JP2016042422A - Crime prevention sensor having tamper switch - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a crime prevention sensor having a tamper switch which is adaptable, with a simple construction, to remarkably uneven wall surface on which the sensor is to be installed, and can easily stably operate the tamper switch.SOLUTION: A tamper switch 3 has a switch body 6, an on/off button 6a, a shaft 7 having a fixed length which is disposed to move in a direction X perpendicular to an on/off direction Y of the on/off button 6a and presses the on-off button through the movement, and a compression spring 8 for applying spring force corresponding to unevenness of a wall surface in the movement direction. A space 10 containing a front side over the on/off button position of the switch body in the movement direction of a shaft is provided in a sensor unit 2. The movement amount of the shaft is absorbed in the space according to the unevenness of the wall surface to keep an on-state of the on/off button, and the on/off button is set to an off-state by detaching the sensor unit in the movement direction.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a security sensor with a tamper switch that detects that a security sensor is installed on a wall surface and that the security sensor is removed from the wall surface.

  As shown in FIG. 5, this type of security sensor 51 is configured such that a sensor unit 52 having a sensor unit S that detects an object based on a detection line for detecting an object is installed on a wall surface K including irregularities. A tamper switch 53 for detecting removal from the wall surface K is attached to the unit 52. For example, the sensor unit S is stored in the front (front) box F of the sensor unit 52, and a battery, a communication device, and the like (not shown) are stored in the back (rear) box B. In some cases, the back box B is not provided. As shown in the partially enlarged view of FIG. 5, the security sensor 51 is provided with an elastic material 58 such as a spring at the rear end of the shaft 57 between the tamper switch 53 and the wall surface K, and the movement amount (stroke) of the shaft 57. Is absorbed to a certain extent and corresponds to the unevenness of the wall surface K.

  FIG. 5 shows a state immediately before the sensor unit 52 is installed on the wall surface K including the recess. By pressing and fixing the sensor unit 52 against the wall surface K in the arrow direction A, the shaft 57 presses the on / off button 56a of the switch body 56, and is turned on. When the security sensor 51 is removed in the direction opposite to the arrow direction A, it is turned off. It is also known to use sponge or rubber instead of the spring.

  As a security sensor with a tamper switch that can be used even if the mounting surface is uneven, a tamper switch actuating member (shaft) with a double slide structure using two types of springs with different strengths is used. And a shaft provided with flanges on the tamper switch side and the center (for example, Patent Document 1).

JP 2010-160908 A

  However, in the conventional security sensor of FIG. 5, the shaft 57 of the tamper switch 53 pushes the on / off button 56a in the on / off direction. For example, when the concave portion of the wall surface K is large (broken line portion α), The amount of movement (stroke) cannot be absorbed and the shaft length must be increased to switch on. On the other hand, when the convex portion of the wall surface is large, the amount of movement of the shaft cannot be absorbed only by compression of the elastic material, and the shaft length needs to be shortened in order to store between the tamper switch and the wall surface. Therefore, when the unevenness of the wall surface is large, a shaft having a certain length may not be able to cope. When using sponge or rubber instead of a spring, it is necessary to consider deformation or crushing due to secular change, and the design becomes complicated, and the movement amount of the shaft changes, so the operation is unstable. It may become.

  Furthermore, since the crime prevention switch of patent document 1 employ | adopts the double slide structure, the structure becomes complicated. As with the switch in FIG. 5, the shaft length needs to be increased when the concave portion of the wall surface is large, and the shaft length needs to be shortened when the convex portion is large. There is.

  The present invention solves the above-mentioned problems, and can cope with this even with large unevenness on the wall surface to be installed with a simple structure, and can easily operate the tamper switch stably. An object is to provide a security sensor with a switch.

  In order to achieve the above object, a security sensor with a tamper switch according to the present invention is a security sensor in which a sensor unit having a sensor unit for detecting an object based on a detection line for detecting an object is installed on a wall surface behind the sensor unit. It is. A tamper switch that detects removal from the wall surface is mounted on the sensor unit, and the tamper switch is arranged to move in a direction orthogonal to the on / off direction of the switch body, the on / off button, and the on / off button, A shaft having a certain length that presses the on / off button by the movement, and a compression spring that is attached to the shaft and applies a spring force according to the unevenness of the wall surface in the movement direction of the shaft. In the sensor unit, a space including the front beyond the on / off button position of the switch body in the movement direction of the shaft is provided, and the movement amount of the shaft is absorbed in the space according to the unevenness of the wall surface. The on / off button is kept on, and the on / off button is turned off by removing the sensor unit in the moving direction.

  According to this configuration, the shaft having a certain length is arranged so as to move in a direction perpendicular to the on / off direction of the on / off button of the tamper switch, and the front of the switch body in the direction of movement beyond the position of the on / off button of the switch body. A space to be included is provided, and the movement amount of the shaft is absorbed in the space according to the unevenness of the wall surface, and the ON state of the ON / OFF button is maintained. Therefore, since the shaft moves in a direction perpendicular to the on / off direction of the on / off button (moving direction) and a space for absorbing the amount of movement of the shaft is secured, it can be easily adjusted even if the unevenness of the wall surface is large. Correspondingly, the tamper switch can be operated stably. Also, unlike the prior art, the shaft moves in the moving direction and presses the on / off button, so that a large pressing force is not directly applied to the on / off button in the on / off direction, so that the tamper switch is not easily damaged. Thereby, even if the unevenness of the wall surface to be installed is large, it is possible to cope with this with a simple structure, and the tamper switch can be easily and stably operated.

  In this invention, it is preferable that the front-end | tip of the said shaft which presses the said on-off button becomes the taper shape which becomes taper gradually. In this case, since the shaft gradually presses the on / off button as the shaft moves, the on / off button can be smoothly pressed even if the shaft moves in a direction orthogonal to the on / off direction of the on / off button.

  In addition, when the security sensor is installed on a wall surface including a recess compared to the case where the security sensor is installed on a flat wall surface, the amount of movement of the shaft that maintains the ON state is small, and the security sensor is installed on a wall surface including a projection. In this case, it is also preferable that the amount of movement of the shaft is large. Accordingly, since a space is secured in front of the moving direction so as to accommodate the shaft having a large moving amount, it is possible to more easily cope with the unevenness of the wall surface and give a width to the design.

  In the present invention, since the shaft moves in a direction (moving direction) perpendicular to the on / off direction of the on / off button and a space for absorbing the moving amount of the shaft is secured in front of the moving direction, the unevenness of the wall surface is Even if it is large, the tamper switch can be stably operated correspondingly.

It is sectional drawing which shows the crime prevention sensor with a tamper switch which concerns on one Embodiment of this invention. (A) is the elements on larger scale which show the security sensor of FIG. 1, (B) is a figure which shows the other example of a tamper switch. It is the elements on larger scale which show the security sensor of FIG. (A), (B) is the elements on larger scale which show operation | movement of the security sensor of FIG. It is sectional drawing which shows the conventional crime prevention sensor with a tamper switch.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a cross-sectional view showing a security sensor 1 with a tamper switch according to an embodiment of the present invention. The security sensor 1 includes a sensor unit 2 having a sensor unit S that detects an object based on a detection line for detecting an object, and is installed on a wall surface K having an uneven surface. A tamper switch 3 for detecting the removal of is attached. FIG. 1 shows a state immediately before the sensor unit 2 is installed on the wall surface K including the recess K1, and FIG. 2A shows a state where the sensor unit 2 is pressed against the wall surface K in the arrow direction A.

  An inner chassis 5 is provided in the center of the sensor unit 2 in FIG. 1 to divide the front and rear (left and right in the figure) boxes. For example, the sensor unit S is accommodated in a front (front) box F and a back ( A battery, a communication device, etc. (not shown) are accommodated in the rear side box B. The security sensor 1 may not have the back box B. In this example, the security sensor 1 is a wireless system including these batteries and a communication device. When the sensor unit 2 is removed from the wall surface in the wired method, it can be detected immediately by cutting the wiring, but since this detection is not possible in the wireless method, it is detected by a tamper switch. Compared with the wired system, the wireless system has the advantage of being easy to construct and requires less wiring.

  The sensor unit 2 is fixed to the wall surface K by screwing or the like (not shown) by a mounting base 4 provided on the back side of the back box B. The sensor unit S is, for example, a passive infrared (PIR) sensor that receives an infrared ray (detection line) from a human body in an outdoor detection area and detects an intruder.

  A switch body 6 of the tamper switch 3 is attached to the lower part of the inner chassis 5. As shown in the enlarged view of FIG. 1, the tamper switch 3 includes the switch body 6, an on / off button 6 a, a shaft 7 having a certain length, and a compression spring 8 attached to the shaft 7. The tamper switch 3 itself can be waterproof.

  The shaft 7 is arranged to move in a direction (movement direction) X orthogonal to the on / off direction Y of the on / off button 6a, and presses the on / off button 6a by the movement. That is, the tamper switch 3 is used sideways. The compression spring 8 applies a spring force in the moving direction X of the shaft 7 according to the unevenness of the wall surface K. Unlike the prior art, the shaft 7 moves and presses in the direction (moving direction) X perpendicular to the on / off direction Y of the on / off button 6a, so that a large pressing force is not directly applied to the on / off button 6a in the on / off direction Y. The switch 3 is not easily damaged. In addition, you may make it add the lever 11 of the shape like FIG.2 (B) which can be rockingly displaced to this on-off button 6a.

  A space 10 is provided in the movement direction X of the shaft 7 in the sensor unit 2 of FIG. 1, and the movement amount (stroke) of the shaft 7 is absorbed in the space 10 according to the unevenness of the wall surface K, and the on / off button 6a. The on / off button 6a is turned off by removing the sensor unit 2 in the movement direction X. The space 10 includes the front side of the switch body 6 that is on the on / off button 6a side (the lower side of the switch body 6 in the drawing) beyond the position of the on / off button 6a in the movement direction X of the shaft 7.

  The shaft 7 has, for example, a quadrangular columnar shaft body 7b that moves in a rectangular cylindrical shaft housing 12, and the front end portion thereof is divided into two to form a tapered portion 7a at the tip and a retaining member 9. . A square columnar bulging portion 7c in contact with the wall surface K is formed at the rear portion of the shaft body 7b. A rectangular through hole 14 is formed in the top wall 13 of the front end portion of the shaft housing 12, and the shaft 7 is prevented from rotating in the circumferential direction by passing through the through hole 14 with the rectangular columnar shaft body 7 b. ing. The rotation of the shaft 7 in the circumferential direction is not limited to the structure of the rectangular cylindrical shaft housing 12 and the rectangular columnar shaft main body 7b, and various known structures such as a shape other than a square can be used. .

  The tapered portion 7a of the shaft 7 has a tapered shape that gradually becomes tapered. The tapered portion 7a is formed on the surface (upper surface) of the shaft 7 facing the on / off button 6a. Accordingly, the tip of the shaft 7 can be smoothly pressed from the tapered portion 7a to the linear shaft body 7b along with the movement in the X direction without being caught by the on / off button 6a protruding in the Y direction. The compression spring 8 has a front end pressed against the top wall 13 and a rear end pressed against the step portion 15 between the shaft body 7b and the bulging portion 7c and compressed between the top wall 13 and the step 15. ing.

  Further, the stopper 9 provided adjacent to the tapered portion 7a at the tip of the shaft 7 can prevent the shaft 7 from being detached from the security sensor 1 before the security sensor 1 is installed on the wall surface K. . The retainer 9 may be omitted as necessary.

  The lower part of the back side of the back box B and the lower part of the mounting base 4 are opened, and the shaft 7 can project in the movement direction X from the sensor unit 2 to the wall surface K side. In this example, the shaft 7 of the tamper switch 3 is opposed to the recess K1 of the wall surface K in the movement direction X, and can project into the recess K1 through the opening 4a of the mounting base 4.

  The length of the shaft 7 is set to a length corresponding to the maximum recess assumed when the mounting surface is the recess K1 in the wall surface K. The longest shaft length is required at the maximum concave, and at this time, the tamper switch 3 can be turned on by causing the shaft body 7b of the shaft 7 to reach the on / off button 6a.

  The size of the space 10 corresponds to the maximum protrusion assumed when the mounting surface of the shaft 7 is the protrusion K2 (FIG. 3). At this time, the amount of movement of the shaft 7 in the moving direction X is the largest, and even in this case, a space 10 for storing the moved shaft 7 is secured.

  When the sensor unit 2 is pressed against the wall surface K in the arrow direction A in FIG. 1, the taper portion 7a of the shaft starts to press the on / off button 6a, and as shown in FIG. 2 (A), the tamper switch near the end of the taper portion 7a. 3 is turned on. The on state is continued in the linear shaft body 7b.

  That is, in this example, the on / off button Ya and the moving direction X of the shaft 7 are orthogonal to each other, instead of pressing the on / off button so that the shaft moving direction matches the on / off direction of the on / off button as in the prior art. As the shaft 7 moves from the taper portion 7a to the shaft body 7b on the on / off button 6a in the moving direction X, it is turned on by pressing it. A space 10 is provided in front of the moving direction X of the shaft 7. Thus, conventionally, the switch body is arranged in front of the moving direction of the shaft and there is a certain limit in the amount of movement of the shaft, but in the present invention, the switch body 6 is in front of the moving direction X of the shaft 7. Since the space 10 is arranged, the movement amount of the shaft 7 can be absorbed in the space 10, and the security sensor 1 with a tamper switch can be easily attached to the wall surface K having various sizes of irregularities. Can do.

  FIG. 3 shows a state in which the shaft 7 of the tamper switch 3 is opposed to the convex portion K2 of the wall surface K in the movement direction X, and the convex portion K2 of this mounting surface is protected through the opening 4a of the mounting base 4. Projecting to the sensor 1 side. Along with this, the shaft 7 is largely moved in the movement direction X (leftward in the figure) in the space 10 as compared with FIG. Other configurations are the same as those in FIG.

  FIG. 4 is a partially enlarged view showing the operation of the security sensor 1 with a tamper switch. Compared with the case where the security sensor 1 is installed on a flat wall surface, the shaft 7 is smaller in the moving direction Y in the space 10 when installed on the wall surface K including the recess K1 as shown in FIG. It moves (to the right in the figure), and the amount of movement of the shaft 7 that keeps the ON state becomes small (L1). When installed on the wall surface K including the convex portion K2 as shown in (B), the shaft 7 has moved greatly in the movement direction X (to the left in the figure) in the space 10 and kept on. The amount of movement of the shaft 7 to be increased is increased (L2).

  Thus, by setting the shaft length to correspond to the maximum recess of the recess K1, and providing the space 10 corresponding to the maximum protrusion of the protrusion K2 in front of the movement direction X of the shaft 7, the protrusion K2 Since it is possible to store the shaft 7 having a different moving amount in the space 10 in accordance with the size of the shaft, it is possible to escape (absorb) the forward protruding portion of the shaft 7 after the movement into the space 10. The tamper switch 3 can be easily and stably operated corresponding to the unevenness of the wall surface K.

  In this case, when the sensor unit 2 is removed from the wall surface K in the direction opposite to the arrow direction A in FIG. 1, the removal amount in the movement direction X in FIG. 4 (A) is greater in (A) than in (B). Since the ON state by the shaft 7 is short, it becomes smaller than the removal amount in the moving direction X in (B). That is, in (A), the sensor unit 2 is pulled out in a moving direction X (leftward in the figure) smaller than (B) and is removed.

  Thus, according to the present invention, the shaft having a certain length is arranged so as to move in a direction orthogonal to the on / off direction of the on / off button of the tamper switch. A space to be included is provided, and the amount of movement of the shaft is absorbed in the space according to the unevenness of the wall surface, and the ON state of the ON / OFF button is maintained. Therefore, since the shaft moves in a direction perpendicular to the on / off direction of the on / off button (moving direction) and a space for absorbing the amount of movement of the shaft is secured, it can be easily adjusted even if the unevenness of the wall surface is large. Correspondingly, the tamper switch can be operated stably. Also, unlike the prior art, the shaft moves in the moving direction and presses the on / off button, so that a large pressing force is not directly applied to the on / off button, so that the tamper switch is not easily damaged. Thereby, even if the unevenness of the wall surface to be installed is large, it is possible to cope with this with a simple structure, and the tamper switch can be easily operated.

  In the above embodiment, the sensor unit uses a passive infrared (PIR) sensor, but an active infrared (AIR) sensor, a microwave (MW) sensor, or the like may be used.

  In the above embodiment, the compression spring 8 is attached to the shaft 7 and arranged on the outer circumference of the shaft. Instead, when the security sensor 1 does not have the back box B, it is arranged in front of the shaft 7. May be. Accordingly, it is possible to cope with a case where the distance between the tamper switch 3 and the wall surface K is shortened by the absence of the back box B.

  The present invention is not limited to the above-described embodiment, and various additions, modifications, or deletions can be made without departing from the gist of the present invention. Therefore, such a thing is also included in the scope of the present invention.

1: Security sensor with tamper switch 2: Sensor unit 3: Tamper switch 6: Switch body 6a: On / off button 7: Shaft 7a: Tapered portion 7b: Shaft body 8: Compression spring 10: Space K: Wall surface S: Sensor portion X: Shaft moving direction Y: ON / OFF button ON / OFF direction

Claims (3)

A sensor unit having a sensor unit for detecting an object based on a detection line for object detection is a security sensor installed on a wall surface behind the sensor unit,
A tamper switch that detects removal from the wall surface is attached to the sensor unit,
The tamper switch is arranged to move in a direction orthogonal to an on / off button, an on / off button, an on / off direction of the on / off button, and a shaft having a fixed length for pressing the on / off button by the movement, and the shaft And a compression spring that adds a spring force according to the irregularities of the wall surface in the moving direction of the shaft,
In the sensor unit, a space including the front beyond the on / off button position of the switch body in the movement direction of the shaft is provided, and the movement amount of the shaft is absorbed in the space according to the unevenness of the wall surface. A security sensor with a tamper switch that keeps the on state of the on / off button and the on / off button is turned off by removing the sensor unit in the moving direction. In claim 1,
A security sensor with a tamper switch, wherein a tip end of the shaft that presses the on / off button is tapered. In claim 1,
Compared to the case where the security sensor is installed on a flat wall surface, when installed on a wall surface including a recess, the amount of movement of the shaft that maintains the ON state is small, and the security sensor is installed on a wall surface including a projection. In some cases, the tamper-switch-provided security sensor has a large movement amount of the shaft.

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