KR100246210B1 - Video camera - Google Patents

Abstract

The present invention relates to a small video camera whose main configuration is that a front block assembly comprising an image pickup device and a rear block assembly is located in a casing between the block assemblies in an opposing open end of the tubular outer casing so as to overlap in the longitudinal direction. Disposed in and installed therein, and also included in the electrical circuit via a flexible flat cable element that interconnects the base plates end to end to output video signals and connects to the image pickup device and connector to the rear block assembly. It includes a plurality of long base plate.

Description

Small video camera

1 is a perspective view of a small video camera having a camera mounting bracket shown in dashed lines in accordance with one embodiment of the present invention.

FIG. 2 is an exploded perspective view of various components of the video camera shown in FIG. 1. FIG.

3 is an exploded perspective view of the inner casing and base plate assembly included in the video cameras of FIGS.

4 is a perspective view showing a state in which the inner casing and the base plate assembly of FIG.

FIG. 5 is a longitudinal cross-sectional view of the video camera of FIG. 1 taken in a vertical plane shown by an arrow V-V line. FIG.

6 is a longitudinal cross-sectional view of the video camera of FIG. 1 taken along the horizontal plane indicated by the arrow VI-VI.

FIG. 7 is an exploded view of the elements included in the front block assembly of the video camera shown in FIG.

8 is a cross-sectional view showing a state in which the optical filter is accommodated in the cylinder portion of the front block assembly.

FIG. 9 is a longitudinal sectional view showing that the elements of the front block assembly shown in FIG. 7 and the lens holder or adapter are assembled together. FIG.

10 is a front elevation view of the video camera shown in FIG.

11 is an enlarged perspective view of a buffer member accommodated in a front block assembly of a video camera according to an embodiment of the present invention.

12 and 13 are elevation views of the shock absorbing member of FIG.

FIG. 14 is a perspective view of the video camera mounting bracket of FIG. 1, showing a partial cutaway view for providing an adjustment mechanism inserted into the mounting bracket.

FIG. 14 is a perspective view of the video camera mounting bracket of FIG. 1, showing a partially broken view showing an adjustment mechanism inserted into the mounting bracket.

FIG. 15 is a partial cross-sectional view showing how the adjustment mechanism is used in connection with the video camera of FIG.

16 and 17 are front views of the video camera of FIG. 1 installed in different directions on the mounting bracket of FIG.

18 is an enlarged main view showing how the base plate is fixed to a video camera according to the prior art.

19 is a front view of an upper frame plate according to the prior art.

20 is a sectional view of a compact video camera according to the prior art.

The present invention relates to a video camera, and more particularly, to a miniaturized video camera.

Video cameras are generally classified according to their use, for example, for broadcasting stations, personal or domestic, and industrial.

These personal or home and industrial video cameras are desirable to be as compact as possible to broaden their scope of application.

In a conventional video camera, a front body supporting a solid state imaging element is fixed to an end portion of the main casing, and various electronic elements and components constituting the driving circuit of the solid state imaging element are relatively closely inserted in the main casing, respectively. In conventional video cameras, the base plate is usually fixed by each screw to the main casing or only one base plate is thus fixed to the main casing and alternately to the other base plate to the base plate fixed by a connector or the like. However, the use of advanced screws to secure one or more base plates in the main casing presents a limitation that does not reduce the size to be reduced such as base plates.

In particular, as shown in FIG. 18, each base plate 100 to be fixed to the main casing with a screw is at least a predetermined distance from the edge of the plate 100 crossing each corner at each corner of the base plate. Each through hole 101 dropped to (d) should be formed. The spacing d should have at least a predetermined value to give sufficient strength and also ensure that the head 102 of each screw fitted through the through hole 101 in the corner of the base plate does not extend beyond the corner of the base plate. do. Thus, it can be seen that each screw used to fix the bay plate 100 to each casing occupies the actual upper surface area of each base plate so that electronic components and components cannot be installed. Therefore, if the electronic components and components are actually reduced in size to reduce the overall size of the base plate, the electronic components and components are required to maintain a screw that is fixed equally to the casing relative to the area of the base plate available for installation. The area ratio of the base plate becomes undesirably large.

Furthermore, since the at least one base plate is fixed to the main casing by a screw, the vibration and shock received by the main casing are directly transmitted to the base plate and an electronic component which is known to be relatively weak to vibration and shock. This problem is exacerbated because the solder volume used decreases as the size of the electronic components and components decreases. The less solder used to make the connections, the greater the risk of component damage when subjected to vibration and shock.

In addition, in the existing video camera, the front body supporting the solid state image pickup device has a long circular cross-sectional path for receiving an optical path, and the passage further includes an image frame plate, an optical filter, and A shock absorbing member is included. The upper frame plate 13 ′ shown in FIG. 19 has an overall circular periphery corresponding to the circular cross section of the passage in the front body, and has a rectangular opening or aspect ratio, and has a 3: 4 aspect ratio that is the same as the imaging surface of the solid state image pickup device. A window 13a having a is formed.

The purpose of the plate 13 'is to prevent unnecessary light from entering the image pickup device, to form an image projected on the image pickup device, and to support the optical filter on its front face.

The development of the solid state image pickup device has reached a stage in which the ratio of the area of the image pickup surface to the total area of the front surface of the image pickup device is considerably increased, thereby significantly reducing its size. In view of this, in order to reduce the overall size of the camera, it can be expected that the passage diameter in the front body accommodating the optical path can be reduced to the outer diameter of the solid state image pickup device. In this case, of course, the diameter D1 of the circular outer circumference of the upper frame 13 'should be reduced accordingly. Since the area ratio of the imaging surface to the total area of the circular front surface of the imaging device is large, the rectangular openings or windows 13 'in the frame plate 13' are similarly increased in size, so that the plate 13 is darkened or Make sure you don't cast shadows. This undesirably decreases the diameter d1 of the frame plate 13 'at the corners of the rectangular opening or window 13'a, which weakens this point of the frame plate 13' and causes problems in manufacturing or use. .

In Fig. 20, in the conventional small video camera, the main casing A 'has a rectangular cross section having a cross sectional aspect ratio substantially equal to that of the rectangular image pickup name 16'a of the solid state image pickup device 16'. Able to know. The front block assembly B 'includes a front body 7' which forms a cylindrical passage or space 11 'in which the upper frame plate 13' and the imaging device 16 'are accommodated. The front body 7 'has a rectangular front part 8' corresponding to the cross section of the main casing A ', and the latter has a through hole at the front part of the main casing A' by means of a screw 12 '. It penetrates and extends from the opposite surface and is inserted into and fixed into the tapped hole on the opposite side of the front body portion 8 '. In FIG. 20, the dimension L ' ₁ measured from the center of the cylindrical passage 11' to the side of each rectangular body portion 8 'and the side of the main casing A' is equal to the radius of the passage 11 '. It can be seen that the sum of the depths of the material of the front body 7 'required to accommodate each screw 12'. The dimension L 'extending diagonally from the center of the passage 11' to each corner of the rectangular cross section of the main casing A 'is obviously larger than the measured value L' ₁ extending laterally. Thus, the pipe or other space interior represented by the dashed-line X-line insertable by the conventional video camera shown in FIG. 20 should have a radius not smaller than the dimension L '. In other words, the other space X or the pipe into which the video camera is to be inserted must have a diameter larger than the transverse dimension of the casing A 'indicated by the diameter of the solid state imaging element 16' or otherwise fully accommodate the base block. It shall be connected to the electronic elements necessary to provide a driving circuit for the imaging device. Thus, the cross-sectional shape of the main casing A 'of the conventional small video camera shown in FIG. 20 limits the space required to accommodate the camera to some extent.

Accordingly, an object of the present invention is to provide a compact video camera in which the base plate is supported by the casing so as to withstand the vibrations and shocks received by the casing, and at the same time, the base plate having the electronic parts installed in the casing can be actually reduced. To provide.

Another object of the present invention is to provide a compact video camera which improves heat distribution and dispersion as described above so that heat generating electronic components can be safely and closely arranged on the base plate in the casing.

It is still another object of the present invention to have a solid-state image pickup device having an image pickup surface having a large surface area of an image pickup device, and that the cylindrical frame or the optical path is larger than that required by the solid-state image pickup device in which an image frame plate in front of the image pickup device is housed therein. Without increasing the diameter, it is to provide a small video camera having a window large enough not to erase or darken the image pickup surface.

Another object of the present invention is to provide a small video camera which is arranged so that the cross-sectional shape of the main casing, the attachment method to the front thereof, and the rear block assembly of the camera are made of the minimum space required to accommodate the camera as described above. To provide.

In one embodiment of the present invention, a small video camera comprises: a tubular outer casing having an opening at its opposite end and having a transverse cross-sectional shape symmetrical about its center; A front block assembly comprising an imaging device fixed in the opening at one end of the casing; A rear block assembly fixed in the opening at opposite ends of the casing, including a connector for outputting a video signal; And a plurality of elongated bay plates disposed to be folded in the outer casing in a folded state and having a plurality of elongated electronic elements installed therein, wherein the base plates are connected to each other in the same manner. For example, the ends of the base plate are connected to each other by a flexible flat cable which is connected to the base plate to form a circuit, and is connected to the image pickup device at one end of the base plate, and outputs a video signal at the other end of the base plate. It is connected to the connector included in the rear block assembly.

Another feature of the present invention further includes an inner casing which accommodates the base plate and is slidable into an outer casing axially through one of the openings of the base plate, the inner casing comprising a plurality of rigs encountered here. And in and out of the inner casing, which are respectively elastically pressed against the electronic element on the base plate and against the inner surface of the outer casing, to cushion the electronic elements against vibrations and shocks received by the outer casing.

A feature of the present invention is that the heat dissipation from the electronic elements installed on the base plate by forming the inner and outer casings of the thermally conductive metal is applied to the conduction by the lugs of the inner casing which elastically presses against the inner surface and the electronic element of the outer casing. The heat dissipation is further enhanced by the reflux by air circulation between the electronic element and the inner casing and between the inner and outer casing and the final radiation from the outer casing.

Another feature of the invention described above is a small video having a thermally conductive material of an elastomer, eg, silicone rubber, which is placed horizontally between base plates to equalize the temperature along the base plate assembly so as to be contacted by electronic elements. To provide a camera.

Another feature of the present invention is the installation of an outer casing having an almost octagonal cross section with four relatively long sides arranged with four relatively short side members, such that the outer casing has the same panel at its top and bottom with its side Is installed at the front and rear block assemblies with their respective installations with cross sections corresponding to the inner section of the outer casing, and at the inclined corners to minimize the space required to accommodate the video camera. By screwing through and extending into each of the mounting portions, the ends of the outer casing are hermetically fitted therein so as to be fixed to the mounting portions of the front and rear block assemblies.

Another feature of the present invention is that the front block assembly of the video camera extends axially away from each mounting portion toward the outer casing and extends along four cylindrical axes along the cylindrical portion at each spaced position corresponding to the coarse slope edge. A cylindrical portion having a groove, an upper frame plate, an optical filter, and an image pickup device continuously installed in the cylindrical portion, wherein the upper frame plate includes: an upper frame plate having a circular outer circumference that is standard to be fitted into the cylindrical portion; And a rectangular window having an aspect ratio corresponding to a rectangular image pickup surface of the image pickup device, and the upper frame plate also has an outward protrusion extending from its outer periphery at the corner of the rectangular window to extend into the groove of the cylindrical portion, Image pick-up of the image pickup device without excessively affecting the strength of the upper frame plate at his window corner In can be minimized.

Another feature of the present invention is that the optical filter is rectangular and is fixed in the groove of the cylindrical portion of the front block assembly for pivoting with the upper frame plate and the imaging element at its corners.

Further features and advantages of the above and the above are described in detail below according to a preferred embodiment of the accompanying drawings in which like reference numerals refer to like parts.

1 and 2, the video camera according to one embodiment of the present invention, the front block assembly is generally installed in the main front or outer casing (A), the open front end of the casing (A). (B), a base plate assembly (C) (FIG. 4) located in the casing (A) between the rear block assembly (D) and the front block assembly (B) installed at the open end of the casing (A); It can be seen that.

The outer or main casing A is preferably formed of a metal having excellent thermal conductivity, and is formed into a thin tubular shape having an octagonal or octagonal cross section. The octagonal section of the casing A has four relatively long side members spaced into four relatively short side members, the outer casing having the same relatively wide panel or face 1 at the top and bottom, and adjacent to the side of the casing. It has an edge or inclined surface 2 inclined at 45 ° to the panel or face 1. The four panels 1 form elongate grooves 3 which increase their surface area to promote heat radiation to the outside in the outer casing A. In addition, the front part of each panel 1 forms a socket 4 used to position the video camera as described later. The panel 1 on the four sides or the panel 1, in particular, the casing A side portion facing the finder in FIGS. 1 and 2, forms a hole 5 in the upper portion thereof, through which the base to be described later. It is possible to controlably communicate with the electronic element included in the plate assembly (C). The front end of the four inclined corners 2 of the casing A has respective holes 6 extending therethrough, and the inclined corners 2 (second) in which the same through holes 6 are located at two diagonals. It is installed in the rear end of Fig.).

As shown in Figs. 2 and 7, the front block assembly B has an octagonal front portion 8 having its outer circumferential surface coinciding with the octagonal outer cross section of the casing A, and the same octagonal angle. The front part 8 can be inserted into the front end portion of the casing A, which is shaped but includes the front block body 7 subsequent to the installation position 9 or the entire position corresponding to the inner end surface of the casing A. ) To be in the same plane.

The cylindrical portion 10 extends rearwardly and integrally from the installation portion 9, and passes through the front block body 7 along the front portion 8 and the installation portion 9. Form a to provide an optical path to the camera. The front surface 8 of the main body portion is provided with a lens mounting auxiliary surface or surface 8a. The inclined corner of the outer circumferential surface of the mounting portion 9 is formed with a screw hole 9a positioned therein so that the mounting hole 9a of the front block body 7 enters the front end of the outer casing A. The front block body 7 is fixed to the main or outer casing A (first, fifth and six degrees) by fitting the screw 12 in line with the through hole 6 at the front end of the inclined corner 2. .

In particular, as shown in FIG. 7, the cylindrical portion 10 of the front block body 7 is located near the front of the slender portion 10 at a position spaced at an angle corresponding to the inclined edge of the mounting portion 9. It has four axial extension grooves or long incisions 10a extending over the length. The outer surface of the cylindrical portion 10 has a reduced diameter in the rear end surface cut out to the outside as in the 10b portion. The installation tab 10C protrudes rearward in the axial direction from the free end of the cylindrical portion 10. The front block body 7 is formed up to an internal thread 10d formed in the front portion of the cylindrical passage 11.

The front block assembly B is inserted in the same axis in sequence into the upper frame plate 13, the optical filter 14, the buffer member 15, and the passage 11 through the open rear end of the cylindrical portion 10. And a solid state imaging device 16. As will be described in detail below, the support member 17 is located at the rear end of the cylindrical portion 10 at the rear of the imaging device 16, so that the adjustment ring member 18 is screwed into the screw 10b so that the front block assembly B The various elements of the above) are kept in an assembled state.

As shown in FIG. 7, the upper frame plate 13 has a substantially annular outer circumference having a diameter D substantially the same as the inner diameter of the cylindrical portion 10, and a rectangular imaging surface 16a of the solid state imaging element 16. As shown in FIG. Has a rectangular window 13a having an aspect ratio equal to that of (). The upper frame plate 13 has an outward protrusion 13b extending from its outer periphery at a position corresponding to the four corners of the rectangular window 13a, which is cylindrical when the upper frame plate 13 is inserted. Into the groove or incision 10a. Thus, the projection 13b causes the upper frame plate 13 to be rotated in the cylindrical portion 10. Of particular importance, when the rectangular imaging surface 16a has an area making up most of the entire front area of the imaging device 16, the upper frame plate 13 erases or darkens the shadow on the imaging surface 16a of the imaging device 16. Even if the window 13a is made large enough so that the projection 13b ensures that the frame plate material is always at an appropriate thickness d at the edge of the window 13a to the upper frame plate 13. Because the projection 13b is accommodated in the groove or cutout 10a of the cylindrical portion 10, such a projection 13b has a cross-sectional size of the installation portion 9 and the cylindrical portion 10 or the outer casing A. This is because no increase is required.

The optical filter 14 has a rectangular shape and covers a plurality of filter elements 14a, for example, a plurality of filter elements composed of a low-pass filter infer red cutoff filter or the like. . The optical filter 14 has a diagonal length L2 than the inner diameter D3 of the cylindrical portion 10, so that the four corner portions of the filter 14 also have grooves or cutouts 10a of the cylindrical portion 10. The optical filter 14 is rotated with respect to the front block 7 by protruding inward. As shown in FIG. 7, the housing of the solid state image pickup device 16 is formed in a circular outer circumference having a flat surface portion or surface 16b extending in parallel with the upper, lower and side portions of the rectangular image pickup surface 16a.

As particularly shown in Figs. 11, 12 and 1, the shock absorbing member 15 is formed in a ring shape as a whole and has an outer diameter smaller than the inner diameter D3 (Figs. 8 and 9) of the cylindrical portion 10. And an annular rim 15a having D2). The projection 15b facing in the same axial direction extends from the rim portion 15a to the outside at four positions spaced from each other by 90 ° with respect to the rim portion 15a to engage the inner surface of the cylindrical portion 10. The shock absorbing member 15 further includes an annular flange 15c directed radially inwardly from the rim 15a about halfway between the front and rear edges of the rim 15a. The annular ridge 15d facing forward extends on the inner circumference 15e of the flange 15c. The rim portion 15a is formed by forming the front of the flange 15c therein at a position between the protrusions 15b so that the edge of the optical filter 14 is accommodated when the shock absorbing member 15 is forced forward. The cutout 15f is supported against the rear surface of the optical filter 14 by the ridge 15d on the flange 15c. The support portion 15'a of the rim portion 15a in front of the flange 15c allows the upper and lower portions to be coupled to each other and is received on the opposite side of the optical filter 14, thereby buffering the optical filter and simultaneously storing the optical filter in the cylinder portion 10. Yieldably located within.

As described above, the housing of the imaging device 16 has a generally circular outer circumference having a flat portion or surface 16b parallel to the top and bottom and sides of the rectangular imaging surface 16a. Similarly to the foregoing, the rim portion 15a of the shock absorbing member 15 has an inner surface constituting a flat portion 15g, which is spaced apart from the rear of the flange 15c, so that the flat portion or surface 16b of the housing of the imaging device 16 is located. ). Further, the projection 15h facing the same axis extends from the inner surface of the rim 15a to the inwardly spaced position between the flat portions 15g at the rear of the flange 15c, so that the overall projection of the housing of the imaging device 16 Join the circular outer periphery. (Figures 11 and 12)

As particularly shown in Figs. 7 and 9, the supporting member 17 is formed in the form of a rough disc, and has an outer diameter that is substantially equal to the outer diameter of the cylindrical portion 10 at the rear end. The circular guide ring portion 17a extends forward from the front of the support member 17 and is spaced inward from the outer circumference of the support member so that the circular guide ring portion 17a can be inserted into the cylindrical portion 10 at the open rear portion. The front surface of the support member 17 is composed of a rear portion located in the circular guide ring portion 17a to engage with the rear portion of the image pickup device 1. The outer circumference of the support member 17 in the upper portion forms a groove 17b of a predetermined size extending in the axial direction, and accommodates the installation tab 10c extending from the rear edge of the cylindrical portion 10, whereby the front block body 7 The rotation of the support member 17 with respect to the cylindrical portion 10 of the c) is restricted.

The adjusting ring member 18 has an internal screw 18a that is screwable to the screw 10b at the rear end of the cylindrical portion 10. The radially inwardly directed flange 18b extends from the rear edge of the adjustment ring member 18 to be engageable forward with respect to the back surface of the support member 17 near the outer circumference.

2 and 3, the base plate assembly C as a whole is provided with the inner casing 20 and several electronic elements 23 installed in the longitudinally folded state and positioned in the inner casing 20. As shown in FIG. It includes a plurality of long base plate 21 having a. The three base plates belonging to the embodiment of the present invention are shown in Fig. 3 as 21A, 21B, and 21C, respectively, and their ends are connected. By way of example, two flexible webs or flexible flat cable 22 means of different lengths are connected so that the base plates are interconnected in a zigzag fashion as shown in FIG. In addition to connecting each base plate 21, the flexible flat cable 22 serves to electrically connect various electronic components 23 provided on both sides of each base plate. An electrical circuit is provided for driving and producing a video signal from its output. The flexible flat cable 22A extends at the free end of the base plate 21A (FIG. 6), giving a proper connection to the image pickup device 16, while the same flexible flat cable 22C is used for the base plate 21C. It extends from the free end of) and is included in the rear block assembly (D) is connected to a connector 33 to be described later to output a video signal.

Preferably in the present invention, the base plate assembly (C) is a silicone rubber placed between the overlapping base plates, that is, between the base plates 21A and 21B and the base plates 21B and 21C in FIGS. 3 and 6. Further comprising a plate-shaped member 34 made of an elastomeric thermal conductive material such as, the heat to damage the electronic elements by contacting the base plate by the electronic element 23 to be the same temperature along the base plate assembly (C) Prevents the occurrence of spots;

The inner casing 20 is preferably formed of a metal material having excellent elasticity and conductivity with high thermal conductivity. In the above-described embodiment, the inner casing 20 has a lower plate-shaped casing member having an upper casing member 20a having a roughly "U" -shaped cross section and an upward flange 20c extending longitudinally along its opposite side edge ( 20b) is coupled to the side wall lower edge portion 20d of the upper casing member 20a. The upper and lower casing members 20a and 20b respectively form a plurality of slits 24 laterally spaced at their front ends, and the adjacent edges 21a of the base plate 21 are shown in particular in FIG. As described above, each end of the base plate is horizontally positioned with respect to the inner casing 20 by being received by the slit 24.

As particularly shown in FIG. 6, the flexible flat cable elements 22 connecting the base plates 21A and 21B to the ends end each form a gentle bend when the base plates are in an overlapping state. In order to position the overlapping base plates 21A and 21B laterally at their rear ends, the upper wall of the upper casing member 20a has a screw hole 25 (FIG. 4) therein, and at its rear portion. The lower casing member 20b also has a lug 24b extending in its rear portion with a screw hole formed therein as well. (FIG. 5) The screw holes of the lugs 24a and 24b are screwed to the screw holes of the lugs 24a and 24b when engaging the slit 24 where the edge 21a at the front end of the base plate is located. 26a and 26b are installed so as to be extended to a gentle curved portion formed by the flexible flat cable 22 connecting the base plates 21A and 21B and positioned at the latter.

The slits 24 and the screws 26a and 26b allow the base plates 21A, 21B and 21C to be spaced in the inner casing 20 at predetermined intervals.

The rear end of the upper and lower casings 20a and 20b is urged inward with elastic protruding lugs 27a and 27b, respectively, and is provided on the rear end of the base plate 21C longer than the other base plates 21A and 21B. By elastically pressing against 23a, the rear side of the flexible flat cable 22 connects the rear end of the base plates 21A and 21B (FIG. 6) to the base plate folded in a zigzag form. Is located. The lugs 27a and 27b which collide with the inner casing 20 and couple to the upper and lower sides of the electronic element 23a are effective for inducing heat release in the latter. The electronic element 23a is one of a kind that generates a substantial amount of heat during its operation.

The other elastic protrusion lugs 27c and 27d are also inwardly contacted in the opposite side walls of the inner casing (FIG. 6) and burned against the electronic elements 23 provided on the outward facing surfaces of the base plates 21C and 21A, respectively. Pressing sexually In other words, the elastic pressure coupling of the lugs 27c and 27d with respect to the electronic elements 23 on the base plates 21C and 21A respectively serves to release heat from the electronic elements.

In addition, the upper and side portions of the upper casing member 20a and the lower casing member 20b have respective elastic lugs 28 contacting outwards, and when located in the outer casing A of the inner casing 20, outwardly The contact lugs 28 are elastically pressed against the inner surface of the outer casing A in the latter four panels 1. Thus, the base plate assembly (C) is elastically supported in the outer casing (A) with a gap between the latter and the inner casing (20), thereby improving heat dissipation by providing air circulation within the gap, and also the outer casing ( A) buffers the electronic element 23 against the vibration or shock received.

As shown in FIGS. 2, 5, and 6, the rear block assembly (D) has a block structure having a rear end plate (29a) formed in an octagonal outer circumferential shape corresponding to the inner end surface of the outer casing (A) at the rear end. (29). The forward facing tab 29b extends in each of the two diagonally opposite edges of the plate 29a. Each tab 29b has a screw hole 30 therein. Thus, when the plate 29a is inserted into the rear end of the outer casing A, the holes 6 formed in the rear end of the two diagonally inclined edges 2 of the outer casing A are screw holes 30. The rear end plate 29a is fixed to the rear end of the outer casing A by fitting the screw 31 in correspondence with the.

The side piece 29c extends forward at one side of the rear end plate 29a, and at its front end, the lower supporting lugs 32a, 32b (second, 5, and 6 degrees) are respectively lugs 24a, 24b. Extend across the upper and lower edges of the side piece 29c. The support lugs 32a and 32b have threaded holes in the lugs 24a and 24b, respectively, so that when the screws 26a and 26b are fitted, the rear block assembly D becomes the base plate assembly C. To be connected to. The rear block assembly D is completed by a board 29d extending laterally from the side plate 29c in front of the end plate 29a and also having electronic elements installed therein, for example, the flexible flat cable 22c. ) And an output circuit connected to the connector 33 installed on the end plate 29a.

To assemble the elements of the front block assembly B described above, a lens holder or adapter 34 is installed at the front end of the front body 7 (FIG. 9). In particular, the lens holder 34 is screwed into the front end of the passage 11 by screwing until the radial surface 34a of the lens holder 34 is in contact with the lens mounting auxiliary surface or surface 8a. It is intended to have a diameter-mounted portion 35 for reducing the external or photographic coupling with the internal screw 10d. The upper frame plate 13, the optical filter 14, the buffer member 15, the solid state image pickup device 16, and the support member 17 are sequentially inserted through the open rear end of the cylindrical portion 10 in a prescribed order. Finally, when the adjusting ring member 18 is screwed into the screw 10b and its flange 18b and moved axially toward the lens holder 34, the mounting portion 35 of the lens holder is adjacent to the outer circumference. The frame plate 13, the filter 14, the buffer member 15, the solid state image pickup device 16, in the axial direction together with the frame plate 13 supported against the end surface 35a of the end face and playing with the front surface thereof. The support member 17 is in contact. Next, an optical distance measuring device is used to measure the distance l ₁ from the lens mounting auxiliary surface 8a to the imaging surface 16a of the solid state imaging element 16 (FIG. 9). If the distance l ₁ is larger than the predetermined design value, the adjusting ring member 18 further pivots and moves its axis forward of the cylindrical portion 10, as a result of which the support member 17 and the imaging device 16 are rotated. ) Is displaced coaxially in that direction to press the annular ridge 15d on the flange 15c. Thus, the distance l ₁ is reduced. On the other hand, if the distance (l ₁ ) is smaller than the desired value, the annular ridge (15d) is elongated by turning the adjusting ring member (18) in the direction of giving axial movement to the rear of the cylindrical portion (10). The image pickup device 16 is moved backward. That is, it moves in the direction which increases the distance ( ₁ ) value. When a predetermined desired distance l ₁ value is obtained, a predetermined adhesive is added to fix the pivot about the cylindrical portion 10 of the adjusting ring member 18.

In assembling the base plate assembly C, the three base plates 21A, 21B, and 21C are bent in a zigzag manner, and the edges 21a of the base plate are placed on the slits 24 of the upper and lower casing members 20a and 20b. ) And cover with upper and lower casing members 20a and 20b. Then, the screw holes in the support lugs 32a and 32b formed in the rear block structure 29 coincide with the through holes 25 formed in the lugs 24a and 24b, so that the screws 26a and 26b are fastened respectively to the base. The plate assembly C and the rear block assembly D are integrally connected.

Finally, the video camera assembly axially inserts the base plate assembly (C) connected to the rear block assembly (D) into the outer casing (A) through an opening in the rear thereof, and then the latter after the outer casing (A). The assembly of the video camera is achieved by fastening the screws 31 into the respective screw holes 30 when they coincide with the through holes 6 at the ends. The elastic lug 28 extending rearward of the inner casing 20 during the axial insertion of the base plate assembly C into the outer casing A is continuously elastically deformed inward so that the base plate assembly C is the elastic lug. (28) is elastically held in the center position in the casing (A). As a result, the front block assembly B is coaxially inserted into the outer casing A through its open front part, and the screw 12 has a screw hole 9a of the inclined corner 2 of the outer casing A. When the front end coincides with the through hole 6, it enters into the screw hole 9a in the mounting portion 9 of the front block 7. As described above, in the assembled video camera embodying the present invention, when vibrations or shocks are applied to the outer casing A, these vibrations or shocks are caused by the elastic lugs 28 extending from the inner casing 20. It is buffered and is not transmitted to the base plates 21A to 21C in the inner casing 20. In addition, since the base plates 21A to 21C are positioned by their edge couplings within the slits 24 of the inner casing 20, even if vibration or shock is applied to the outer casing A, the base plates are not relatively displaced. .

Vibration and shocks applied externally to the video camera are isolated from the components installed on the electronic components and the base plates 21A to 21C, thereby reducing the strength of the electronic components and reducing the impact. The size of electronic components can be reduced without worrying that the failure rate due to vibration and shock is increased. In particular, by joining the edge 21A of the base plate in the slit 24 of the upper and lower casing members 20a and 20b, by positioning the base plates 21A through 21C in the inner casing 20, No other attachment elements are necessary, thereby increasing the area ratio of each base plate used to install the electronic elements relative to the total area of the base plate. Thus, the size of the base plate can be reduced, thereby reducing the overall size of the video camera.

Inevitably determined by the diameter of the image pickup element, the specific diameter D3 of the passage 11 required for the front block 7 for the optical optical path affecting the solid state image pickup device 16 (FIGS. 9 and 10). Given this, as can be seen from the comparison between FIG. 10 and FIG. 20, the octagonal cross-sectional form of the mounting portion 9 of the front block 7 and the outer casing A in the video camera according to the embodiment of the present invention is a camera. It is possible to significantly reduce the size and required space thereof. In particular, as shown in FIG. 10, the installation portion 9 and the outer casing A of the front block 7 having the above-described octagonal cross section are provided so that the inclined edge of the outer casing A is screwed ( By accepting 12), the casing A is fixed to the front block 7. In such inclined corners, the thickness of the installation portion 9 outside the passage 11 is substantially larger than the thickness of the installation portion 9 on the side opposite to the diameter of the passage 11. Thus, in FIG. 10, the distance L measured radially outward from the center 0 to the outer surface of each corner, i.e., the distance forming the radius of the distance X1 necessary to accommodate the video camera according to the embodiment of the present invention, In the prior art shown in FIG. 20 from the center 0, it is almost equal to the lateral dimension L ' ₁ measured from a distance to the outer side of the camera. The diagonal distance L in the video camera according to the embodiment of the present invention shown in FIG. 10 is considerably smaller than the diagonal distance L 'shown in FIG. 20, in which case it is necessary to accommodate the conventional video camera. The radius of space X is formed.

Therefore, the cross-sectional shape given to the outer casing A of the video camera according to the present invention, which allows the outer casing to be fixed to the front block 7 at an inclined corner in which the outer casing is positioned diagonally, can make the size of the video camera smaller. do.

In addition, as described above, the projection 13b extending from the outer circumference of the frame plate 13 to the corner of the rectangular window 13a and received in the groove 10a of the cylindrical portion 10 of the front body 7 is provided. By installing, the size of the above-described window 13a can be increased, so that the frame plate is not necessary at the corner of the enlarged window 13a without increasing the diameter D3 of the passage 11 extending through the front block 7. It is possible to prevent darkening of the imaging surface 16a of the solid-state imaging device 16 without undesirably weakening (13).

The octagonal cross section of the outer casing A is symmetrically around the center (0) and installs the mounting bracket 36 so that the video camera is mounted on the mounting bracket 36 as shown in FIGS. 16 and 17, respectively. To be supported in one of two different rotations. In particular, the above-described mounting bracket 36 extends at one side of the base portion 37 and ends at the top, and extends in the same direction as the base portion 37 at the latter at the axial extension portion 39 and at the vertical portion 38. And a base portion 37 having a vertical portion 38 perpendicular to). The mounting bracket 36 also includes a clamping member having right angle arms 40 and 41 and a flange 42 extending in the opposite direction of the arm 40 at the end of the arm 41 away from the arm 40. Since the lower portion of the vertical portion 38 and the flange 42 have threaded holes 44 to coincide with the respective holes 43 and 44, the insertion of the screw 45 into the aligned holes 43 and 44 results in a flange 42. ) Can be releasably fixed to the vertical portion 38 as shown in FIGS. 16 and 17.

When a part of the mounting bracket 30 is fixed together as described above, the upper portions of the arms 40 and 41 and the vertical portion 38 of the clamping member, and the axial extension 39 thereof, are shown in FIGS. As shown in FIG. 17, respectively, an outer casing having four relatively wide sides or panels 1 thereof joined by arms 40 and 41, a vertical portion 38, and an axial extension 39; Surround (A) is a rectangular space designed to accommodate dimensions. In particular, as shown in FIG. 14, the mounting pin 46 extends upwardly from the arm 41 of the mounting bracket 36 and is formed on the surface of the outer casing a or on the socket 1. It is receivable in, and engages the arm 41 of the mounting bracket so that the camera prevents sliding in the axial direction with respect to the mounting bracket. The video camera according to the embodiment of the present invention is arranged in a different turn in the mounting bracket because of the symmetrical installation of the outer casing A section around the center (0) and the rectangular shape of the space formed in the mounting bracket 36. By way of example, they are arranged horizontally as shown in FIG. 17 or with a relatively long axis of their rectangular imaging surface 16a extending vertically as shown in FIG. In each case, the socket 4 facing the face or panel 1 of the outer casing A and downward from the arm 41 is suitably engaged on the arm 41 by means of an installation pin 46.

In order to fix the mounting bracket 36 in some position where a video camera is to be used, the base portion 37 extends therethrough and tapped holes 48 to accommodate the anchor screw 49. Form a boss 47 located in the center with. As shown in FIG. 14, the base portion 37 has a long hole 50 on the opposite surface of the boss 47, and accommodates another fixing member (not shown).

As shown in particular in FIG. 3, of the electronic elements or parts installed in the base plate 21C, electronic elements 23B each having a rotatable adjusting member having a slot head are installed in the assembled video camera, The passage to the rotatable adjustment member passes through the passage opening 5 in the outer casing A, and the opening 51 in the inner casing C side portion coinciding with the passage opening 5 (FIGS. 3 and 4). Go through). When adjusting one of the elements 23b, it is very important that the screwdriver or other similar tool used here does not exert excessive axial pressure on the element 23b. Because the element is small, it can be damaged by such axial pressure. Therefore, in this invention, the special mechanism 52 (FIG. 15) of a special purpose is used. As shown, the special mechanism 52 is formed of a continuous length of rigid wire bent to include two parallelly spaced connected straight sections 53, 54, and a bend to make a handle at one end. At the end of the straight portion 54 away from the bend 55, forming a 55 and having a feather-shaped end portion 56 extending longitudinally from the end of the straight portion 53 away from the bend 55; The distance d2 extending beyond the horizontal piece 57 extending in the axial direction and crossing the other straight portion 53 extends through the holes 5 and 51 on the outer surface of the casing A. Determine the distance you can stretch inward. Thus the axial pressing force exerted by the mechanism 52 on the adjustable element 23b is limited by the engagement of the transverse piece 57 with the outer surface of the casing A.

In order to prevent grooves from occurring on the outer surface of the casing A when the mechanism 52 is rotated, a plastic sleeve 58 is installed on the transverse piece 57.

In order to ensure that the special mechanism 52 is always available to effectively adjust the video camera, the distance between the spaced apart linear portions 53 and 54 of the mechanism 52 is different from other straight lines as shown in FIG. While the portion 54 is elastically in contact with the boss 47 on the base portion 37, the instrument is held together with one of its straight portions 53 which is seated within an angle between the flange 42 and the arm 41. Select to retain elastically. By simply pushing manually towards each other end of the straight portions 53, 54 away from the bend 55, the mechanism 52 is easily released in the fitted position shown in FIG.

As described above with reference to the accompanying drawings as a preferred embodiment of the present invention, the present invention is not limited to these specific embodiments, but various modifications can be made without departing from the spirit of the invention described in the appended claims.

Claims (30)

A video camera, comprising: a tubular outer casing having a transverse cross-sectional shape symmetric about its center and an opening at its opposite end; Front and rear block assemblies respectively fixed in the openings at opposite ends of the casing; An imaging device included in the front block assembly; Connector means included in the rearblock assembly for outputting a video signal; And a plurality of elongated base plates located in the outer casing between the front and rear block assemblies and having electronic elements installed thereon, the plurality of elongated base plates being installed in a longitudinally overlapping state, and connecting the ends of the base plate to each other. And a base plate assembly having means for connecting a circuit, and means for connecting the circuit to the image pickup device at one end of the base plate and to the connector means at the other end of the base plate. camera. The small video camera according to claim 1, wherein at least three base plates of the plurality of base plates are provided in a zigzag form. The small video camera of claim 2, wherein at least one of the base plates has a greater length than the other of the base plates. The miniature video camera of claim 1, wherein the means for connecting the base plate between the ends is a flexible flat cable element. The tubular outer casing is made of a thermally conductive material; The base plate assembly includes an inner casing for receiving the base plate, the inner casing being axially slid into the outer casing through one of the latter openings, the inner casing being made of a thermally conductive material and in contact therewith. Each of the inner and outer lugs facing inward and outward in the inner casing, the inner and outward lugs elastically pressing against each of the electronic elements on the base plate and against the inner surface of the outer casing, respectively, A small video camera which improves heat dissipation from the electronic element to the atmosphere by allowing air circulation between the elements and the inner casing and between the inner and outer casings. 6. The inner casing according to claim 5, wherein the inner casing has a plurality of slits axially spaced adjacent to at least one end of the inner casing, and an edge of the base plate is accommodated in the slit so that Small video camera located across each end of the baseplate. 6. The base plate assembly of claim 5, wherein the base plate assembly includes a plate-shaped member made of an elastomeric thermally conductive material placed between the base plates so as to be brought into contact with the electronic elements to uniform the temperature along the base plate assembly. Small video camera. 8. The compact video camera of claim 7, wherein the plate member is made of silicone rubber. The base plate assembly of claim 1, further comprising a plate-shaped member made of an elastomeric thermally conductive material interposed between the base plates, wherein the base plate assembly is brought into contact with the electronic elements so that the temperature is uniform along the base plate assembly. Decommissioned compact video camera. 10. The compact video camera of claim 9, wherein the elastomeric thermally conductive material is silicone rubber. 2. The base plate assembly of claim 1, wherein the base plate assembly includes an inner casing to receive the base plate, axially slidable into the outer casing through one of the latter openings, the inner casing being on the base plate. And a plurality of lugs each facing inward and outward from the inner casing to elastically press against the electronic elements of the outer casing and the inner surface of the outer casing, so that the electronic elements are buffered against the impact the outer casing receives. One compact video camera. 12. The inner casing of claim 11, wherein the inner casing has a plurality of slits spaced apart in the axial direction at an end of the inner casing adjacent to the front block assembly, and adjacent edges of the base plate are disposed by the slits. Is received so as to cross each end of the base plate with respect to; The means for connecting the base plates end to end includes flexible flat cable elements that form respective bends when the base plate is in the overlapping state above, and the inner casing adjacent to the end near the rear block assembly comprises: A small video camera having an opposite screw hole for receiving a screw that engages in the bent portion of a flexible flat cable element that connects the base plate adjacent the rear block assembly at an inner end thereof. 12. The upper portion of claim 11, wherein the inner casing has a lower portion having an upper flange extending in a longitudinal direction along an opposite side edge thereof, and an upper portion of an “U” cross-sectional shape fitted together with the flange along the lower side edge. Small video camera comprising a. 12. The apparatus of claim 11, wherein each of said inner and outer casings has an octagonal cross section with four relatively long sides that span four relatively short sides, wherein said outer casing is between said upper, lower, and sides thereof. Small video camera with the same panel as the corner slope of the camera. 15. The front and rear block assemblies of claim 14, wherein each of the front and rear block assemblies have respective mounting portions having a cross section corresponding to an inner end face of the outer casing, and are fixed to the latter at each end thereof, and the end of the outer casing. Has a hole in the corner inclined surface engaging with each screw hole in the installation portion, each screw coupled to the front and rear block assembly is fixed to the outer casing. 2. The outer casing according to claim 1, wherein the outer casing has an octagonal cross section having four relatively long sides installed at four relatively short sides so as to have a panel at the top, the bottom thereof, and the side inclined therebetween; And the front and rear block bodies are fixedly fitted to each end of the outer casing. 17. The front block assembly of claim 16, wherein the front block assembly extends axially from the respective mounting portion to the outer casing and extends along the cylindrical portion at each spaced position corresponding to the outline inclined edge edge of the outer casing. A cylindrical portion having a groove extending in the axial direction, an upper frame plate, an optical filter, and an imaging element provided continuously in the cylindrical portion, wherein the imaging element has a rectangular imaging surface having a predetermined aspect ratio; And the upper frame plate has a circular outer circumference that is standardized so as to fit into the cylindrical portion and the rectangular window at the predetermined aspect ratio, and further includes an outward protrusion extending from the outer circumference in the upper frame plate and the base of the rectangular window. Extends into the groove of the cylindrical portion, and the size of the rectangular window A small video camera which can be minimized to the image plane without affecting the strength of the upper frame plate. 18. The compact video camera according to claim 17, wherein the optical filter is rectangular, and the upper frame plate and the image pickup device are fitted into grooves of the cylindrical portion for rotational arrangement. 19. The compact video camera of claim 18, wherein the front block assembly further comprises a buffer member made of an elastic material disposed between the optical filter and the image pickup device. 20. The method of claim 19, wherein the cylindrical portion has an internal screw, and the mounting portion of the front block assembly has a lens mounting surface; The front block assembly includes a lens holder coupled to the inner screw and positioned with respect to the lens mounting surface, an outer screw on the cylindrical portion, a support member on the rear side of the image pickup device, and a support member. And an adjustment ring element screw-coupled to said external screw to adjust the distance between said lens mounting surface and said imaging surface by axially adjusting said imaging device with respect to a yieldable support of said buffer member. 21. The cylinder according to claim 20, wherein the cylindrical portion has a shaft protrusion extending rearward, and the support member slides to receive the shaft protrusion so as to rotate the support member and the image pickup device with respect to the cylindrical portion. Small video camera having a shaft groove on its outer periphery. 21. The method of claim 20, wherein the cushioning member extends outwardly from the rim in a position spaced around the latter for engaging the inner surface of the cylindrical portion with an annular rim having a smaller outer diameter than the inner diameter of the cylindrical portion. Small video camera with axial projection. 23. The method of claim 22, wherein the buffer member, the annular intermediate flange radially inward from the rim between the front and rear edges of the latter, and the inner peripheral portion of the annular intermediate flange for coupling to the optical filter And a ridge facing forward, said rim having a cutout in front of said intermediate flange between said protrusions to receive an edge of said optical filter. 24. The apparatus according to claim 23, wherein the imaging device includes a housing having a generally annular outer circumference having flat portions parallel to the upper, lower, and side portions of the rectangular imaging surface; The rim portion of the shock absorbing member has an axially directed projection extending inwardly from the inner surface to engage the outer periphery of the housing between the planar portion and the spaced plane portion engaging the planar portion of the imaging device housing. Small video camera with an inner surface at the rear of the intermediate flange. 2. The outer casing according to claim 1, wherein the outer casing consists of four relatively long sides lying on four relatively short sides, the outer casing having four identical panels connected to the inclined corners, each of which is in its interior. Having a socket in the same position; A clamping member having a base portion having a vertical portion extending there and ending at a laterally extending portion at a right angle thereof, a right angled arm having a flange extending at one end of the arm, and the flange and vertical having a matching hole; And a screw engageable with the matching hole to secure the clamping member to the mounting bracket together with the panel of the outer casing coupled by the vertical and axial extension portions and the arm angle. Compact video camera. 26. The compact video camera of claim 25, wherein at least one of the arms has an elongated installation pin adapted to engage in the socket of the panel one joined by the one arm. 26. The apparatus of claim 25, wherein at least one of the electronic elements has a rotatable adjustment member having a slotted head and an upper outer casing has an opening for passage to the slotted head; And an adjustment mechanism having a feather-shaped end extending through the opening that provides a passage and engaging with the slotted head, and extending transverse to the feather-shaped end and engageable with an outer surface of the casing to restrict insertion of the mechanism. Small video camera further comprising a horizontal plane. 28. The miniature video camera of claim 27, wherein the transverse piece has a plastic cover overlying it to prevent grooves on the outer surface of the casing. 28. The blade end of claim 27 wherein the quill end is oriented at one end of a continuous length of rigid wire comprising two parallel straight lines spaced at one end by a bend to extend in the axial direction from the other end of the straight part. And a handle having said transverse piece extending across said one straight portion and said feathered end extending longitudinally from one other end of said straight portion. The base portion of the mounting bracket has a vertical boss, and the spacing between the spaced apart straight portions of the adjustment tool is equal to one of the straight portion and the base portion between the flange and one arm of the clapping member. And a small video camera configured to elastically hold the tool by another portion of the straight portion pressed against the boss.