JPH02756B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an abnormal gas usage detection device that monitors the gas flow rate to determine whether it is normal or abnormal, and in the event of an abnormality, sounds an alarm to prevent disasters. It is something.

Recently, various incidents have occurred in apartments and other residences, such as explosions caused by gas leaks or gas suicides, explosions caused by turning on a light switch after going home without noticing a gas leak, and explosions in underground malls. disasters have occurred.

For this reason, various gas detection devices have been proposed to detect gas leaks that cause these accidents. Since a gas detector may detect the occurrence of a gas leak, a device is required that detects a gas leak from the gas flow rate and sounds an alarm.

This invention was developed in consideration of the above points, and focuses on the fact that in abnormal situations such as gas leaks, forgetting to turn off the gas, or gas suicide, the flow rate of gas per unit time remains constant without fluctuation over a long period of time. It was made by That is, the present invention is designed to determine whether the state of gas usage is normal or abnormal according to the rhythm of life in which humans use gas.

In general, it is normal for the amount of gas used for cooking or operating a heater to change over time. For example, the amount of gas used for 1 minute every 10 minutes, that is, 9 minutes and 19 minutes after gas usage starts. , when measuring each minute after 29 minutes have elapsed, it is rare that the amount will be the same three or four times in a row. Therefore, if the amount of gas used per minute is the same three times in a row, it is considered that a gas leak has occurred, including suicide, and this should be reported as an abnormality. This invention will be explained below.

The drawing is a block diagram showing one embodiment of the present invention. 1 is a pulse generator that generates a number of pulses according to the flow rate of gas. For example, a permanent magnet is attached to an impeller that rotates according to the flow rate, and the permanent magnet is It consists of one or more reed switches placed on the rotation trajectory of the magnet. 2 is a counter that counts pulses; 3 is a gate pulse generator that generates pulses with a constant pulse width at regular intervals; for example,
A pulse with a pulse width of 1 minute is generated every 10 minutes.
4 is a comparator circuit, and 5 is an arithmetic unit that multiplies the output of the counter 2 by a certain ratio. For example, when the output of the counter 2 is "100", adding ±8% of the output, "92~
108''. 6 is a storage device that stores the value of the arithmetic unit 5, which in the above example is ``92 to 108''.
A number counter 7 counts how many times the same contents are stored in the storage device 6. 8 is a pre-counter, and 9 is a collation circuit, which verifies whether the value set by the pre-counter 8 and the value counted by the number of times counter 7 match, and outputs an output when they match. 1
0 is an alarm device which generates an alarm sound with a buzzer when the output of the verification circuit 9 is received. 11 is a switch that is switched as shown by a dotted line in conjunction with the locking of a door such as an entrance, and 12 is an amplifier.

Next, the operation will be explained.

When someone is in the room, the door is not locked, so the switch 11 is in the position shown by the solid line. In this state, if no gas is used and there is no gas leakage, the flowmeter (not shown) will not operate, and the pulse generator 1 will not generate pulses.
Therefore, the circuits after counter 2 do not operate at all.

On the other hand, if gas is used or there is a gas leak, the pulse generator 1 generates a number of pulses corresponding to the gas flow rate. On the other hand, the gate pulse generator 3 regularly generates a gate pulse GP with a pulse width of 1 minute, for example once every 10 minutes. The counter 2 counts the number of pulses from the pulse generator 1 for one minute of this pulse width, and sends this counted value _A1 to the comparator circuit 4 via the switch 11. The comparison circuit 4 compares the value in the storage device 6 with the count value of the counter 2. Initially, the storage device 6 stores "0", so the two values do not match. Therefore, the count value _A1 of the counter 2 is sent to the arithmetic unit 5 at the same time as the reset output R is output. The arithmetic unit 5 performs an operation to add or subtract a certain ratio to the count value _A1 . That is, A ₁ (1
±α). For example, α is 0.08
(8%). Then, at the same time that the value of A ₁ (1±α) is stored in the storage device 6, “1” is counted in the number counter 7.

At the next gate pulse GP, the counter 2 again reads the one-minute count value _A2 , which is compared with the value _A1 (1+α) previously stored in the storage device 6 in the comparator circuit 4. ₂ is within the range of A ₁ (1±α), it is judged that the two match, the reset output R is not output, and the second count value A ₂ is sent to the calculator 5.
is sent to A ₂ (1+α), and at the same time this value is stored in the storage device 6, the number counter 7 is incremented by 1 and becomes 2. On the other hand, an appropriate value is set in advance in the pre-counter 8, and when the number of times counter 7 has counted the number of times equal to this set value, an output is output from the verification circuit 9 and an alarm is issued from the alarm device 10. In other words, whether the next count value _A2 of counter 2 is within the range of _A1 (1±α) obtained by performing a predetermined calculation on the previous count value _A1 , and whether the next count value _A3 is within the range of If the number of times within the range continues for _a predetermined number of times, e.g. 4 times (30 minutes in time),
It is determined that it is abnormal. Count values A ₁ and A ₂
The reason why these are not directly compared is that even if there are small or large fluctuations, it is assumed that the gas flow rate is constant. If the next counted value falls outside the range before the number of times within the range reaches a predetermined value, a reset output R is output from the comparator circuit 4 and the memory device 6 and number counter 7 are reset.

When someone leaves a room, the door is usually locked. In conjunction with this locking, the switch 11 is switched as shown by the dotted line. At the same time, the gate pulse generator 3 is also disconnected. Therefore, if even one pulse is output from the pulse generator 1 in this state, the output is amplified by the amplifier 12, and the alarm 10 is activated to notify that there is a gas leak. In other words, when no one is present, it is not necessary to check the fluctuations in the amount of gas used, but it is necessary to check whether gas is being used, and by this, it is possible to immediately determine whether the user has forgotten to turn off the starter.

In addition, in order to prevent an alarm from being triggered by gas when someone is in the room, a certain threshold value can be set and the gas flow rate above this threshold will be subject to an alarm. good.

In addition, when using a fixed amount of gas for a long time over low heat, or when using a fixed amount of gas for a long time because there is a large amount of object to be heated, the abnormal gas usage detection device of this invention should be deactivated in advance. It is better to set the value of the pre-counter 8 to a large value.

As explained in detail above, the present invention counts pulses from a pulse generator that generates a number of pulses according to the gas flow rate for a fixed time at predetermined time intervals, and the current counted value is the same as the previous counted value. We check whether the value is within a certain range based on the numerical value, and if the number of times within the range continues for a predetermined number of times, it is judged as abnormal, so it is possible to accurately judge abnormality regardless of the size of gas usage. It has the advantage of being

[Brief explanation of drawings]

The drawing is a block diagram showing one embodiment of the present invention. In the figure, 1 is a pulse generator, 2 is a counter, and 3
is a gate pulse generator, 4 is a comparison circuit, 5 is an arithmetic unit, 6 is a storage device, 7 is a number counter, 8 is a pre-counter, 9 is a collation circuit, 10 is a sound alarm, 11 is a switch, and 12 is an amplifier. be.

Claims (1)

[Claims] 1 A pulse generator that generates a number of pulses according to the gas flow rate, a counter that counts the pulses generated from the pulse generator for a certain period of time at predetermined time intervals, and an operation that multiplies the counted value of this counter by a certain ratio. an arithmetic unit to perform the calculation, a storage device that stores the output of this arithmetic device, and a value in this storage device that compares the next count value of the counter to determine whether the count value is within the range of the value in the storage device. determine,
a comparison circuit that sends the counted value to the arithmetic unit when it is within the range; a number counter that stores the number of times that the counted value falls within the range of the value in the storage device; and a pre-counter that sets an arbitrary number of times in advance. and,
It is characterized by comprising a verification circuit that outputs an output when the number of times set in the pre-counter matches the count value of the number of times counter, and an alarm that is activated by the output of this verification circuit and generates an alarm signal. Abnormal gas usage detection device.