JP3489915B2 - Detection device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a detection device for detecting an intruder.

[0002]

2. Description of the Related Art FIG. 2 shows the outline of an example of a detection device. The illustrated detection device 1 includes a cover 2 that protects the built-in detection unit, a chassis 3 that holds the detection unit, and a mounting substrate 4 for mounting the detection device 1 on a ceiling or a wall. FIG. 7 shows a detection unit housed in the detection device 1. The detector 5 is attached to the frame 8 so that the pyroelectric element 6 and the concave mirror 7 face each other. Further, shafts 9 are provided at both ends of the frame 8. This shaft 9 is the chassis 3
It is rotatably held by the holder 10 fixed to the. Then, by adjusting the rotation angle of the shaft 9, the orientation of the detection unit 5 changes, and the monitoring area of the detection device 1 is adjusted.

The monitoring area of the detection device 1 will be described with reference to FIG. Since the monitoring angle A of the detector 5 is constant,
The width of the monitoring range differs depending on whether the monitoring area is set far or near. (A) shows the case where the monitoring area is set far, and the monitoring range 21 at this time is wide. (B) shows the case where the monitoring area is set close, and the monitoring range 22 at this time is narrowed.

[0004]

The detection device 1 determines the presence or absence of an intruder based on the amount of infrared energy within the monitoring range. Therefore, as shown in FIG. 8A, when the monitoring area is set far and the monitoring range 21 is wide, the ratio of the intruding object to the monitoring range is small. Therefore, a small animal 23 such as a cat or a mouse is not detected even if it enters the detection range, but a human occupies a large proportion of the detection range 11 and is detected as an intruder.

On the other hand, as shown in FIG. 8B, when the monitoring area is set close and the monitoring range 22 is narrow,
The ratio of intruders in the surveillance range 22 becomes large. Therefore, even the small animal 23 may be detected as an intruder and may give a false alarm. As described above, in the conventional detection device, when the monitoring area is set close to the detection device, the detection sensitivity of the detection device is increased, and a small animal may be erroneously detected as a human intruder. On the other hand, if the detection sensitivity is set as a standard when the monitoring area is set close, the detection sensitivity of the detection device is lowered when the monitoring area is set far, and an intruder may not be detected.

It is an object of the present invention to enable a detection device for detecting an intruder to keep the detection sensitivity substantially constant even if the setting of the monitoring area changes.

[0007]

In order to achieve the above-mentioned object, the present invention comprises a detection means for detecting infrared energy, and
Infrared energy incident from the monitoring area is reflected and condensed
In a detection device comprising a condensing means for making the detecting means incident , the condensing means is made incident from the monitoring region.
The infrared energy and the condensing means reflect the detection element.
The above-mentioned detection is performed so as to transmit infrared energy that is collected and collected.
It is arranged so that it can be inserted between the knowing means and the light collecting means.
In some areas, the amount of infrared energy transmitted varies.
To adjust the amount of infrared energy transmitted
An energy variable means is provided.

The detecting device sets the monitoring area of the detecting device by changing the directions of the detecting means and the condensing means. At the same time, the position of the energy varying means is changed with respect to the path through which the infrared energy condensed from the condensing means to the detecting means passes. For the above reason, the detection sensitivity of the detection device changes depending on the monitoring area. Further, the amount of infrared energy transmitted from the light collecting means to the detecting means is changed depending on the position of the energy varying means. The detection device of the present invention makes it possible to keep the detection sensitivity substantially constant no matter where the monitoring region is set, by making the change in the detection sensitivity uniform due to the change in the transmission amount. Therefore, a small animal will not be erroneously detected as an intruder or will not be overlooked.

Further, according to the present invention, the energy varying means may be fixed, and the condensing means and the detecting means may be attached to a common movable frame. Thus, when the monitoring area of the detection device is set by adjusting the direction of the frame, the amount of transmission of the energy changing means with respect to infrared energy is also adjusted by the direction of the frame.
Therefore, according to this detection device, the detection sensitivity can be adjusted at the same time only by setting the monitoring region by adjusting the direction of the frame.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. FIG. 2 shows the outer shape of the detection device. The illustrated detection device 1 includes a cover 2 that protects the detection part, a chassis 3 that holds the detection part, and a mounting substrate 4 for mounting the detection device on a ceiling or a wall.

FIG. 1 shows the detection unit 5 housed in the detection device 1. The detection unit 5 is composed of a pyroelectric element 6 and a concave mirror 7 which are attached to face a common frame 8 and a filter 11 which is attached to a filter fixing plate 12. Shafts 9 are provided at both ends of the frame 8. This axis 9
Is rotatably held by a holder 10 fixed to the chassis 3. Then, by adjusting the rotation angle of the shaft 9, the orientation of the detection unit 5 is changed, and the monitoring area of the detection device 1 is set. The filter 11 is thicker on the filter fixing plate 12 side and gradually thinner toward the tip. That is, the filter 11 has a large amount of infrared energy transmitted on the tip side thereof, and has a smaller amount of infrared energy transmitted toward the filter fixing plate 12 side.

By adjusting the rotational position of the frame 8, the directions of the pyroelectric element 6 and the concave mirror 7 are changed and the monitoring area is set, as shown in FIGS. At the same time, the position of the filter 11 inserted in the infrared energy path from the concave mirror 7 to the pyroelectric element 6 changes. Figure 3
(A) shows a state in which the monitoring area is set to the farthest distance of the detection device 1. In this state, from the concave mirror 7 to the pyroelectric element 6
The infrared energy path up to is set at a position off the filter 11. Therefore, the infrared energy reflected and condensed from the concave mirror 7 is input to the pyroelectric element without being cut.

FIG. 3B shows a state in which the monitoring area is set at the intermediate position. In this state, the tip portion of the filter 11 is inserted into the infrared energy path from the concave mirror 7 to the pyroelectric element 6. The infrared energy reflected and condensed from the concave mirror 7 is attenuated by the filter 11. FIG. 3C shows a state in which the monitoring area is set to the shortest distance. In this state, the filter 11 is provided in the infrared energy path from the concave mirror 7 to the pyroelectric element 6.
The thicker part will be inserted.

As is clear from the above figures, the detection sensitivity of the detection device 1 increases as the monitoring area is set from a long distance to a short distance. On the other hand, when the setting of the monitoring area changes from a long distance to a short distance, the filter 11 is inserted, and the thickness of the inserted portion becomes thicker. That is, as the detection sensitivity changes from a low place to a high place, the amount of infrared energy transmitted decreases.

Therefore, the change in the detection sensitivity due to the change in the monitoring area is canceled by the change in the amount of infrared energy transmitted by the filter 11, and the detection sensitivity of the detection device 1 can be kept substantially constant. In FIG. 3, the filter 11 is arranged substantially at the midpoint between the pyroelectric element 6 and the concave mirror 7.
By arranging 1 toward the concave mirror 7 side, infrared energy from an intruder reaches the concave mirror 7 through the filter 11, is condensed and reflected when the monitoring area is at an intermediate position or at a short distance. Further, the light is incident on the pyroelectric element 6 again via the filter 11. Therefore, the infrared energy is transmitted twice to the filter 1 before entering the pyroelectric element 6.
Therefore, the attenuation of infrared energy can be increased without increasing the thickness of the filter 11.

(Other Embodiments) The present invention can be modified in various ways as described below. In the example described above, the filter 11 is fixed, and it is only necessary to adjust the position of the frame 8 to set the monitoring area and filter 11.
The detection sensitivities are equalized by the same time. However, if the filter 11 is movable,
It is also possible to adjust the amount of transmitted infrared energy independently of the setting of the monitoring area.

The filter can also be variously modified as described below. The filters having different thicknesses can be formed by integral molding, but by laminating a plurality of filters, it is possible to form the filters 13 having different thicknesses depending on places. Figure 4
Shows a cross section of the filter 13 in which a plurality of filters 13-1, 13-2, 13-3 are laminated. Also in this case, the thickness of the filter can be gradually changed by tapering the tip of each filter.

The filter can be changed by adjusting the amount of coloring instead of changing the amount of infrared energy transmitted depending on the thickness. That is, the filter is colored with a color that absorbs or reflects infrared energy, and as shown in FIG.
It is possible to provide -1 and provide colored portions 14-2 and 14-3 whose color becomes darker as the distance from the tip portion increases. Also in this example, the color change can be gradually changed.

Further, the surface of the filter may be processed to have minute irregularities so that infrared energy is reflected to change the amount of transmission. In this case, as shown in FIG. 6, the number of irregularities 16 is small at the tip portion of the filter 15 and is large at the portion away from the tip, thereby changing the amount of transmission. Furthermore, the sensing device
It may be used by mounting it vertically on a wall. Also in this case, the filter may be set such that the transmission amount is large when the monitoring region is set far, and the transmission amount is small when the monitoring region is set close.

[0020]

According to the present invention, in a detection device for detecting an intruder, the detection sensitivity can be kept substantially constant even if the setting of the monitoring area changes.

[Brief description of drawings]

FIG. 1 is a perspective view showing a detection unit in an embodiment of a detection device of the present invention.

FIG. 2 is a perspective view showing an outer shape of an embodiment of the present invention and a conventional detection device.

FIG. 3 is a diagram for explaining a positional relationship between a monitoring area and a filter of the detection device in FIG.

FIG. 4 is a first modification of the filter used in the detection unit of FIG.

5 is a second modification of the filter used in the detection unit of FIG.

6 is a third modification of the filter used in the detection unit of FIG.

FIG. 7 is a perspective view showing a detection unit of a conventional detection device.

8 is a diagram showing a relationship between a monitoring area and detection sensitivity in the apparatus of FIG.

[Explanation of symbols]

1 ... Detection device 2 ... Cover 3 ... Chassis 4 ... Mounting board 5 ... Detector 6 ... Pyroelectric element 7 ... Concave mirror 8 ... Frame 9 ... Axis 10 ... Holder 11 ... Filter 12 ... Filter fixing plate 13, 14, 15 ... Filter

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Claims (2)

(57) [Claims] 1. A detection means for detecting infrared energy, and a reflection and collection of infrared energy incident from a monitoring area.
And a condensing means for making the incident light incident on the detecting means, the infrared energy entering the condensing means from the monitoring region.
And the light is condensed and reflected on the sensing element from the light collecting means.
It is insertably disposed between the detecting means and the focusing means so as to transmit infrared energy, by having an amount of transmission different portions of the infrared energy by the location, the energy for adjusting the amount of transmitted infrared energy A detecting device comprising: a variable unit. 2. Detecting means for detecting infrared energy and reflecting and condensing infrared energy incident from a monitoring area
And a light condensing means for making the light incident on the detecting means, the detection means and the light condensing means are mounted, and the detecting means is monitored by moving the detecting means and the light condensing means. A monitoring range adjusting means for adjusting a range, and a fixedly arranged position that can be inserted between the detecting means and the light condensing means, and a portion having a different amount of transmission of infrared energy depending on a location, the monitoring range When the detecting means and the light collecting means are moved to predetermined positions by the adjusting means
Infrared energy entering the light collecting means from the monitoring area.
Energy and reflected light from the light collecting means to the sensing element
And a variable energy unit that adjusts the amount of infrared energy that is condensed by the detecting unit by transmitting the infrared energy that is generated.