KR102069727B1 - 6households remote meter for swap protocol control - Google Patents

Abstract

The present invention relates to a remote meter device for 6 households for the swap protocol control. When connected to a DC PLC communication line of water meter, gas, calorie, hot water and cooling related electronic meters, in order to prevent unjust error charging of usage of empty households during error wiring construction or vacation of a facility operator, a control signal of a protocol, an individual profile, and virtual signaling information is generated and analyzed to correspond to and compare a protocol, an individual profile, and virtual signaling information for each pre-stored and managed household, so that the error wiring can be quickly replaced by notifying the control signal to the facility operator or a manager, and a user for each household, and more effectively performing remote metering for the facility operator, the user for each household, and the control manager.

Description

6th generation remote meter for swap protocol control {6households remote meter for swap protocol control}

The present invention relates to a sixth generation remote meter for controlling the swap protocol, the proposed technique of the present invention is a variety of electronic usage meter for the billing of customers, for example, water, gas, electricity, hot water, heating meter Inspect equipment installation wiring errors, such as equipment inspections, in advance, and check the equipment generation wiring errors for 6th generation, which prevents charging errors due to the error wiring by notifying the equipment builder in advance whether the wiring is incorrect. This paper proposes a 6th generation remote metering device for swap protocol control.

In general, an electronic meter that displays the amount of electricity, gas, and water is installed in a consumer building, such as a home, a new building, or an apartment, and facility builders use a meter reading device in a consumer building to purchase a consumer's consumption for each household. The billing is applied in terms of.

On the other hand, the equipment builders have caused the problem of re-construction of the initial equipment by inducing the error meter wiring work in the process of installing the equipment wiring according to the construction and electrical equipment plan. Since it adds to the construction cost, it is urgently needed to notify the equipment builder before the final facility finishing work, and it has been necessary to automatically determine this and restart the wiring as well as the notification.

Recently, due to the development of IoT and information communication technology, the application of the network protocol is being expanded by applying the protocol of the network protocol. However, until now, the facility metering remote system has a different protocol for each manufacturer, and there is the trouble of unifying the facility meter with the product sold by a single manufacturer when configuring the system. It is inconvenient to replace only with the product of a specific maker.

Conventionally, as a remote metering system, the published patent applications of 10-2005-0092617 and 10-2019-0026305 are merely to provide a remote metering system that can efficiently reduce the number of wires by performing a meter-related signal by performing power line communication For the purpose of this, the detailed description of the detailed arrangements for generating the control signal of the swap protocol of the present invention to notify the equipment installer to make the correct wiring is not specified. Therefore, the present invention intends to differentiate the 6th generation remote metering device for swap protocol control from the prior art.

The present invention is to solve the problems of the prior art, an object of the present invention is to generate a control signal of the swap protocol for confirming and notifying the sixth generation meter reading wiring error, and the error wiring by the control signal Swap protocol control video system for detecting and notifying errors of 6G generation meter wiring for detecting errors by rules and using wired / wireless interface unit to perform error notifications to customers' intercoms and equipments. The purpose is to provide. In addition, the swap protocol control imaging system detects a signal of a protocol corresponding to the control signal when a swap protocol control signal is generated, thereby quickly replacing an error wiring, and helps to handle an emergency situation for an on-site meter reading facility. Has a purpose.

In order to achieve the present invention, a sixth generation remote meter reading device for swap protocol control according to the present invention is constructed.

6. A sixth generation remote meter reading device for controlling a swap protocol, comprising: a sixth generation remote meter reading device (10) that is divided into six generations for each generation to remotely measure usage of each generation of devices; An LCD 20 which displays the measured amount by receiving the amount of usage by wire or wireless for each generation of usage; A measurement meter 30 for measuring the usage amount for each generation; A generation error meter 40 for checking the error wiring for each generation; And a distribution line for electrically connecting the sixth generation remote meter reader 10, the measurement meter 30, and the error meter 40 to each other.

The generation error gauge 40 is configured to be attached to and detached from the mounting holder 50, when the error wiring check and check, the error measuring instrument 40 is mounted to the mounting holder 50, and used as the mounting holder 50 Is characterized in that it comprises electrically connected to the wiring line at the lower terminal of the meter 30.

A swap protocol receiver (100) configured in the sixth generation remote meter (10); A swap protocol transmitter 200 included in the mounting holder 50; The generation meter 30 for each generation is characterized in that it comprises a meter for each device (210 ~ 214) for measuring the five kinds of usage of water, gas, heat, hot water, cooling for each generation.

The swap protocol transmitter 200 includes a sequential identifier converter 233 for temporarily converting an identifier protocol of each generation sequentially; It characterized in that it comprises a; integrated microcomputer controller 150 for each generation swap protocol control

The swap protocol transmitter 200 generates and stores an identifier protocol of each generation, transmits the generated identifier protocol of each generation to the swap protocol receiver 100, assigns an identifier protocol for each generation, and swap protocol when checking an error wiring. And comparing the identifier protocol of the receiver 100 with the identifier protocol of the swap protocol transmitter 200 to identify the error wiring.

The integrated microcomputer controller 150 compares the generation protocol of each generation assigned to the swap protocol receiving unit 100 with the generation protocol of the generation protocols stored in the swap protocol transmitting unit 200, and when a match is found, a green LED is turned on. Or a blinking, and if there is a mismatch, it is characterized in that it comprises a protocol incorrect wiring determination unit 154 to display the identification so that the green LED does not turn on.

The swap protocol control imaging system for checking and notifying the 6th generation meter wiring error of the present invention detects a protocol control signal for error wiring during the construction of a meter facility and notifies or informs the error information of the facility of a supplementary facility later. Information is provided using a wired or wireless interface, and the swap protocol control video system detects a signal of a protocol corresponding to the control signal when a swap protocol control signal is generated, and quickly reconnects correctly. It has the effect of preventing inadvertent charging due to the error wiring.

1 is a connection diagram of a remote generation meter for sixth generation of the normal generation protocol rules of the present invention
2 is a connection configuration diagram of a connection configuration diagram of an error generation protocol rule of a sixth generation remote metering device according to the present invention.
Figure 3 is a detailed block diagram of the Swap protocol transmitter of the sixth generation remote meter reading apparatus of the present invention
4 is a detailed configuration diagram of the Swap protocol receiver of the sixth generation remote meter reading apparatus of the present invention
5 is a detailed block diagram of the integrated micom control unit for the Swap protocol control of the present invention

Hereinafter, with reference to the accompanying drawings (Figs. 1 to 5) with respect to the configuration and operation of the embodiment of the present invention will be described in detail.

1 shows a connection diagram of a sixth generation remote metering device according to the normal generation protocol rule of the present invention.

The sixth generation remote meter reading device is divided into six generations for each generation and the sixth generation remote meter reader 10 for remotely measuring the usage amount of each generation device; An LCD 20 which displays the measured amount by receiving the amount of usage by wire or wireless for each generation of usage; A measurement meter 30 for measuring the usage amount for each generation; A generation error meter 40 for checking the error wiring for each generation; And a distribution line for electrically connecting the sixth generation remote meter reader 10, the measurement meter 30, and the error meter 40 to each other.

The sixth generation remote meter reading device includes a swap protocol receiver 100 configured inside the sixth generation remote meter reader 10; A swap protocol transmitter 200 included in the mounting holder 50; The generation meter 30 for each generation includes a meter for each device (210 ~ 214) for measuring the five types of usage of water, gas, heat, hot water, cooling for each generation, the distribution line is DC PLC (direct current A power line) is electrically connected between the swap protocol receiver 100 and the swap protocol transmitter 200 for each generation through a communication line, and the communication line is any one of RS-232, RS-422, and RS-485; Characterized in that.

The sixth generation remote meter reader 10 is divided by each generation so as to be displayed on the LCD 20 for the usage of each generation of devices, including a swap protocol receiver 100, the generation meter 30 for each generation ) Is divided into 30-1, 30-2, 30-3, 30-4, 30-5, 30-6 for each household, and water, gas, calories, hot water, air-conditioning (heating) It is configured to be connected and connected to each device to perform five kinds of meter reading.

The error measuring unit 40 for each generation is disposed one by one for each generation, is configured to be detachable to the mounting holder 50, the error measuring instrument 40 is mounted on the mounting holder 50 when checking the error wiring check When the inspection is completed, the error measuring instrument 40 is removed from the mounting holder 50 and removed. The mounting holder 50 is electrically connected to the wiring line 40 at the lower end of the measurement meter 30 terminal. In the case of the error measuring instrument 40 mounted to the mounting holder 50 is configured to be connected to each other via the measurement meter 30 and the mounting holder 50, the mounting holder 50 is remote for 6 generations It comprises a swap protocol transmitter 200 for transmitting and receiving with the swap protocol receiver 100 of the meter reader 10, the error meter 40 is replaced by a portable portable device or a mobile phone function and the error meter 40 Inside the 6th generation remote meter (10) The swap protocol related program includes an integrated microcomputer control unit in which the swap protocol related program is embedded, and the swap protocol related program can be downloaded through the 6G remote meter reader 10 or the app can be downloaded and used on the Internet.

In addition, the connection connection between the swap protocol receiver 100 and the swap protocol transmitter 200 may be connected through a wired or wireless communication line, and the LCD displays a current usage amount.

In general, since the meter 30 connected to each generation uses all the same protocols, it is difficult to check even if a wiring error occurs when connecting a device for each generation in the field, but an embodiment of the present invention provides a swap protocol transmitter ( After generating the identification protocol for each household through 200), the identification number for each household is assigned to check whether it is incorrectly wired. Therefore, it is possible to reconnect correctly easily so that there is no unfair charging due to the error wiring of each household. It has the effect of preventing in advance.

For example, in the present embodiment, the measurement meter 30 is divided into households, and each generation meter includes five types of meters (water, gas, calorific value, hot water, and cooling) inside the measurement meter 30. In addition, the measurement meter 30 for each generation is for checking whether there is an error wiring in the wiring connection state with the 6th generation remote meter 10 and the swap protocol transmitter 200 is the first generation for each generation. The A1 identifier protocol, the second generation A2 identifier protocol, the third generation A3 identifier protocol, the fourth generation A4 identifier protocol, the fifth generation A5 identifier protocol, the sixth generation A6 identifier protocol Create, store, and transmit the generated identifier protocol to the swap protocol receiver 100 so that the swap protocol receiver 100 can assign an identifier protocol for each generation, and the swap protocol receiver The identifier protocol of 100 and the swap protocol transmitter 200 compare the identifier protocol to check the error wiring, and the power supply of the DC PLC communication line is characterized in that a power supply of 12V is supported.

In addition, the error measuring instrument 40 is used to attach to the mounting holder 40 when it is necessary to check whether or not the error wiring, the error measuring instrument 30 is attached to each generation when checking the wiring error check and when the check is finished It is configured to be separated and removed, and can also be applied to each generation by one error measuring instrument 40 individually to check whether the error wiring, the error meter 40 is required to check whether the error wiring In case of new facility construction, interim replacement and renovation work, either the accumulated usage of the meter for each household is detected as overuse or underuse over a certain amount compared to average usage per month or average use over the last 6 months. Characterized in that case.

The swap protocol receiver 100 and the swap protocol transmitter 200 are shown in solid lines to facilitate identification between components, and the swap protocol receiver 100 is configured inside the 6th generation remote meter 10. The swap protocol transmitter 200 may be configured in the mounting holder 50, and may be configured in each generation of the error measuring unit 40 by using the swap protocol program included in each generation of the error measuring unit 40. The integrated management using the swap protocol transmitter 200 also has a possible feature.

In the present invention, the expression of the sixth generation remote metering device is not limited to the sixth generation, but is merely divided into six generations for easy description in the present invention. Hundreds of households can be divided into unit groups.

Figure 2 shows a connection diagram for the error generation protocol of the sixth generation remote metering apparatus of the present invention.

FIG. 2 illustrates a case in which the first and third generation meter meters 30-1 and 30-3 are inverted due to the installation of equipment or error wiring when the measurement meter 30 is replaced. ) Is mounted and connected to the mounting holder 50 at the bottom of the measurement meter 30 terminal for each generation, the swap protocol transmitter 200 generates an identifier protocol for each generation, and then receives the receiver of the sixth generation remote meter reader 10. To transmit the identifier protocols A1 to A6 for each household by transmitting them to the profile storage unit 130 for each protocol / generation and to manage them.

In addition, the swap protocol transmitter 200 stores the identifier protocols A1 to A6 generated for each generation in the protocol storage for each generation, and the sixth generation of the identifier protocols A1 to A6 generated for each sixth generation. Match the instruments 40-1 to 40-6, i.e. A1 is 40-1, A2 is 40-2, A3 is 40-3, A4 is 40-4, A5 is 40-5, A6 will be stored and managed in line with 40-6.

The swap protocol transmitter 200 includes an error meter 40 for each generation, and the error meter 40 for each generation includes the LCD display 40a, a green LED 40b, an on button 40c, and an off button. 40d, the sequential identifier conversion button 40e, and the confirmation button 40f.

After connecting the error measuring device 40 for each generation to the lower end of the measurement meter 30 terminal for each generation, and then pressing the on button 40c, the swap protocol transmitter 200 described above provides an identifier protocol for each generation. Create and store, send to the receiver of the sixth generation remote meter reader 10 to give the identifier protocol A1 to A6 for each generation and store it, and store the identifier protocol (A1 to A6) generated for each sixth generation After performing a series of processes to match the 6th generation error measuring instruments (40-1 ~ 40-6), each generation identifier stored in the swap protocol receiving unit 100 in the generation-specific protocol identification unit 300 of FIG. The protocol is compared with the identifier protocol for each generation stored in the swap protocol transmitter 200.

The embodiment corresponds to the case where the measurement meter 30 of the first and third generations is reversed, and in this case, the second and fourth generations of the fourth and sixth generations are green in the error meter 40 of each generation. Since the LED is operated and the first and third generation green LEDs are not operated, it is possible to check the error wiring for the measurement meter 30 of the first and third generation and to make the correct wiring.

However, in case of error wiring check and check, if the second generation has an error wiring, change wiring for the second generation, and connect. Keep the operating state, press the sequential identifier conversion button (30-5) for each error meter 40 for each generation of the error meter (40) that the green LED is not operated to check the error wiring to induce correct wiring Done.

Since each generation error meter 40 includes an app with a built-in program related to the swap protocol transmitter 200, the generation error indicator 40 of each generation is provided with the same identifier protocol as that of each generation identifier protocol. In addition, each generation identifier protocol for the entire 6 generations is also stored, and each generation identifier protocol (sequential) is sequentially displayed on the display window each time the sequential identifier conversion button 40e of the error generation instrument 40 for each generation is pressed. A1 to A6) are configured to appear sequentially, and when the corresponding identifier protocol is selected (operation button operation), the identifier protocol selected by the corresponding error meter 40 is temporarily assigned to the corresponding error meter 40 to store the changed identifier protocol. do.

For example, in the 6th generation remote meter reader, the 1st generation, 5th generation, and 6th generation LEDs operate normally, and the 2nd generation (A2), the 3rd generation (A3), and the 4th generation (A4) If the green LED does not operate due to a mutual wiring error, the 2nd generation error measuring instrument 40-2 selects the identifier protocol A3 of the 3rd generation A3 through the sequential identifier conversion button 40e and selects 2 After changing the identifier protocol of the call generation error meter 40-2 from A2 to A3 temporarily, and then pressing the confirmation button 40f, if the green LED is operated, the swap protocol receiver 100 is the 6th generation remote meter reader 10 It is understood that the second generation (A2) of) is an error wiring since it is wired with the swap protocol transmitter 100, that is, the third generation error meter 40-3.

When changing the identifier protocol through the sequential identifier conversion button 40e, out of six protocols of each sixth generation, generation 1, generation 5, and generation 6 are normal operations, except for the second generation that do not operate. In this case, the identification protocol (A2, A3, A4) corresponding to the 3rd and 4th generations of the identification protocols is temporarily converted to the inspection, so that the inspection can be performed quickly.

In addition, if the green LED does not operate despite the change of the identifier protocol of the second generation error measuring instrument 40-2 from A2 to A3, the identifier protocol A2 stored in the second generation error measuring instrument 40-2 is changed. In the same manner as the method described above, change to the fourth generation identifier protocol A4 to check and check, and if the green LED operates as a result of the check, the second generation of the swap protocol receiver 100 and the sixth generation remote meter 10 ( A2) is in the state of being wired with the swap protocol transmitter 100, that is, the 4th generation error meter 40-4, and it can be seen that it is an error wiring.

In addition, if the third generation error meter 40-3 or the fourth generation error meter 40-4 is checked in the same manner, the remaining wiring errors can be easily found, so that there is no unreasonable charge due to the error wiring. It has an effect of preventing in advance.

Figure 3 shows a detailed configuration of the Swap protocol transmitter of the sixth generation remote meter reader of the present invention.

The detailed configuration of the Swap protocol transmitter 200 is composed of a meter unit, a protocol information generator, and an integrated control unit for each generation, and the meter unit for each generation is a water meter 210, a gas meter 211, and a calorimeter. The meter 212, the hot water meter 213, the cooling meter 214, the protocol information generation unit generation protocol identification unit 220, generation protocol storage unit 221, usage meter reading storage unit 222, the generation profile storage unit 223, wherein the integrated control unit includes a wired / wireless interface unit 230, a protocol information transmitting unit 231, a generational profile transmitting unit 232, and a sequential identifier converting unit ( 233).

The household meter unit comprises a water meter, a gas meter, a calorimeter, a hot water meter and a cooling meter (including a heating meter) for each household. It is detected by the number of and accumulated on the meter and displayed.

The protocol information generation unit generation generation protocol identification unit 220 for presetting each generation identifier protocol in advance, and generation-specific protocol storage unit for storing the generation-specific protocol set by the generation-specific protocol identification unit 220 ( 221, a usage meter reading unit 222 for storing a usage meter reading value for each household, and a generational profile storage unit 223 for storing household information.

The generation protocol identification unit 220 generates a protocol for each generation of the lakes (1 to 6) corresponding to each generation, based on the integration result value (usage) of the usage amount of each generation, Swap protocol transmission unit 200 An identifier protocol is assigned to each generation through the generation, and the identification for each generation is identified using a format for protocol identification, and the attributes of the protocol format include a data identification field, a length field, an address field, an error check field, and an end. Field, protocol generation signal information field, and generation profile information field.

The generational protocol storage unit 221 stores and manages the generational identifier protocol signal generated by the generational protocol identification unit 220, and also changes the temporary identifier protocol due to the operation of the sequential identifier conversion button 40e. Will also be stored.

The meter reading storage unit 222 stores the data value by remotely reading in real time the number of the meter reading and the current meter reading data from the cumulative meter reading data measured by the meter for each generation.

The household profile storage unit 223 stores household profile information for each household separately from the protocol identification for each household, and the household profile information includes household ID, designated password, number of household members, and average monthly usage. In the last 6 months, the average usage is stored.

For example, if the cumulative amount of wiring work due to an error or vacation generation is charged over the average usage of the month, the history by the integrated micom control unit 150 for the Swap protocol control of the sixth generation remote meter reader of FIG. Managed by the table unit 155, the error value details of the total amount and the charge is notified to the notification unit 156 or the display unit 157 through the accumulated amount and charge details for each household displayed in the history table unit 155 It has the effect of preventing the error of billing by generation.

The integrated control unit includes a wired and wireless interface unit 230 for transmitting and receiving a wired and wireless connection with the swap protocol receiving unit 100, a protocol information transmitting unit 231 for transmitting a protocol for each generation, and a profile for each generation. Generation profile transmission unit 232 for transmitting the sequential protocol conversion unit 233 is configured to include.

The wired / wireless interface unit 230 selects any one of RS-232, RS-422, and RS-485 as a communication line to enable transmission and reception with the Swap protocol receiver 100 so as to use HDMI capable of image transmission. It is composed.

In addition, the wired / wireless interface unit 230 includes a small CCD character recognition camera (including an OCR) on each of the measurement meters 210 to 214 so that the meter reading value read by the generation meter 30 for each generation can be used together with the image. It can be configured to recognize and detect the reading number of each reading image, and to convert the image to text processing to transmit the recognition signal of the corresponding integration amount to the Swap protocol receiver 100.

The protocol information transmission unit 231 transmits the generation protocol identifier for each generation stored in the protocol storage unit 221 for each generation to the swap protocol receiver 100, and also provides usage meter reading related information stored in the usage meter reading storage unit 222. Swap protocol receiver 100 transmits.

The generational profile transmitter 232 transmits the generational profile information for each generation stored in the generational profile storage 223 to the receiver 100.

The sequential identifier converting unit 233 sequentially generates 6 generations of identifier protocols for each generation of protocols generated by each generation and stores the generation protocols for each generation when the sequential protocol conversion button is pressed in FIG. 2. The temporary identifier protocol changed due to the operation of the sequential identifier converting unit 233 is stored and managed in the generational protocol storage unit 221 and uses the corresponding information when necessary.

Figure 4 shows a detailed configuration of the Swap protocol receiver of the sixth generation remote meter reader of the present invention.

The swap protocol receiver 100 of the sixth generation remote meter reader 10 includes a protocol / generation profile information receiver 110, a protocol / generation profile information classification unit 120, and a protocol / generation profile information storage unit 130. ), The information selecting unit 140, the integrated microcomputer control unit 150, and the image processing unit 160.

The protocol / generation profile information receiving unit 110 receives a signal for the integrated information including the identifier protocol, generation profile information, usage meter reading information, etc. for each generation.

The protocol / generation profile information classification unit 120 classifies data by classifying the integrated information including protocol, generation profile, and usage metering information to classify the respective information according to the attribute. .

The protocol / generation profile information storage unit 130 stores and manages the information classified by each attribute in the protocol / generation profile information classification unit 120.

The information selection unit 140 is configured to allow the equipment builder to directly select the information from the sixth generation remote meter reader 10 to determine the error wiring, in this case to download the SWAP program-related app to the portable device or mobile phone After running the app, it is configured to check the fault wiring in the same way

A detailed description of the integrated microcomputer controller 150 will be described with reference to FIG. 5.

The image processor 160 obtains a captured image of any one or more of images captured in real time by a generation meter of the measurement meter from a small CCD character recognition camera (including an OCR), and the device-specific meters 210 to ˜ of the measurement meter 30. 214, each of the meter reading number is recognized by the image recognition, and the image processing is converted into a text to transfer the integrated amount to the integrated microcomputer controller 150, a small CCD character recognition camera which is a technical feature of the image processor 160 Acquiring and processing captured images by capturing them in real time (including OCR) is installed as a double check concept in case an error occurs in the meter unit of each generation, so it can be selectively selected and used by the user. Do.

The meter reading value captured by the image processor 160 is transmitted to and stored in the history table unit 155 inside the integrated microcomputer controller 150, and is measured in real time by the comparator 152 inside the integrated microcomputer controller 150. If a difference occurs by comparing the detected value of the usage detected by the meter 30 with the detected value captured by the image processor 160, the notification unit 156 and the display unit 157 are notified through a related configuration and related process. By making it possible to check whether there is an error wiring, it is possible to induce a quick check of the error wiring, thereby preventing the unfair charging from occurring.

5 is related to the integrated micom control unit 150 for the Swap protocol control of the present invention.

The integrated microcomputer controller 150 may include a protocol / generation profile information analysis unit 151, a comparison unit 152, a protocol / generation profile determination unit 153, a protocol miswiring determination unit 154, and a history table unit ( 155, a notification unit 156, a display unit 157, and an interface unit 158.

The protocol / generation profile information analysis unit 151 classifies the reception information for each generation information into categories so that the reception information of each generation information can be compared with previously stored information, and analyzes the corresponding information. Will be

The comparison unit 152 compares the protocol information of each generation with the previously stored information based on the information analyzed by the protocol / generation profile information analysis unit 151 with respect to the protocol / generation profile. In addition, it is compared with the amount of usage present in the current measurement based on information such as the profile of each generation, ID of each household, designated password, number of household members, average monthly usage, and average monthly usage.

In addition, when the on button 40c is pressed in FIG. 2, the comparison unit 152 selects each generation identifier protocol signal stored in the swap protocol receiver 100 and each generation identifier protocol signal stored in the swap protocol transmitter 200. In the case of pressing the confirmation button 40f in FIG. 2, the identifier protocol signal of the corresponding generation stored in the error measurer 40 of the corresponding generation is temporarily changed in the SWAP protocol receiving unit 100 and the SWAP protocol transmitting unit 200. Will be compared.

The protocol / generation profile determining unit 153 compares the average monthly usage or the last 6 months average usage with the currently measured usage based on the number of members of each household based on the information of the personal profile, or overuse a predetermined amount or more. If it detects under-use under a certain amount, it is determined whether it is applicable.The above-mentioned amount means that the currently measured usage increases by more than 20% or decreases by less than 20% of the average monthly use of each household, or averages the last six months of each household. It means that the amount of usage increases by more than 10% or decreases by less than 10%. If it is determined that the amount is used more than the predetermined amount or less than the predetermined amount, the corresponding data is transmitted to the protocol miswiring determination unit 154 to determine the error wiring. Has characteristics.

The protocol miswiring determination unit 154 determines whether there is a miswiring connection connection for each generation call, and the currently measured usage amount based on the data transmitted to the protocol / generation profile determining unit 153 for one month. If it is determined that the wiring has been used more than a certain amount or under the predetermined amount by comparing the average usage of the average usage or the last 6 months and the currently measured usage, it is determined to be in error wiring. Inform them to re-route the wiring errors quickly and correctly.

In addition, the protocol miswiring determination unit 154 is connected to the SWAP protocol receiver 100 and the SWAP protocol transmitter 200 in relation to the operation of the on button 40c or the confirmation button 40f transmitted from the comparator 152. The green LED is turned on or flashes when the stored identifier protocol signals for each generation are matched, and the green LED is not turned on when they are not matched. Also, the SWAP protocol receiver 100 and the SWAP protocol transmitter 200 The green LED turns on or blinks when the generation protocol of each generation that is temporarily changed is matched, and the green LED does not turn on when it does not match.

The history table unit 155 is a comparison unit and information associated with the household profile for the monthly usage and integration amount, monthly average usage, last 6 months average usage, billing details appearing in each generation meter 30 152 and the history of information generated by the protocol miswiring determination unit 165 are stored in the form of a table so that related data can be checked if necessary, and can be finally transmitted to the display unit 157 for display. It can be configured to simply display the final result value, or can be configured and displayed in a table form for easy viewing by the administrator.

When the notification unit 156 or the display unit 157 is determined to be an error wiring through a swap control signal, it informs one or more of the system manager, the contractor, the user's wall pad of each household, and the control unit to make unreasonable billing. It is configured to inform correct wiring for fault wiring so that it does not occur.

The interface unit 158 is configured to execute an input / output function for transmitting and receiving a signal related to the integrated microcomputer control unit 150.

The above embodiments may be configured by selectively combining all or some of the embodiments so that various modifications can be made.

10 6th Generation Remote Meter 20 LCD
30 Meter 40 Error Instrument
50 Mounting Holder
100 swap protocol receiver
150 integrated microcomputer control unit
151 Profile / Information Profile Analysis Unit by Protocol / Generation
152 Comparison Unit 153 Protocol / Generation Profile Determination Unit (153)
154 Protocol Wrong Decision Unit 155 History Table Unit
156 Notification section 157 Display section
158 interface
200 swap protocol transmitter
210 water meter 211 gas meter
212 calorie meter 213 hot water meter
214 Air Conditioner 220 Generation Protocol Identification Unit
221 Protocol Storage Unit by Generation 222 Meter Reading Storage Unit
223 Generation profile storage unit 230 U, wireless interface unit
231 Protocol information transmitter 232 Profile transmitter by generation
233 Sequential Protocol Conversion Unit

Claims (6)

In the 6th generation remote metering device for swap protocol control,
A remote meter reader 10 that is divided into six generations for each generation to remotely measure the usage of each generation of devices; An LCD 20 which displays the measured amount by receiving the amount of usage by wire or wireless for each generation of usage; Measuring meter 30 for each generation; A generation error meter 40 for checking error wiring for each generation; And a distribution line for electrically connecting the remote meter reader 10, the measurement meter 30, and the error meter 40 to each other.
The generation error gauge 40 is configured to be attached to and detached from the mounting holder 50, when the error wiring check and check the error measuring instrument 40 is mounted to the mounting holder 50, the mounting holder 50 Includes an electrical connection with a wire line 40 at a lower end of the measurement meter 30 terminal,
The error measuring device 30 is attached to each generation during the wiring error check check, and used for each generation, and after the check check, the sixth generation remote metering device for the swap protocol control, characterized in that it comprises a configuration used to be removed . delete The method of claim 1,
A swap protocol receiver (100) configured inside the sixth generation remote meter (10); A swap protocol transmitter 200 included in the mounting holder 50; The generation meter 30 for each generation includes a meter for each device (210 ~ 214) for measuring the five types of usage of water, gas, heat, hot water, cooling for each generation for the swap protocol control 6th generation remote meter reading device. The method of claim 3, wherein
The swap protocol transmitter 200 includes a sequential identifier converter for temporarily converting an identifier protocol of each generation sequentially; Integrated microcomputer control unit 150 for each generation of the swap protocol control; Remote meter reading device for the sixth generation for swap protocol control comprising a. The method of claim 3, wherein
The swap protocol transmitter 200 generates and stores an identifier protocol of each generation, transmits the generated identifier protocol of each generation to the swap protocol receiver 100, assigns an identifier protocol for each generation, and swap protocol when checking an error wiring. The sixth generation remote meter reading device for swap protocol control, comprising a configuration for comparing the identifier protocol of the receiver 100 and the identifier protocol of the swap protocol transmitter 200 to check the error wiring. The method of claim 4, wherein
The integrated microcomputer controller 150 compares the generation protocol of each generation assigned to the swap protocol receiving unit 100 with the generation protocol of each generation stored in the swap protocol transmitting unit 200, and when it matches, the green LED is turned on. Or a blinking, and if there is a mismatch, the protocol miswire determination unit 154 for identifying the indicator so that the green LED does not light up.

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