JPS62263489A - Infrared-ray warning apparatus - Google Patents

Abstract

PURPOSE:To reduce power consumption, by detecting the synchronous infrared pulse light from a light transmitting side to control the detection operation period of warning infrared pulse light. CONSTITUTION:The title apparatus consists of a plurality of light transmitting parts not shown by a drawing emitting infrared rays toward a warning region and a plurality of light receiving parts 2-1, 2-2,..., 2-n arranged across the warning region and each light receiving part detects the infrared rays from the corresponding light transmitting part and generates a light blocking signal when infrared rays are not detected over a predetermined time or more to emit an alarm from an alarm device 31. In this apparatus, because this apparatus is controlled by the synchronous pulse based on the synchronous infrared pulse light from the light transmitting part, a frequency dividing circuit 23, an one shot multivibrator 29 and an OR circuit 30 keep a synchronous state by a synchronous pulse before blocking even when all of rays are blocked and generate no step out. Then, control is performed so that warning infrared pulse lights from a plurality of the light transmitting parts are successively emitted at a predetermined interval and a plurality of the light transmitting parts emit warning infrared pulse lights one at a time and power consumption can be reduced.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an infrared warning device, and in particular, the present invention is directed to an infrared warning device that emits infrared rays from a plurality of light transmitting parts to a plurality of light receiving parts separated from a warning area. The light receiving unit detects when the light is interrupted and issues an alarm.

This relates to an infrared warning device that provides fence-like warning using multiple infrared rays.

[Prior art]

Referring to FIG. 6, this type of infrared warning device is shown.

Generally, a plurality of light transmitting units 1-1.1-2. ..., 1-n
A light transmitter 1 equipped with multiple stages of light transmitters 1, and a plurality of light receivers 2-1, 2-2. ...,
It has a light receiver 2 having multiple stages of light receivers 2-n. Light sending part 1
-1. ..., 1-n and corresponding receiving section 2-. 1,・
..., 2-n are adjusted so that their optical axes are aligned with each other.

Generally speaking, for the purpose of warning, infrared warning devices do not need to emit infrared rays continuously from the light transmitting unit; it is sufficient to emit infrared rays at regular (minute time) intervals; From the point of view of saving money, the light transmitting section requires each light receiving section 2-1. . . , 2-n needs to detect only infrared light from the corresponding light transmitting portions 1-1° . . . , 1-n.

However, as mentioned above, although the optical axes of the light transmitting section and the light receiving section that correspond to each other are aligned, due to the spread of the emitted light and the diffusion due to rain, fog, etc., the light emitted from one light transmitting section may In reality, the infrared light is incident not only on the corresponding light receiving section but also on other light receiving sections.

Therefore, in each light receiving section, it is necessary to select the emitted light of the corresponding light transmitting section from among the incident infrared lights.

In order to easily make such a selection at the light receiving section,
Conventionally, the times at which infrared pulsed light is emitted from a plurality of light transmitting units are staggered, and the number of pulsed lights emitted each time is varied for each light transmitting unit.

For example, referring to FIG. 7, the light transmitting section 1-1 emits one infrared pulse light at a time, and after a predetermined period of time, the transmitting section 1-1 emits one infrared pulse light at a time.
Two infrared pulse lights are emitted from the light transmitting section 1-n, and n infrared Noculus lights are emitted from the light transmitting section 1-n in the same manner. In this way, the light receiving section 1-1. ..., 1
-n, by counting the number of infrared pulsed lights incident at predetermined time intervals, it can be determined whether or not they are infrared pulsed lights from the corresponding light transmitting section.

[Problems with conventional technology]

As mentioned above, varying the number of infrared and cis light emitted at one time for each light transmitting section means that the number of infrared pulsed lights emitted by the translucent device as a whole increases, which is inevitable. This results in an increase in power consumption.

This is particularly disadvantageous for solar cells, which are conveniently used as a power source for devices of this type.

solve this. Therefore, it has been considered to synchronize the light transmission of each light transmitter and the detection operation of the corresponding light receiver by connecting the light transmitter and receiver with a cable, but in actual equipment, there are several connections between the light transmitter and the receiver. The length is 100 meters, and depending on the installation location, there may be roads, rivers, etc. in between, making it impossible to lay the cable and making it impractical.

The present invention aims to solve these problems.

[Means for solving problems]

In order to achieve the above objects, the present invention provides a light transmitter having a plurality of light transmitting sections that radiate infrared rays toward a guarded area, and a light transmitter that is installed apart from the guarded zone and corresponds to each of the plurality of light transmitting sections. Consisting of a light receiver with multiple light receiving sections, each light receiving section detects infrared rays from the corresponding light transmitting section, generates a light blocking signal when the infrared rays are not detected for a predetermined period of time, and issues an alarm based on the light blocking signal. In the infrared warning device, the light transmitter sequentially emits warning infrared pulsed light from the plurality of light transmitting sections at predetermined intervals, and also performs a predetermined method with respect to the warning infrared/base pulse light. The light receiver is configured to emit synchronizing infrared pulsed light from at least one light transmitting section at a time when the synchronizing infrared pulse light is emitted from the plurality of light receiving sections. The detection output is configured to set the detection operation time of the warning infrared pulsed light at the plurality of light receiving sections, thereby allowing each light transmitting section to communicate with the corresponding light receiving section. This is an infrared warning device characterized by maintaining synchronization.

Hereinafter, one embodiment of the present invention will be described in detail with reference to the drawings.

〔Example〕

Referring to FIG. 1, in the present invention, each light transmitting section 1-i e
1-2 # ... + 1-n emits one warning infrared pulse light every cycle (712 usually selected from several meters to several tens of milliseconds), but the emission from each light transmitting unit The time is a predetermined time (T21 usually 10 μ3 to several 100 μs)
(selected). When there are n light transmitting parts, T,
)T2X(n-1) is preferably selected to be T, >T2×n.

Therefore, when one infrared light of the light transmitting section 1-1 is taken as a reference, the light transmitting sections l-2, . . . , 1-n are sequentially T2
After a time (T, -r2x(n-1)) after the emission of the infrared and Cruz light from the light transmitting section 1-n, the second light transmitting section from the light transmitting section 1-1 of infrared pulsed light is emitted.

Thereafter, this operation is repeated, and at a predetermined time during this operation, the synchronizing infrared nozzle light S is transmitted to all the light transmitting units 1-1. ..., 1-n. In FIG. 1, in the third cycle, the light transmitter 1-n is configured to emit a synchronizing infrared pulsed light S after emitting a warning infrared pulsed light. That is, the light transmitting section 1
-1 for a predetermined period of time (T
3) It is emitted later. Here T3 is #T,)T,)T
It is determined to satisfy 2X(n-1).

This synchronizing infrared 9-lux light may be emitted every cycle, but here it is emitted every three cycles to save power consumption.

FIG. 2 is a diagram showing a circuit on the light transmitter side that controls the light transmission/turn of such a light transmitter. In the same figure, 11 is a crystal resonator, 12 is an oscillation circuit, 13 is a frequency dividing circuit, and 14F
i pulse width shaping circuit, 15tlj: NOR circuit, 16 is 1
A counter having an output terminal corresponding to a numerical value up to (n+1), 17-1 to 17n are AND circuits, 18-1 to 18
-n is an OR circuit, and light transmitting sections 1-1 to 1-n are connected to the output of the OR circuit, respectively.

A pulse of several MHz is oscillated by the crystal oscillator 11 and the oscillation circuit 12, and the missed output/Grus is oscillated by the frequency dividing circuit 13 of several kHz.
z to several tens of kHz. That is.

The period of the frequency-divided pulse signal is set to be T2 in FIG.

The output of the frequency dividing circuit 13 is input to the Noculus width connecting circuit 14, where the Noculus width is shaped to a constant narrow width. The pulse width-shaped pulse is inputted to a counter 16 via a NOR circuit 15. The counter 16 counts the number of Kanoyals of this person and outputs an H level signal to an output terminal corresponding to the counted value. Therefore, the counter 16 is (n+1)1
(When counting, an H level signal is output to the corresponding output terminal, and this H level signal is given to the other input terminal of the NOR circuit 15, so the pulse width shaping circuit 14
Passage of the output of 9 pulses through the NOR circuit 15 is stopped.

- The base pulse width shaping circuit 14 also generates a heliset signal for the counter 16 at a period of T. This resets the contents of the counter 16.

The output signal of the terminal corresponding to the count value (n+1) changes from the H level to the L level, thereby opening the NOR circuit 15, and the output/mother pulse of the Noculus width shaping circuit 14 passes through the NOR circuit 15 again to the counter 16. is counted. /4' Lux shaping circuit 14. Noah circuit 15. From now on, the counter 16
Repeat the same action.

Therefore, the output a of the NOR circuit 15 and the (n+
The time relationship between the output of the output terminal corresponding to 1) and the reset signal C from the pulse width shaping circuit 14 is as shown by a*b+c in Figure @3.

When the counter 16 starts counting the number 9, the count value is 1.
, 2, ama, and n, respectively, appear at the output terminals, and this is output to the AND circuit 17-1.
．． 17-2. . . , 17-n. On the other hand, the output pulse of the NOR circuit 15 is not only input to the counter 16, but also input to the AND circuit 1.
7-1.17-2. . . , 17-n is also applied to the other terminal of the AND circuit 17-1, 17-2 .
..., one 14 rus is 1 in the output of 17-n.
? The signals are sequentially output with a delay of one pulse (that is, with a 12-hour difference). Each AND circuit 17-1. ..., 17-
The output signal of n is each OR circuit 18"it...#t
Corresponding light transmitting unit 1 ” 1 # 1-2 through sn
e ”” is supplied to e 1-n.

Emit infrared/mother-wave light. OR circuit 18-1゜18
-2 and 18-n output signals egfeg'fc are shown in e*f*g in FIG.

/ bus width shaping circuit 14 inputs A? to the other input terminal of OR circuit 18-1, 18-2...*18-n every (2T, +T,). Lus (Fig. 3d) t-Supply. this)4
Rusuha, synchronization No. 81 e 32 #..., S
n (eef*g in FIG. 3) as light transmitting unit 1-111-2,
−.

1-n. Each light transmitting unit is adjusted accordingly.

At the same time, it emits infrared and mother Lus.

The circuit on the light receiver side that receives the infrared Nors emitted from the light transmitting sections 1-1, 1-2, and -01-n will be described with reference to FIGS. 4 and 5.

Referring to FIG. 4, 2-1. . . , 2-n is a light receiving section similar to that shown in FIG. 6, which converts incident light/Gurus into electricity/Gurus signals. 21 is an oscillation circuit equipped with a crystal resonator, and 22 and 23 are frequency dividing circuits.

24-1.24-2. ...e 24-n is an OR circuit, 25-1.25-2. ...125-n is an AND circuit, 26 is an OR circuit, 27 is an AND circuit, 28.29 is a one-shot multivibrator, and 30 is an OR circuit.

Excavation output of the oscillation circuit 21 (several MHz to several tens of MHz
) is frequency-divided by the frequency dividing circuit 22. That is, the 9 frequency divider circuit 22
has period T, /J? Lume signal OR circuit 24-1
, 24-2, ``'', and 24-n sequentially with a time delay of T2, and also supplies a .9 pulse signal with a period of 3T1 to the AND circuit 27. The pulse width of the output tp pulse of this frequency dividing circuit 22 is made wider than the width of the output pulse of the pulse width shaping circuit 14 shown in FIG.

OR circuit 24-1, 24-2 and 24 of frequency divider circuit 22
The output signals a, b, and c to -n and the output signal d to the AND circuit 27 are shown as a, b, and c in FIG.

Each is shown in d. Note that this output signal d is
It is T3 away from the 9 pulse signal a, and the OR circuit 24-
1.24-2. ++*+, is supplied to the other input terminal of 24-n.

OR circuit 24-1, 24-2, ・=, 24-
The output of light receiving section 2-1.2-2. ..., 2-n output signal and AND circuit 25-1.25-2. ..., 2
5-n, and the AND circuits 25-1, 25-2. ..., 25-n have light receiving sections 2-1, 2-2, -, 2-n K corresponding light transmitting sections 1-1.1-2. ..., infrared No. 4 from l-n
Four luscious signals based only on the luscious light are output. The output signals e, f, g of the AND circuits 25-1, 25-2 and 25-n are expressed as e in FIG.

They are shown in f2g.

AND circuit 25-1.25-2. ...*25-n output signal is given to the alarm circuit 31 and processed. That is, when a predetermined number or a predetermined number of these plurality of output signals does not appear, an alarm is generated.

AND circuit 25. -1.25-2. ..., the output of 25-n passes through the OR circuit 26 and becomes the output signal d of the divide-by-1 circuit 22.
The AND circuit 27 calculates the logical product of the synchronizing infrared pulses generated from each light transmitting section.
5 is obtained at the output of the AND circuit 27. The eafeg shown in Figure 5 is synchronized with Gurusuwo S1. S2. Indicated as Sn. Further, the output signal h2 of the OR circuit 26 is shown in h of FIG. 5, and the output l of the AND circuit 27 is shown in i of FIG.

This synchronization, #Russ S is 5th in one shot multi 28
As shown in Figure J, the pulse is narrow and the OR circuit 307
It is applied to the divide-by-1 circuits 22 and 23 through fr, and resets them.

Note that when the pulse from the oscillation circuit 21 starts to be input in the reset state, the 9 frequency divider circuit 22 starts the first division/'P pulse a (to the OR circuit 24-1) with a time delay of 5 (T1-T3). supply/gurus).

Therefore, since the operation on the light receiving side is controlled by the synchronization pulse based on the synchronizing infrared and base light transmitted from the light transmitter, the operation on the light receiving side is synchronized with that on the light transmitting side, and no synchronization occurs. .

Frequency divider circuit 23, one shot multi 29 and OR circuit 3
0 even when all light rays are blocked.

This is to maintain the synchronized state of synchronization/Grus S before shutoff. That is, after being reset, the frequency divider 1 circuit 23 generates a frequency divider signal after 3T1.

This /1' Luss is a one-shot multi 29 with a narrow width.
The signal is shaped into a cell (t in FIG. 5) and input to the OR circuit 3o.

When the synchronization pulse S is detected, Noculus j and t
occur at the same time. Sync A? When the pulse S is not detected rL, that is, when the light is shielded, the noise and the pulse t are
2.23 to prevent large synchronization deviations while there is no synchronization pulse.

In the above embodiment, the infrared pulsed light for synchronization is emitted from all the light transmitting parts, but it can be emitted only from some light transmitting parts, and it can be emitted not every three cycles but every cycle or Furthermore, one shot may be fired with an interval.

〔Effect of the invention〕

According to the present invention, from the light transmitting side, there is an infrared beam for synchronization. The light-receiving side sends out the pulsed light, detects it on the light-receiving side, and sends out warning infrared pulsed light to multiple light-emitting parts at once without the risk of detecting the infrared pulsed light from the light-receiving part. Only pulses can be emitted, which is extremely advantageous in terms of power loss.

[Brief explanation of drawings]

FIG. 1 is a diagram illustrating an example of the number and turn of infrared and cis light transmitted from a plurality of light transmitting units according to the present invention. FIG. 2 is a diagram showing a circuit of one embodiment of the light transmitter, and FIG. 3 is a time chart of signals of each part of the circuit of FIG. FIG. 4 is a diagram showing a circuit of one embodiment of a light receiver, FIG. 5 is a time chart of signals of each part in FIG. 4, and FIG. 6 is a diagram showing a schematic configuration of an infrared warning device using a plurality of warning lights. 7th
This figure is a diagram showing a conventional pattern of infrared and base light transmitted from a light transmitting section in FIG. 6. 1-1, 1-2, ・#1-n...Light transmitting section, 2-1°2-2. ..., 2-n...light receiving section, s
es, ,..., Sn...Synchronization reference, 2
2... Frequency dividing circuit, 24-1. .... 24-n...OR circuit z 25-1 #...#25
-n...Figure 6, Figure 7!

Claims (1)

[Claims] 1. Consisting of a light transmitter having a plurality of light transmitting sections that emit infrared rays toward a guarded area, and a light receiver having a plurality of light receiving sections installed apart from the guard zone and corresponding to the plurality of light transmitting sections, respectively. In an infrared warning device, each light receiving section detects infrared rays from a corresponding light transmitting section, generates a light blocking signal when the infrared rays are not detected for a predetermined period of time or more, and generates an alarm based on the light blocking signal. , the light transmitter sequentially emits warning infrared pulsed light from the plurality of light transmitting units at predetermined intervals, and synchronizes the warning infrared pulsed light from at least one light transmitting unit at a predetermined time. The light receiver is configured to emit synchronizing infrared pulsed light from the outputs of the plurality of light receiving parts, and the detection output is configured to emit the synchronizing infrared pulsed light. The infrared warning unit is configured to set the detection operation timing of the warning infrared pulsed light at the unit, thereby maintaining synchronization between each light transmitting unit and the corresponding light receiving unit. Device.