KR200222937Y1 - infrared sensor - Google Patents

Abstract

The present invention relates to an infrared detector, comprising: a transmitter configured to generate infrared rays of a pulse waveform having a predetermined period to emit to the outside; and an infrared detector comprising one set of a receiver configured to receive infrared rays emitted from the transmitter. It further includes an auxiliary light receiving unit for detecting infrared light emitted from the light emitting unit other than the light emitting unit to detect the infrared light by a separate light emitter or a light emitter of another boundary area, thereby preventing overlapping or other boundary areas of the separate light emitter. The present invention relates to an infrared detector for preventing interference by a light emitter.

Description

Infrared sensor

The present invention relates to an infrared detector, and more particularly, to an infrared detector composed of one set of a light emitter and a light receiver, and more particularly to an infrared detector for detecting infrared rays introduced by a separate transmitter in addition to the one set of emitters.

Infrared detector is composed of one light emitter and one light receiver and generates an alarm when the light is blocked between the light emitter and the light receiver, and is used to prevent theft and manage entry / exit. It is a device that is installed inside and outside the protected area to notify in advance of unexpected entry or exit of people or goods to prevent theft or accidents caused by it.

FIG. 1 is a diagram illustrating an installation of such an infrared detector. Referring to FIG. 1, the infrared detector generates a infrared ray of a pulse waveform having a predetermined period and emits the infrared rays to the outside. After receiving the infrared rays emitted through the light receiving unit 20 to determine whether the person or the object is approached by the amount of light received, as shown in Figure 1, the light transmitting unit 10 and the light receiving unit 20 optically Install to face each other.

When the infrared detector installed as described above passes an unexpected person or an arbitrary object between the light transmitting unit 10 and the light receiving unit 20, the infrared detector detects this by the amount of infrared light received by the light receiving unit 20 to generate an alarm. Let's do it.

FIG. 2 is a diagram illustrating an internal structure of an optical unit of a general infrared detector. Referring to FIG. 2, the optical unit inside the light transmitting unit 10 and the light receiving unit 20 is as follows.

First, in the case of the light transmitting unit 10, a light transmitting element 11 for generating an infrared ray to be emitted to the light receiving unit 20, and a light transmitting lens 13 for diffusing the infrared light generated by the light transmitting element 11 at a predetermined direction angle And optical filters 12 and 14 installed at the front ends of the light transmitting element 11 and the light transmitting lens 13 to filter further wavelengths including visible light so as to use only necessary infrared rays. In this case, the light receiving lens 23 collects the infrared rays emitted from the light transmitting part 10 at a predetermined directivity angle, the light receiving element 21 receiving the infrared light collected through the light receiving lens 23, and the light receiving lens. (23) and optical filters 22 and 24 which make it possible to use only the infrared rays necessary in front of the light receiving element 21.

In general, the infrared detector is a pulse wave infrared light having a certain period in order to be able to distinguish the infrared light generated through the light emitting unit 10 and all the light containing the infrared light, such as the sun, the light of the car in the light receiving unit 20. To this end, as shown in FIG. 2, a light-transmitting and receiving lens 13 and 23 having a directing angle and a plurality of optical filters 12, 14, 22, and 24 are installed inside the optical unit of the infrared detector. In addition, the light emitting unit 10 selects and emits the infrared rays necessary by the optical filters installed in the light transmitting unit 10 and the light receiving unit 20, and the light receiving unit 20 filters the infrared rays to receive the light.

On the other hand, Figure 3 is an exemplary view showing the light transmission and reception range of the general infrared detector, as shown in FIG. 2, the infrared and the light receiving and receiving lens 13, 23, the boundary area is marked to actually allow the infrared detector to perform its function when it is radiated or condensed with a directivity angle.

Referring to FIG. 3, the boundary area for allowing the infrared detector to perform its function includes a range B where infrared light is emitted by the light transmitting unit 10 and a range A where infrared light is collected by the light receiving unit 20. 3 overlaps the region C, and the region C is divided into two parts. Thus, the boundary region is divided into two parts. In the case of an infrared sensor installed outdoors, the light emitting part 10 and the light receiving part ( 20) It is to ignore the temporary shading by the leaves and other foreign matter. That is, when only one region of the boundary region C divided into two parts is shielded, the light receiving unit 20 is temporarily shielded by fallen leaves or other foreign matter, rather than shielding by an external intruder or an arbitrary object. Judgment does not sound an alarm.

However, in the case of an infrared detector installed indoors to distinguish a protection area in an office or a factory, one boundary area may be used without dividing the boundary area.

4 is an internal block diagram of the light receiving unit of the infrared detector. Referring to FIG. 4, the light receiving unit of the infrared detector is a light receiver 41, an amplifier 42, a light shielding discriminator 43, and a light shielding time comparator 44. ) And an alarm unit 45, wherein the light receiver 41 receives infrared rays generated from the outside with a predetermined directivity angle, and the amplifier 42 receives the infrared light received through the light receiver 41. Amplify and output the received waveform.

On the other hand, the light-shielding discriminator 43 stores a predetermined light receiving value, receives a light receiving waveform output from the amplifier 42 at a predetermined period, measures the light receiving amount, and then compares the light receiving amount with the preset setting value. When the amount of received light is less than the preset value, it is determined that the light is blocked, and as a result, a signal indicating that the light is blocked is transmitted to the light blocking time comparator 44.

Then, the shading time comparator 44 sets a reference shading time for informing the shading to the outside in advance, counts the shading time, and when the shading time is longer than a preset setting value by an unexpected person or object. It is determined that shading has occurred, and generates an alarm signal, and the alarm 45 receives the alarm signal to generate an alarm to the outside.

FIG. 5 is a flowchart for detecting an approach of a person or an object in a light receiving unit of a general infrared detector. Referring to FIG. 5, in the general light receiving unit, a light receiving amount a of light received through the light receiver 41 is calculated (s501). Then, the calculated value (a) is compared with the preset light received value (b) (s502), and if the calculated value (a) is smaller than the preset light received value (b) (s503), an unexpected person or It is determined that light transmitted from the light transmitting part by any object is shielded.

Accordingly, after counting the time c from the time of blocking the light (s504), the counting light blocking time (c) is compared with the preset setting value (d) (s505) to set the light shielding time (c). If it is longer than the set value (d), it is determined that the boundary area is randomly released by an arbitrary person or object, and an alarm is generated (S506).

The conventional infrared detector emits light by the separate transmitter if a person who wants to invade the area where the infrared detector is installed or a person having another malicious purpose installs a separate transmitter between the conventional transmitter and the receiver. Since the light receiving unit continuously collects the infrared rays, there is a disadvantage in that it does not detect that light is shielded between the existing light transmitting unit and the light receiving unit.

That is, as shown in FIG. 6A, when a separate transmitter 300 is installed at a different angle from the transmitter 100 between the transmitter 100 and the receiver 200 installed in pairs, the receiver ( 200 collects all the infrared rays emitted by the plurality of light transmitters 100 and 300. Therefore, even if the area D between the conventional light emitter 100 and the separate light emitter 300 is blocked by an arbitrary person or a molten material, since there is infrared light received by the separate light emitter 300, It will not be detected.

Therefore, in the conventional infrared detector, a person having a malicious purpose may install a separate transmitter 300 in a region where the infrared detector is installed, and a double projection signal to the receiver 200 by the transmitter 300. When generating a, it may be freely invade or travel through the area (D) that does not detect the light shielding, the infrared sensor has a disadvantage that it can not prevent this.

In addition, there is a disadvantage in that it is not possible to detect that the boundary region of the infrared detector is blocked by the optical interference by infrared rays emitted from a transmitter installed in another boundary region.

That is, as shown in FIG. 6B, when a plurality of infrared detectors forming one set of the transmitter / receiver are installed in an adjacent area, the first receiver 200 forming one set with the first transmitter 100 is the second receiver. By receiving the infrared rays emitted from the second light emitter 300 paired with the 400, there was a disadvantage in that it is not possible to detect that the boundary area (E) is blocked.

The present invention has been made to solve the above disadvantages, consisting of a light emitting unit for generating infrared radiation of a pulse wave having a predetermined period to the outside, and a pair of light receiving unit for receiving the infrared radiation emitted from the light transmitting unit. An infrared detector, comprising: an auxiliary receiver having a larger directivity than a directivity of the light receiver, and providing an infrared detector capable of detecting infrared rays entering from an angle different from that of the transmitter. do.

According to the present invention, the infrared detector further includes an auxiliary light receiving unit that is different from the light transmitting unit in a horizontal position, and the infrared light emitted from the light emitter of a separate light emitter or another boundary region by the light receiving level difference between the light receiving unit and the main light receiving unit. It is a second object to provide an infrared detector which makes it possible to detect.

The present invention provides an infrared detector in the infrared detector, by installing a plurality of light receiving elements in the light receiving unit to detect the infrared radiation emitted from a separate light emitter or a light emitter in another boundary region by the light receiving level difference between the light receiving elements. It is a third purpose to do it.

The light receiving part of the infrared detector of the present invention for achieving the first object has a first light receiving means for receiving external light with the same light beam angle as the light beam angle of the light transmitting portion, and a direction larger than that of the first light receiving means. A second light receiving means for generating an alarm generating signal when an arbitrary light is received by operating at an angle; and determining whether the light is blocked by the amount of light received through the first light receiving means, and outputting an alarm generating signal when light is blocked And an alarm means for generating an alarm by an alarm generation signal generated by said light shielding discrimination means or said second light receiving means.

In addition, the light-receiving portion of the infrared detector of the present invention for achieving the second object, the first light-receiving means for receiving the light at the same height as the light-emitting means in the light-transmitting unit having the same directivity angle as that of the light-emitting means; Second light receiving means which is provided at the upper end or the lower end of the first light receiving means to receive light with the same direction angle as the light receiving means, and whether or not the light shielding by the amount of light received through the first light receiving means Light blocking discrimination means for outputting an alarm occurrence signal at light shielding, a first light receiving level indicating an amount of light received by the first light receiving means, and a second light receiving level indicating an amount of light received by the second light receiving means; In comparison, the light-receiving level comparing means for outputting an alarm signal when the difference between the first and second light-receiving level is a predetermined value or more, the light-shielding discriminating means or Characterized in that it comprises an alarm means for generating an alarm by the alarm generation signal generated in the light receiving level comparison means.

On the other hand, the light receiving unit of the infrared detector of the present invention for achieving the third object includes a first and a second light receiving element, the light receiving unit for receiving the light emitted from the light transmitting part by the same angle of directivity as the light transmitting portion Means for determining whether the light is blocked by the amount of light received by the first and second light receiving elements of the light receiving means and outputting an alarm generation signal upon light shielding; and receiving by the first light receiving element of the light receiving means. By comparing the first light receiving level indicating the amount of light received and the second light receiving level indicating the amount of light received by the second light receiving element of the light receiving means, the difference between the first and second light receiving levels is equal to or greater than a predetermined value. A light receiving level comparing means for outputting an alarm generating signal when the alarm is generated; and an alarming means for generating an alarm by the alarm generating signal generated by the light blocking discriminating means or the light receiving level comparing means. Characterized in that configured.

1 is an installation example of a general infrared detector,

2 is an internal structure diagram of an optical unit of a general infrared detector;

3 is an exemplary view showing a light transmission and reception range of a general infrared detector;

4 is an internal block diagram of a light receiving unit of a general infrared detector;

5 is a flowchart for detecting the approach of a person or an object in a light receiving unit of a general infrared detector;

6 is an exemplary view showing a state in which overlapping projection by a separate light emitting unit is generated in a general infrared detector;

7 is an operation explanatory diagram of an infrared detector according to the first embodiment of the present invention;

8 is an internal block diagram of a light receiving unit of the infrared detector according to the first embodiment of the present invention;

9 is a configuration diagram of a light receiving unit of an infrared detector according to a second embodiment of the present invention;

10 is an operation explanatory diagram of an infrared detector according to a second embodiment of the present invention;

11 is an internal block diagram of a light receiving unit of an infrared detector according to a second embodiment of the present invention;

12 is an operation explanatory diagram of an infrared detector according to a third embodiment of the present invention;

13 is an internal block diagram of a light receiving unit of an infrared detector according to a third embodiment of the present invention;

<Explanation of symbols for main parts of the drawings>

100, 300: light transmitting part 200, 400, 500, 600: light receiving part

81, 111: first receiver 82, 112: first amplifier

83, 113, 136: light shielding discriminator 84, 114, 137: light shielding time comparator

85, 115, 138: alarm 86, 116: second receiver

87, 117: second amplifier 118, 139: light receiving level comparator

130: light receiver 131: first light receiving element

132: second light receiving element 134: first amplifier

135: second amplifier

Hereinafter, with reference to the accompanying drawings, it will be described in detail the present invention through an embodiment of the present invention.

7 is an explanatory view of the operation of the infrared detector according to the first embodiment of the present invention. Referring to FIG. 7, the infrared detector according to the first embodiment of the present invention may include a light transmitting unit 100 and a light receiving unit 200. The general infrared detector configured as one set further includes a second light receiver 400 for receiving external light with a light beam angle β larger than the light beam angle α of the light receiver 200.

Therefore, in the infrared detector according to the first embodiment of the present invention, a separate light emitting unit 300 is installed in the boundary area of the infrared detector, and the second light receiving unit emits infrared rays emitted from the separate light emitting unit 300. By detecting at 400, the malfunction of the infrared detector can be prevented.

That is, by generating an alarm when any light is received through the second light receiver 400, the user is notified that abnormal light is received by the light receiver 200.

FIG. 8 is an internal block diagram of a light receiving unit of the infrared detector according to the first embodiment of the present invention. Referring to FIG. 8, the light receiving unit of the infrared detector according to the first embodiment of the present invention is equal to the orientation angle of the light transmitting unit. A first receiver 81 for receiving external light with a directivity angle, a first amplifier 82 for amplifying the light received through the first receiver 81 to a predetermined size, and the first number The second receiver 86 for receiving external light with a direction angle larger than that of the madness 81 and the light received through the second receiver 86 are amplified to a predetermined size. If it is equal to or more than the predetermined value, the second light receiver 87 for generating an alarm generation signal and a light shielding discriminator for discriminating whether or not light is blocked by the amount of light received through the first light receiver 86 ( 83) and the light shielding time when the light shielding discriminator 83 determines that the light is blocked. Alarm by the alarm generation signal generated by the shading time comparator 84 and the shading time comparator 84 or the second amplifier 87 when the shading time becomes longer than a predetermined time. It consists of the alarm 85 which makes it generate.

9 is a block diagram of a light receiving unit of an infrared detector according to a second embodiment of the present invention. Referring to FIG. 9, the light receiving unit 500 of the infrared detector according to the second embodiment of the present invention has a plurality of light receiving elements. It includes a conventional light receiver 520 for receiving external light, and an auxiliary light receiver 510 installed on top of the existing light receiver 520 for preventing malfunction of the infrared detector.

At this time, the auxiliary receiver 510 is installed with the same optical axis as the conventional receiver 520, and the installation position of the auxiliary receiver 520 is the upper end of the existing receiver 520 as shown in FIG. The present invention is not limited thereto, and the existing light receiver 520 may be installed at any position of the lower side or the left side or the right side.

10 is an explanatory view of the operation of the infrared detector according to the second embodiment of the present invention. Referring to FIG. 10, the infrared detector according to the second embodiment of the present invention further includes an auxiliary light receiving unit having a horizontal position different from that of the light transmitting unit. It is to be able to detect the infrared radiation emitted from the separate light emitter or the light emitter of the other boundary area by the difference in light reception level of the auxiliary light receiving unit and the main light receiving unit.

That is, as shown in FIG. 10, in addition to the light emitting unit 500 forming one set with the light receiving unit 500 of the present invention, when a separate light transmitting unit 300 is installed, the light E emitted from the light transmitting unit 100 is provided. Is uniformly introduced into the existing light receiver 520 and the auxiliary light receiver 510, but the light F emitted from the separately installed light emitter 300 is mainly limited to the conventional light receiver 520 due to the characteristics of the light emission angle. It is introduced to the auxiliary receiver 510 is not introduced or only a small amount of light is introduced. Accordingly, the second embodiment of the present invention utilizes such characteristics, and indicates the level indicating the amount of light introduced into the existing light receiver 520 and the level indicating the amount of light introduced into the auxiliary receiver 510. In comparison, an alarm is generated when the level difference is greater than or equal to a predetermined value, thereby informing the user that abnormal light is received by the light receiving unit 200.

FIG. 11 is an internal block diagram of the light receiving unit of the infrared detector according to the second embodiment of the present invention. Referring to FIG. 11, the light receiving unit of the infrared detector according to the second embodiment of the present invention may include first and second numbers. It consists of the madness 111 and 116, the first and second amplifiers 112 and 117, the light shielding discriminator 113, the light shielding time comparator 114, the alarm 115 and the light receiving level comparator 118.

The first light receiver 111 receives the light at the same height as the light transmission means in the light transmission unit at the same angle of directivity as the light projection means, and the second light receiver 116 is the first light receiver 111. Installed at an upper end or a lower end of the receiver) and receives light having the same direction angle as that of the light transmitting means, and the first and second amplifiers 112 and 117 are configured as the first and second receivers 111 and 116. It amplifies the amount of light input through a certain size and outputs it.

Meanwhile, the light blocking unit 113 and the light blocking time comparator 114 determine whether the light is blocked by the amount of light received through the first light receiver 111, as in the conventional case. An alarm generation signal is output through the light shielding time comparator 114.

In addition, the light receiving level comparator 118 receives a first light receiving level indicating the amount of light received by the first light receiver 111 and a second light receiving indicating the amount of light received by the second light receiver 116. By comparing the levels, when the difference between the first and second light receiving level is a predetermined value or more outputs an alarm generation signal, the alarm 115 is in the light blocking time comparator 114 or the light receiving level comparator 118 An alarm is generated by the generated alarm generation signal.

At this time, the light receiving level comparator 118 presets a limit of an error between the first and second levels due to a system error, and compares the first and second levels so that the difference between the levels is the limit of the error. If an error occurs, output an alarm signal.

12 is an explanatory view of the operation of the infrared detector according to the third embodiment of the present invention. Referring to FIG. 12, in the third embodiment of the present invention, a plurality of light receiving elements are installed in the light receiving unit to receive light levels between the light receiving elements. In order to be able to detect the infrared radiation emitted by a separate emitter or a transmitter in another boundary area by the car.

That is, in the infrared detector composed of one set of the light transmitting / receiving units 100 and 600, as shown in FIG. 12, when one additional light transmitting unit 300 is installed, a plurality of light receiving sensors constituting the light receiving unit 600 ( Since the received amount of light received by each of the 610 and 620 is different from each other, the device detects this and informs the malfunction of the infrared detector.

Referring to FIG. 12, in the case of the infrared ray E emitted from the light transmitting unit 100 paired with the light receiving unit 600, the plurality of light receiving sensors 610 and 620 are uniformly introduced, but the separately provided light transmitting unit The light G emitted from the 300 is introduced into the light receiving sensor closer to the light emitting part 300 in the vertical direction among the plurality of light receiving sensors due to the property of the light transmitting angle.

In the example of FIG. 12, since the light transmitting part 300 is installed at the lower part of the light receiving part 600, the light flowing into the light receiving sensor 620 is lower than the amount of light flowing into the light receiving sensor 610. More quantity

Accordingly, by measuring the amount of light flowing into the plurality of light receiving sensors 610 and 620, respectively, and comparing the levels, it is possible to determine whether abnormal light is introduced.

FIG. 13 is an internal block diagram illustrating a light receiving unit of an infrared detector according to a third embodiment of the present invention. Referring to FIG. 13, the light receiving unit of the infrared detector according to the third embodiment of the present invention includes a plurality of light receiving elements 131, 132 is composed of a light receiver 130, the first and second amplifiers 134, 135, light shielding discriminator 136, light shielding time comparator 137, alarm 138 and light receiving level comparator 139 do.

The light receiver 130 receives and outputs the light emitted from the light emitting unit through the plurality of light receiving elements, that is, the first and second light receiving elements 131 and 132, which operate at the same angle as the directing angle of the light transmitting unit. The first amplifier 134 amplifies and outputs the received amount of light received through the first light receiving element 131, and the second amplifier 135 amplifies and outputs the received amount of light received through the second light receiving element 132. do.

Then, the light shielding discriminator 136 receives the output values of the first and second amplifiers 134 and 135, compares the sum of the two values with a reference value, and determines whether the light is blocked. The time comparator 137 outputs an alarm generation signal when the light blocking time becomes longer than a predetermined time when it is determined as light shielding by the light shielding discriminator 136.

On the other hand, the light receiving level comparator 139 compares the light receiving levels output from the first and second amplifiers 134 and 135 to compare the amount of light received by the first light receiving device 131 with the second light receiving device 132. ), If the difference in the amount of light received by the sensor exceeds a certain value, an alarm signal is output.

The alarm 138 generates an alarm in response to the alarm generation signal output from the light blocking time comparator 137 or the light receiving level comparator 139.

At this time, the light receiving level comparator 139 sets a limit of an error for a difference in light receiving amount between the light receiving elements 131 and 132 due to a system error in advance, and the difference in light receiving amount is greater than or equal to the limit of the error. If so, output the alarm signal.

In the infrared detector of the present invention as described above, in the infrared detector consisting of a light emitting unit for generating a radiation of a pulse wave having a predetermined period to emit to the outside, and a light receiving unit for receiving the infrared radiation emitted from the light transmitting unit, It further includes an auxiliary light receiving unit for detecting the infrared radiation emitted from the light emitting unit other than the light transmitting unit to detect the infrared rays introduced by a separate light emitter in addition to the one set of light emitters, by using a separate light emitter to the infrared detector There is an advantage that can not be released arbitrarily border zone.

In addition, by preventing the mutual interference generated between the infrared detectors installed in the adjacent area, there is an advantage that it is possible to detect that the boundary area of the infrared detector is blocked by the transmitter installed in the other boundary area.

Claims (4)

Light emitting means for generating infrared rays of a pulse waveform having a predetermined period and radiating them to the outside; light receiving means for receiving external light having the same directivity angle as that of the light transmitting means; and light received through the light receiving means. Light-shielding discrimination means for discriminating whether or not light-shielding is determined by quantity, light-shielding time comparing means for outputting an alarm generation signal by comparing the light-shielding signal determined by said light-shielding discrimination means with a preset time, and outputting to said light-shielding time comparing means An infrared detector comprising an alarm means for generating an alarm by an alarm generating signal, wherein the light receiving means operates with a large directing angle and generates an alarm generating signal if the received light is equal to or greater than a predetermined value. Infrared detector, characterized in that by configuring the light receiving means. The light receiving level according to claim 1, wherein the second light receiving means compares a first light receiving level indicating an amount of light received by the light receiving means with a second light receiving level indicating an amount of light received by the second light receiving means. An infrared detector, comprising a comparison means. 3. The infrared detector according to claim 2, wherein the light receiving level comparing means outputs an alarm generation signal if the level comparison error between the first light receiving level and the second light receiving level is more than a limit of an arbitrarily set error. The method of claim 1, wherein the second light receiving means is connected to a light shielding discrimination means for outputting an alarm generation signal during light shielding by determining whether the light is blocked by the amount of light received by the same beam angle as the beam beam angle of the light projecting means. Infrared sensor, characterized in that.