KR200487338Y1 - Compact-type filter change assembly and camera having the same - Google Patents

Abstract

A filter base 10 having a rectangular plate shape in which a center hole 11 is formed between two guide rails 12, a visible light filter 21 and an infrared filter 22, A composite filter module 20 having a filter base 10 and a filter base 10 and linearly moving between the two guide rails 12 of the filter base 10. The filter module 20 includes a magnetic body 32 inserted into the housing 31, A rotation module 30 including the wound solenoid 33 and a connecting rod 40 having a magnetic body 32 at one end and a composite filter module 20 at the other end, 32 are arranged in the internal magnetic field region of the solenoid 33, and the filter is changed by moving the composite filter module 20 while rotating. This may be advantageous in that the entire system of the filter change assembly is simplified and miniaturized, and the weight can be reduced.

Description

A compact filter change assembly and a camera to which the filter change assembly and camera are applied,

The present invention relates to a filter change assembly for changing the type of light reaching a CCD (Charge Coupled Device) while two filters linearly reciprocate, and a camera to which the filter change assembly is applied.

Surveillance cameras are installed in highways, buildings, alleyways and borders to record and monitor the surrounding situation. The performance of the surveillance cameras depends on whether the captured images are clear or not. However, when the climatic environment such as fog or yellow dust occurs in which the light is absorbed or scattered, there is a problem that the sharpness of the photographed image is lowered and the object becomes hard to recognize.

In an environment in which a weather phenomenon such as fog or seawater occurs, it is difficult to shoot an object with visible light only, so that a camera that detects a long wavelength such as an infrared ray is being developed. Day and night filters are used in these cameras. The day and night filters are a method in which a visible light filter and an infrared filter are arranged side by side on a square frame, and a rectangular frame is moved linearly between the camera lens and the CCD And the type of light reaching the CCD is changed. The camera must be able to swiftly and accurately replace the filter with only a small amount of power in that it is an electronic device with many internal components and small components.

In this regard, Korean Unexamined Patent Publication No. 10-2010-0104556 entitled " Drive Assembly for Filter Conversion for Camera Module and Filter Conversion Apparatus Including the Same " discloses a technique in which a filter is linearly reciprocated And the like. This requires a space for mounting the yoke, and the magnet itself moves in an arc shape, so that a space considering the radius of motion of the magnet is required, which limits the miniaturization of the driving assembly Structure.

Another prior art Korean Patent Registration No. 10-0996470 entitled " A filter change assembly for a camera module using an electronic rotary device and an operation method thereof " is a method of arranging electromagnet coils on the left and right sides of an electromagnet rotation device, Thereby rotating the electromagnet. In addition, since the two electromagnet coils must be disposed on both sides of the electromagnet rotation device, there is a limitation in miniaturizing the filter change assembly.

The present invention is directed to a compact filter change assembly which is advantageous for miniaturization design and which can reduce the overall weight of the camera and simplify the system, and a camera to which the filter change assembly is applied. The present invention is not limited to the above-described technical problems, and another technical problem may be derived from the following description.

A filter change assembly according to the present invention comprises: a filter base formed in a rectangular plate shape having a central hole and having two flat guide rails projecting parallel to each other on both sides of a central hole on one side; A composite filter module formed in a rectangular plate shape having a visible ray filter and an infrared ray filter and sandwiched between two guide rails of the filter base and moving linearly; A cylindrical body formed in a cylindrical shape and inserted into the inside of the housing, a magnetic body having a magnetic pole characteristic having an S pole at the center of the circle and a N pole at the center of the circle, and a coil, A rotation module including a solenoid wound to pass; And a connecting rod which is formed in a bar shape and has one end fixedly coupled to one end of the magnetic body of the rotation module and rotating together with the magnetic body, and the other end being engaged with the composite filter module.

The magnetic body is disposed in an inner magnetic field region of the solenoid and rotates in a clockwise or counterclockwise direction by a direction of a magnetic field formed inside the solenoid, and the connecting rod rotates in a clockwise or counterclockwise direction Clockwise or counterclockwise and the composite filter module engaged with the other end of the connecting rod moves along two guide rails of the filter base so that any one of the visible light ray filter and the infrared ray filter moves to the filter And is located in the center hole of the base.

Wherein the housing includes an outer case of a cylindrical metal material and an inner holder of a non-metallic material formed in a shape of a combination of two fan-shaped parts and inserted into the outer case and having a cylindrical space at its center, The magnetic body is accommodated in the cylindrical space at the center of the inner holder, and the winding of the solenoid can pass through the space between the two sectors of the inner holder in the longitudinal direction of the magnetic body.

Wherein a plurality of magnetic force stoppers in the form of rods of metal are formed on the inner wall of the outer case of the housing in the longitudinal direction of the housing and when the magnetic field of the solenoid is extinguished, Can be fixed.

A camera according to another aspect of the present invention includes a camera lens; A filter change assembly according to one aspect of the present invention; And a CCD assembly mounted on the opposite side of the camera lens with respect to the filter change assembly.

By disposing a cylindrical magnetic body in the coil-shaped solenoid, the magnetic body can rotate clockwise or counterclockwise according to the direction of the magnetic field formed inside the solenoid. Further, the magnetic substance and the composite filter module are respectively coupled to both ends of the rod-shaped connecting rod, and the filter can be replaced by linear movement of the composite filter module while rotating the magnetic rod in accordance with the rotation of the magnetic body. Particularly, in the rotary module, a cylindrical magnetic body is inserted into a cylindrical housing, and the winding of the solenoid is wound to pass both ends of the magnetic body so as to pass both ends of the cylindrical magnetic body, Thereby making it possible to minimize the size and weight of the filter change assembly.

The inner holder of the non-metallic material in which the two fans are combined is inserted into the outer case of the cylindrical metal material and the magnetic material is accommodated in the cylindrical space at the center of the inner holder so that the magnetic material can be stably rotated inside the housing . Further, the winding of the solenoid can be wound in the space between the two sectors of the inner holder in the longitudinal direction of the magnetic body so that the winding of the solenoid passes both ends of the magnetic body accommodated in the cylindrical space in the center of the inner holder.

A plurality of magnetic force stoppers, which are metal rods, are formed on the inner wall of the outer case of the housing in the longitudinal direction of the housing. Thus, when the internal magnetic field of the solenoid disappears, the rotation of the magnetic body is fixed by the attractive force between the magnetic body and the magnetic force stator, The module can remain fixed at the last position immediately before the power shutdown.

1 is an exploded perspective view of a filter change assembly according to one embodiment of the present invention.
FIG. 2 is an enlarged plan view and a cutaway perspective view of the rotation module 30 shown in FIG.
3 to 6 are flowcharts of the filter replacement operation of the camera shown in Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below relate to a compact filter change assembly and a camera to which the filter change assembly is applied. Hereinafter, a filter change assembly of a miniaturized structure will be briefly referred to as a " filter change assembly ".

FIG. 1 is an exploded perspective view of a filter change assembly according to an embodiment of the present invention, FIG. 2 is an enlarged plan view and a cutaway perspective view of the rotation module 30 shown in FIG. 1, and FIGS. 1-6, the filter change assembly according to the present embodiment includes a filter base 10, a composite filter module 20, a rotation module 30, a connecting rod 40 And a cover 50. As shown in Fig. Other embodiments described below may further include other additional components.

The filter base 10 is formed in the shape of a rectangular plate having a central hole 11. Two guide guide rails 12 protrude in parallel with each other on both sides of the center hole 11 on one side of the filter base 10. The filter base 10 is a rectangular plate assembled to the rear end of the camera barrel, and may be made of a non-metallic plastic material. At the center of the rectangular plate of the filter base 10, a circular central hole 11 penetrating the filter base 10 is formed. It is preferable that the center hole 11 has an appropriate size so that light passing through the lens barrel of the camera can be easily passed through.

Two guide rails 12 protrude from both sides of the center hole 11. The guide rail 12 is a protruding line segment that straightly connects two corners symmetrical to each other of the four corners of the filter base 10, that is, left and right or upper and lower corners. It is preferable that the two guide rails 12 are formed parallel to each other and a center hole 11 is formed therebetween. In particular, it is preferable that the composite module filter 20 is inserted between the guide rails 12 so as to have a distance Do.

The square composite filter module 20 is disposed between the two guide rails 12 and is in a state in which it can move left and right only. A bolt hole is formed in the outer periphery of the filter base 10 such as a corner or a corner to be engaged with a camera barrel and a screw. Here, a through hole is formed in the vicinity of the vertex of the left upper end of the filter base 10 so that the magnetic body 32 of the rotation module 30 can be inserted and assembled. This through hole can be formed in a circular shape in conformity with the cylindrical magnetic body 32.

The composite filter module 20 is formed in the shape of a rectangular plate having a visible light filter 22 and an infrared filter 23. The composite filter module 20 is sandwiched between two guide rails 12 of the filter base 10 and linearly moves. Specifically, the composite filter module 20 is composed of a frame 21, a visible light filter 22, and an infrared filter 23. The frame 21 of the composite filter module 20 is a rectangular flat plate made of a plastic material, and rectangular holes are formed side by side as shown in FIG. A visible light filter 22 and an infrared filter 23 are disposed in two holes of the frame 21 of the composite filter module 20. Each of the visible light filter 22 and the infrared filter 23 is a quadrangular translucent plate and is made of a material for selectively shielding light of a specific wavelength. The visible light filter 22 and the infrared filter 23 each have a larger area than the hole formed in the frame 21, so that the hole of the frame 21 can be completely covered. The light passing through the hole of the frame 21 must pass through the visible light filter 22 or the infrared filter 23 to reach the CCD.

The composite filter module 20 is disposed between the two guide rails 12 of the filter base 10. The light passing through the center hole 11 of the filter base 10 passes through any one of the two holes of the frame 21 and passes through the visible light filter 22 or the infrared filter 23 covering the hole, The light of the wavelength is blocked. Here, when the frame 21 is shaken between the two guide rails 12, the photographed image may be adversely affected. In order to prevent this, it is preferable that the distance between the two guide rails 12 substantially coincides with the width of the frame 21 so that there is almost no clearance after the frame 21 is sandwiched between the two guide rails 12.

The frame 21 of the composite filter module 20 is formed with a portion protruding outward at a certain height at one corner of the quadrangular four corners. The protruded portion can be engaged with the connecting rod 40 by forming an elongated hole 23 in one through the thickness direction. Referring to FIG. 1, a rectangular protrusion may be formed laterally in the frame 21 where the slot 23 is formed. The longitudinal axis of the elongated hole 23 is preferably formed in the vertical direction so as to be perpendicular to the moving direction of the frame 21. The elongated hole 23 is formed in the longitudinal direction of the connecting rod 40 The engaging projection 41 of the engaging portion 41 is fitted.

Hereinafter, the case where the frame 21 is moved from the left to the right will be described in order. 3, the engaging projection 41 of the connecting rod 40 is positioned at the uppermost position of the elongated hole 23 when the frame 21 is at the leftmost position. Thereafter, the connecting rod 40 rotates counterclockwise around the rotation module 30, and moves the frame 21 to the right. As shown in FIG. 4, as the frame 21 moves to the middle of the field base 10, the engaging projections 41 of the connecting rod 40 move downward from the slot 23. Thereafter, when the connecting rod 40 further rotates in the counterclockwise direction and the frame 21 moves to the right, the engaging projection 41 of the connecting rod 40 moves again to the uppermost position in the slot 23 do. The process in which the connecting rod 40 rotates in the clockwise direction and the frame 21 moves from right to left is the reverse order of the above procedure. Thus, when the connecting rod 40 is rotated clockwise or counterclockwise, the engaging projections 41 of the connecting rod 40 are moved up and down within the range of the long hole 23. The composite filter module 20 can reciprocate linearly between the two guide rails 12 of the filter base 10 while maintaining the engaged state with the connecting rod 40. [

The rotation module 30 is composed of a cylindrical housing 31, a magnetic body 32, and a solenoid 33.

The magnetic body 32 of the rotation module 30 is formed in a cylindrical shape and inserted into the inside of the housing 31. The housing 31 is disposed on the bottom surface of the through hole of the filter base 10 and the magnetic body 32 is disposed on the top surface of the filter base 10. [ Thereafter, the magnetic substance 32 is inserted into the housing space of the housing 31, and the winding is wound up and down the magnetic body 32 so that both ends of the magnetic body 32 are not seen, (32). Thereafter, the cover 50 may be assembled or bonded so as to cover the magnet body 32 to prevent the magnetic body 32 from escaping.

Here, the housing 31 of the rotation module 30 is composed of an outer case 311 made of a metal and an inner holder 312 made of a non-metal material. Referring to FIG. 2, the outer case 311 of the housing 31 is formed in a cylindrical shape having open top and bottom. The inner holder 312 of the housing 31 is formed in a shape in which the two fans are coupled and inserted into the outer case 311 of the housing 31. A cylindrical space is formed in the center of the inner holder 312 of the housing 31.

An inner holder 312 is inserted into the outer case 311 of the housing 31 and a magnetic body 32 is inserted into the inner holder 312 of the housing 31, . That is, the magnetic body 32 is accommodated in the cylindrical space at the center of the inner holder 312. It is preferable that the cylindrical space formed in the center of the inner holder 312 of the housing 31 has a slightly larger diameter than the magnetic body 32 in consideration of smooth rotation of the magnetic body 32. [ Here, the inner holder 312 of the housing 31 is formed with a plastic body in the form of a body in a symmetrical manner with respect to the accommodation space. The inner holder 312 of the housing 31 is formed with a space in which a plastic body of a body is present and a space in which the upper and lower surfaces are penetrated because a body of the body is not formed. The windings of the solenoid 33 pass through both ends of the magnetic body 32 while passing in the longitudinal direction of the magnetic body 32 in a space between two sectors of the inner holder 312. The magnetic body 32 is disposed in a space inside the solenoid 33 in the form of a coil and is rotated in a clockwise or counterclockwise direction by an internal induced magnetic field generated in the solenoid 33.

The magnetic body 32 has the magnetic pole characteristic that the half of the cylinder is the S pole and the other half is the N pole with the diameter of the cylinder as a boundary. The solenoid 33 is formed in a coil shape and is wound on the magnetic body 32 in the longitudinal direction of the magnetic body 32 so that the winding passes both ends of the magnetic body 32. Both ends of the magnetic body 32 are not exposed to the outside due to the winding of the windings of the solenoid 33, respectively. 2, when a current is applied to the solenoid 33 in a state in which the magnetic substance 32 is disposed inside the solenoid 33 wound with a winding, the current is applied to the inside and outside of the solenoid 33 according to the Ampere's law A magnetic field is induced. The magnetic field formed inside the solenoid 33 changes the polarity of the magnetic field as the direction of the current applied to the winding is changed, so that the attracting force or the repulsive force is applied to the magnetic body 32. The magnetic body 32 is disposed in the inner magnetic field region of the solenoid 33 and rotates clockwise or counterclockwise according to the direction of the internal magnetic field of the solenoid 33. [

The connecting rod 40 is formed in a bar shape and is coupled with the magnetic body 32. One end of the connecting rod 40 is fixedly coupled to one end of the magnetic body 32 of the rotation module 30 and rotates together with the magnetic body 32. The other end of the connecting rod 40 is engaged with the composite filter module 20. In particular, a coupling protrusion 41 is formed at the other end of the connecting rod 40. The coupling protrusion 41 of the connecting rod 40 may extend in a direction perpendicular to the longitudinal direction of the rod as shown in FIG. 2 and fit into the slot 23 of the composite filter module 20.

The magnetic body 32 rotates in accordance with the direction of the internal magnetic field of the solenoid 33. The connecting rod 40 rotates clockwise or counterclockwise as the magnetic body 32 rotates clockwise or counterclockwise . The composite filter module 20 which is engaged with the other end of the connecting rod 40 moves along the two guide rails 12 of the filter base 10 and moves either one of the visible light filter 21 and the infrared filter 22 Is located in the center hole of the filter base 10. [

In the case where the solenoid 33 is not supplied with electricity and the magnetic field disappears in the solenoid 33, there is no device capable of fixing the composite filter module 20 on the filter base 10, The composite filter module 20 can be moved by an external factor such as vibration. Due to the movement of the composite filter module 20, the light reaching the CCD before power is supplied and the light reaching the CCD after the power is cut off may be different from each other. Further, when the composite filter module 20 is not completely moved to one of the both ends of the filter base 10, the visibility is blocked.

In consideration of this point, the present embodiment has focused on the internal structure of the rotation module 30 so that the composite filter module 20 does not move in the final position when the power of the camera is cut off in an optimal miniaturized structure. Specifically, in the rotation module 30, a plurality of magnetic force stoppers 34 in the form of rods of metal are formed in the inner wall of the outer case 311 of the housing 31 in the longitudinal direction of the housing 31 have. Each of the magnetic force stoppers 34 is formed in a rod shape and is made of a metal material, so that attraction force acts on the magnetic body 32. As shown in FIG. 2, the four magnetic force stoppers 34 may be arranged symmetrically with respect to one outer case 311.

Only the self magnetic force due to the polarity of the magnetic body 32 is left when the induction magnetic field disappears because no electricity flows through the solenoid 33 so that the attractive force between the magnetic body 32 and the magnetic force stopper 34 made of a metal acts. Therefore, the composite filter module 20 can be fixed without being moved by the attractive force between the magnetic body 32 and the magnetic force stopper 34 even when the power of the solenoid 33 is not supplied. Here, the magnetic force stopper 34 may be a metal rod separately coupled to the housing 31 as shown in FIG. 2 (a), and may be a rod such as a bar As shown in FIG.

More specifically, when no electric power is supplied to the solenoid 33 and the induction magnetic field disappears, the magnetic body 32 has a magnetic portion having a strongest magnetic force, that is, a center portion of the semi- And is rotated so as to be a viewing position. The present embodiment can prevent the compound filter module 20 from being moved by an external force even when power of the solenoid 33 is not supplied using the attraction force between the magnetic force stopper 34 and the magnetic body 32. [ In addition, since magnetic attraction is continuously applied between the magnetic body 32 and the magnetic force stopper 34, the composite filter module 20 can be restored to the outside due to external vibrations or vibrations.

Korean Patent Registration No. 10-0996470 discloses a structure in which an electromagnet stagnant of a metal material is formed inside an electromagnet coil and an electromagnet stagnant is fixed in close contact with an electromagnet rotator when no current flows through the electromagnet coil . This is advantageous in reliably fixing the position of the filter when power is not supplied. However, in order to rotate the electromagnet rotating device when electric power is supplied again, it is necessary to make energy more than the work force acting between the electromagnet rotating device and the electromagnet rotating device. . The present embodiment is a structure in which the magnetic force stopper 34 and the magnetic body 32 are at a close distance where attraction is exerted and are not in contact with each other at the same time. Therefore, when power is supplied again to the rotation module 30, only a minimum amount of electric power is required to generate a rotational force greater than the attractive force between the magnetic body 32 and the magnetic force stopper 34, so that power consumption for rotating the magnetic body Can be minimized.

3 to 6 are flowcharts of the filter replacement operation of the camera shown in Fig. Referring to FIG. 3, the first composite filter module 20 is located on the left side of the filter base 10. The magnetic body 32 is not seen from the outside because the winding of the magnetic body 32 is wound so that the winding of the solenoid 33 passes both ends of the magnetic body 32. 3 shows a state immediately after inducing a magnetic field by applying a current such that a current flowing in the winding flows from the left side to the right side with respect to the magnetic body 32. The magnetic field inside the solenoid 33 is formed by the S pole and the N pole on the lower side and the same pole is formed on the side near the N pole and the S pole of the magnetic body 32 by the Angfer law according to the direction of the current. The repulsive force acting on the magnetic body 32 acts as a force for rotating the magnetic body 32 counterclockwise. Thus, the connecting rod 40 coupled with the magnetic body 32 rotates counterclockwise, and the composite filter module 20 assembled at the end of the connecting rod 40 moves to the right.

4 shows the composite filter module 20 as it is located in the middle of the filter base 10 while moving from left to right on the filter base 10. [ This is because the gap between the two holes of the composite filter module 20 is located in the center hole 11 of the filter base 10 but actually the composite filter module 20 moves instantaneously, . The coupling rod 40 rotates in the form of a toroidal arc by the rotation of the magnetic body 32 and the coupling protrusion 41 of the connecting rod 40 is rotated in the longest hole 23 of the composite filter module 20 Respectively.

Referring to FIG. 5, the composite filter module 20 is located on the right side of the filter base 10, and the filter change operation is completed. In this case, different poles are most adjacent between the internal magnetic field of the solenoid 33 and the magnetic body 32 to complete the filter change operation. 6, the direction of the current applied to the solenoid 33 is switched, that is, a current is applied from the right side to the left side around the magnetic body 32 to change the position of the solenoid 33 33 to rotate the magnetic body 32 disposed in the solenoid 33 in the opposite direction. This process is the reverse of the above-described FIG. 3 to FIG.

Korean Unexamined Patent Publication No. 10-2010-0104556 discloses a structure in which a rectangular yoke is disposed at the bottom of a magnet so that the magnet is spaced apart from a rectangular yoke and is reciprocated by a magnetic force, A space for arranging the yoke is required, and a frame for fixing the yoke must be separately provided, which leads to a limitation in miniaturization. Korean Patent Registration No. 10-0996470 discloses a structure for rotating an electromagnet using a magnetic field generated outside the electromagnet coil. Therefore, a space for arranging the electromagnet coil is indispensably required, and a metal There is a problem in that the overall system is complicated and the volume of the filter change assembly is increased in that the structure is such that the electromagnetism of the material is disposed and the electromagnet can not be built in.

In consideration of this point, the present embodiment takes the magnetic substance 32 into the solenoid 33 by winding the magnetic body 32 while the winding of the solenoid 33 passes the both ends of the magnetic body 32 in the longitudinal direction of the magnetic body 32 ). It is possible to reduce the size of the filter change assembly as the magnetic body 32 is disposed in the internal magnetic field region of the solenoid 33. The magnetic body 32 can be rotated clockwise or counterclockwise by the direction of the internal magnetic field of the solenoid 33, So that the composite filter module 20 can be moved. That is, the present embodiment is a compact structure in which the magnetic body 32 and the solenoid 33 are all arranged in the most efficient space in the cylindrical housing 31, and is optimized for the miniaturization of the filter change assembly. The camera to which the above-described filter change assembly is applied has a structure in which the camera barrel and the CCD assembly are further assembled. However, in order to prevent the characteristics of the present embodiment from being blurred, description of general components of the camera not related to the features of this embodiment will be omitted do.

The present invention has been described with reference to preferred embodiments. It will be understood by those skilled in the art that the present invention may be embodied in various other forms without departing from the spirit or essential characteristics thereof. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is indicated by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

10: filter base 11: center hole
12: Guide rail
20: hardware filter 21: frame
22 Visible light filter 23: Infrared filter
24: Slots
30: rotation module 31: housing
311: outer case 312: inner holder
32: magnetic body 33: solenoid
34: Magnetic force stopper
40: connecting rod 41: engaging projection
50: cover

Claims (4)

A filter base 10 formed in a rectangular plate shape having a center hole 11 and having two flat guide rails 12 projecting in parallel with each other on both sides of a central hole 11 on one side;
A composite filter module 20 formed in the shape of a rectangular plate having a visible light filter 22 and an infrared filter 23 and sandwiched between two guide rails 12 of the filter base 10 and moving linearly;
A cylindrical body 31, a magnetic body 32 formed in a cylindrical shape and inserted into the housing 31 and having a magnetic pole characteristic that the half of the cylinder is an S pole and the other half is an N pole with a diameter as a boundary, A rotation module (30) including a solenoid (33) wound and wound so that a winding passes across both ends of the magnetic body (32); And
A connecting rod 40 having one end fixedly coupled to one end of the magnetic body 32 of the rotary module 30 and rotated together with the magnetic body 32 and the other end engaged with the composite filter module 20, Lt; / RTI >
The magnetic body 32 is disposed inside the solenoid 33 and rotates clockwise or counterclockwise according to the direction of the magnetic field formed inside the solenoid 33,
The connecting rod 40 rotates clockwise or counterclockwise together as the magnetic body 32 rotates clockwise or counterclockwise,
The composite filter module 20 engaged with the other end of the connecting rod 40 moves along the two guide rails 12 of the filter base 10 and passes through the visible light filter 21 and the infrared filter 22 Is located at the center hole 11 of the filter base 10,
The housing 31 includes an outer case 311 made of a cylindrical metal material and a base metal 311 inserted into the outer case 311 and having a cylindrical space formed at the center thereof, An inner holder 312 made of a material,
The magnetic body 32 is accommodated in a cylindrical space at the center of the inner holder 312 and a winding of the solenoid 33 is inserted into a space between two sectors of the inner holder 312, Filter change assembly passing longitudinally. delete The method according to claim 1,
A plurality of magnetic force stoppers 34 in the form of rods of metal are formed on the inner wall of the outer case 311 of the housing 31 in the longitudinal direction of the housing 31,
Wherein rotation of the magnetic body (32) is fixed by attraction between the magnetic body (32) and the magnetic force stopper (34) when the internal magnetic field of the solenoid (33) disappears. A camera to which the filter change assembly of claim 1 is applied,
Camera lens;
The filter change assembly of claim 1; And
And a CCD assembly assembled on the opposite side of the camera lens relative to the filter change assembly.

Images