JP3113398B2 - Smoke detector - Google Patents

Abstract

PURPOSE:To prevent the blank time in a smoke detection operation by being generated by detecting the non light emission of a light emitting lamp and alarming that the limit of the life of the light emitting lamp is close when the number of the times of the non light emission is more than the prescribed number of times. CONSTITUTION:From the time when a smoke sensor 1 is installed or a xenon lamp 10 is exchanged, the number of times when the xenon lamp 10 does not emit the light at the time to emit the light, that is, the number of the times of the non light emission is stored every month. That is, when a light emitting level by a light receiving element 20 does not arrive at a prescribed level at the time of a light emitting instruction from a control circuit 50, the number of the times of the non light emission is increased by '1.' Then, the number at every month is stored in an EEPROM 63. The total number of the times of the non light emission in the month and the figure of an alarm level, 7 times for instance, are compared by the control circuit 50 every month and a life alarm signal is outputted when the total number of the times of the non light emission in the month is more than 7. Thus, the failure of the xenon lamp 10 can be recognized beforehand and the blank period in the smoke sensing operation is not generated.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention provides a light-emitting lamp such as a xenon lamp and a light-receiving element in a smoke room, emits light from the light-emitting lamp, and responds to an output signal of the light-receiving element receiving the light from the light-emitting lamp. The present invention relates to a smoke detection device that detects smoke concentration.

[0002]

2. Description of the Related Art Light is emitted by a xenon lamp, and in response to an output signal of a light receiving element receiving light from the xenon lamp,
In a conventional smoke detector such as a smoke detector that detects the concentration of smoke in a smoke chamber, when a xenon lamp emits light for a predetermined number of years or for a predetermined number of years, the luminous efficiency decreases or stops emitting light, so that the smoke detector Normal operation cannot be performed.

[0003]

As described above, in order to detect that a xenon lamp is out of order, conventionally,
The light receiving level from the xenon lamp is detected, and when this light receiving level cannot be maintained at or above the predetermined level, it is determined that the xenon lamp has failed. Specifically, a time period of about 30 seconds or 1 minute is set in advance, and when there is no light receiving level within a predetermined level, the xenon lamp is determined to have failed. Then, an alarm is sounded to notify that the xenon lamp is out of order.

However, according to the above-mentioned conventional method, it is possible to notify that the xenon lamp has already failed, but it is not possible to predict the failure. Therefore, in the conventional example, after the xenon lamp has actually failed, the maintenance person knows that the xenon lamp has failed, as well as until the maintenance person knows the failure. Since the smoke detector does not operate until the replacement is completed, there is a problem that a blank period occurs in the smoke detection operation. This problem also occurs in light-emitting lamps other than the xenon lamp.

The present invention, by to be able to know in advance a failure of the lamps, and an object thereof is to provide a smoke detection device can be prevented to cause a blank period in the smoke sensing operation Things.

[0006]

SUMMARY OF THE INVENTION The present invention has a light emitting lamp and a light receiving element for receiving light from the light emitting lamp, and detects a smoke concentration in accordance with an output signal of the light receiving element. Detecting the non-light emission of the light-emitting lamp corresponding to the light-emitting command to cause the light-emitting lamp to emit light, storing the number of times of no light emission, and when the number of times of no light emission is equal to or more than the predetermined number, the life of the light-emitting lamp is near It warns that.

[0007]

According to the present invention, there is provided a smoke sensing device having a light emitting lamp and a light receiving element for receiving light from the light emitting lamp, and detecting the density of smoke in accordance with an output signal of the light receiving element. The non-light emission of the light-emitting lamp corresponding to the light-emitting command to be detected is detected, and the number of times of this light emission is stored. The failure of the light-emitting lamp can be known in advance, so that a blank period can be prevented from occurring in the smoke sensing operation.

[0008]

FIG. 1 is a block diagram showing an embodiment of the present invention.

In the smoke detector 1 of this embodiment, the smoke room 3
The xenon lamp 10 and the light receiving element 20 are provided in the inside of the light shielding plate 34.
Are separated by And a xenon lamp 10
Emits light, and the light is scattered by the smoke in the smoke chamber 30 and reaches the light receiving element 20.
The control circuit 50 determines the density of the smoke within zero.

The xenon lamp 10 is supplied with a high voltage required for light emission from a high voltage generating circuit 12 and a trigger circuit 11
The light emission timing is controlled by a trigger signal supplied from. The trigger circuit 11 generates a trigger signal based on a control signal supplied from the control circuit 50.

The smoke chamber 30 is connected to a sampling pipe 31 for guiding the atmosphere in which the smoke detector 1 is provided to the smoke chamber 30, and a pipe 32 for guiding the air in the smoke chamber 30 to the outside of the smoke detector 1. A suction fan 33 is provided in the pipe 32.

The amplifier 40 amplifies the output signal of the light receiving element 20, the gain of which is controlled by a gain switching circuit 41, and the peak hold circuit 42 is a circuit for holding the peak of the output signal of the amplifier 40. , A / D
The conversion circuit 43 is a circuit that converts an analog signal output from the peak hold circuit 42 into a digital signal.

The control circuit 50 controls the entire smoke detector 1 and determines the current smoke density in the smoke chamber 30 based on a digital signal from the A / D conversion circuit 43. It is composed of a computer and the like.

The ROM 60 stores the program of the flowchart shown in FIG.
Is a ROM that stores the number of times that the xenon lamp 10 does not emit light when it should emit light (the number of times that no light is emitted), and stores the number of times that the xenon lamp 10 does not emit light for each month. RAM 64 is
This is a working memory.

The D / A conversion circuit 71 includes a signal transmission circuit 7
2. To send a signal to the receiver 2 via the connector C,
This is a circuit that converts a digital signal output by the control circuit 50 into an analog signal.

The life warning signal sending circuit 73 is a circuit for sending a life warning signal for warning that the life of the xenon lamp 10 is near.

Light receiving element 20, control circuit 50 and ROM 60
Is an example of non-emission detecting means for detecting non-emission of a light-emitting lamp corresponding to the light-emission command by monitoring a light-emission command for causing the light-emission lamp to emit light and emission of the light-emission lamp. This non-light emission detecting means determines that the light-emitting lamp is non-light-emitting if the light-receiving element 20 does not detect light emission corresponding to the light-emission command when a light-emission command is issued. The EEPROM 63 is an example of a storage unit that stores the number of times of non-emission for each predetermined period. Also, EEPROM
63 is also an example of electrically rewritable nonvolatile storage means. The control circuit 50 and the ROM 60 are examples of comparing means for comparing the number of times of non-emission with a predetermined number of times.
This is also an example of a life warning unit that warns that the life of a light emitting lamp is near when the number of times of non-emission is equal to or more than a predetermined number.

Next, the operation of the above embodiment will be described.

FIG. 2 is a flowchart showing the operation of the above embodiment.

First, in this embodiment, the xenon lamp 1
The number of times that light is not emitted when 0 should be emitted, that is, the number of times that light is not emitted, is stored for each month. Since the number of non-emissions in the first month is counted from the time when the smoke detector 1 is installed or the time when the xenon lamp 10 is replaced, the function n indicating the month is set to "1". And a function An indicating the number of non-emissions in the n-th month
Is set to "0" (S1). Thereafter, each time one month elapses (S2), the function n is incremented by one, and the function An of the number of non-emissions in the new month is set to “0” (S3).

When the light emission command is issued from the control circuit 50 (S4), if the level of light received by the light receiving element 20 does not reach the predetermined level (S5), the number of non-light emission is increased by one (1). S6). That is, the function An of the number of non-emissions in the month is increased by 1 and
It is stored in the corresponding location of OM63.

Then, the control circuit 50 compares the value of the function An of the number of no light emission in the month (total number of no light emission in the month) with the alarm level A _max (7 in the above embodiment) (S11). If the total number of no light emission in the month is 7 or more, a life warning signal is output (S).
12). This life warning signal is sent to the receiver 2 via the sending circuit 73 and the connector C.

The above operations (S2 to S12) are executed each time a light emission command is issued, and thereafter, a smoke density detection operation is performed (S20). That is, the signal output from the light receiving element 20 is amplified by the amplifier 40, the peak value is held by the peak hold circuit 42, and the held value is stored in the D / A conversion circuit 43.
Is converted into a digital signal, and the control circuit 50 determines the smoke density based on the digital signal. And D / A
The conversion circuit 71 converts the signal into an analog signal and outputs the signal.
2. A signal is sent to the receiver 2 via the connector C, and the receiver 2 displays the smoke density based on the signal.

FIG. 3 shows the EEPRO in the above embodiment.
9 shows a storage example of the number of times of non-emission stored in M63. In this example, from the installation of the smoke detector 1, no light emission does not occur once in the first to sixth months, but occurs once each in the seventh and eighth months. 12, 1
3, 2, 3, 5, and 10 times occurred in the third month, respectively. By looking at these stored contents, it can be determined whether or not it is time to replace the xenon lamp 10 installed in the smoke detector. In other words, when the xenon lamp 10 breaks down, the number of times of non-emission increases gradually, and usually after a certain number of times, the xenon lamp 10 breaks down. It can be determined whether it is time to replace.

If the total number of non-emissions in the month is equal to or more than a predetermined number without looking at the stored contents, a life warning signal is output, and the receiver 2 sounds an alarm based on this signal. , The failure of the xenon lamp 10 can be easily predicted. When the life is warned, a sound such as a bell or a voice may be used, or a visual means such as a lamp or a display display means may be used. Further, a bell, a lamp, and the like may be provided in the smoke detector 1.

FIG. 4 shows the EEPRO in the above embodiment.
It is a figure showing the relation between the number of times of no light emission stored in M63, and an alarm level. In this embodiment, the alarm level _Amax is set to seven times, but another number may be set.

In the above embodiment, the case where a xenon lamp is used has been described. However, as long as the lamp has an unstable failure mode, a lamp other than the xenon lamp is similar to the xenon lamp.

In the above embodiment, if the light receiving element 20 does not detect light emission corresponding to the light emission command when the light emission command is issued, it is determined that the light emitting lamp is not emitting light.
Instead, another non-light emission detecting means may be provided. That is, a light-sensitive element other than the light-receiving element 20 or a heat-sensitive element for detecting the heat of the light-emitting lamp is provided, and when a light-emitting command is issued, if the light-receiving element other than the light-receiving element 20 does not detect light emission, or if the heat-sensitive element emits light. If is not detected, it may be determined that the light emitting lamp does not emit light. Also, looking at a change in the output voltage or output current of the high voltage generation circuit 12, if the change is smaller than usual,
It may be determined that the light emitting lamp does not emit light.

In the above embodiment, the control circuit 50 determines that no light is emitted by using the light emission command generated by the control circuit 50 itself. By using the trigger signal or the control signal of the trigger circuit 11 as the light emission command, no light emission may be determined. Furthermore, in the above embodiment, the EEPROM 63 stores the number of times of non-emission for each month. However, the EEPROM 63 does not emit light for every predetermined period other than the month, such as every week, every ten days, every 100 days, or the like. The number of times may be stored. Further, instead of the EEPROM 63, a RAM with a backup battery or simply a RAM may be used. In the above embodiment, the signal indicating the smoke density is converted into an analog signal by the receiver 2.
, But a digital signal may be used instead of an analog signal.

In the above embodiment, the number of non-emissions per month is compared with the alarm level (A _max ).
For example, the total number of some of the numbers stored in the EEPROM 63, such as the total number of non-light emission times in the past three months, may be compared with the alarm level (A _max ).

Although the above embodiment has been described with reference to the case where the smoke detector is a smoke detector, storage means such as an EEPROM for storing the number of times of non-emission and comparison means for comparing the number of times of non-emission with a predetermined number of times. , Receiver 2 or a repeater (not shown). In this case, when the smoke detector detects no light emission, a signal indicating that no light emission has occurred is sent from the sensor to the receiver 2 or the repeater, and the receiver 2 or the repeater is provided for each sensor. The result is added and stored in the corresponding storage means, for example, on a monthly basis.

[0032]

According to the present invention, when the number of times of non-emission is equal to or more than a predetermined number, the warning that the life of the light-emitting lamp is near is warned, so that the failure of the light-emitting lamp can be known in advance. There is an effect that a blank period can be prevented from occurring in the smoke sensing operation.

[Brief description of the drawings]

FIG. 1 is a block diagram showing one embodiment of the present invention.

FIG. 2 is a flowchart showing the operation of the embodiment.

FIG. 3 shows an example of storing the number of times of non-emission stored in the EEPROM 63 in the above embodiment.

FIG. 4 is a diagram showing a relationship between the number of non-emissions and an alarm level stored in an EEPROM 63 in the embodiment.

[Explanation of symbols]

1: smoke detector, 2: receiver, 10: xenon lamp, 1
DESCRIPTION OF SYMBOLS 1 ... Trigger circuit, 20 ... Light receiving element, 30 ... Smoke chamber, 40 ...
Amplification unit, 41 ... gain switching circuit, 50 ... control circuit,
60: ROM, 63: EEPROM for storing the number of times of non-emission,
73 ... Sending circuit for life warning signal.

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-60-79699 (JP, A) Patent 2545298 (JP, B2) Patent 2515404 (JP, B2) Patent 2511440 (JP, B2) (58) Fields investigated (Int.Cl. ⁷ , DB name) G08B 17/103 H04B 41/14-41/234 G08B 27/54

Claims (5)

(57) [Claims] 1. A smoke sensing device having a light-emitting lamp and a light-receiving element for receiving light from the light-emitting lamp, and detecting the density of smoke in accordance with an output signal of the light-receiving element. Non-light emission detecting means for detecting no light emission of the light-emitting lamp corresponding to the light-emitting instruction by monitoring the light emission of the light-emitting lamp; A comparing means for comparing the number of times of no light emission with a predetermined number of times; and a life warning means for warning that the life of the light emitting lamp is near when the number of times of no light emission is equal to or more than the predetermined number of times. A smoke sensing device characterized by the following. 2. The light-emitting lamp according to claim 1, wherein the light-emitting lamp emits no light unless the light-receiving element detects light-emission corresponding to the light-emitting instruction when the light-emitting instruction is issued. Smoke sensing device characterized by determining that there is. 3. The light-emitting device according to claim 1, wherein said non-light-emitting detecting means is configured such that, when said light-emitting command is issued, a light-sensitive element other than said light-receiving element or a heat-sensitive element for detecting heat of said light-emitting lamp responds to said light-emitting command. If the corresponding light emission is not detected, it is determined that the light emitting lamp emits no light. 4. The light emitting device according to claim 1, wherein the light emitting command for causing the light emitting lamp to emit light is a light emitting command in a control circuit for controlling light emission of the light emitting lamp, a control signal for a trigger circuit, or a trigger signal for the light emitting lamp. Features smoke detector. 5. The smoke sensing device according to claim 1, wherein said storage means is an electrically rewritable nonvolatile storage means.