KR100363866B1 - gas meter - Google Patents

Abstract

The present invention relates to a gas meter, a magnetic sensor for detecting a magnetic change caused by the rotation of the magnet is installed outside the tube, a flow rate detection circuit for calculating the flow rate of the gas in accordance with the repetition frequency of the magnetic change detected by the sensor In order to cut off the flow of gas if necessary, it is installed on the pipe, and the gas flow rate value calculated from the flow detection circuit is read and calculated according to the internal program, accumulated and stored in the memory and displayed on the display. One-chip microcomputer, one-chip microcomputer, etc. to shut off the gas shutoff valve by receiving the gas leakage signal from the sensor and control the operation of peripheral devices, power supply means for supplying the necessary power, and one-chip microcomputer and external communication transceiver Communication that is installed in between to enable input and output of necessary data It is composed of I / O circuit, and there is no error in flow measurement, it is possible to check whether there is a failure or gas leakage at the remote place, and also can automatically read at the remote place. It can save time, effort and cost, and it can shorten the process of charging due to automatic charge of gas usage fee.

Description

Gas meter

The present invention relates to a gas meter, and more particularly, to a gas meter that enables the user to know the amount of gas used in each household by measuring and displaying a flow rate of gas supplied to each household.

The conventional gas meter is connected to a rotating shaft and a rotating shaft rotated by a diaphragm that is stretched and contracted according to the amount of gas that passes, and a link that changes the linear movement of the diaphragm into a rotary motion. It consists of a mechanical counter indicating the usage amount. The structure of the rotating shaft rotated by the diaphragm and link and its operation process can be found in detail in Utility Model Publication No. 89-2131, “Diaphragm Gas Meter”.

The counter used in the conventional mechanical gas meter has several gears engaged with each other, so if one gear is deformed or a foreign object is caught between the two gears, a heavy load is placed on the gear and the gas displayed on the gas meter. There is a large error between the quantities of. In addition, in order to read the amount of usage, there is a problem that the meter reader should visit each family and check with the eyes.

It is an object of the present invention to provide a gas meter which can reduce the manpower, time and cost required for management and metering by allowing remote management and automatic meter reading as well as long error and long life in measuring the amount of gas passing through. It is.

1 is a block diagram showing a gas meter according to the present invention;

2 is a cross-sectional view showing an example of a configuration of a gas shutoff valve.

Explanation of symbols on the main parts of the drawings

100 gas meter 112 diaphragm

114: magnet 120: magnetic sensor

122: flow rate detection circuit 124: one-chip microcomputer

126 display 128 battery

130: power supply voltage determination circuit 132: communication power generation circuit

134: communication I / O circuit 136: communication transceiver

138: pulse output circuit 140: receiver and other equipment

150: gas shutoff valve 152: gas shutoff circuit

154: gas sensor 155: locking groove

156: valve body 157: first spring

158: second spring 159: latch

160: solenoid mechanism 161: tube

An object of the present invention is installed in the diaphragm and the diaphragm is stretched in accordance with the degree of flow of the gas passing through the tube and the pipe is connected between the two gas pipes to provide a gas passage is rotated in proportion to the degree of expansion of the diaphragm A gas meter for measuring the amount of gas passing through a pipe having a magnet and a display for displaying the measured flow rate, the gas meter being installed outside the pipe to detect a magnetic change due to the rotation of the magnet. A flow rate detection circuit for calculating the flow rate of the gas according to the repetitive number of times the magnetic change detected in the gas flow valve, a gas shutoff valve for blocking the flow of the gas if necessary, and a gas flow rate value calculated at the flow rate detection circuit. Read it and calculate it according to the internal program, add it to the memory, store it in the memory, and display it on the display. One-chip microcomputer, one-chip microcomputer, etc. to shut off the gas shutoff valve and control the operation of peripheral devices by receiving gas leakage signal from the gas leakage signal, and between power supply means for supplying necessary power and between one-chip microcomputer and external communication transceiver It can be achieved by a gas meter, characterized in that it comprises a communication I / O circuit to be installed in the input and output the necessary data.

The one-chip microcomputer further includes a pulse output circuit for notifying a gas flow rate by sending a signal to a receiver, and the gas shutoff valve includes a valve body having a catching groove and a first spring and a catching groove elastically supporting the valve body. And a second spring for acting the moment in one direction on the latch and the latch, which can be caught on one side, and the solenoid mechanism for pushing away the latch in one direction as necessary to disengage from the catch groove. Even better.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a gas meter according to the present invention.

1 shows a tube 110. The pipe 110 is installed between the two pipes to connect the two pipes, the inside of the gas passage through which the passage can be formed, of course.

As shown in the drawing, a diaphragm 112 is provided on the moving path of the gas inside the tubular body 110. The diaphragm 112 serves as a pump, and is repeatedly stretched and contracted according to the flow rate of the gas passing through the pipe 110, and the number of expansion and contraction is proportional to the flow rate.

As shown in FIG. 1, the gas meter 100 according to the present invention includes a magnet 114. This is rotated by the diaphragm 112, and what is necessary is just to install it on the rotating shaft rotated through the link as shown in utility model publication No. 89-2131 "diaphragm type gas meter." It is preferable to use a permanent magnet as this magnet 114, and it is good to comprise in disk shape. That is, when the diaphragm repeats the expansion and contraction movement through the crank and the diaphragm 112, the magnet 114 rotates in proportion to the repetition frequency.

As shown, the magnetic sensor 120 is installed outside the tubular body 110. The magnetic sensor 120 is installed at a position adjacent to the magnet 114, and is for detecting a magnetic change caused by the rotation of the magnet 114.

As shown, the flow rate detection circuit 122 is connected to the magnetic sensor 120. The flow rate detection circuit 122 is for calculating the amount of gas that passes according to the repetition number of magnetic changes detected by the magnetic sensor 120.

As shown, the gas meter 100 according to the present invention includes a gas shutoff valve 150, a gas shutoff circuit 152, and a gas sensor 154. Here, it is preferable to use a solenoid valve as the gas shutoff valve 150. When the gas sensor 154 detects a gas leak and applies a predetermined signal to the one chip microcomputer 124, the one chip microcomputer 124 operates the gas shutoff valve 150 through the gas shutoff circuit 152 to supply the gas. It is to be able to block the flow of.

The one-chip microcomputer 124 is connected to the flow rate detection circuit 122. The one-chip microcomputer 124 reads, calculates and integrates the gas flow rate data calculated by the flow rate detection circuit 122, stores it in a memory, and displays a display 126 connected to a place, for example, the one-chip microcomputer 124. It also displays the accumulated gas flow rate by applying data, etc., controls the operation of other necessary equipment, and also sends and receives data when requested. In addition to the calculation and integration functions, the one-chip microcomputer 124 has functions of memory, instantaneous flow rate detection, gas leakage determination, maximum gas flow rate detection, and data transmission / reception. The display 126 displays accumulated accumulated flow rate, instantaneous flow rate, voltage drop warning, and other warnings so that the user can easily recognize the display. An LCD (liquid crystal display device) is suitable for this display 126.

As shown, the gas meter 100 according to the present invention includes a power supply means consisting of a battery 128 and the like. The power supply means is for supplying power to the necessary portion, and this includes a lithium battery 128, a power voltage lower determination circuit 130, a communication power generation circuit 132, and the like.

As shown, a communication I / O circuit 134 is connected to the one chip microcomputer 124. This is for the one-chip microcomputer 124 to transmit and receive data with the external communication transceiver 136, and the communication power generation circuit 132 is connected thereto. The communication transceiver 136 is intended to be connected to a management server for comprehensively managing each gas meter through a network such as the Internet. The power supply voltage deciding circuit 130 detects that the voltage of the battery 128 falls below a reference value and applies the same to the one-chip microcomputer 124 so as to display a voltage drop warning on the display 126.

In addition, the pulse output circuit 138 is connected to the one-chip microcomputer 124. The pulse output circuit 138 is to transmit a pulse signal to a receiver or other device 140 such as an alarm installed at a position far away from the gas meter 100 so that an alarm can be generated. It is preferable.

2 is a cross-sectional view showing an example of a configuration of a gas shutoff valve.

As shown in FIG. 2, the locking mechanism 156 which elastically supports the valve body 156 having the locking groove 155 with the first spring 157 and receives the moment by the second spring 158 is rotated in place. Leave it connected to the solenoid mechanism 160 in the installed state. When the gas leak is detected in this state, the one-chip microcomputer 124 operates the solenoid mechanism 160 and pulls the catch 159 so that the catch 159 rotates in a counterclockwise direction. The part that was caught in the) is separated from the locking groove 155. Then, the valve body 156 moves forward by receiving the elasticity of the first spring 157 and the front end thereof blocks one side passage of the pipe 161. That is, the flow of gas can be blocked. In order to release the blocking state, the valve body 156 may be retracted so that the locking groove 155 is caught by the end of the locking hole 159.

That is, when gas flows into the tube body 110, the diaphragm 112 expands and contracts, which is converted into a rotational movement of the rotation shaft through the link. Accordingly, the permanent magnet 114 installed on the rotating shaft is also rotated together. Then, the magnetic sensor 120 installed outside the tubular body 110 detects the magnetic change caused by the rotation of the permanent magnet 114 and applies it to the flow rate detection circuit 122. The flow rate detection circuit 122 is a pipe 110 based on the repetition degree of the magnetic change in the magnetic sensor 120 and the gas flow rate per revolution of the magnet 114 by the diaphragm 112 measured by the experiment. The flow rate of the gas passing through is calculated and applied to the one-chip microcomputer 124. Then, the one-chip microcomputer 124 calculates and integrates the flow rate newly passed through the tube 110 to the existing accumulated flow rate by the self-stored program, stores it in its own storage means, and integrates it on the display 126. Display the flow rate. In addition, instantaneous flow rate detection, gas leak detection, and maximum flow rate detection are performed. When requested from the outside, data is transmitted and received. When the fact of the gas leak determination, etc. is confirmed, the gas blocking valve 150 is operated through the gas blocking circuit 152 to block the flow of gas.

In addition, a pulse per unit liter of the amount of gas passing through the gas meter 100 through the pulse output circuit 138 to be sent to the receiver 140 to display the gas usage in the remote.

On the other hand, when a request for data transmission from the outside, such as a remote management server that is remote from the remote place through the communication I / O circuit 134 and the communication transceiver 136 to transmit the requested data. In this way, the gas meter management server that is remote from the remote can be used to determine the automatic meter reading, failure, gas leakage, etc. in the gas meter of hundreds to thousands of households. Of course, the communication power generation circuit 132 generates and provides a power supply suitable for communication.

On the other hand, the current validity period of the gas meter is five years, so the battery 128 and other components should be used for a lifespan longer. The battery 128 continuously supplies the necessary power to the one-chip microcomputer 124 and the like, and the power voltage deciding circuit 130 connected thereto monitors whether the power voltage falls below the reference value, and such a situation occurs. If so, an abnormal signal is applied to the one-chip microcomputer 124. Then, the one-chip microcomputer 124 generates an alarm signal through the pulse output circuit 138, or reports a drop in power supply voltage when there is a data request from an external management server. Accordingly, the manager promptly replaces the gas meter 100.

This allows you to manage the gas meter remotely.

As can be seen from the above description, when using the gas meter according to the present invention, there is no error in the flow rate measurement due to the load due to the conventional gear train, and it is possible to check whether there is a failure at the remote site, gas leakage, as well as to automatically read the remote site. It is possible to save time, effort and money according to the conventional meter reader visit each home every day.

In addition, by checking the automatically metered flow rate, you can automatically charge for the use of gas, thereby reducing the process of charging.

Claims (2)

A pipe body 110 connected between two gas pipes to provide a gas flow path, a diaphragm 112 expanded and contracted according to the flow rate of the gas passing through the pipe body, a display 126 displaying the same, and external communication. In the gas meter which consists of the communication I / O circuit 136 which inputs / outputs the data read by the transceiver, and detects gas amount, A magnetic sensor 120 that detects a magnetic change as the diaphragm 112 repeats the stretching movement and the disk-shaped magnet 114 rotates in proportion to the repetition frequency; A flow rate detection circuit 122 for measuring a gas flow rate with a repetitive number of times according to the magnetic change of the magnetic sensor 120; According to the repetition frequency of the magnetic change of the magnetic sensor 120, the gas flow rate is calculated and integrated according to an internal program after reading the gas flow rate value calculated by the detection circuit 122, and stored in the memory, and the gas sensor 154 A one-chip microcomputer 124 for controlling the operation of a peripheral device to receive the gas leakage signal to block the gas shutoff valve and transmitting / receiving data detected when requested from the outside, and outputting a gas leakage determination and a maximum flow rate detection; A gas shut-off circuit 152 installed in the tube to block the flow by operating the gas shut-off valve 150 and a signal input from the microchip microcomputer 124; And a pulse output circuit (138) connected to the one-chip microcomputer (124) to output a pulse signal to a receiver (140) or other device such as an alarm. The gas shutoff valve 150 of claim 1, wherein the gas shutoff valve 150 includes a valve body 156 having a locking groove 155, a first spring 157 elastically supporting the valve body 156, and the locking groove ( 155 may be caught by one side and the locking hole 159 is installed so that it can be rotated in place, the second spring 158 for applying a moment in one direction to the locking hole 159, and the locking hole 159 as necessary Gas meter characterized in that it comprises a solenoid mechanism 160 to push in one direction to leave the locking groove (155).