JPH04111696U - gas meter device - Google Patents

Abstract

(57) [Summary] [Purpose] We focused on the fact that in a gas meter device, a system that allows the valve inside the gas meter to be shut off by an alarm signal from the alarm device can shut off the gas in the event of a gas leak that could lead to a serious accident. The aim is to ensure safety and improve convenience by having the system shut off depending on the length of continuous use, depending on the presence or absence of an alarm. [Structure] When the connection detection means 2d detects that the alarm 5 is not connected, the cutoff signal output means 2e immediately outputs a signal when there is no change in the flow rate for a certain period of time set for each flow rate category. The solenoid valve 4 is shut off. Further, when the alarm device 5 is connected, if there is no change in the flow rate for a predetermined time period set for each flow rate category, a cutoff signal is output to shut off the solenoid valve 4 after a predetermined time period.

Description

[Detailed explanation of the idea]

0001

[Industrial application field]

The present invention relates to a gas meter device having a metering function to measure the amount of gas used. In addition to the measuring section that measures the flow rate of gas flowing through the gas flow path, Gas meter device having a control unit that monitors the flow rate of gas and performs various tasks It is something.

0002

[Conventional technology]

Conventionally, this type of gas meter device has the configuration shown in Fig. 6. It was. In the figure, a control section 2 built into a gas meter body 1 includes a gas meter. A flow rate sensor 3 that generates a flow rate signal in conjunction with the operation of the measuring unit 11 of No. 1, and a gas flow path. The solenoid valve 4 installed in the house and the gas leak alarm 5 installed in the house are connected to the signal line L.₁No To L₃network control unit (NCU) 6 and telephone line L. _Four It is connected to a center (not shown) via. In addition, 7 is an LP gas cylinder, 8 9 is a gas pipe serving as a gas flow path, and 9 is a gas appliance.

0003 With the above configuration, the control unit 2 can control the flow rate at a constant flow rate based on the flow rate signal from the flow rate sensor 3. Detects when gas has been used for more than a certain period of time (continuous use time exceeded) It determines that the gas appliance 9 has been turned off and outputs a cutoff signal to the solenoid valve 4 to turn off the gas. It is designed to shut off, and also for example 5 minutes before the specified time above. A warning signal is output to the gas leak alarm 5 to generate a warning sound before the gas is used. Gas appliances are now being issued to remind people not to forget to turn off gas appliances.

Further, when the gas leak alarm 5 detects a gas leak, a gas leak signal is sent from the gas leak alarm 5 to the control unit 2 via the signal line L ₃ , and the control unit 2 receives the gas leak signal. In response to this, a cutoff signal is stepped to the solenoid valve 4 to shut off the gas.

When the solenoid valve 4 is shut off, the gas supplier's center is notified via the NCU 6 and telephone line L ₄ that the solenoid valve ₄ has been shut off. When receiving a shutoff command signal sent from the center, the solenoid valve 4 is shut off.

[0006] On the other hand, if the system shown in Figure 6 cannot be constructed due to cost reasons, Control unit 2 is a gas leak alarm, the NCU is not controlled, and the meter alone determines flow abnormality. Some systems are also in use that allow for shutoffs to occur. What is flow abnormality here? In addition to exceeding the continuous usage time mentioned above, exceeding the total flow rate, exceeding the increased flow rate, Such as minute leakage.

[0007]

[Problem that the idea aims to solve]

As mentioned above, in the conventional system, even if the gas leak alarm 5 is connected, it is not connected. Even if the solenoid valve 4 is not turned off, the solenoid valve 4 is shut off after a certain period of time.

[0008] The above fixed time is determined statistically by investigating the usage time of certain gas appliances. The predetermined data for each of the plurality of flow rate monitoring categories constitutes the control unit 2. It is stored in the memory of a microcomputer (CPU). but Depending on the development status of gas appliances and gas usage conditions, unnecessary shields may be shut off even during normal use. There is a possibility that a disconnection may occur.

[0009] If such unnecessary shutdowns occur frequently, users may be unable to use the device even though they are using it normally. However, the gas flow path will be blocked, and you will have to go outside to restore the shutoff. Contact your gas supplier and turn on the supply equipment if the problem is not clear or you do not know the cause of the shutoff. This is inconvenient for users, and it is difficult for suppliers to For users, the problem is that the burden increases due to more troubles with users. there were.

0010 Therefore, in view of the above-mentioned conventional problems, the present invention has been developed by installing an alarm in the control section of the gas meter. connected, and the valve in the gas meter can be shut off by the alarm signal from the alarm In such a system, in the event of a gas leak that could lead to a serious accident, Focusing on the fact that the alarm can be used to shut off the alarm, the alarm can be shut off due to the continuous use time. A gas meter that ensures safety and improves convenience by making the The goal is to provide data storage equipment.

[0011]

[Means to solve the problem]

The gas meter device created by this invention to solve the above problems is based on the basics shown in Figure 1. As shown in the configuration diagram, the flow rate sensor 3 operates in conjunction with the operation of the measuring section 11 of the gas meter 1. monitors for no change in flow rate based on the flow signal generated by the When there is no change in the flow rate until the specified time before the set time, each flow rate is When there is no change in the flow rate for a certain period of time set for each category, the In a gas meter device having a control unit 2 that performs control to shut off a solenoid valve 4, Connection detection means for the control unit 2 to detect whether or not the alarm device 5 is connected to the control unit 2 2d, and the connection detection means 2d detects that the alarm 5 is not connected. The flow rate changes for a certain period of time set for each flow rate category only when A cutoff signal output that outputs a cutoff signal to immediately cut off the solenoid valve 4 when there is no It is characterized by having means 2e.

0012 In the gas meter device shown in Fig. 1, which was developed according to the present invention in order to solve the above problems, , the cutoff signal output means 2e detects whether the alarm 5 is connected by the connection detection means 2d. If it is detected that the As soon as there is no change in the flow rate for a period of time, the alarm 5 is activated by the connection detection means 2d. If it is detected that the When there is no change in the flow rate for a certain period of time, the solenoid valve 4 is shut off after a certain period of time. It is characterized by outputting a cutoff signal to disconnect.

[0013]

[Effect]

In the above configuration, the connection detection means 2d of the control section 2 detects the connection of the alarm device 5. Only when the cutoff signal output means 2e detects that the Immediately when there is no change in the flow rate for a set period of time, the solenoid valve 4 is output to shut off the solenoid valve 4, and the alarm 5 is connected. When there is no change in the flow rate for a certain period of time set for each flow rate category, Since the solenoid valve 4 is not shut off, it is possible to eliminate unnecessary shutoffs while ensuring safety. can.

[0014] Further, the cutoff signal output means 2e is connected to the alarm 5 by the connection detection means 2d. If it is detected that the connection is not connected, the Immediately when there is no change in the flow rate for a certain period of time, the connection detection means 2d issues an alarm. If it is detected that the device 5 is connected, the settings are made for each flow rate category. If there is no change in the flow rate for a specified period of time, then after a certain period of time, e.g. After a period of time when it can be determined that the person is away, outputs a cutoff signal to cut off the solenoid valve 4. Since the solenoid valve 4 is shut off, safety is ensured and unnecessary shutoffs are eliminated. It is possible to prevent major accidents from occurring while the user is away.

[0015]

【Example】

Hereinafter, embodiments of the present invention will be described based on the drawings. Figure 2 shows the gas meter according to the present invention. 6 is a block diagram showing an embodiment of the computer device, in which The same parts as in the conventional one are given the same reference numerals.

[0016] In FIG. 2, the control unit 2 is a microphone that operates according to a predetermined control program. A ROM that is configured by a computer (CPU) and stores a control program 2a and the data area for storing various data and the workpiece used in the signal processing process. It has a RAM 2b having areas and the like.

The flow rate sensor 3 is connected to the control unit 2 via a signal line _L1 , and is connected, for example, to a diaphragm constituting a measuring unit of a gas meter or a link mechanism that transmits the reciprocating motion of this diaphragm to an indicating unit. It consists of a combination of a magnet and a reed switch that detects the position of the magnet. This gas flow rate sensor 3 generates a flow rate signal by turning on and off the reed switch, and the control unit 2 that receives this flow rate signal measures the gas flow rate by measuring the time from one turn on of the reed switch to the next turn on. You can know.

The solenoid valve 4 is connected to the control unit 2 via a signal line L ₂ , and is a self-holding type that combines a magnet and an electromagnetic coil provided in the gas flow path. The gas flow path is cut off by the cutoff signal. This electromagnetic valve 4 is configured to self-maintain in an open state using a magnet, thereby reducing consumption of a battery as a power source. Further, the shutoff operation is performed when the self-holding state is released as the electromagnetic force generated by passing a current through the electromagnetic coil overcomes the holding force of the magnet that keeps the valve open. Once the circuit is cut off in this way, the holding force of the magnet alone will not cause the circuit to open, and there is no longer a need for current to flow. To open the valve, open it manually and position it so that it can be held by a magnet.

The gas leak alarm 5 is connected to the control unit 2 via an interface 10 and a signal line L ₃ so as to be able to communicate bidirectionally, and has a sensor unit consisting of a detection element that detects CO gas or combustion gas. It consists of an alarm section consisting of a sounding device such as a buzzer. When the gas leak alarm 5 detects gas with a predetermined concentration or higher, it activates the alarm unit to generate an alarm sound and sends a gas detection signal indicating this to the control unit 2 via the signal line L ₃ and the interface 10. to shut off the solenoid valve 4. Further, the alarm section is activated to emit a warning sound based on a cutoff notice signal and a cutoff signal from the flow rate market inputted from the control section 2 through the interface 10 and the signal line _L3 .

[0020] A network control unit (NCU) 6 transmits signals from the control unit 2 to the center and sends signals from the control unit 2 to the center. The controller 2 is equipped with a gas leak alarm. A connection setting device 12 is connected to the connection setting device 12 for setting the presence/absence of connection of 5.

[0021] The control unit 2 measures the gas flow rate based on the flow rate signal from the flow rate sensor 3, monitors that there is no change in the measured gas flow rate, and waits for a certain period of time set for each flow rate category. When it is determined that there is no change in the flow rate until a predetermined time before the gas leak alarm 5, it outputs a cutoff warning signal to the gas leak alarm 5 and notifies the center via the network control unit 6 and telephone line _L4 .

[0022] After that, if the control unit 2 determines that there is no change in the flow rate for a certain period of time set for each flow rate category, it determines that the gas appliance corresponding to that flow rate has been used for a longer time than the normal usage time. Therefore, such a state indicates some kind of abnormality, and it is determined whether the gas leak alarm 5 is connected based on the signal from the interface 10, and if it is determined that it is not connected, it immediately issues a cutoff signal. A signal is sent to the solenoid valve 4 via the interface 10 and the signal line _L3 , and the solenoid valve 4 is driven to shut off the gas flow path, and a network control is sent to a remote center to notify that the solenoid valve 4 has been shut off. Notify the center via unit 6 and telephone line _L4 .

On the other hand, when the control unit 2 determines that the gas leak alarm 5 is connected based on the signal from the interface 10, the warning signal to the gas leak alarm 5 continues to be output, but the solenoid valve 4 is shut off. Otherwise, a timer configured in the RAM 2b is started to measure a certain period of time, for example, a period during which it can be determined that the user is away, and if there is still no change in the gas flow rate during this period, a cutoff signal is sent to the interface 10 and signal line L. ₃ to the solenoid valve 4 to drive the solenoid valve 4 to shut off the gas flow path, and to notify the remote center that the solenoid valve 4 has been shut off via the network control unit 6 and telephone line L. Report to the center via ₄ .

[0024] In the control unit 2, the gas flow rate measured by the flow rate signal from the flow rate sensor 3 is , the flow remains at a constant value for more than a specified time, and the gas appliance equivalent to that flow rate is in normal use. In order to judge that the gas has been used for a longer time than the In addition, the type of gas meter, the maximum flow rate of the equipment used, and the gas stove. A setting device 11 for selecting presence/absence is connected. This is enough unburned material to explode. Since the amount of burning gas varies depending on the type of gas, it is determined from the amount of gas passing through the gas meter. It is necessary to change the predetermined time for determining danger depending on the type of gas, and The type of meter is the amount of gas that passes through the meter with one round trip of the diaphragm. This is because the risk varies depending on the type and number of combustors in the equipment used. This is because the predetermined time and flow rate used to judge risk are different.

In the above-described embodiment, the connection setting device 12 for setting whether or not the gas leak alarm ₅ is connected is connected to the control unit 2. A function is provided to detect that the alarm 5 is not connected and generate a signal indicating the disconnected state, and the control unit 2 determines whether or not the gas leak alarm 5 is connected based on this signal. It may be possible to do so. By doing this, even in a system where the gas leak alarm 5 is connected, even if the signal line _L3 is disconnected for some reason, it will be determined that the gas leak alarm 5 is not connected, so the system will continue operating. It is possible to shut down the device when the usage time has exceeded.

[0026] The work performed by the CPU constituting the control unit 2 for the operation of the device outlined above is shown below. This will be explained below with reference to the flowcharts of FIGS. 3 and 4.

[0027] The control unit 2 consisting of a CPU starts operating when the power is turned on, and the flowchart shown in FIG. In the first step S1 of the process, the flow rate is determined by the flow rate signal from the flow rate sensor 3. After measuring, the process proceeds to step S2. In step S2, step S Determine whether the flow rate measured in step 1 is within a predetermined range, and make this determination. If NO, proceed to step S3 and check the flow rate abnormality other than the continuous usage time over abnormality. After performing normal processing, the process returns to step S1. In addition, in this abnormality processing, Performs tasks such as notifying the center of abnormalities and outputting a cutoff signal to the solenoid valve 4. .

[0028] When the determination in step S2 is YES, that is, the flow rate is within a predetermined range. In some cases, the process proceeds to step S4, where it is specified which flow rate category the flow rate falls into. After that, the process proceeds to step S5, where the flow rate area specified in step S4 is The presence or absence of a flow rate change is determined based on whether the minutes have changed from the previously specified classification. Ru. When the determination in step S5 is YES, that is, when there is a change in flow rate, Proceed to step S6 and reset the time limit timer formed in RAM2b. Then, the process returns to step S1.

[0029] If the determination in step S5 is NO, that is, there is no change in flow rate, step S After carrying out the time limit processing in step 7, the process returns to step S1.

[0030] The continuous use time processing in step S7 is as shown in the flowchart of FIG. In the first step S7a, the time limit timer measures the current flow rate. It is determined whether it is 5 minutes before the fixed time limit. The determination in step S7a is N. If the answer is O, the process proceeds to step S7b, where it is determined whether or not the time limit has elapsed. When the determination in step S7b is NO, the process returns to the flowchart of FIG. , S2, S4, and S5, and steps S7a and S7b are repeatedly executed.

[0031] If the determination in step S7a becomes YES five minutes before the time limit, step Proceeding to S7c, a warning signal to the gas leak alarm 5 is output, and the subsequent step S7 d, the flow rate is flowing to the center without changing even 5 minutes before the limit time. After making a report, the process returns to the flowchart in Figure 3. When the determination in step S7a is made, the determination in step S7a becomes NO and the process proceeds to step S7. Then, the process proceeds to step S until the determination becomes YES in step S7b. 1, S2, S4, and S5, and steps S7a and S7b are repeatedly executed. In addition , the warning signal in step S7c continues to be output until it is reset. Setting is performed when it is determined that the abnormality has disappeared.

[0032] If the determination in step S7b is YES, proceed to step S7e, and connect here. Determine whether the gas leak alarm 5 is connected based on the setting of the setting device 12, If the determination is NO, that is, the gas leak alarm 5 is not connected, step S Proceed to step 7f, output a cutoff signal to solenoid valve 4 to cut off the gas flow path, and then return to step 7f. In step S7g, the center is notified of the interruption, and the process returns to the flowchart of FIG.

[0033] On the other hand, when the determination in step S7e is YES, that is, the gas leak alarm 5 is connected. If it is connected, the process advances to step S7h and it is determined whether flag F is 1 or not. However, when the determination in step S7h is NO, the RAM is For example, the 6-hour timer formed in step S7j is started, and the process proceeds to step S7j. After setting the flag F to 1, the process returns to the flowchart of FIG.

[0034] After that, the process returns to step S7h again, but at this time, the determination in step S7h is Y. It becomes ES and proceeds to step S7k, where the tie that started in step S7i is If the determination in step S7k is NO, Sometimes, the process returns to the flowchart in FIG. Timer star in step S7i If 6 hours have passed since the start and the determination in step S7k is YES, step S7m The process proceeds to step S7f, where the flag F is set to 0, and the process proceeds to step S7f, where the solenoid valve 4 is shut off. After outputting the disconnection signal, the process returns to the flowchart of FIG.

[0035] In addition, in the embodiment of the flowchart in FIG. 4, the gas leak alarm 5 is not connected. automatically when there is still no change in flow rate 6 hours after the time limit has elapsed. Although a cutoff signal is output and the solenoid valve 4 is driven to cut off the gas flow path, As shown in the flowchart of FIG. 5, when the gas leak alarm 5 is connected, may be configured such that the cutoff signal is not output. In this case, step The center that received the notification of step S7d calls the gas consumer, confirms the situation, and then In such a case, the electromagnetic power can be removed by sending a cutoff command signal from the center side. All that is required is to shut off the valve 4.

[0036] Furthermore, in the above-mentioned embodiment, a system that can report to the center is assumed. Needless to say, the present invention is equally applicable to systems that cannot report to the center. Nor.

[0037]

[Effect of the idea]

As explained above, according to the present invention, each alarm is activated only when the alarm is not connected. Immediately shuts off when there is no change in flow rate for a certain period of time set for each flow rate category. Outputs a disconnection signal to shut off the solenoid valve, and if an alarm is connected, if continued use Since the system is designed not to shut down due to overtime, unnecessary shutoffs may occur. Furthermore, for safety reasons, it is necessary to determine whether or not to shut off the alarm depending on whether or not the alarm is connected. Since this has been determined, there is no possibility of disconnection of the signal line from the alarm or if the alarm was not connected from the beginning. Safety will not be compromised even when applied to a system that is not certified. Therefore, safety It is possible to improve convenience while ensuring functionality.

[0038] In addition, if an alarm is connected, the settings for each flow rate category can be set individually. When there is no change in the flow rate for a certain period of time, a cutoff signal is output after a certain period of time. By forcing the solenoid valve to shut off, you can determine whether the user is away. Even if this invention is applied to a system that cannot report to the center, safety will be compromised. There's nothing wrong with that.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the basic configuration of a gas meter device according to the present invention.

FIG. 2 is a block diagram showing an embodiment of a gas meter device according to the present invention.

FIG. 3 is a main flowchart showing the work performed by a CPU constituting the control section in FIG. 2;

FIG. 4 is a flowchart showing details of a portion of FIG. 3;

FIG. 5 is a diagram showing a flowchart of a modification of the present invention.

FIG. 6 is a diagram showing a general configuration of a conventional gas meter device.

[Explanation of symbols]

1 Gas meter 11 Measuring part 2 Control unit (CPU) 2d CPU (connection detection means) 2e CPU (cutoff signal output means) 3 Flow rate sensor 4 Solenoid valve 5 Gas leak alarm (alarm)

Claims (2)

[Scope of utility model registration request] [Claim 1] Monitoring whether there is no change in the flow rate based on the flow rate signal generated by the flow rate sensor in conjunction with the operation of the measuring section of the gas meter, and monitoring the flow rate before a predetermined time period set for each flow rate category. In the gas meter device, the gas meter device has a control unit that performs control to shut off a solenoid valve provided in a gas flow path when there is no change in the flow rate for a certain period of time set for each flow rate category, respectively. The control unit includes connection detection means for detecting whether or not an alarm is connected to the control unit, and a connection detection means for each flow rate segment only when the connection detection means detects that the alarm is not connected. A gas meter device comprising a cutoff signal output means for outputting a cutoff signal to cut off the electromagnetic valve immediately when there is no change in the flow rate for a predetermined period of time. [Claim 2] Monitoring whether there is no change in the flow rate based on the flow rate signal generated by the flow rate sensor in conjunction with the operation of the measuring section of the gas meter, and monitoring the flow rate before a predetermined time period set for each flow rate category. In the gas meter device, the gas meter device has a control unit that performs control to shut off a solenoid valve provided in a gas flow path when there is no change in the flow rate for a certain period of time set for each flow rate category, respectively. The control unit includes a connection detection means for detecting whether or not an alarm is connected to the control unit, and a connection detection means for each flow rate classification when the connection detection means detects that the alarm is not connected. Immediately when there is no change in the flow rate for a certain period of time, the connection detection means detects that the alarm is connected. and a cutoff signal output means for outputting a cutoff signal to cut off the electromagnetic valve after a certain period of time.