KR101231697B1 - Method for correction meter reading data of waterworks consumer - Google Patents

Abstract

PURPOSE: A water supply customer metering data correction method is provided to select a certain period of time as a reference model among information collected by a plurality of metermen and correct the omitted metering amount, thereby calculating the accurate metering amount. CONSTITUTION: Metering information of one metering section is selected as a reference model(S501). A correction rate in a correction object period is calculated from flow information(S502). Each correction rate is multiplied by a daily average in a second metering section to correct the amount of daily meter(S503,S504). The amount of corrected monthly meter in the second metering section is calculated(S506). The amount of corrected monthly meter in the second metering section is stored(S507). [Reference numerals] (S501) Selecting a period metered by a meterman as a reference model by selecting one metering section among a plurality of metering sections as a reference metering section; (S502) Correcting the metered period in a second metering section; (S503) Converting a monthly integration amount into a daily average; (S504) Calculating a correction rate in a correction period; (S505) Correcting a daily metering amount of a mismatched data; (S506) Calculating a monthly metering amount in the second metering section; (S507) Storing in a metering amount correction server; (S508) The other metering section?; (S509) Correcting in a third metering section; (S510) Adding the metering amount in all sections

Description

Method for Correction Meter Reading Data of Waterworks Consumer}

The present invention relates to a method for correcting meter reading data of a water supply customer, and more particularly, to a method of increasing the accuracy of a flow rate calculated by using a supply flow rate and a meter reading amount of a water supply inflow flow meter for each block.

In general, with the introduction of a block system for the purpose of water management, a supply flow meter is installed for each of a plurality of blocks, and the flow rate (% is measured using the sum of the total water readings of the corresponding block by measuring the supply of tap water with the supply flow meter). In the block system, the water purification system in the water purification plant goes through a plurality of reservoirs before being supplied to a home or office, and a water treatment plant supplies water through several reservoirs. A water supply zone for supplying constant water to each of the plurality of reservoirs is called a block, and the constant water is supplied to a home or office through a drain pipe connected to the drain main pipe through a drain main pipe connected to the drain water. The water supply area for each drain pipe is called a small block. Meanwhile, the flow rate (%) means the ratio of the total output of the tap water to the total output of the amount that generates the monetary income for the water supply, and the formula for calculating the flow rate is (flow rate / output) * 100. Here, the amount of running water is included in the effective water in the total supply of tap water and is approximately equal to the amount of meter reading.

Flow rate is recognized as data of management performance of water supply projects of water service providers and local governments in Korea. This can be thought of from three perspectives: economic feasibility, suitability for operational management, and investment efficiency. The low flow rate means that the economic recovery rate is low for the cost of production. Improving the flow rate is essential for the sound financial operation of water supply projects. In terms of operation management, high flow rate means good management condition from tap water production to toll collection, and low flow rate indicates problems in the operation management of facilities, such as meter deadness, leakage, fraud, etc. You can conclude that there is. In addition, the expansion and investment of water supply facilities are enormously funded, and there are various constraints in making decisions about proper replacement / replacement. This is because it is very difficult to make decisions about how and where to prioritize facility expansion, facility improvement, and operation improvement by comparing / analyzing the amount of tap water and the amount of tap water lost. In this case, the flow rate is an important indicator in deciding whether to expand the facility in terms of water supply management. Therefore, it is very important to increase the accuracy of the flow rate analysis.

In the past, the meter reading of the amount of water used by the metering staff visited each customer to read, record, and collect a meter installed in the customer. In the block system, a large number of meter readers read the data in units of blocks, and thus, the metering zones are divided by blocks, and a plurality of meter readers perform meter reading at different times. Therefore, the total meter reading of customers read at different time periods in each block reading area is used to calculate the flow rate of the block, and there is a limit in calculating accurate meter reading, such as an error in flow rate analysis. There was a problem. Meanwhile, the term block refers to a small block.

In addition, the above-mentioned problem is solved by introducing the automatic meter reading system at the same time by the introduction of the automatic meter reading system, but it is not only expensive to apply and apply the automatic meter reading system, but also due to the communication cost due to the meter reading. The proliferation is slowing down.

On the other hand, as a prior art, the rate control system linked to the rate management system of the Republic of Korea Patent Publication No. 10-1042304 is a rate management system for recording and managing the meter flow rate information of the customer, and installed in the water supply pipe network to remotely detect the flow rate and oil pressure The flow rate and leakage rate analysis system calculates monthly or / and daily flow rate variation, flow rate and leakage rate for each block in the block monitoring control system information, and if the daily flow rate is 10% or more, a leak state alarm is generated in the corresponding block. Is disclosed. This provides the convenience of calculating monthly or / and daily flow rate fluctuations, flow rates, and leak rates for each block, but limits the yield of more accurate flow rates, along with the complexity of the system and the cost of installing them. There was.

The present invention is to solve the above problems, by selecting any one of the periods of information read by a plurality of meter readers for each block as a reference model to correct the amount of readings missed in other periods more accurate monthly unit The purpose is to be able to calculate the meter reading.

In addition, the present invention can calculate the more accurate flow rate by minimizing the customer reading error when calculating the flow rate for each block, the determination of the timing of the diagnosis and maintenance of the whole or relevant block of water, and the setting of maintenance costs This is another purpose to be able to reflect on policy decisions.

In order to achieve the above object of the present invention, (a) charge control through wired / wireless communication network at a meter reader terminal for information read by a plurality of meter readers for a predetermined period of time in a plurality of consumers in each block in a plurality of meter zones When transmitting to the server, the charge management server transmits the received meter reading information to the meter reading correction server, and the meter reading correction server uses the meter reading information of one meter reading area as a reference model from the meter reading information for a plurality of meter reading areas received. Selecting; (b) The meter reading correction server converts the monthly accumulated meter reading into a daily average from the meter reading information read in the second meter reading area, in addition to the selected reference model, and calculates the period of the correction from the flow rate information measured and transmitted by the supply flow meter. Calculating a calibration period of the reference model that does not coincide with the metering period of the metering zone; (c) the meter reading correction server correcting the daily meter reading by multiplying the daily average in the second meter reading area by the correction ratio of the period to be corrected; (d) the meter reading correction server calculates a corrected month reading of the second meter reading area, including a period not matching the reference model, and (e) a second meter reading at the meter reading correction server. Stores the corrected monthly meter reading information of the zone and, if there is a third or more different meter reading zone, repeats the steps (b) to (d) after reading the meter reading information from the third or more other meter reading zone. It is characterized in that it provides a water supply customer reading data correction method comprising the step of integrating the corrected reading amount for the entire block.

In addition, in the step (a), the meter reading information includes a meter reading date, meter reading amount and meter reading period.

In addition, in step (b), the monthly integrated meter reading amount SUMa for the second meter reading area is divided by the number of days of the meter reading period and converted into a daily average (k), and on the i-i + n days of the correction target period. each one supply flow rate of the measurement in the supply flow meter _{(a i ~ a i + n} ) a second average daily feed rate (Aa) by dividing the correction ratio of the measurement in the supply flow meter during the reading period of the reading zone the month (b _i to b _{i + n} ).

In addition, in the step (c), the daily reading amount is corrected by multiplying each of the correction ratios b _i to b _{i + n} by the daily average k in the second reading range for the period to be corrected.

In addition, in the step (d), the correction month reading amount of the second reading area is

It is made to calculate.

Further, in the step (e), the corrected reading amount for all blocks is (corrected monthly reading amount in the second reading area) + (month reading amount in the reference model) + (corrected month in the third reading area) Can be integrated with a meter reading).

According to the present invention, the meter reading data of the customer read per unit block is corrected for each period from the reference model to improve the accuracy of the overestimated or underestimated flow rate, and to provide a more accurate flow rate of the entire jurisdiction water supply. The water supply for each block can be diagnosed, and there is an advantage that can be reflected in the decision making such as determining the maintenance time and calculating the maintenance cost.

1 is a configuration diagram showing a system for correcting water supply meter reading data according to an embodiment of the present invention.
2 is a flowchart illustrating a method of correcting water supply meter reading data according to the present invention.
3 is a flowchart illustrating a main method of correcting tap water meter reading data according to the present invention.
Figure 4 is a schematic diagram showing the division of a block for supplying tap water in the block system into a plurality of meter reading area.
5 is a graph showing the flow rate supplied to the customer in the block system, the data read by the corresponding meter for each period of the meter reading area.
6 is a graph showing the flow rate supplied to the customer in the block system by the monthly reading amount corrected for each reading area.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings for a method for calibrating tap water meter reading data.

In FIG. 1, the meter reader terminal 10 can read and input a meter by installing a water meter installed in a water supply customer, and includes a PDA, a smartphone, a tablet PC, etc., which is improved in portability and mobility. The meter reader terminal 10 has a built-in program capable of inputting and outputting various information related to the meter reading, such as the identification number, the meter reading date, the meter reading amount, the meter reading of the corresponding customer. The meter reader terminal 10 may be wired or wirelessly connected to transmit and receive meter information with an external terminal. In addition, the meter reader terminal 10 may be able to transmit the meter information in real time to the remote charge management server 30 connected to the wired and wireless communication network 20 at the same time the meter reading information input.

The fee management server 30 calculates a water rate corresponding to the metered information by receiving the metered information from the plurality of customers located in the plurality of partitioned blocks. The fee management server 30 classifies each household's customer or company's customer from the monthly meter reading information, and sets and manages a fee according to a corresponding billing standard.

The supply flow meter 40 measures the flow rate supplied through a water pipe piped through a water purification plant from a water source to a real customer, and is installed at the inlet of the water pipe set to the corresponding block. The supply flow meter 40 may be installed for each set block or for each unit block. The supply flow meter 40 may transmit the measured data to the flow collection server 50 in real time through the wire / wireless communication network 20 or transmit the measured flow information to the flow collection server 50 using a separate terminal. have.

The flow rate collection server 50 collects and stores flow rate information from the at least one supply amount flow meter 40 through the wired / wireless communication network 20. The flow collection server 50 stores the identification information and the supply amount of the corresponding supply flow meter 40 and generates statistics or graphs on the supply flow rate as necessary.

The meter reading correction server 60 uses the meter reading correction program with built-in meter reading information of the plurality of customers collected for each meter reading area in the block and rate information measured by the supply flow meter 40 in the charge management server 30. It is to calibrate meter reading data of water supply customer. In addition, the flow rate measured by the supply flow rate meter 40, that is, the amount of production and the plurality of meter reading areas for each of the meter readers calculates the flow rate from the data corrected from the data read by the water meter of the actual consumer, that is, the flow rate.

The water supply meter reading data correction method of the present invention made as described above will be described with reference to FIGS. 2 to 5.

First, in FIG. 2, a block of a predetermined range in which water is piped is partitioned into a plurality of meter reading zones, and each meter reading meter reads the water meter of each customer (S100). For example, in Fig. 4, a whole range of blocks in which a supply flowmeter 40 is installed is divided into three meter reading zones, where each meter reader A, meter reader B, and meter reader C read the water meter of each customer. And each meter reader inputs the meter reading amount to the meter reader terminal 10 (S200). The meter reading information input to the meter reader terminal 10 is transmitted to the fee management server 30 via the wired / wireless communication network 20 (S300). And the charge management server 30 calculates the meter reading information (measurement date, meter reading, meter reading period, etc.) received from each meter reader terminal 10 for each meter reading area and transmits it to the meter reading correction server 60. (S400).

In addition, the meter reading correction server 60 corrects the meter reading using the built-in meter reading correction program (S500). The calibration of the meter reading correction program of the meter reading correction server 60 can be seen with reference to the detailed flowchart of FIG. 3.

The meter reading correction server 60 selects a meter reading information for each meter reading area as a reference model from meter reading information for a plurality of meter reading areas received from the fee management server 30 (S501). That is, in Figure 4, the meter reading source B to read the metering zone is selected as the reference model. Then, the meter reading area that meter reader A reads is selected as the second metering area, and the metering area that meter C reads is selected as the third metering area. Moreover, even if one whole block is divided into more metering zones, one of them may be selected as a reference model using the metering zone as a reference zone. In this way, the period read in the second meter reading zone is corrected from the reference model (S502).

In addition, in FIG. 5, the data read for each meter reading area received by the meter reading correction server 60 includes a period during which the meter reads the daily supply flow rate. The supply flow rate is displayed as a graph repeatedly rising and falling according to the amount of tap water used on a daily basis, and includes the data read by the meter readers A, B, and C at the respective meter reading areas. In one embodiment of the present invention, the meter reader A reads the entire data (SUMa: monthly integrated meter reading) from the meter reading zone (second meter reading zone) from the 15th of the month to the 15th of the following month (the metering period of the meter A). The daily average supply flow rate (Aa) measured by the supply flow meter 40 during the meter reading period of meter A is included, and meter B is measured from the 17th of the month to the 17th of the following month (the metering point B). Metering period) includes the total data read (SUMb: total accumulated meter reading) and the daily average supply flow rate (Ab), and meter C is in the metering area (the third metering area) from the 19th of the month to the 19th of the following month. The total data (SUMc: monthly accumulated meter reading) and the daily average supply flow rate (Ac) measured by the supply flow meter 40 during the meter reading period of the meter C are included. Here, the meter reading correction server 60 is selected by the meter reading data (SUMb) in the meter reading area corresponding to the meter B as a reference model.

In addition to the selected reference model, the meter reading correction server 60 converts the monthly accumulated meter reading SUMa into a daily average k from the meter reading information read in the second meter reading area (S503). In other words, the daily average (k) is converted by dividing the monthly integrated meter reading (SUMa) by the number of days in the meter reading period. Further, the correction ratios b _i to b _{i + n of} each of the correction target periods i to i + n are calculated from the flow rate information measured by the supply flow meter 40 (S504). That is, the correction ratio (b _i to b _{i + n} ) is a reading period of the second meter reading zone for each daily supply flow rate (a _i to a _{i + n} ) measured by the supply flow meter 40 on i to i + n days. It is calculated by dividing by the daily average supply flow rate (Aa) of the month measured by the supply flow meter (40). Here, the correction target period is a reading period of the reference model that does not coincide with the reading period of the second reading area, and a ₁₅ and a ₁₆ are shown in FIG. 5.

The meter reading correction server 60 calculates a correction ratio (b _i to b _{i + n} ) of the meter reading period of the reference model that does not coincide with the meter reading period of the second meter reading area in the daily average k in the second meter reading area. Each of them is multiplied and corrected (S505). That is, the daily meter reading is corrected by multiplying the respective correction ratios b _i to b _{i + n} by the daily average k. In addition, the meter reading correction server 60 calculates the corrected monthly meter reading of the second meter reading area, including a period that does not coincide with the period matching the reference model (S506). That is, the corrected monthly reading of the second reading area is

Calculate In this case, the correction ratio (b _i to b _{i + n} ) of the day corresponding to the case where the date to be corrected in the second metering zone is one day or two or more times is multiplied by the daily average (k) and calculated. do.

And the meter reading correction server 60 stores the corrected monthly meter reading information of the second meter reading area (S507), if there is a third or more other meter reading area (S508), the meter reading information from the third or more meter reading area After repeating the steps (S502) to step (S507) (S509), the corrected reading amount for the entire block is integrated (S510). That is, the corrected reading amount for all blocks is integrated as (monthly reading amount of the second reading area) + (month reading amount of the reference model) + (corrected monthly reading amount of the third or more reading areas). This is the block correction month reading amount indicated by the dotted line in FIG. 4 to 6, which is an embodiment of the present invention, the metering zone is divided into three, and the periods to be corrected in the second and third metering zones are 2 days each.

Meanwhile, in FIG. 2, the flow rate collection server 50 measures flow rate information supplied from the flow rate flow meter 40 to the corresponding block (S600), and the measured flow rate information is flow rate collection server 50 via the wired / wireless communication network 20. Is transmitted (S700). The flow rate collection server 50 transmits the sum of the supply flow rates for each block to the meter reading correction server 60, and the meter reading correction server 60 checks the sum of the meter readings corrected for each block in step S500 and step 800 Analyze the flow rate from the sum of the received feed flow in each block. The flow rate is calculated as a percentage (%) by multiplying 100 by dividing the metered amount by the metered amount by the supplied amount. Here, the daily supply flow rate (a _i ~ a _{i + n} ) and the daily average supply flow rate (Aa), which is the flow rate information measured from the supply flow meter (40), is passed through the flow rate collection server (50) and the meter reading correction server (60). Is used to calibrate the daily meter reading.

In this way, by setting one period among the data read by the meter reader for each metering zone as a reference model and correcting the amount of daily meter reading missed in another period, more accurate monthly meter reading can be estimated. Underestimated flow rate accuracy can be increased.

While the invention has been shown and described with respect to the specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Anyone who has it will know it easily.

10: meter reader terminal 20: wired and wireless communication network 30: charge management server 40: supply flow meter 50: flow collection server 60: meter reading correction server

Claims (6)

(a) In the entire block divided into a plurality of meter reading areas, information read by a plurality of meter readers for a certain period of time in a plurality of meter reading areas is transmitted from a meter reader terminal to a fee management server through a wired / wireless communication network. Transmitting the meter reading information to the meter reading correction server, and the meter reading correction server selecting the meter reading information of one meter reading area as a reference model from the meter reading information for a predetermined period of the plurality of meter reading areas received;
(b) The meter reading correction server converts the monthly accumulated meter reading (SUMa) into the daily average (k) from the meter reading information read in the second meter reading area in addition to the selected reference model, and converts it into a daily average (k). The correction ratio of the correction target period (the metering period of the reference model that does not coincide with the metering period of the second metering zone) is calculated from the flow rate information measured and transmitted in the above, wherein the correction ratios b _i to b _{i + n} Each daily supply flow rate (a _i ~ a _{i + n} ) measured by the supply flow meter on the i-i + n day, which is the period of calibration, is calculated by the daily average supply of the month measured by the supply flow meter during the meter reading period of the second metering zone. Dividing by the flow rate (Aa) and calculating each;
(c) the meter reading correction server correcting the daily meter reading by multiplying the daily average k in the second meter reading area by the respective correction ratios b _i to b _{i + n} of the period to be corrected ;
(d) The meter reading calibration server adjusts the corrected monthly meter reading of the second meter reading area, including a period which does not coincide with the reference model.

(Where k is the daily average in the second meter reading zone, b _i to b _{i + n} are the respective correction ratios of the periods to be corrected), and
(e) storing the corrected monthly meter reading information of the second meter reading area in the meter reading correction server, and reading the meter reading information read from the third or more other meter reading areas when there is a third or more meter reading area; And repeating step (d) to accumulate the corrected meter reading for all the corresponding blocks.
The method of claim 1,
In the step (a), the meter reading information consists of the meter reading date, meter reading amount and meter reading period.
delete delete delete The method of claim 1,
In step (e),
The calibrated water reading for all blocks is the water supply meter reading integrated as (corrected monthly reading in the second reading area) + (month reading in the reference model) + (corrected monthly reading in the third or more reading areas) Data correction method.

Images