KR200289185Y1 - System for Telemetering Calorimeters - Google Patents

Abstract

The present invention relates to a system for remote metering and management of a calorimeter at a remote location. The remote meter reading system of the present invention is installed in each generation or each heat-use complex to detect all or part of meter data including calories used by the calorimeter, fault status of the calorimeter, and data on the pressure of the fluid supplied to the calorimeter. A plurality of remote meter reading calorimeter module; A communication module connected to all of the remote meter reading calorimeter modules to collect and store all or part of data related to the calories, failure states, and fluid pressures detected by the remote meter reading calorimeter modules; And a remote device disposed at the remote location to receive the data from each of the remote meter reading calorimeter modules at a designated meter reading time and to perform calorimeter reading, fault condition monitoring, and fluid pressure monitoring of the calorimeter using the received data. And a meter reading center.

The present invention has the advantage of easy management and maintenance of the calorimeter because it can monitor various fault conditions and the pressure of the fluid generated from the calorimeter without remote equipment.

Description

System for Telemetering Calorimeters

The present invention relates to a remote meter reading system of a calorimeter, and more particularly, to a remote meter reading system of a calorimeter for remotely collecting calorimeter reading data of a calorimeter and remotely monitoring and managing a fault condition of a calorimeter.

Calorimeters are installed in each household in a group dwelling, such as apartments or apartment houses that provide central and district heating, and are used to quantify and display the calories used by each household. In addition, the calorimeter is used as an industrial calorimeter as well as a calorimeter for each household in the household. An example of the use of an industrial calorimeter is to supply heat to the air conditioning rooms of each apartment complex in the district heating construction, and to heat each household by exchanging heat in the air conditioning rooms of each apartment complex. At this time, the calorimeter is installed in the air conditioning room of each apartment complex in the district heating work. In the following specification, a heat use complex means a complex that receives heat from a heating construction of an apartment complex, a villa, an officetel, and the like, unlike each household.

The calorie measured by the calorimeter installed in each household or heat-use complex is recorded by the meter reader who belongs to the host establishment in the area and visited by the Gaho lake or the heat-use complex for each unit period, and reads the value indicated by the calorimeter. do. The meter reading recorded by the meter reader is compiled by the relevant management office and issued in the form of a bill for payment of the amount of heat used for each household or heat use complex.

Recently, a remote meter reading calorimeter module has been proposed to improve the meter reading method by direct visit of a meter reader so as to remotely read the calorific value calculated by a calorimeter installed at each generation or each heat use complex.

Figure 1 shows a schematic block diagram of a remote meter reading calorimeter module according to the prior art. As shown in FIG. 1, the remote meter reading calorimeter module is installed for each generation or each heat use complex, and the supply temperature sensor 102, the recovery temperature sensor 104, and the flow rate sensing unit 106 and each generation or A calorific value calculating module 110 and a communication module 120 connected to a terminal box 108 of a heat use complex, each of which is supplied from a supply pipe 142 and is refluxed through a reflux pipe 144. Detect the amount of heat used in the household or each heat-use complex.

The supply temperature sensor 102 detects a supply temperature of the fluid supplied through the supply pipe 142, and the recovery temperature sensor 104 detects a recovery temperature of the fluid recovered through the reflux pipe 144.

Inside the pipe 146 connecting the supply pipe 142 and the reflux pipe 144 is installed in the form of a disc at the top of the impeller 148 and the impeller 148 to rotate in accordance with the flow of the fluid to rotate with the impeller 148 The permanent magnet 150 is provided. The flow rate sensing unit 106 includes a magnetic sensor disposed at a position adjacent to the permanent magnet 150 outside the tubular body 146 to detect a change in polarity according to the rotation of the permanent magnet 150. The flow rate detecting unit 106 calculates the flow rate of the fluid according to the number of changes in the polarity of the permanent magnet 150, and generates one flow pulse per unit flow rate according to the detected flow rate.

The terminal box 108 introduces an external telephone line 117 and a commercial AC power line 118 into each household or each thermal use complex, and includes a plurality of wirings 131, 132, 134, for wiring in the household or the thermal use complex. 135) with a terminal terminal.

The calorific value calculating module 110 performs a function of calculating the amount of heat consumed by the corresponding heat mechanism of each generation or heat use complex and displaying the calculated result, and the calorific value calculating unit 112, the display unit 114, and the power supply unit 116. It is provided.

The calorific value calculating unit 112 calculates the flow rate by counting the flow rate pulses provided by the flow rate detecting unit 106, and calculates the calculated flow rate, supply temperature and recovery temperature detected by the supply temperature sensor 102 and the recovery temperature sensor 104. Calculate the calories used in each household or heat-use complex (building or heat appliance) by multiplying the difference between by and the calorie conversion factor. In addition, the calorie calculator 112 generates one calorie pulse for each calorie calculated for the remote meter reading. The calorie pulse generated by the calorific value calculating unit 112 is transmitted to the communication module 120 in the form of a pulse through the wirings 132 and 133 of the terminal box 108 together with the flow rate pulse received from the flow rate detecting unit 106. .

The display unit 114 accumulates and displays the flow rate detected by the flow rate sensor 106 and the heat amount calculated by the calorific value calculating unit 112 by letters or numbers.

The power supply unit 116 includes an AC-DC converter and converts AC power provided through the wiring 131 of the terminal box 108 into DC power to supply the calorific value calculation module 110.

The communication module 120 is connected to the meter reading center 150 at a remote location through a public switched telephone network (PSTN) 140 connected to the telephone line 117 of the terminal box 108, and the calorie calculation module 110 Performs a function of transmitting the data about the amount of heat and flow received from the meter reading center 150. The communication module 120 includes a pulse connection unit 122, a control unit 124, a modem unit 126, and a power supply unit 128.

The pulse connection unit 122 receives the calorie pulses and the flow rate pulses transmitted from the calorie calculation module 110 through the wire 133 of the terminal box 108 and transmits them to the controller 124.

The control unit 124 calculates the calorific value and the flow rate used in each generation or each heat use complex using the calorific pulse and the flow rate pulse received through the pulse connection unit 122 to generate the meter reading data for the remote meter reading. The meter reading data generated by the controller 124 is provided to the modem unit 126 through the wiring 135 of the terminal box 108.

The modem unit 126 is connected to the telephone line 117 of the terminal box 108, and the meter reading center 150 of the remote place through the public communication network 140 via the telephone line 117 to read the meter data provided from the control unit 124 To send.

However, in the above-described remote meter reading calorimeter module, the supply temperature sensor 102, the recovery temperature sensor 104 or the flow rate sensor 106 may be aged when used for a long time and easily cause a failure. In particular, the supply temperature sensor 102 and the recovery temperature sensor 104 are always exposed to hot fluid, causing frequent failures. If a failure occurs in the supply temperature sensor 102, the recovery temperature sensor 104, or the flow rate detection unit 106, the failure of these supply temperature sensors 102, the recovery temperature sensor 104, or the flow rate detection unit 106 may occur. In order to check the status, the meter reader shall check the site by visiting the site where the remote meter calorimeter module is installed. Therefore, it was not possible to read the calories used in the generation or heat use complex in which the remote metering calorimeter module was installed from the point of failure of the remote metering calorimeter module to taking a recovery measure for the remote metering calorimeter module.

In addition, when noise or chattering occurs in the wirings 132 and 133 of the terminal box 108 connecting the calorie calculating module 110 and the communication module 120, the calorie calculating module 110 An error occurs in the calorie pulse and the flow rate pulse transmitted from the communication module 120 to the communication module 120, and the amount of heat calculated by the calorie calculation module 110 is significantly different from the calorie value confirmed by the remote meter reading center 150. There was a problem that occurred.

In addition, although there may be a failure in which fluid leaks in the supply pipe installed in each generation or heat use complex and the pressure of the fluid is lowered, there is currently no apparatus and method for detecting such a failure state.

Therefore, an object of the present invention is to provide a remote meter reading system that minimizes a transmission error of calorie related data read in a calorimeter.

Another object of the present invention is to provide a remote meter reading system that remotely monitors the failure status of the calorimeter in a remote meter reading center.

Another object of the present invention is to provide a remote meter reading system for remotely monitoring the supply pressure of the fluid at the site where the calorimeter is installed.

1 is a schematic block diagram of a remote meter reading calorimeter module according to the prior art,

Figure 2 is a block diagram of a remote meter reading system of the calorimeter according to the present invention,

3 is a detailed block diagram of the remote meter reading calorimeter module and communication module shown in FIG.

<Explanation of symbols for the main parts of the drawings>

102, 302: supply temperature sensor 104, 304: recovery temperature sensor

106, 306: flow rate detection unit 112: calorie calculation unit

122: pulse connection unit 126, 214, 338: modem unit

202, 204: calorimeter module for remote meter reading 206: communication module

212: remote meter reading module 216, 318, 334: storage

308: pressure sensing section 312: terminal section

314 operation and control unit 322 communication module connection unit

332: operation module connection unit 336: communication control unit

According to the present invention for achieving the above object, a system for remote metering and managing the calorimeter at a remote location is installed in each generation or heat use complex, the meter reading data including the calorie use of the calorimeter, the failure state of the calorimeter and the A plurality of remote meter reading calorimeter modules for detecting all or part of the data on the pressure of the fluid supplied to the calorimeter; A communication module connected to all of the remote meter reading calorimeter modules to collect and store all or part of data related to the calories, fault states, and fluid pressures detected by each of the remote meter reading calorimeter modules; And a remote device disposed at the remote location to receive the data from each of the remote meter reading calorimeter modules at a designated meter reading time and to perform calorimeter reading, fault condition monitoring, and fluid pressure monitoring of the calorimeter using the received data. And a meter reading center.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the present invention will be described in detail as follows.

2 shows a block diagram of a remote meter reading system constructed in accordance with the present invention.

The remote meter reading system of the present invention includes a plurality of remote meter reading calorimeter modules 202 and 204, a communication module 206, a communication network 208 and a remote meter reading center 210.

Each remote meter reading calorimeter module (202, 204) is installed in each household or heat use complex, calculates the amount of heat used in heat appliances such as boilers in each household or heat use complex, monitors various fault conditions, The pressure of the fluid supplied to the instrument is detected. Various meter reading data, fault status data and fluid pressure data, including the calories calculated by each remote meter reading calorimeter module 202, 204, are provided to the communication module 206.

Each remote meter reading calorimeter module 202, 204 is cascaded in parallel to the communication module 206. The communication module 206 performs serial communication to collect and store the calories read, the supply pressure, and various fault conditions read from each of the remote meter reading calorimeter modules 202 and 204. Data related to heat, supply pressure, and various fault conditions collected and stored in the communication module 206 are transmitted to the remote meter reading center 210 through the communication network 208 at every meter reading request of the remote meter reading center 210.

Each of the remote meter reading calorimeter modules 202, 204 connected in parallel to the communication module 206, eg, the remote meter reading calorimeter module 202, may be configured as a system together with the communication module 206. have. In the present invention, a module in which the communication module 206 and the remote meter reading calorimeter module 202 are combined is referred to as a remote meter reading master calorimeter module 218. The remote metering calorimeter module 204 connected in parallel to the communication module 206 of the remote metering master calorimeter module 218 is referred to as the remote metering slave calorimeter module. Each of the remote meter reading master calorimeter module 218 and the remote meter reading slave calorimeter 204 is usually manufactured in the form of a printed circuit board (PCB).

The remote meter reading master calorimeter module 218 is installed only in one household or one heat use complex per group residential complex, such as an apartment or apartment house, or in the same unit of apartment, and the slave meter calorimeter module 204 for remote meter reading Installed at each generation or heat use complex and connected in parallel to the communication module 206 of the remote meter reading master calorimeter module 218. In the present invention, the remote meter reading by combining the calorimetric calculation module and the communication module for each generation or heat use complex as in the prior art by installing separately by the remote metering master calorimeter module 218 and the remote metering slave calorimeter 204 Installation costs can be significantly reduced compared to calorimeter modules.

The communication network 208 includes a public communication network using a wired modem, a wired LAN, a dedicated line, and the like, used for communication with the remote meter reading center 210 in the communication module 206. In addition, the communication network 208 may include a wireless communication network when the communication module 206 uses a wireless modem, a wireless LAN, a radio frequency (RF) module, or the like.

The remote meter reading center 210 is connected to the communication module 206 through a communication network 208 at a remote location to collect meter data of each of the remote meter reading calorimeter modules 202 and 204 collected and stored in the communication module 206. It consists of a computer system. The remote meter reading center 210 includes a remote meter reading module 212, a modem unit 214, and a storage unit 216.

The remote meter reading module 212 manages and operates the remote meter reading calorimeter modules 202 and 204, collects various meter reading data from the remote meter reading calorimeter modules 202 and 204, and analyzes various statistics using the collected meter reading data. To monitor the fault status of the remote meter reading calorimeter modules 202 and 204, to set operating parameters of the remote meter reading calorimeter modules 202 and 204, and to monitor the supply pressure, It is a software program. The remote meter reading module 212 connects a data call to the communication module 206 using the modem unit 214 at a predetermined periodic reading time or at any time by the operator. The meter reading temporarily stored in the communication module 206 is performed. Bring in data

The modem unit 214 is configured as a dial-up modem that communicates with the remote meter reading master calorimeter module 218. The modem unit 214 is connected to the remote metering master calorimeter module 218 under the control of the remote metering module 212 to read meter data, supply pressure and fault conditions of the remote metering calorimeter modules 202 and 204. Receive related data.

The storage unit 216 stores data about meter reading data, supply pressure, and fault state received through the modem unit 214. The storage unit 216 is generally configured as a hard disk of a computer system.

3 shows a detailed configuration of the remote meter reading calorimeter module 202, 204 and the communication module 206.

As shown in FIG. 3, each of the remote meter reading calorimeter modules 202 and 204 includes a supply temperature sensor 302, a recovery temperature sensor 304, a flow rate sensing unit 306, a pressure sensing unit 308, and a terminal unit. 312, a calculation and control unit 314, a display unit 316, a storage unit 318, a power supply unit 320, and a communication module connection unit 322, and the communication module 206 includes a calorie calculation module connection unit 332. And a storage unit 334, a communication control unit 336, and a modem unit 338.

The supply temperature sensor 302 is composed of a temperature resistance sensor which is installed in a supply pipe to which the fluid is supplied, and whose resistance value changes according to the temperature of the fluid flowing in the supply pipe, that is, water. The supply temperature sensor 302 detects the temperature of the fluid and provides the detected supply temperature of the fluid to the calculation and control unit 314 through the terminal portion 312.

The recovery temperature sensor 304 is composed of a temperature resistance sensor which is installed in a reflux tube through which the heat-exchanged fluid is recovered and whose resistance value changes according to the temperature of the fluid recovered through the reflux tube. The recovery temperature sensor 304 provides the recovery temperature of the detected fluid to the calculation and control unit 314 through the terminal portion 312.

The flow rate sensing unit 306 detects the flow of the fluid passing through the supply pipe of the calorimeter, and calculates the supply flow rate using the flow rate representing the flow of the fluid and the cross-sectional area of the supply pipe. In addition, the flow rate detection unit 306 generates one flow pulse for each calculated unit flow rate, and provides the generated flow rate pulse to the calculation and control unit 314 through the terminal unit 312.

The pressure sensing unit 308 is composed of a pressure sensor installed in the supply pipe of the calorimeter and the amount of current changes according to the pressure of the fluid flowing in the supply pipe. The amount of current representing the change in pressure detected by the pressure sensing unit 308 is provided to the calculation and control unit 314 through the terminal unit 312 to detect the pressure of the fluid.

The terminal unit 312 is a terminal configured to connect only wires by mounting only terminal terminal components in the PCB-type remote meter reading calorimeter modules 202 and 204. The terminal unit 312 draws an external telephone line 321 and a commercial AC power line 323 into each heat generation complex or a heat use complex, and provides a plurality of wirings 324 and 325 for indoor wiring in each generation or heat use complex. Terminals 326, 327, 328, 329, and 330. The terminal unit 312 supplies power required for the power supply unit 320 and the communication module 206 through the commercial AC power supply line 323. The supply temperature sensor 302, the recovery temperature sensor 304, the flow rate sensing unit 306, and the pressure sensing unit 308 are connected to the wirings 324, 325, 326, and 327 of the terminal unit 312, respectively. An operation and control unit 314, a power supply unit 320, and a modem unit 338 are connected to 328, 329, and 330, respectively.

The calculation and control unit 314 is supplied with the supply temperature, the recovery temperature and the supply temperature provided from the supply temperature sensor 302, the recovery temperature sensor 304, and the flow rate detection unit 306 through the wirings 324, 325, and 326 of the terminal unit 312. The amount of heat is calculated using the flow rate pulse, and the pressure of the fluid according to the change of the amount of current provided from the pressure sensing unit 308 is calculated through the wiring 327 of the terminal unit 312. The calorific value and the fluid pressure calculated by the calculation and the control unit 314 are described as follows.

The calculation and control unit 314 calculates the temperature difference Δt between the supply temperature and the recovery temperature, calculates the flow rate value by counting the flow rate pulse, and converts the calorie conversion factor K into the temperature difference Δt and the flow rate value. Multiply to get calories. The calorific value is calculated at a predetermined time interval or whenever a flow rate pulse is generated in the flow rate sensing unit 306, and is transmitted to the remote meter reading center 210 at every meter reading request of the remote meter reading center 210.

The calculation and control unit 314 is generated according to the pressure of the fluid in the pressure sensing unit 308 converts the provided current value of 4 mA ~ 20 mA to a voltage value, and converts the converted voltage value into a digital voltage value to pressure data Use as. The pressure data generated by the calculation and control unit 314 is transmitted to the remote meter reading center 210 along with the meter data of the calorific value whenever required by the remote meter reading center 210.

In addition, the calculation and control unit 314 performs a function of monitoring a failure of the supply temperature sensor 302, the recovery temperature sensor 304, the flow rate sensing unit 306, the pressure sensing unit 308, and the power supply unit 320. do. The failure monitoring functions of the supply temperature sensor 302, the recovery temperature sensor 304, the flow rate sensing unit 306, the pressure sensing unit 308, and the power supply unit 320 by the calculation and control unit 314 are described below.

The calculation and control unit 314 sets the range of the temperature upper limit value and the temperature lower limit value for the supply temperature sensor 302 and the recovery temperature sensor 304, respectively, to the supply temperature sensor 302 and the recovery temperature sensor 304. When the supply temperature and the recovery temperature detected by the controller deviate from the ranges of the set temperature upper limit value and the lower limit value, the supply temperature sensor 302 and the recovery temperature sensor 304 determine that a failure has occurred, and the failure state is determined by the remote meter reading center 210. Report as.

The calculation and control unit 314 sets a range of the upper limit value to the number of flow pulses generated by the flow rate detection unit 306 to detect the flow rate when the number of flow pulses generated by the flow rate detection unit 306 is outside the set upper limit value. The unit 306 determines that a failure has occurred, and reports the failure state to the remote meter reading center 210.

The calculation and control unit 314 sets the upper limit current value corresponding to the upper limit pressure value and the lower limit current value corresponding to the lower limit pressure value, and the upper limit current value and the lower limit current value to which the current value measured by the pressure sensing unit 308 is set. If out of the range of the pressure sensing unit 308 determines that a failure has occurred, and reports the failure status to the remote meter reading center (210). The upper and lower limit current values may be arbitrarily determined as necessary, but the lower limit current value is preferably 3 mA to 5 mA and the upper limit current value is 15 mA to 25 mA.

The operation and control unit 314 determines that a failure occurs in the power supply unit 320 when a sudden voltage change or the like occurs in the power supply unit 320, and reports the failure state to the remote meter reading center 210.

As described above, the calorific value, the fault state, and the pressure detected by the operation and control unit 314 are reported to the remote meter reading center 210 at every meter reading request of the remote meter reading center 210. Accurate time information is required to report regularly and periodically from the calculation and control unit 314 to the remote meter reading center 210. In most cases, the time information may use a real time clock that is generated by the operation and control unit 314 itself, but the real time clock may be different from the time information of the remote meter reading center 210 after a long time. Errors occur in the time information of each of the remote meter reading calorimeter modules 202 and 204, and these errors gradually accumulate. In order to prevent this, in the present invention, when the periodic meter reading at the remote meter reading center 210, the time information of the remote meter reading center 210 to notify each remote calorimeter module (202, 204) to be modified, Even if a long time passes, error does not occur in time information.

The display unit 316 displays the supply temperature, the recovery temperature, the supply calorific value, the supply flow rate, the fault state, the fluid pressure, etc. calculated by the operation and control unit 314 in numbers, letters, or figures. The amount of heat or flow rate displayed on the display unit 316 is displayed as an accumulated value every time the supply calorie value and the supply flow rate are calculated by the calculation and the control unit 314, and are reset to a zero value for a certain period of time, for example, on a monthly basis.

The storage unit 318 checks the metering data such as supply temperature, recovery temperature, supply calorific value, supply flow rate, and fluid pressure calculated by the operation and control unit 314 and the fault status monitored by the operation and control unit 314 at regular intervals. For example, various parameters required for operation of the remote meter reading calorimeter modules 202 and 204, stored hourly, daily, monthly, and yearly, for example, ID, calorie conversion factor, upper and lower temperature values, and upper and lower flow rates of the remote meter reading calorimeter module. Stores pulse values, upper and lower current values, and so on.

The power supply unit 320 includes an AC-DC converter, and converts AC power provided through the wiring 329 of the terminal unit 312 into DC power for the remote meter reading calorimeter module 202 and 204 and the communication module 206. To feed. When a failure occurs in the commercial AC power input to the power supply unit 320, power supply through the battery is made under operation and control of the controller 314 so that the power supply is not interrupted.

The communication module connection unit 322 is connected in parallel to the communication module 206 through the multipoint bus 340, and under the control of the operation and control unit 314, the meter reading data and the fault state data stored in the storage unit 318. And transmit fluid pressure data to the communication module 206 via the multipoint bus 340.

Meanwhile, the communication module 206 may be included in the remote meter reading master calorimeter module 218 to collect meter reading data, fault state data, and fluid pressure data of each of the remote meter reading calories. And a calculation module connection unit 332, a storage unit 334, a communication control unit 336, and a modem unit 338.

Each of the remote meter reading calorimeter modules 202 and 204 is connected in parallel to the arithmetic module connection unit 332 through the multipoint bus 340, and the meter reading data and the fault provided by the remote meter reading calorimeter modules 202 and 204 are connected. State data and fluid pressure data are received in a serial communication manner.

The multipoint bus 340 is composed of two wires, and the communication module connection part 322 of the remaining remote meter reading calorimeter module 204 other than the remote meter reading calorimeter module 202 is connected in parallel. In the present invention, the communication between each communication module connection unit 322 and the communication module 206 uses an M-bus (Meter Bus) serial communication method or RS-485 serial communication method. The M-bus serial communication method and the RS-485 serial communication method are half duplex in which the other communication module connection part receives only data at the moment when one communication module connection part 322 transmits data to the calculation module connection part 332. Half Duplex) communication method is supported. In addition, the M-bus serial communication method and the RS-485 serial communication method may compensate for an error in transmission data by communication between each communication module connection unit 322 and the calculation module connection unit 332. That is, by sending an error check byte together with the data, it is possible to request the retransmission of the data to receive normal data when an error occurs. Therefore, as in the prior art, it is necessary to transfer meter reading data, fault data, and pressure data in the form of data, without transferring heat and flow values in the form of pulses, but when an error occurs during the transmission of these data. By retransmission, transmission error of data can be minimized.

The storage unit 334 temporarily stores the meter data, the failure state data, and the fluid pressure data provided by each of the remote meter reading calorimeter modules 202 and 204, and stores various parameter values necessary for the operation of the communication module 206. .

The communication control unit 336 temporarily stores the meter reading data, the fault state data, and the fluid pressure data of the plurality of calorie calculation modules 310 connected to the calculation module connection unit 332 in the storage unit 334, and the remote meter reading center 210. In response to the meter reading request, the data stored in the storage unit 334 is transmitted to the remote meter reading center 210 through the modem unit 338 so that a quick response is made. In addition, the communication control unit 336 reports a failure state to the remote meter reading center 210 when a major failure occurs in each calorie calculation module 310.

The modem unit 338 is under the control of the communication control unit 336, the modem of the remote meter reading center 210 via the telephone line 323 connected to the wiring 330 of the terminal portion 312 of the remote meter reading master calorimeter module 218 In communication with the unit 338, the meter reading data, the failure state data, and the fluid pressure data collected in the remote meter reading master calorimeter module 218 are transmitted to the remote meter reading center 210.

Accordingly, the remote meter reading center 210 collects statistics by reading meter data, fault status data, and fluid pressure data of each of the remote meter reading calorimeter modules 202 and 204 transmitted from the respective meter reading master calorimeter module 218. It can be used for analysis, monitor the failure status of each remote metering calorimeter module 202, 204, and check the pressure of the fluid supplied to the site.

The present invention is not limited to the above-described embodiment, it will be understood by those skilled in the art that various modifications and changes can be made without departing from the technical gist of the present invention.

Therefore, according to the present invention described above, by transmitting a calorific value, a flow rate, a pressure, and a fault state in the form of data, not in the form of a pulse, but adopting a method of retransmitting these data when an error occurs during the transmission of these data, The error can be minimized.

In addition, the present invention has the advantage that it is easy to manage and maintain the calorimeter because it can monitor various fault conditions and fluid pressure generated in the calorimeter without remote equipment at a remote location.

In addition, the present invention has the advantage that can greatly reduce the installation cost by configuring a single communication module in the master meter calorimeter module for remote meter reading.

Claims (12)

In the system to remotely read and manage the calorimeter remotely, A plurality of remote meter reading calorimeter modules installed in each generation or heat use complex for detecting all or part of meter data including calories used by the calorimeter, fault status of the calorimeter and data on the pressure of the fluid supplied to the calorimeter. ; A communication module connected to all of the remote meter reading calorimeter modules to collect and store all or part of data related to the calories, failure states, and fluid pressures detected by the remote meter reading calorimeter modules; And A remote meter that is disposed at the remote site and receives the data from each of the remote meter reading calorimeter modules at a designated meter reading time, and performs the calorimeter reading, the fault condition monitoring, and the fluid pressure monitoring of the calorimeter using the received data center Remote meter reading system comprising a. The method of claim 1, The remote meter reading center, A modem unit connected to the communication module through the communication network to receive all or a portion of the meter data, the failure state data, and the pressure data transmitted from the communication module; A storage unit which stores meter reading data, fault state data and pressure data received by the modem unit; And Collect all or part of the reading data, the failure state data and the pressure data from the remote meter reading calorimeter module, statistical analysis using the meter reading data, monitoring the failure status of the remote meter reading calorimeter module, the remote meter reading Remote metering module that monitors the fluid pressure of the calorimeter module to manage and operate the remote meter reading calorimeter module Remote meter reading system comprising a. The method of claim 1, The communication module, An operation module connection unit connected in parallel with each of the remote meter reading calorimeter modules and receiving all or a part of the meter reading data, the fault status data, and the fluid pressure data provided in a serial communication manner from each of the remote meter reading calorimeter modules. ; A storage unit for temporarily storing all or part of the meter data, the fault state data, and the fluid pressure data of each of the remote meter reading calorimeter modules received through the calculation module connection unit; A communication control unit for reporting all or part of the meter reading data, the fault status data, and the fluid pressure data stored in the storage unit to the remote meter reading center; And A modem unit for transmitting meter reading data, fault condition data and fluid pressure data reported to the remote meter reading center under the control of the communication control unit to the remote meter reading center through the communication network. Remote meter reading system comprising a. The method of claim 1, The remote meter reading calorimeter module, A supply temperature sensor detecting a supply temperature of a fluid supplied to the calorimeter; A recovery temperature sensor for detecting a recovery temperature of the fluid recovered from the calorimeter; A flow rate sensor for detecting a flow rate of the fluid supplied to the calorimeter and generating one pulse per detected flow rate; A pressure sensor for generating a pressure of the fluid supplied to the calorimeter as a change in the amount of current; The calorific value is calculated using the difference between the supply temperature and the recovery temperature detected by the supply temperature sensor and the recovery temperature sensor and the flow rate pulse detected by the flow rate sensing unit, and the supply temperature sensor and the recovery temperature sensor And detecting fault conditions of the supply temperature sensor, the recovery temperature sensor, the flow rate sensor, and the pressure sensor by using the upper and lower limits of the temperature, the flow pulse, and the current amount of the flow rate sensor and the pressure sensor. A calculation and control unit for calculating a fluid pressure according to a current change in the pressure sensing unit; A storage unit which stores meter reading data, fault state data, and fluid pressure data generated by the calculation and control unit for a predetermined period; And Under the control of the operation and control unit, the communication module connection unit for transmitting the meter data, the failure state data and the fluid pressure stored in the storage unit to the communication module using a serial communication method Remote meter reading system comprising a. The method of claim 4, wherein The calculation and control unit sets a range of a temperature upper limit value and a temperature lower limit value to the supply temperature sensor and the recovery temperature sensor, respectively, so that the supply temperature and the recovery temperature are outside the ranges of the set temperature upper limit value and the temperature lower limit value. And detecting the failure of the supply temperature sensor and the recovery temperature sensor. The method of claim 4, wherein The calculation and control unit sets an upper limit value to the number of pulses generated by the flow rate sensing unit, and when the pulse number is out of the set upper limit value, the remote meter reading system characterized in that the failure occurs in the flow rate sensing unit . The method of claim 4, wherein The calculation and control unit sets a range of an upper limit value and a lower limit value to the current amount of the pressure sensing unit, and when the amount of current measured by the pressure sensing unit is out of the range of the set upper limit value and the lower limit value, a failure occurs in the pressure sensing unit. A remote meter reading system, characterized in that the detection of the occurrence. The method of claim 4, wherein The calculation and control unit is a remote meter reading system, characterized in that for indicating the specified reading time by referring to the time information provided from the remote meter reading center. The method of claim 4, wherein The remote meter reading calorimeter module further comprises a display unit for displaying the reading data, the failure state and the fluid pressure detected by the operation and control in numbers, letters or figures. The method of claim 4, wherein The serial communication method between each of the remote meter reading calorimeter module and the communication module includes an M-bus (Meter Bus) method or RS-485 method. The method of claim 4, wherein The pressure sensing unit is installed in the supply pipe of the calorimeter remote meter reading system characterized in that consisting of a pressure sensor that changes the amount of current in accordance with the pressure of the fluid. The method of claim 1, Combining the communication module to one of the plurality of remote meter reading calorimeter module to configure a remote meter reading master calorimeter module, The remote meter reading master calorimeter module is installed in any one generation of each of the generations or each heat use complex or one heat use complex.