) is provided so as to pass outside the right side surface 12F of the case 12, and in this example, a grip belt is provided so as to pass outside the cover 52. 12 are respectively attached to the front surface 12A and the rear surface 12B, and an insertion space of the right palm is formed between the cover 52 and the grip belt. Therefore, the user of the image pickup apparatus 10 inserts the right palm between the cover 52 and the grip belt, and takes a picture by grasping the cover 52 and portions located above and below the cover 52.

According to the configuration as described above, the first and second engaging convex portions 6410 and 6412 of the cover 52 are engaged with the first and second engaging grooves 5802 and 5804 of the case 12, respectively, and the outer surface portion 6002 and the inner surface Since the portion 6610 is abutted to be attached to the case 12 of the cover 52, the cover 52 can be provided without newly providing the number of parts necessary for attaching the cover 52 as compared with the conventional structure using a hinge or a lock mechanism. Therefore, it is advantageous in reducing assembly man-hours, cost reduction, and downsizing.
Further, the first and second engaging convex portions 6410 and 6412 of the cover 52 are engaged with the first and second engaging grooves 5802 and 5804 of the case 12, respectively. Both movements are blocked.
In particular, as described above, when the cover 52 constitutes the right side surface 12F of the case 12 and is a portion that is gripped when the imaging apparatus 10 is used, the cover 52 rattles when gripped by hand. Is surely prevented, which is advantageous in improving the operability of the imaging apparatus 10.
Further, as described above, the second engagement convex portion 6412 and the second engagement groove 5804 are arranged in the extending direction of the upper edge that borders the opening 56, and the first engagement convex portion 6410 and the first engagement groove 5802 are arranged in the extending direction. When two are provided at the sandwiched portions, the movement of the cover 52 in the left-right direction can be reliably prevented, and rattling of the cover 52 is more reliably prevented when the cover 52 is gripped by hand. This is more advantageous for improving the operability of the apparatus 10.

Further, since the hard disk housing portion 50 is provided on the side surface of the case 12 and the cover 52 for opening and closing the hard disk housing portion 50 is provided, the hard disk device 44 can be assembled at the final stage of the assembly process. It becomes. Therefore, if a strong impact or vibration is applied, the magnetic disk or magnetic head inside the hard disk device 44 may collide with each other and be damaged. However, according to the present example, the hard disk device 44 is incorporated at the final stage, so that it is described above. This is advantageous in eliminating the fear of
Further, since the hard disk housing portion 50 is provided on the side surface of the case 12 and the cover 52 for opening and closing the hard disk housing portion 50 is provided, only the hard disk device 44 can be easily attached to and detached from the electronic device. The effect that the hard disk device 44 can be easily replaced or repaired when the hard disk device 44 is later replaced with a hard disk device 44 having a larger data capacity, or when the hard disk device 44 is repaired (maintenance). Is also played.
Further, since the hard disk device 44 is provided on the right side surface 12F of the case 12 via the hard disk housing 50, a heat source that generates heat, such as the image sensor 18 and the display panel 20, is separated from the hard disk device 44, for example, on the left side. It can be arranged at a location near the surface, and this arrangement is advantageous in increasing the operational stability of the hard disk device 44 and extending its life.

Next, the configuration of the damper 54 will be described in detail.
24 is a perspective view showing the configuration of the damper 54, FIGS. 25A and 25B are explanatory diagrams of the operation of the damper 54, and FIG. 26 is an enlarged cross-sectional view showing the configuration of the surroundings of the damper 54 and the hard disk case 45. 27 is an explanatory view of the operation of the damper of the comparative example.

As shown in FIGS. 24 and 25, the damper 54 includes a portion including two corners on both sides on one side of the hard disk case 45, and two corners on both sides on one side opposed to the one side. Accordingly, a plurality of dampers 54 are mounted at intervals in the extending direction of the edge of the hard disk case 45, and two dampers 54 are provided in this example.
First, a description will be given from the periphery of the hard disk case 45 to which the damper 54 is mounted. As shown in FIG. 26, an edge 4502 constituting the periphery of the hard disk case 45 is a hard disk case part inside the edge 4502. It is formed so as to protrude in a thin plate shape with a thickness smaller than the thickness of the hard disk case portion inside the edge portion 4502 from the middle portion in the thickness direction. Side surfaces 4504 of the hard disk case portion inside the edge 4502 are located on both sides of the edge 4502 in the thickness direction at the base of the edge 4502.

As shown in FIGS. 24 and 25, the damper 54 includes a first member 70 and a second member 72.
The first member 70 is made of a hard synthetic resin and includes a holding groove 74 that holds an edge portion 4502 of the hard disk case 45 (a portion including two corners on one side of the hard disk case 45). .
The first member 70 includes a pair of opposing wall portions 7402 that are opposed to each other and are in contact with both sides in the thickness direction of the edge portion 4502 of the hard disk case 45, and a bottom wall that connects the back portions of the pair of opposing wall portions 7402. The pair of opposing wall portions 7402 and the bottom wall portion 7404 extend in a straight line, and therefore the first member 70 has an elongated shape.
In this example, the holding groove 74 is constituted by a pair of opposing wall portions 7402 and a bottom wall portion 7404, and the holding groove 74 extends in the longitudinal direction of the first member 70, and one side of the hard disk case 45 is connected to the holding groove 74. It has a length that holds it over its entire length.

The second member 72 is made of an elastic material and is formed to cover the first member 70 with the holding groove 74 exposed.
The second member 72 includes a main body portion 76 that extends linearly and covers the first member 70, and two leg portions 78 that respectively protrude from both sides of the main body portion 76.
Accordingly, the damper 54 has a thickness along the direction in which the pair of opposing wall portions 7402 face each other, and the main body portion 76 is provided so that the holding groove 74 is located at the center in the thickness direction of the damper 54. Yes.
In addition, as a hard synthetic resin which comprises the 1st member 70, ABS resin or polyacetal (POM) etc. are employable, for example. Moreover, as an elastic material which comprises the 2nd member 72, the gel material for shock absorption using sponge, an elastomer, etc., sponge material, etc. are employable, for example.
In this example, the damper 54 composed of the first member 70 and the second member 72 made of different materials is formed by two-color molding.
Then, as shown in FIG. 26, second surfaces 7402A positioned opposite to the surfaces facing each other of the pair of facing walls 7402 and outer surfaces 7404A of the bottom wall 7404 positioned on the extension of the outer surface 7402A are respectively The portions 72A of the member 72 are located, and the portions 72A of the second member 72 are deformed following the displacement in the thickness direction of the hard disk case 45 so as to be deformed. 7402A and the outer surface 7404A of the bottom wall portion 7404 are integrally joined to each other.
Further, the outer surface 7404B of the bottom wall portion 7404 orthogonal to the outer surface 7404A is also joined to the second member 72, and therefore, the entire outer surface of the first member 70 excluding the holding groove 74 becomes a portion of the second member 72. It is joined.

As shown in FIG. 3, the hard disk housing 50 includes four side portions 5002 facing the vertical and horizontal sides of the hard disk case 45, a bottom portion 5004 facing one surface in the thickness direction of the hard disk case 45, and the hard disk case 45. And an opening 56 for opening the other surface in the thickness direction.
Then, the hard disk device 44 with the dampers 54 mounted on the two sides of the hard disk case 45 is moved along the thickness direction of the hard disk case 45 to be accommodated in the hard disk accommodating portion 50, and the opening 56 is the cover 52. Is blocked.
In this state, the main body portion 76 of the second member 72 of the two dampers 54 comes into elastic contact with the two side portions 5002 facing each other among the four side portions 5002 of the hard disk housing portion 50.
Further, the leg portions 78 of the second members 72 of the two dampers 54 are in elastic contact with the remaining two side portions 5002 of the four side portions 5002 of the hard disk housing portion 50 and are held in the holding grooves 74. The remaining hard disk case 45 is in elastic contact with the opposite sides.
In addition, as shown in FIG. 26, in a state where the edge portion 4502 of the hard disk case 45 is held by the holding groove 74, the tips 7402B of the pair of opposing wall portions 7402 are in contact with the side surface 4504 of the hard disk case portion. .
In addition, with the edge 4502 of the hard disk case 45 held by the holding groove 74, the tip 4502A of the edge 4502 is in contact with the bottom wall 7404.
Furthermore, as shown in FIG. 25, the two dampers 54 are sandwiched between the bottom portion 5004 of the hard disk housing 50 and the inner surface of the cover 52 from the thickness direction of the hard disk case 45. In this state, the hard disk device 44 It will be held in the container 50.
Therefore, the clamping part for clamping the damper 54 is constituted by the bottom part 5004 of the hard disk housing part 50 and the inner surface of the cover 52.

In FIG. 24, reference numerals 7410 and 7210 denote one of the opposing wall portions 7402 of the pair of opposing wall portions 7402 and a missing portion formed in the portion of the second member 72 that covers the opposing wall portion 7402. The notch is for inserting a conductive sponge attached to the bottom 5004 of the hard disk housing 50.
In FIG. 24, reference numerals 7412 and 7212 denote the other opposing wall portion 7402 of the pair of opposing wall portions 7402 and a missing portion formed in the portion of the second member 72 that covers the opposing wall portion 7402. This notch is for material reduction.

According to the above-described configuration, as shown in FIG. 25A, the hard disk device 44 is approximately centered in the depth direction of the hard disk housing portion 50 by the damper 54 when no shock or vibration is applied to the case 12. And is held at a substantially central portion in the up-down and front-back directions.
Here, when an impact or vibration in the thickness direction of the hard disk case 45 is applied to the case 12, the hard disk device 44 is displaced in the thickness direction (arrow direction) as shown in FIG. The member 70 is displaced together with the hard disk device 44, and the portion 72A of the second member 72 is deformed following the displacement of the hard disk case 45 in the thickness direction.
At that time, the portion 72A of the second member 72 facing the one outer surface 7402A of the outer surfaces 7402A of the pair of opposing wall portions 7402 is compressed, and at the same time, the portion of the second member 72 facing the other outer surface 7402A. 72A is expanded.
Accordingly, the impact and vibration are reduced by compressing the portion 72A of the second member 72, and at the same time, the impact and vibration are also reduced by extending the portion 72A of the second member 72. Thus, the impact and vibration on the hard disk device 44 can be effectively reduced, and the displacement amount of the hard disk device 44 can be suppressed.
Therefore, the size of the space secured between the hard disk case 45 and the inner surface of the cover 52 and the size of the space secured between the hard disk case 45 and the bottom portion 5004 of the hard disk housing portion 50 can be reduced. This is advantageous in reducing the size of the case 12.
In particular, the hard disk device 44 has a structure in which the magnetic disk and the magnetic head are opposed to each other in the thickness direction of the hard disk case 45 inside the hard disk case 45, so that impact and vibration in the thickness direction of the hard disk case 45 are prevented. Mitigating has become one of the most important problems, and therefore, according to the above-described configuration, it is possible to effectively mitigate shock and vibration in the thickness direction of the hard disk case 45 with a very simple configuration. This is extremely advantageous when the hard disk device 44 is provided.
In the above-described configuration, the damper 54 is formed by two-color molding, and the outer surface 7404B of the bottom wall portion 7404 orthogonal to the outer surface 7404A is also joined to the second member 72. At the time of displacement, the impact and vibration are alleviated by the shearing action of the portion of the second member 72, and the impact and vibration on the hard disk device 44 are effectively mitigated.

Here, a comparative example will be described.
FIG. 27 is an explanatory view of the operation of the damper 54 ′ of the comparative example, and the same or corresponding parts as those in FIG.
As shown in FIG. 27, in the damper 54 ′ of the comparative example, the outer surfaces 7402A of the pair of opposing wall portions 7402 and the portion 72A of the second member 72 are not joined.
Therefore, when the hard disk device 44 is displaced in the thickness direction (arrow direction) and the first member 70 is displaced together with the hard disk device 44, the second facing the one outer surface 7402A of the outer surfaces 7402A of the pair of opposed walls 7402 is second. The portion 72A of the member 72 is compressed, but the portion 72A of the second member 72 facing the other outer surface 7402A is not expanded, and a gap is formed between the outer surface 7402A and the portion 72A.
For this reason, since only the shock and vibration due to the compression of the portion 72A of the second member 72 are mitigated, the impact and vibration mitigation effect on the hard disk device 44 is reduced as compared with the damper 54 having the above-described configuration. And the displacement of the hard disk device 44 increases.
Therefore, the damper 54 configured as described above has a greater effect of mitigating shock and vibration than the comparative example, and is advantageous in suppressing the amount of displacement of the hard disk device 44. Therefore, it is advantageous in reducing the size of the case 12. It is.

Next, the damper 54 shown in FIGS. 28 and 29 will be described.
The damper 54 shown in FIGS. 28 and 29 is configured to suppress the displacement amount of the hard disk device 44 to a smaller value.
FIG. 28 is a perspective view showing the configuration of the damper 54, and FIGS. 29A and 29B are operation explanatory views of the damper 54.
In the following description, parts and members that are the same as or similar to those in FIGS. 24, 25, and 26 are denoted by the same reference numerals.

As shown in FIGS. 28 and 29, a columnar or prismatic convex portion 80 is formed on the outer surface 7402A of the pair of opposing wall portions 7402 in the direction opposite to the surfaces facing each other in the portion 72A of the second member 72. Each is protruding.
A tip surface 8002 of each convex portion 80 is formed as a flat surface parallel to the pair of opposing wall portions 7402.
The portion 72B of the second member 72 is located on the tip surface 8002 of each convex portion 80 and is integrally joined to the tip surface 8002 respectively. Of course, the peripheral surface of each convex portion 80 is also integrally joined to the portion of the second member 72.

According to the damper 54 of FIG. 28 and FIG. 29, as shown in FIG. 29A, the portion 72B of the second member 72 facing the tip end surface 8002 of each convex portion 80 is not provided with the convex portion 80. The thickness is smaller than that of the portion 72A of the second member 72 facing the outer surface 7402A of the opposing wall portion 7402.
Accordingly, an impact or vibration in the thickness direction of the hard disk case 45 is applied to the case 12, and the hard disk device 44 is displaced in the thickness direction (arrow direction) as shown in FIG. When the portion 72A of 72 is deformed following the displacement in the thickness direction of the hard disk case 45, the second member 72 facing the tip end surface 8002 of each convex portion 80, as compared with the damper 54 of FIGS. Since the dimension in the thickness direction of the portion 72B is small, the amount of compression and expansion of the portion 72B is reduced, and therefore the amount of displacement in the thickness direction of the hard disk case 45 is suppressed.
Therefore, in the damper 54 of FIGS. 28 and 29, it is of course advantageous that the impact and vibration on the hard disk device 44 are effectively mitigated, which is more advantageous in suppressing the displacement amount of the hard disk device 44 to a small value. Become.
Therefore, for example, the size of the space secured between the hard disk case 45 and the inner surface of the cover 52 and the size of the space secured between the hard disk case 45 and the bottom portion 5004 of the hard disk housing portion 50 can be reduced. This is more advantageous in reducing the size of the case 12.

Next, the damper 54 shown in FIGS. 30 and 31 will be described.
The damper 54 shown in FIGS. 30 and 31 reliably prevents contact between the hard disk case 45 and the case 12 (cover 52) by limiting the movable range of the hard disk case 45.
FIG. 30 is a perspective view showing the configuration of the damper 54, and FIGS. 31A and 31B are operation explanatory views of the damper 54.

As shown in FIGS. 30 and 31, the second member 72 is not located in a partial region 7402C of the outer surface 7402A of the pair of opposing wall portions 7402, and the region 7402C is exposed in the hard disk housing portion 50. ing.
In each region 7402C of the outer surface 7402A of the pair of opposing wall portions 7402, a columnar or prismatic convex portion 82 is protruded in a direction opposite to the mutually opposing surfaces of the pair of opposing wall portions 7402.
The front end surface 8202 of each convex portion 82 is formed as a flat surface parallel to the pair of opposing wall portions 7402, and the front end surface 8202 of the convex portion 82 facing the hard disk housing portion 50 side of each convex portion 82 is the hard disk housing portion. The front end surface 8202 of the convex portion 82 facing the bottom portion 5004 of the 50 and facing the cover 52 faces the inner surface of the cover 52.

30 and 31, when the impact or vibration in the thickness direction of the hard disk case 45 is applied to the case 12 and the hard disk device 44 is displaced in the thickness direction, the front end surface 8202 of the convex portion 82. Until the front end surface 8202 of the convex portion 82 abuts against the inner surface of the cover 52 until the end portion abuts against the bottom portion 5004 of the hard disk housing portion 50 or the damper 54 in FIGS. The impact and vibration are alleviated by the portion 72A of the second member 72 located on the outer surface 7402A of the 7402 and the outer surface 7404A of the bottom wall portion 7404.
As shown by the arrow in FIG. 31B, when the hard disk device 44 is greatly displaced in the thickness direction, the front end surface 8202 of the convex portion 82 on the hard disk housing portion 50 side is the bottom portion 5004 of the hard disk housing portion 50. The movable range of the hard disk case 45 is limited by the contact, and the central portion of the hard disk case 45 is prevented from colliding with the bottom 5004 of the hard disk housing 50.
When the hard disk device 44 is greatly displaced in the direction opposite to the arrow direction in FIG. 31B, the tip end surface 8202 of the convex portion 82 on the cover 52 side comes into contact with the inner surface of the cover 52, thereby The movable range is limited, and the central portion of the hard disk case 45 is prevented from colliding with the inner surface of the cover 52.
Therefore, in the damper 54 shown in FIGS. 30 and 31, as with the damper 54 shown in FIGS. 24 to 26, it is a matter of course that the impact and vibration on the hard disk device 44 can be effectively reduced. Since the amount of displacement of the device 44 can be suppressed more reliably, the dimension of the space secured between the hard disk case 45 and the inner surface of the cover 52 and the space between the hard disk case 45 and the bottom portion 5004 of the hard disk housing 50 are secured. The size of the space to be reduced can be reduced, which is more advantageous in reducing the size of the case 12.
Further, since the central portion of the hard disk case 45 can be prevented from directly colliding with the bottom 5004 of the hard disk housing 50 or the inner surface of the cover 52, the hard disk device 44 can be prevented from being damaged, and the hard disk device 44 against impact and vibration can be avoided. It is more advantageous in protecting the above.

Next, the damper 54 shown in FIGS. 32 and 33 will be described.
The dampers of FIGS. 32 and 33 are modified examples of FIGS. 30 and 31 and further improve the impact mitigating action applied to the hard disk case 45.
FIG. 32 is a perspective view showing the configuration of the damper 54, and FIGS. 33A and 33B are operation explanatory views of the damper 54.

As shown in FIGS. 32 and 33, the second member 72 is not positioned in a partial region 7402C of the outer surface 7402A of the pair of opposing wall portions 7402, and the region 7402C is exposed in the hard disk housing portion 50. ing.
Convex portions 84 project from the regions 7402C of the outer surface 7402A of the pair of opposing wall portions 7402 in the direction in which the pair of opposing wall portions 7402 face each other and away from the outer surface 7402A, and the tips of the respective convex portions 84 An elastic piece 86 that is elastically deformable in a direction in which the pair of opposed wall portions 7402 face each other is provided.
In this example, the convex portion 84 and the elastic piece 86 are formed integrally with the first member 70.

32 and 33, when the impact or vibration in the thickness direction of the hard disk case 45 is applied to the case 12 and the hard disk device 44 is displaced in the thickness direction, first, the elastic piece 86 is moved to the hard disk. The second portion located on the outer surface 7402A of the opposing wall portion 7402 and the outer surface 7404A of the bottom wall portion 7404 is similar to the damper 54 of FIGS. 24 to 26 until it contacts the bottom portion 5004 of the housing portion 50 or the inner surface of the cover 52. The impact and vibration are alleviated by the portion 72A of the member 72.
Then, when shock or vibration in the thickness direction of the hard disk case 45 is applied to the case 12, and the hard disk device 44 is largely displaced in the thickness direction (arrow direction) as shown in FIG. The elastic piece 86 on the storage unit 50 side contacts the bottom 5004 of the hard disk storage unit 50, and the elastic piece 86 is elastically deformed along the thickness direction of the hard disk case 45. When the elastic deformation of the elastic piece 86 exceeds a predetermined stroke, the elastic piece 86 is overlapped to become a rigid body, is located at the tip of the convex portion 84 and abuts against the bottom portion 5004 of the hard disk housing portion 50. The central portion is prevented from colliding with the bottom portion 5004 of the hard disk housing portion 50.
The same applies when the hard disk device 44 is greatly displaced in the direction opposite to the arrow direction in FIG.
Therefore, the damper 54 shown in FIGS. 32 and 33 can of course achieve the same effect as the damper 54 shown in FIGS. 30 and 31, and the impact and vibration applied to the hard disk case 45 can be reduced by the elastic force of the elastic piece 86. This is more advantageous in improving the impact and vibration mitigating effects on the hard disk device 44.

  The outer surfaces 7402A and 7404A and the second member 72 may be joined with an adhesive. However, if the first member 70 and the second member 72 are formed by two-color molding, such adhesion is achieved. This is advantageous in reducing costs without requiring work.

Next, attachment of the microphone 26 will be described.
34 is an exploded perspective view showing a structure for attaching the microphone 26, FIG. 35 is a perspective view showing a state where the microphone 26 is attached, and FIG. 36 is a cross-sectional view of FIG.
As shown in FIGS. 34 and 36, the microphone 26 is disposed inside the case 12 via a holding member 88, a storage chamber 90, a sound insulation member 92, a holder 94, and the like.
The microphone 26 is configured to include a cylindrical case 96 whose front surface is open, a microphone body incorporated in the case 96, and the like.
The front surface of the macrophone 26 is a sound collecting surface, and the microphone 26 has a rear surface located on the opposite side of the front surface and a peripheral surface (a peripheral surface of the case) that connects the front surface and the rear surface. ing.
In this example, two microphones 26 are provided so that two channels of sound can be picked up.
In FIG. 34, reference numeral 97 denotes a flexible substrate that connects the microphone 26 and the audio signal amplifier 1006 (FIG. 10).

The holding member 88 holds the two microphones 26.
As shown in FIG. 36, the holding member 88 is made of an elastic material such as rubber, and is formed in an elongated plate shape having a thickness and vertical and horizontal dimensions larger than this thickness. Two fitting holes 98 are formed penetrating in the thickness direction at intervals in the direction.
When the microphone 26 is fitted into the fitting hole 98, the microphone 26 is held immovably in the front-rear direction, and the rear surface of the microphone 26 is located substantially on the same plane as the thickness direction of the holding member 88, or In this state, the microphone 26 is held by the holding member 88 with its front and rear surfaces open.

A cylindrical wall 9002 that protrudes in a cylindrical shape from the front wall that forms a part of the front surface 12A of the case 12 to the rear is provided inside the case 12, and the cylindrical wall 9002 has a horizontal width that is larger than the vertical height. It has a cylindrical shape.
A locking wall 9004 protrudes from the inner surface of the cylindrical wall 9002 at the middle portion of the cylindrical wall 9002 in the front-rear direction.
In this example, a locking wall 9006 (see FIG. 34) for partitioning the inside of the cylindrical wall 9002 to the left and right is also provided in the middle portion of the cylindrical wall 9002 in the left-right direction.
The holding member 88 holding the microphone 26 is housed in the housing chamber 90 so that the front surface of the microphone 26 faces the locking wall 9004. In this state, the holding member 88 is held by the locking walls 9004 and 9006 on the rear surface of the microphone 26. Is prevented from moving in the direction toward the front.
The locking wall 9004 protrudes from the inner surface of the cylindrical wall 9002 at a height located outside the front surface of the microphone 26 in a state where the holding member 88 holding the microphone 26 is housed in the housing chamber 90. ing.
That is, the storage chamber 90 is provided inside the case 12 in a state where the movement of the holding member 88 in the direction from the rear surface of the microphone 26 toward the front surface is prevented and the front surface and rear surface of the microphone 26 are opened. A holding member 88 is accommodated.

The sound insulation member 92 blocks transmission of sound and vibration generated inside the case 12 to the microphone 26.
As shown in FIGS. 34 and 36, the sound insulating member 92 is formed in a long and narrow plate shape having a larger contour than the holding member 88 by a material having sound insulating properties and elasticity such as rubber, and is formed on the rear surface of the holding member 88. Be placed. By arranging the holding member 88 in this way, the entire rear surface of the microphone 26 is covered with the sound insulating member 92.

As shown in FIGS. 34 and 36, the holder 94 has a main body portion 9402, a mounting piece 9404, and a locking piece 9406.
The main body portion 9402 of the holder 94 has a bottom wall 9408 that is large enough to cover the rear end of the cylindrical wall 9002 and a peripheral wall 9410 that stands up from the periphery of the bottom wall 9408.
The bottom wall 9408 is formed in an elongated plate shape having a size corresponding to the sound insulating member 92.
The attachment piece 9404 protrudes upward from the front end of the peripheral wall 9410, and the attachment piece 9404 is fitted to the inner wall surface 1202 of the case 12.
The locking piece 9406 protrudes rearward from the lower end of the bottom wall 9408, and the end of the locking piece 9406 is locked in the engagement groove 1204 in the wall portion of the case 12.
35 and 36, the bottom wall 9408 is aligned with the sound insulation member 92, the mounting piece 9404 is aligned with the inner wall surface 1202 of the case 12, and the screw 9412 inserted through the screw insertion hole of the mounting piece 9404 is provided. The sound insulation member 92 is attached to the inside of the case 12 by being screwed into the screw hole of the wall surface 1202 and the engaging piece 9406 is engaged with the inside of the case 12. It is comprised so that it may compress between. In other words, the microphone 26 is supported by the front and outer periphery via the holding member 88 and the rear part via the sound insulating member 92. Therefore, the microphone 26 is floated by the elastic holding member 88 and the sound insulating member 92 having elasticity and sound insulating properties. Will be supported.
In this state, the rear end of the cylindrical wall 9002 is covered with the bottom wall 9408 of the main body portion 9402, and the outer periphery of the cylindrical wall 9002 is covered with the peripheral wall 9410.
Further, when the bottom wall 9408 is aligned with the sound insulating member 92, the mounting piece 9404 is aligned with the inner wall surface 1202 of the case 12, and the locking piece 9406 is engaged with the interior of the case 12, the mounting piece 9404 is moved to the case by the elasticity of the holder 94. It is comprised so that it may be urged | biased by the direction fitted to the wall surface 1202 of 12 inside.

  As shown in FIGS. 34 and 36, a plurality of sound collection openings 1206 penetrating through the wall portion are formed in the wall portion of the case 12 located in front of the front surface of the microphone 26.

According to the above-described configuration, it is needless to say that the sound collection performance by the microphone 26 is ensured. The microphone 26 is held by the holding member 88 and the rear surface of the microphone 26 is covered by the sound insulating member 92. Since it is accommodated in the accommodation chamber 90, unnecessary sound and vibration due to various operations and operations occurring inside the case 12 are reliably prevented from being transmitted to the microphone 26 by the holding member 88 and the sound insulation member 92.
Further, since the microphone 26 is accommodated in the accommodation chamber 90 by elastically contacting the sound insulation member 92 to the rear surface of the microphone 26 held by the holding member 88, the microphone 26 and the holding member 88 are attached, and the sound insulation member 92. It is possible to perform both the mounting and the mounting with one holder 94, which simplifies the structure compared to the conventional structure, reduces the number of parts, and is advantageous in terms of easy assembly and cost reduction.
Further, in this example, the rear end of the cylindrical wall 9002 is covered with the bottom wall 9408 of the main body portion 9402 and the outer periphery of the cylindrical wall 9002 is a peripheral wall 9410 in a state where the microphone 26 is stored in the storage chamber 90. Since it is covered, it is advantageous in enhancing the sound insulation effect against unnecessary sound generated inside the case 12.
Further, when the bottom wall 9408 is aligned with the sound insulating member 92, the mounting piece 9404 is aligned with the inner wall surface 1202 of the case 12, and the locking piece 9406 is engaged with the interior of the case 12, the mounting piece 9404 is moved to the case by the elasticity of the holder 94. Since the holder 94 is biased in a direction to be fitted to the inner wall surface 1202, the holder 94 can be easily temporarily fixed to the case 12, and therefore, the work of fastening the attachment piece 9404 to the case 12 with the screw 9412 can be easily performed. This is advantageous for improving the efficiency of assembly work.

Next, an electronic device system including the imaging device 10 and the cradle 200, which is a main part of the present invention, will be described in detail.
FIG. 37 is an explanatory view showing the mounting operation of the imaging device 10 and the cradle 200, FIG. 38 is a perspective view of the cradle 200, and FIG. 39 is an exploded view showing the inside of the cradle 200.
As shown in FIGS. 37, 38 and 39, the cradle 200 includes a rectangular plate-like lower case 230 and an upper case 232 attached on the lower case 230.
The upper case 232 is formed of an upper surface, a wall portion 232A standing up from the upper surface in a rectangular frame shape, and the upper surface portion surrounded by the wall portion 232A, and has the same rectangular outline as the lower surface 12D of the case 12 of the imaging device 10 Mounting surface 232B and four side surfaces 232C connected to the edge of the upper surface.
A multi-connector 202 is provided substantially at the center of the mounting surface 232B, and a positioning boss 234 is provided in the vicinity of the multi-connector 202.
The lower surface 12D of the case 12 of the imaging device 10 faces the mounting surface 232B of the cradle 200, and the boss 234 is fitted into a positioning hole 1250 (see FIG. 2) provided in the lower surface 12D, thereby allowing the imaging device to Ten multi-connectors 42 are configured to be connected to the multi-connector 202 of the cradle 200.
Then, with the multi-connectors 42 and 202 connected, the lower surface 12D of the case 12 of the imaging device 10 abuts the placement surface 232B, and the front surface 12A, the rear surface 12B of the case 12, and the lower surfaces 12D of the left and right side surfaces 12E and 12F. The image pickup apparatus 10 is configured to be held in a state of being placed on the cradle 200 by causing the close portions to contact the inner surface of the wall portion 232A.

As shown in FIGS. 38 and 39, a data communication connector 210, an A / V connector 212, and an external power supply terminal 214 are provided on one side 232 </ b> C of the upper case 230.
As shown in FIG. 10, the data communication connector 210 is connected to a data communication connector (not shown) of the personal computer 4 via a cable.
The A / V connector 212 connects the video input terminal and the audio input terminal of the television apparatus 6 via an A / V cable.
The external power supply terminal 214 is connected to the external power supply 8.
As shown in FIG. 39, these connectors 210, 212, and 214 are mounted on a printed circuit board 236 that is attached to the upper surface of the lower case 230, and the printed circuit board 236 and a flexible circuit board connected to the printed circuit board 236. It is electrically connected to the multi-connector 202 via 238.
As shown in FIG. 39, the multi-connector 202 is attached to the upper case 230 via an attachment member 240.

As shown in FIG. 38, an operation switch 220 is provided on the upper surface portion of the upper case 230 near the side surface 232C opposite to the side surface 232C where the connectors 210, 212, and 214 are provided.
As shown in FIG. 39, the operation switch 220 is mounted on a printed circuit board 221 provided on the lower case 220 and is connected to the multi-connector 202 via the flexible substrate 239.
That is, as shown in FIG. 10, the operation switch 220 has one end connected to the ground and the other end connected to a terminal of the multiconnector 202. One or more operation switches 220 may be provided.
In the present embodiment, the operation switch 220 is configured as a push button switch, and is in an off state (open state) when not pressed and is turned on (conductive state) when pressed.

Next, the multi-connectors 42 and 202 will be described in detail.
Each of the multi-connectors 42 and 202 has a plurality of terminals.
The multi-connector 42 of the imaging apparatus 10 includes a plurality of data communication terminals (not shown) connected to the USB interface unit 47 and a plurality of A / V signal terminals (not connected) connected to the A / V signal generation unit 1022. A plurality of power supply terminals (not shown) connected to the drive voltage unit 1024, and a signal input terminal 4202 connected to the control unit 1026 (corresponding to the communication control unit in the claims). Yes.
The multi-connector 202 of the cradle 200 corresponds one-to-one to each of the data communication terminals (not shown) provided corresponding to each of the data communication terminals and each of the A / V signal terminals. A / V signal terminals (not shown) provided in correspondence with each other, power supply terminals (not shown) provided in a one-to-one correspondence with the respective power supply terminals, and signal input terminals 4202 The signal output terminal 242 is provided.
The multi-connectors 42 and 202 are connectors that have been used in the past, and some of the connectors that were not previously used in these connectors are used as the signal input terminal 4202 and the signal output terminal 242. is there.
When the imaging apparatus 10 is placed on the cradle 200 and the multi-connectors 42 and 202 are connected, the data communication terminals are connected, the A / V signal terminals are connected, and the power supply terminals are connected. The signal input terminal 4202 and the signal output terminal 242 are connected.
When the multi-connectors 42 and 202 are connected as described above, the video signal and audio signal output from the A / V signal generation unit 1022 are sent to the A / V connector 212 of the cradle 200 via the multi-connectors 42 and 202. It is supplied to the connected external television apparatus 6.
In addition, the power from the external power supply 8 connected to the external power supply terminal 214 of the cradle 200 is supplied to the drive voltage unit 1024 via the multi-connectors 202 and 42, so that the drive voltage unit 1024 uses the supplied power. Supply to each part of the imaging device 10 after adjusting to a predetermined voltage and current, or supply each part of the imaging device 10, or charge the battery 38.
In this embodiment, the multi-connector 42 of the imaging apparatus 10 constitutes an electronic device-side connector as claimed in the claims, and the multi-connector 202 of the cradle 200 constitutes the cradle-side connector as claimed in claims. The connector 210 constitutes an external device connector as claimed.
The A / V signal terminal on the imaging device 10 side constitutes the video signal terminal or the video / audio signal terminal on the imaging device side in the claims, and the A / V signal terminal on the cradle 200 side claims. The video signal terminal or the video / audio signal terminal on the cradle side in the range is configured. Further, the drive voltage supply unit 1024 constitutes a power supply unit as claimed.
Further, the hard disk device 44 of the image pickup apparatus 10, more specifically, the magnetic disk constituting the hard disk device 44 constitutes the recording medium of the claims.

Next, data communication between the imaging device 10 and the personal computer 4 via the cradle 200 will be described.
When the imaging apparatus 10 is placed on the cradle 200 and the multi-connectors 42 and 202 are connected, the data communication terminals are connected, the A / V signal terminals are connected, and the power supply terminals are connected. The signal input terminal 4202 and the signal output terminal 242 are connected.
Here, when the operation switch 220 is not operated and is in an off state, the signal output terminal 242 is in an open state, and the signal input terminal 4202 connected to the control unit 1026 of the imaging device 10 is “H”.
When the signal input terminal 4202 is “H”, the control unit 1026 controls the USB interface unit 47 to control the imaging device 10 (electronic device) and the personal computer 4 (external device) via the USB interface unit 47. No data communication between them.
Next, when the operation switch 220 is operated and turned on, the signal output terminal 242 changes from the open state to the conductive state, and the signal input terminal 4202 connected to the control unit 1026 of the imaging device 10 changes from “H” to “L”. Transition. In other words, an operation signal “L” is supplied to the control unit 1026.
As a result, the control unit 1026 controls the USB interface unit 47, whereby predetermined data by USB between the imaging device 10 (electronic device) and the personal computer 4 (external device) via the USB interface unit 47 is controlled. Execute communication.
In the present embodiment, the predetermined data communication is an operation of transferring image data and audio data recorded in the hard disk device 44 as a recording medium to the personal computer 4, in other words, a data backup operation. .
The personal computer 4 backs up the transferred data to the hard disk device of the personal computer 4.
Alternatively, the personal computer 4 is backed up by writing the transferred data onto an optical disc such as a DVD-R by means of an optical disc device provided therein.
By simply operating the operation switch 220 in this way, the image data and audio data recorded by the imaging device 10 can be easily backed up to the hard disk device or optical disk of the personal computer 4, and the hard disk device 44 of the imaging device 10 can be backed up. This is advantageous because it can cope with data loss due to a failure or the like.

According to the present embodiment, when data communication is performed between the imaging apparatus 10 placed on the cradle 200 and an external device such as the personal computer 4, the operation switch 220 provided on the cradle 200 is operated. An operation signal is directly supplied to the imaging apparatus 10 via the signal output terminal 242 of the cradle side connector and the signal input terminal 4202 of the electronic apparatus side connector without interposing the interface unit, and communication by the imaging apparatus 10 is performed by the operation signal. To do. Therefore, communication between the imaging apparatus 10 and the external device via the cradle 200 can be easily performed by a simple configuration in which the operation switch 202 is provided, and the interface unit needs to be incorporated in the cradle 200 as in the past. Therefore, it is advantageous for downsizing and cost reduction.
In the present embodiment, since some of the terminals of the multi-connectors 42 and 202 are used as the signal input terminal 4202 and the signal output terminal 242, in addition to the multi-connectors 42 and 202, an operation signal is transmitted. There is no need to newly add a connector for transmission, which is advantageous in reducing costs.
In the present embodiment, one end of the operation switch 220 is connected to the ground, and the operation switch 220 is operated so that a signal of the ground potential is directly supplied as an operation signal to the signal output terminal 242 without interposing an interface. Therefore, only the operation switch 220 is required to generate the operation signal, which is more advantageous in simplifying the configuration. Note that the operation signal is not limited to the ground potential, and is arbitrary such as an “H” level or a pulse signal. However, when the ground level is used as the operation signal as in the present embodiment, the circuit configuration is further improved. It will be easy.

In the present embodiment, the case where the data communication method performed between the imaging apparatus 10 and the personal computer 4 is USB (Universal Serial Bus) has been described. However, between the imaging apparatus 10 and the personal computer 4 is described. The method of data communication performed in is arbitrary.
In the present embodiment, the case where the recording medium of the electronic device is configured by the hard disk device 44 has been described. However, the recording medium only needs to hold data in a readable manner. Of course, it may be a semiconductor memory, a memory card, an optical disk, or a magnetic disk.
In this embodiment, the case where the electronic device is an imaging device such as a video camera or a digital still camera has been described. However, the present invention is not limited to the imaging device, and may be a PDA, a mobile phone, a built-in device, or an external device. The present invention can be widely applied to various known electronic devices that perform data communication with external devices such as personal computers, such as a music player using a built-in memory and a music player with a built-in hard disk, via a cradle.

1 is a perspective view of an imaging device 10. FIG. 1 is a perspective view of an imaging device 10. FIG. 1 is an exploded perspective view of an imaging device 10. FIG. 2 is a right side view of the imaging apparatus 10. FIG. 2 is a left side view of the imaging apparatus 10. FIG. 2 is a front view of the imaging apparatus 10. FIG. 2 is a rear view of the imaging apparatus 10. FIG. 2 is a plan view of the imaging apparatus 10. FIG. 2 is a bottom view of the imaging apparatus 10. FIG. 3 is a block diagram illustrating a configuration of a control system of the imaging apparatus 10. FIG. It is AA sectional view taken on the line of the principal part of FIG. It is BB sectional drawing of the principal part of FIG. 2 is a right side view of the imaging apparatus 10. FIG. It is explanatory drawing of mounting | wearing operation | movement of the cover 52 in the AA sectional view of FIG. It is explanatory drawing of mounting | wearing operation | movement of the cover 52 in the AA sectional view of FIG. It is explanatory drawing of mounting | wearing operation | movement of the cover 52 in the AA sectional view of FIG. It is explanatory drawing of mounting | wearing operation | movement of the cover 52 in the BB line cross section of FIG. It is explanatory drawing of mounting | wearing operation | movement of the cover 52 in the BB line cross section of FIG. It is explanatory drawing of mounting | wearing operation | movement of the cover 52 in the BB line cross section of FIG. FIG. 10 is an explanatory diagram of the mounting operation of the cover 52. FIG. 10 is an explanatory diagram of the mounting operation of the cover 52. FIG. 10 is an explanatory diagram of the mounting operation of the cover 52. FIG. 10 is an explanatory diagram of the mounting operation of the cover 52. 4 is a perspective view showing a configuration of a damper 54. FIG. (A), (B) is operation | movement explanatory drawing of the damper 54. FIG. FIG. 4 is an enlarged cross-sectional view showing a configuration around a damper 54 and a hard disk case 45. It is operation | movement explanatory drawing of the damper of a comparative example. 4 is a perspective view showing a configuration of a damper 54. FIG. (A), (B) is operation | movement explanatory drawing of the damper 54. FIG. 4 is a perspective view showing a configuration of a damper 54. FIG. (A), (B) is operation | movement explanatory drawing of the damper 54. FIG. 4 is a perspective view showing a configuration of a damper 54. FIG. (A), (B) is operation | movement explanatory drawing of the damper 54. FIG. 3 is an exploded perspective view showing a mounting structure of a microphone 26. FIG. It is a perspective view which shows the state in which the microphone 26 was attached. It is sectional drawing of FIG. FIG. 10 is an explanatory diagram illustrating a placement operation of the imaging device 10 and the cradle 200. 2 is a perspective view of a cradle 200. FIG. 2 is an exploded view showing the inside of a cradle 200. FIG.

Explanation of symbols

4 ... Personal computer, 10 ... Imaging device, 1026 ... Control unit, 46 ... Electronic device side connector, 4202 ... Signal input terminal, 200 ... Cradle, 202 ... Cradle side connector, 210 ... External device Connector, 220 ... operation switch, 242 ... signal output terminal.

Claims (11)

An electronic device, and a cradle on which the electronic device is placed,
The electronic device includes a communication control unit, an interface unit connected to the communication control unit, and an electronic device side connector,
The cradle is detachably connected to the electronic device side connector when the electronic device is mounted, and is electrically connected to the cradle side connector and detachable to a connector of an external device. And an external device connector connected to
The electronic device side connector and the cradle side connector are connected, and the external device connector is connected to the external device, whereby the electronic device and the external device are connected to the interface unit and the electronic device. An electronic device system configured to perform communication via a side connector, the cradle side connector, and the external communication connector,
The cradle-side connector has a plurality of terminals, and one of the plurality of terminals is configured as a signal output terminal,
The electronic device side connector has a plurality of terminals, and one terminal of the plurality of terminals is directly connected to the communication control unit without the interface unit interposed therebetween, and the electronic device side connector is connected to the electronic device side connector. It is configured as a signal input terminal connected to the signal output terminal when connected to the cradle side connector,
The cradle is provided with an operation switch that is electrically connected to the signal output terminal and supplies an operation signal to the signal output terminal by being operated;
When the operation signal is supplied from the signal output terminal via the signal input terminal, the communication control unit causes communication between the electronic device and the external device via the interface unit. It is configured,
An electronic device system characterized by that.   The electronic device system according to claim 1, wherein the interface unit performs communication by USB. The electronic device includes a recording medium for holding data,
2. The communication performed between the electronic device and the external device via the interface unit includes transfer of data held in the recording medium to the external device. Electronic equipment system. The electronic device is an imaging device;
The imaging optical system, an imaging element that captures a subject image guided by the imaging optical system, and a signal processing unit that records image data generated based on an imaging signal generated by the imaging element on a recording medium Prepared,
The communication performed between the electronic device and the external device via the interface unit includes transfer of the image data recorded on the recording medium to the external device.
The electronic device system according to claim 1. The electronic device is an imaging device;
Generated based on the imaging optical system, an imaging element that captures a subject image guided by the imaging optical system, a microphone that collects sound and generates an audio signal, and an imaging signal generated by the imaging element A signal processing unit that records the image data and audio data generated based on the audio signal on a recording medium,
The communication performed between the electronic device and the external device via the interface unit includes transfer of the image data and the audio data recorded on the recording medium to the external device.
The electronic device system according to claim 1.   The electronic device system according to claim 1, wherein the operation signal is a ground potential signal.   The operation switch has one end connected to the ground potential and the other end connected to the signal output terminal, and is operated to connect the one end and the other end, and the operation switch is operated to operate the ground. The electronic apparatus system according to claim 1, wherein a potential signal is supplied to the signal output terminal as the operation signal. The plurality of terminals of the electronic device-side connector include data communication terminals on the electronic device side for communicating the data,
The plurality of terminals of the cradle side connector include a data communication terminal on the cradle side that is connected to a data communication terminal on the electronic device side when the electronic device side connector is connected to the cradle side connector,
The electronic device system according to claim 1. The electronic device has a power supply unit to which power from the outside is supplied,
The plurality of terminals of the electronic device-side connector include power supply terminals on the electronic device side for supplying power to the power supply unit.
The plurality of terminals of the cradle-side connector include a cradle-side power supply terminal that is connected to the electronic device-side power supply terminal when the electronic device-side connector is connected to the cradle-side connector.
The electronic device system according to claim 1. The electronic device is an imaging device;
The imaging optical system, an imaging element that captures a subject image guided by the imaging optical system, and a signal processing unit that records image data generated based on an imaging signal generated by the imaging element on a recording medium Prepared,
The plurality of terminals of the electronic device side connector include a video signal terminal on the electronic device side for outputting a video signal generated based on the image data, in addition to the signal input terminal,
The plurality of terminals of the cradle side connector include a video signal terminal on the cradle side that is connected to a video signal terminal on the electronic device side when the electronic device side connector is connected to the cradle side connector,
The electronic device system according to claim 1. The electronic device is an imaging device;
Generated based on the imaging optical system, an imaging element that captures a subject image guided by the imaging optical system, a microphone that collects sound and generates an audio signal, and an imaging signal generated by the imaging element A signal processing unit that records the image data and audio data generated based on the audio signal on a recording medium,
The plurality of terminals of the electronic device-side connector include video and audio signal terminals for outputting a video signal generated based on the image data and an audio signal generated based on the audio data,
The plurality of terminals of the cradle-side connector are cradle-side video / audio signal terminals that are connected to the video / audio signal terminals on the electronic device side when the electronic device-side connector is connected to the cradle-side connector. Including,
The electronic device system according to claim 1.

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