JP2016071310A - Filter changing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize about 30% miniaturization in terms of an area ratio of a filter changing device to be used in a monitor camera and the like.SOLUTION: A filter switching device for switching blockage of an infrared-ray or transmission thereof in accordance with a photograph condition comprises: a holder 1 that includes an aperture part corresponding to an optical path of an imaging device and being composed of a non-magnetic substance; two kinds of sliders of a slider being arranged capable of sliding into the holder 1, including an infrared transmission filter and composed of the non-magnetic substance, and a slider including an infrared transmission filter and composed of the non-magnetic substance; and driving means for causing the sliders to be putt in and pulled out by switching to the optical path thereof, in which two kinds of the sliders are arranged at a different position in a slide direction and a vertical direction, slide in a mutually inverse direction, and are then put in and pulled out by switching to the optical path.SELECTED DRAWING: Figure 1

Description

The present invention relates to a filter switching device for switching a filter according to shooting conditions, and more particularly to a filter switching device for switching an infrared filter between daytime and nighttime in an imaging device for continuous shooting day and night.

  Surveillance cameras are often used outdoors and often monitor the day and night with the same camera. In general, the sensitivity curve of the image sensor extends to the infrared region more than the sensitivity curve of the human eye, so in a day and night continuous camera, an infrared cut filter is used in the daytime to capture images in color mode, and at night. A method is used in which imaging is performed by removing the infrared cut filter from the optical path and increasing the sensitivity in the monochrome mode.

When the infrared cut filter is removed from the optical path, the entire optical path length changes and the focus shifts. To prevent this, a dummy filter that is an infrared transmission filter with the same optical path length as the infrared cut filter is used for visible light. The method of insertion is used.

Utility Model Registration No. 3147474

On the other hand, there is the above-mentioned document as related prior art.

  The reference in the above-mentioned document is to thin and miniaturize the mechanism for blocking infrared rays and switching transmission. However, since this reference is an integrated filter with an infrared cut filter and an infrared transmission filter dummy filter arranged in series in the slide direction, the filter switching device in the slide direction becomes longer, and the intended miniaturization is insufficient. Had the problem of being.

The present invention is intended to reduce the size of the filter switching device, which is the above-mentioned problem, particularly by shortening the length of the filter switching device in the sliding direction.

"Means 1"
A filter switching device for switching between blocking and transmitting infrared light in accordance with imaging conditions, a holder made of a non-magnetic material having an opening corresponding to the optical path of the imaging device, and slidably disposed on the holder In addition, there are two types of sliders, a slider made of a non-magnetic material having an infrared cut filter and a slider made of a non-magnetic material having an infrared transmission filter, and drive means for switching to and from the optical path. Therefore, the two types of slurders are arranged at different positions in the vertical direction with respect to the slide surface, and are linearly moved in opposite directions to be switched in and out of the optical path.
"Means 2"
In the means 1, the two kinds of sliders are linearly moved in opposite directions to each other by the driving means that is a single-phase coil electromagnetic actuator that reciprocally rotates at a finite angle provided on one side in the sliding direction across the opening. A filter switching device using means for switching in and out.
"Means 3"
In the means 1, the electromagnetic actuator, which is a driving means for switching the two kinds of sliders in and out of the optical path, is fixed to the holder with the rotation axis perpendicular to the slide surface, and a pair of arms is formed from the rotor. Provided in the opposite direction of 180 degrees, one arm is connected to the slider with the infrared cut filter and the other arm is connected to the slider with the infrared transmission filter so that the circular motion can be converted into linear motion. ,
A filter switching device having means for moving and positioning a slider having an infrared cut filter in one direction rotation and a slider having an infrared transmission filter in the opposite direction rotation to the opening.
"Means 4"
The filter switching device according to means 1, wherein the two types of sliders are provided with elongated holes in the sliding direction and are movable with the fixing pins as guides.
"Means 5"
In the means 1, the two types of sliders which are arranged at different positions in the actuator axial direction perpendicular to the slide surface of the slider and slide in opposite directions to switch to and out of the optical path are in a state of being back to back with each other. A clearance holding guide in the holder so as to keep a small clearance by point contact or at least one of the above-mentioned two types of sliders and having a plurality of substantially spherical microprotrusions. Etc. A filter switching device using means for sliding.

1) The filter switching device has a double slider configuration in which an infrared cut filter and an infrared transmission filter dummy filter are provided in separate sliders, and the sliders are arranged in double positions at different positions perpendicular to the slide direction. The length in the slide direction is about 30% in actual measurement, and the size is reduced.
2) Since it is driven by a single-phase coil electromagnetic actuator that reciprocates at a finite angle, it is an inexpensive filter switching device.
3) A simple and inexpensive mechanism that converts a finite angle arc motion of a pair of arms into a linear motion by fitting a long hole and a pin slightly smaller than the short diameter of the long hole into one actuator. Since each of the double sliders is simultaneously driven in the opposite directions, the filter switching device becomes compact even with the double slider, realizing a reduction in size and cost.
4) If the above-mentioned two types of sliders are provided with elongated holes in the sliding direction and can be moved with the fixing pin as a guide, the sliders are accurate in the moving direction and have less lateral movement.
5) When two types of sliders slide back to back with each other, the filters can slide without contact with each other, the thickness of the filter switching device can be reduced, and the surface slide can be slid between a point and a surface. Alternatively, if a small clearance is provided, the thickness increases to a certain extent, but the frictional force during sliding decreases and a long life is realized.
6) The actuator may be a stepping motor, but if it is an electromagnetic actuator with a single-phase coil that operates in a finite angle, the cost including the drive circuit is low.

Three-dimensional view of actuator arrangement on holder according to the present invention Arrangement of infrared cut filter, dummy filter and arm of the present invention Sectional view of the vertical center line in FIG. Illustration of another slider of the present invention Another partial perspective view according to an embodiment of the present invention Prior art diagram

  FIG. 1 shows an example of the configuration of the present invention, and relates to an embodiment of the filter switching device of the present invention, and is a three-dimensional view of actuator arrangement on a holder, excluding a slide portion including a filter. In FIG. 1, reference numeral 1 denotes a holder, which is a non-magnetic product made by resin molding or the like. Reference numeral 10 denotes an opening provided in the holder 1, which is a window for an optical path. Although the slider and the filter are not shown in the figure, for example, when it is desired to cut infrared rays, the infrared cut filter is positioned so as to be substantially the same shape as the holder opening 10 and overlap the position of the opening 10. The central portion of the arm 11 that is operated by the repetitive movement of the actuator is coupled to the rotation shaft of the actuator rotor, and the arms 11 extend a pair of arms from the central portion in the opposite direction by 180 degrees. Pin 6 and pin 7 are provided, respectively. A pair of pins 6 and 7 repeats a circular arc motion in opposite directions to drive a slider shown in FIG. Reference numeral 13 denotes a coil bobbin portion that is exposed from the actuator, and reference numeral 14 denotes a coil wound around the outer periphery thereof.

FIG. 2 is a layout diagram of a slider having an infrared cut filter, a slider having a dummy filter, and an arm according to an embodiment of the filter switching device of the present invention. 3 is a cross-sectional view taken along the vertical center line of FIG. Reference numeral 2 shows one of the thin sheet-like sliders of the present invention that move variably. Reference numeral 4 denotes a long hole portion having a long axis perpendicular to the sliding direction provided in the slider 2, and is fitted to a pin 6 provided on the arm 11 attached to the rotor of the actuator and a single shaft portion of the long hole portion 4. Thus, the arc motion of the pin portion around the actuator axis 12 which is the center point of the arm 11 is converted into a linear motion.
The operation principle of the double slider of the present invention will be described with reference to FIGS.
In the slider No. 2, an infrared cut filter 8 having a size slightly larger than the window portion is held by a claw portion or the like protruding from the corners of the four corners and fixed to the slider. Therefore, as shown in FIG. 3, the slider 2 and the infrared cut filter 8 are not on the same plane, and the infrared cut filter 8 protrudes by the thickness. Similarly, another thin sheet-like slider of the present invention, 3, has an infrared-transmitting dummy filter 9. Similarly, the dummy filter 9 protrudes by the thickness of the dummy filter 9. Similar to the slider 2, the slider 3 also engages with the pin 7 through the long hole portion 5 to convert the arc motion of the pin 7 portion into a linear motion. As shown in FIG. 3, if the infrared cut filter 8 is in a position overlapping the opening 10 of the holder 1, the dummy filter 9 takes the position shown in FIG. 2 and is farthest from the opening 10 of the holder. Position. The slider 2 and the slider 3 are arranged so as to be slidable in the vertical direction in FIG. The reason for this is that, as described above, the infrared cut filter 8 and the dummy filter 9 protrude about the thickness of the filter. This is because the filter can be made thin as long as it does not oppose, and there is no sliding scratch between the filters, resulting in a longer life.
Further, the two types of sliders are not limited to those described above. Although illustration is omitted, for example, one or both of the sliders may have a plurality of substantially spherical minute protrusions and may be slid by contact with the surface at a point. When both have a plurality of substantially spherical microprojections, the planar microprojection positions may be positions that do not interfere with each other. Alternatively, the holder can be slid by providing a clearance holding guide or the like so as to maintain a minute clearance.

As shown in FIG. 2, the long holes 4 and 5 provided in the sliders 2 and 3 are fitted with the pins 6 and 7 provided on the arm 11 as described above. The sliders 2 and 3 are slid in a direction opposite to each other, that is, linearly moved, by the arm 11 repeatedly rotating at a desired finite angle about the actuator axis 12 which is the center point thereof. The positions of the sliders 2 and 3 shown in FIG. 2 correspond to the positions of the pair of arms 11 and the pins 6 and 7 that have come out of the actuator shown in FIG.
Next, although illustration is omitted, if the arm 11 is driven counterclockwise at a desired finite angle with respect to the position shown in FIG. 2, the pin 6 is the pin currently shown in the vertical direction in FIG. Move down to position 7 and stop. In that case, since the arm 11 moves like a seesaw, the pin 7 shown in the figure moves to the position of the pin 6 shown in the figure in the vertical direction in FIG. 2 and stops, and the dummy filter 9 is not shown. The filter is switched by positioning it in the window of the holder. In this case, the sliders 2 and 3 guide and guide the side portions of the sliders 2 and 3 with the holder 1 so that they do not shift laterally during sliding.

FIG. 4 is an explanatory diagram of a slider having a filter according to the present invention. As described above, the side portions of the sliders 2 and 3 are guided and guided by the holder 1 so that the sliders 2 and 3 do not shift laterally when sliding, but if this is not sufficient, the slider 2 can be described as shown in FIG. The long holes 17 and 18 having a long diameter equal to or longer than the sliding distance are provided in the sliding direction, and the pins 15 and 16 fixed to the holder are fitted and guided. If the short diameter of the long holes 17 and 18 is set to a value having an appropriate clearance with respect to the pin diameter, a sufficient effect of preventing the slider from shifting laterally can be obtained. Further, the horizontal movement distance L _H of the pin 6 and the vertical movement distance L _V of the slurder 2 in the long hole 4 provided in the slider 2 of FIGS. 4 and 2 are set such that the pitch of the pin 6 and the pin 7 is 2l. If the maximum deflection angle with the horizontal line of the arm 11 is θ _m , the following is obtained.
L _H = l (1-cosθ _m ) (1)
L _V = 2lsinθ _m (2)
Thus, in FIG. 4, the major axis of the value of the slot 4 may be at least the sum of the diameter of the pin 6 and L _H. The major axis of the value of the slot 17 and 18 should be at least the sum of the diameter and _{L V} of the pin 15 or 16. The same applies to the slot 5 of the slider 3.

Actuators for use in the present invention are can be positioned at the maximum deflection angle theta _m of a horizontal line of the arm 11, as long as it can repeat the operation. For example the step angle of a stepping motor may be used those one integer n minutes of theta _m. n is an integer of 1 or more, and the stepping motor may perform repeated positioning operations in n steps. Furthermore, if a single-phase coil electromagnetic actuator that reciprocates at a finite angle is used, the cost is further reduced.
Other, a general motor may control a finite angle theta _m.

FIG. 5 is another partial three-dimensional view according to the embodiment of the present invention. The sliders 2 and 3 are shown in a three-dimensional exploded view. 8 is an infrared cut filter, and 9 is a dummy filter. As described above, the sliders 2 and 3 face each other back to back and move linearly in opposite directions. In FIG. 2, FIG. 3, FIG. 5, etc., there is no problem even if the slider 2 has the infrared transmission filter 9 and the slider 3 has the infrared cut filter 8 to form two types of sliders.

FIG. 6 is an explanatory diagram of the prior art, and shows a configuration in which the infrared cut filter 8 and the dummy filter 9 are arranged in series in the slide direction and fixed to the slider 18. The details correspond to FIG. 2 of the reference document “Utility Model Registration No. 3147474”. Further, in FIG. 6 of the reference, the infrared cut filter 29 and the dummy filter 30 are arranged and arranged in series in the sliding direction and fixedly held on the slider. Therefore, if the filter size is the same, the slide switching device is longer in the sliding direction than the present invention. Will be. The present invention can shorten the overall length by 30% on the basis of actually measured values that have been prototyped. As described above, since the thickness of the slide switching device is determined by the axial thickness of the actuator portion, the thickness of the slide switching device of the present invention is almost the same as that of the reference. Therefore, the present invention is about 30% smaller in volume ratio than the reference conventional product.

The slide switching device according to the present invention is miniaturized, has a long life, and is extremely practical. Therefore, in the case of application to surveillance cameras, significant industrial contribution is expected.

Explanation of main symbols

1 Holder 2, 3, slider 4, 5, 17, 18 slot
6, 7, 15, 16 pins
8, Infrared cut filter 9, Dummy filter 10 Holder opening 11 Arm 12 Actuator axis 13 Bobbin 14 Coil

Claims (5)

A filter switching device for switching between blocking and transmitting infrared light in accordance with imaging conditions, a holder made of a non-magnetic material having an opening corresponding to the optical path of the imaging device, and slidably disposed on the holder In addition, there are two types of sliders, a slider made of a non-magnetic material having an infrared cut filter and a slider made of a non-magnetic material having an infrared transmission filter, and drive means for switching to and from the optical path. The filter switching device is characterized in that the two types of slurder are arranged at different positions in the vertical direction with respect to the slide surface, and are linearly moved in opposite directions to be switched in and out of the optical path. 2. The optical path according to claim 1, wherein the two kinds of sliders are linearly moved in opposite directions to each other by a driving means that is a single-phase coil electromagnetic actuator that reciprocally rotates at a finite angle provided on one side of the sliding direction across the opening. A filter switching device characterized by switching to and out of the filter. 2. The electromagnetic actuator according to claim 1, wherein the electromagnetic actuator as a driving means for switching the two types of sliders to and from the optical path is fixed to a holder with a rotating shaft perpendicular to the slide surface, and a pair of arms from the rotor. Are provided in the opposite direction, and one arm is connected to the slider having the infrared cut filter and the other arm is connected to the slider having the infrared transmission filter so that the circular motion can be converted into a linear motion. And
A filter switching device characterized in that a slider provided with an infrared cut filter is rotated in one direction and a slider provided with an infrared transmission filter is rotated in the opposite direction and moved to the opening. 2. The filter switching device according to claim 1, wherein the two types of sliders are provided with elongated holes in the sliding direction so that they can be moved with a fixed pin as a guide. 2. The two types of sliders according to claim 1, which are arranged at different positions in the direction of the actuator axis perpendicular to the slide surface of the slider, and which are slid in opposite directions to switch to and out of the optical path in a state where they are back to back In order to maintain a small clearance by contact between the surface and the point, or by having a plurality of substantially spherical microprotrusions on one or both of the above two types of sliders, A filter switching device, wherein the holder is provided with a clearance holding guide or the like and is slid.