JP2014202613A - Gas pressure measurement device and airtightness testing method for gas piping - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gas pressure measurement device, which is especially effective for a multiple dwelling house such as a condominium and is capable of easily acquiring the information of a measurement unit in a remote place, and an airtightness testing method using the gas pressure measurement device.SOLUTION: Gas piping 3 is laid in a multiple dwelling house 1. The gas piping 3 is branched to each dwelling unit. Valves 5 are disposed at the predetermined positions of the gas piping 3. Thus, the gas piping 3 can be divided into a plurality of sections by closing the valves 5. A measurement unit 7 is connected to each of the divided gas piping 3. The measurement unit 7 is able to measure the pressure of gas in the gas piping 3. The measurement unit 7 is able to wirelessly exchange information with a terminal equipment 9. Also, only one terminal equipment 9 is able to exchange information with a plurality of measurement units 7. The terminal equipment 9 is able to display and record the operation of the measurement unit 7 or various information measured by the measurement unit 7.

Description

  The present invention relates to a gas pressure measuring device for performing an airtight test in piping of an apartment house and an airtight test method using the same.

  When laying gas pipes such as city gas and propane gas, and in order to periodically evaluate the soundness of the pipes, air tightness tests of pipes and the like are performed. In the airtight test, gas is pressurized or depressurized at a predetermined pressure in a pipe divided in advance, and the presence or absence of gas leakage from the pipe is determined from the change in gas pressure.

  As a gas tightness test method using such a gas pressure gauge, there is a method of performing a gas tightness test with high accuracy by correcting the temperature in the pipe (for example, Patent Documents 1 and 2).

WO2005 / 080935 JP 2003-227773 A

  In a conventional air tightness test, a pressure gauge is connected to a divided pipe, and the pressure change in the pipe is measured by this pressure gauge. At this time, the pressure gauge can record and display a change in pressure by a circular chart paper or digital display. That is, the conventional pressure gauge has a function of measuring a change in gas pressure and recording / displaying the measurement result.

  However, in a housing complex such as a condominium, there is a wide range of airtight tests, and it is necessary to use many devices. Therefore, the cost increases. Moreover, in order to collect the airtight test results measured by each device, it is necessary to organize the data separately. For this reason, work man-hours are required. Further, conventional pie chart paper and digital display (for example, a line graph) have poor visibility, particularly when measurement is performed over a long period of time. However, when the device is enlarged, workability such as transportation of the device is deteriorated.

  The present invention has been made in view of such a problem, and is particularly effective in, for example, a housing complex such as a condominium, and a gas pressure measuring device capable of easily acquiring information on a measuring instrument at a remote location and the use thereof The purpose is to provide an airtight test method.

  In order to achieve the above-described object, the first invention is a gas pressure measuring apparatus, which displays and stores at least a measuring instrument for measuring the pressure of gas and at least information measured by the measuring instrument. A terminal that can transmit the information wirelessly, and the terminal includes a receiver that receives the information transmitted from the measuring instrument. This is a gas pressure measuring device.

  Thus, the measuring instrument can be reduced in size by separating the measuring instrument that measures the gas pressure from the terminal that can collect the operation and information of the measuring instrument. For this reason, the installation work of a measuring instrument, etc. are easy. Even if the measuring instrument is downsized, the measurement result is displayed on the terminal, so that the visibility of the measurement result is excellent. In addition, since the measurement result can be obtained at a remote location, the measurement data can be easily confirmed.

  In the present invention, it is preferable that the terminal can collect the information of a plurality of the measuring instruments.

  By doing in this way, the data from a plurality of measuring instruments can be obtained with one terminal. For this reason, it is possible to grasp the measurement results of a plurality of measuring instruments at a time at a distant place.

  In the present invention, the information includes gas pressure information, time information when the pressure information is measured, and temperature information in a measurement unit, and the terminal changes in temperature with respect to a change in gas pressure. It may be possible to perform correction according to.

  By doing in this way, the influence by the temperature change in piping can be made small, and an airtight test can be performed more accurately.

  In the present invention, it is preferable that the terminal can display a pressure change with a circular chart in which the circumferential direction is time and the radial direction is pressure.

  By doing in this way, it is easy to visually recognize a change in gas pressure. In addition, a change in pressure can be displayed within a predetermined display range even when measurement is performed for a long time compared to a line graph or the like.

  In the present invention, the terminal may be capable of displaying a pressure change by a plurality of the measuring devices in a superimposed manner on one circular chart.

  By doing in this way, the measurement result by a some measuring device can be grasped at a glance.

  A second invention is a gas pipe airtightness test method using the gas pressure device according to the first invention, wherein a predetermined pressure is applied to each section of the gas pipe divided into a plurality of sections, and each section is provided with a predetermined pressure. A plurality of attached measuring instruments respectively measure pressure changes in each section, transmit pressure information from each measuring instrument to the terminal, receive the pressure information by the terminal, and the terminal The gas pipe air-tightness test method is characterized in that the pressure change in each section is displayed on the screen.

  By doing in this way, the measurement result of an airtight test can be obtained easily when there are a plurality of measurement sections such as an apartment house.

  ADVANTAGE OF THE INVENTION According to this invention, it is especially effective, for example in apartment houses, such as an apartment, The gas pressure measuring device which can acquire the information of a measuring instrument easily in a distant place, and an airtight test method using this can be provided.

The figure which shows the use condition of the gas pressure measuring device. The hardware block diagram of the measuring device 7. FIG. The hardware block diagram of the terminal device 9. FIG. The flowchart which shows the usage method of the measuring device 7 and the terminal device 9. FIG. The figure which shows an example of the display screen 31 of the terminal device 9. FIG.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram illustrating a usage state of the gas pressure measuring device 10. In addition, although the example shown in FIG. 1 shows the example in which the gas pressure measuring device 10 is used for the airtight test of the apartment house 1, the present invention can also be used for other gas pressure measurements. Moreover, this invention can respond to any gas, such as city gas and propane gas. The gas pressure measuring device 10 includes a measuring instrument 7 and a terminal 9.

  A gas pipe 3 is laid in the apartment house 1. The gas pipe 3 is branched to each dwelling unit. A valve 5 is provided at a predetermined position of the gas pipe 3. Therefore, the gas pipe 3 can be divided into a plurality of sections by closing the valve 5. A measuring instrument 7 is connected to each of the divided gas pipes 3. The measuring instrument 7 can measure the pressure of the gas in the gas pipe 3. Details of the measuring instrument 7 will be described later.

  The measuring instrument 7 and the terminal 9 can exchange information wirelessly. In addition, information can be exchanged with a plurality of measuring instruments 7 by a single terminal 9. A plurality of terminals 9 may be used. The terminal 9 can display and record the operation of the measuring instrument 7 and various information measured by the measuring instrument 7. For example, the terminal 9 can perform a measurement start operation, a measurement end operation, a zero point correction operation, and the like by the measuring instrument 7. Details of the terminal 9 will be described later.

  FIG. 2 is a hardware configuration diagram of the measuring instrument 7. The measuring instrument 7 includes a control unit 11, a storage unit 15, a transmission / reception unit 13, a display unit 17, an information acquisition unit 19, and the like, which are connected via a bus or the like.

  The control unit 11 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. The CPU calls a program stored in the storage unit 15, ROM, recording medium or the like to a work memory area on the RAM, executes it, drives and controls each unit connected via the bus, and performs processing performed by the measuring instrument 7. Realize.

  The transmission / reception unit 13 is a communication control device, and includes a transmission unit that transmits information and a reception unit that receives information. The transmission / reception unit 13 can transmit or receive various types of information wirelessly. For example, wireless communication in accordance with the BlueTooth (registered trademark) standard is realized.

  The storage unit 15 is a ROM or a RAM, and stores a program executed by the control unit 11, data necessary for program execution, measurement data, and the like. The storage unit 15 stores various data used in the present invention.

  The display unit 17 displays measurement data and the like. The display unit 17 is a display device such as a liquid crystal panel. The measurement data can also be output on chart paper by a printer or the like. Note that the display unit 17 is not necessarily required for the measuring instrument 7, and measurement data may be displayed only by the terminal device 9 described later.

  The information acquisition unit 19 is a part that measures pressure, and an existing pressure gauge such as a mechanical type, an optical type, or an electric type can be applied.

  In addition to this, an operation unit (key or touch panel type input unit) for operating the measuring instrument 7 may be provided, but the measuring instrument 7 may be operated only by the terminal device 9 described later.

  FIG. 3 is a hardware configuration diagram of the terminal 9. The terminal 9 includes a control unit 21, a storage unit 25, a transmission / reception unit 23, a display unit 27, an operation unit 29, and the like, which are connected via a bus or the like. The terminal device 9 is, for example, a tablet terminal.

  The control unit 21 includes a CPU, a ROM, a RAM, and the like. The CPU calls a program stored in the storage unit 25, ROM, recording medium or the like to the work memory area on the RAM, executes it, drives and controls each unit connected via the bus, and performs processing performed by the terminal 9 Realize.

  The ROM is a non-volatile memory and permanently holds a computer boot program, a program such as BIOS, data, and the like. The RAM is a volatile memory, and temporarily stores a program, data, and the like loaded from the storage unit 25, ROM, recording medium, and the like, and includes a work area used by the control unit 21 for performing various processes.

  The storage unit 25 is an HDD (hard disk drive), an SSD (flash SSD) (solid state drive), or the like, and stores a program executed by the control unit 21, data necessary for program execution, an OS (operating system), and the like. . As for the program, a control program corresponding to an OS (operating system) and an application program corresponding to processing described later are stored. Each of these program codes is read by the control unit 21 as necessary, transferred to the RAM, read by the CPU, and executed as various means. The storage unit 25 stores various data used in the present invention.

  The transmission / reception unit 23 is a communication control device, and includes a transmission unit that transmits information and a reception unit that receives information. The transmission / reception unit 23 can transmit or receive various types of information wirelessly. For example, wireless communication in accordance with the BlueTooth (registered trademark) standard is realized. The measuring instrument 7 and the terminal 9 can exchange various information with each other through the transmission / reception units 13 and 23.

  The display unit 27 is a display device such as a liquid crystal panel. Further, the operation unit 29 can perform operation instructions and data input of the terminal 9. The operation unit 29 can also be performed by a touch panel that is the display unit 27. The operation unit 29 can not only operate the terminal 9 but also transmit operation information by the transmission / reception unit 23 and perform various operations of the measuring instrument 7 wirelessly.

  Next, an airtight test method using the gas pressure measuring device 10 will be described. FIG. 4 is a diagram illustrating a process of an airtight test performed by the gas pressure measuring device 10. First, as shown in FIG. 1, the gas pipe 3 is divided into predetermined ranges, and a measuring instrument 7 is attached to each of the divided gas pipes. Further, the inside of the gas pipe 3 is pressurized to a predetermined pressure by a gas pressure feeding device (not shown).

  In this state, by operating the operation unit 29 of the terminal 9, the control unit 21 transmits a measurement start instruction (step 101). The measurement start instruction is transmitted from the transmission / reception unit 23 and received by the transmission / reception unit 13 of each measuring instrument 7 (step 102). When receiving the measurement start instruction, the control unit 11 of the measuring instrument 7 starts measuring the pressure change (step 103). That is, pressure information (pressure data) is acquired at predetermined intervals by the information acquisition unit 19 (step 104). Note that the measurement start instruction from the terminal 9 can be given to a specific measuring instrument 7 or can be transmitted to all the measuring instruments 7 at once.

  In order to perform an operation on a specific measuring instrument 7, identification information for specifying the measuring instrument 7 may be transmitted simultaneously with the operation information. In this case, each measuring device 7 may be configured so that the control unit 11 performs processing based on the operation information only when the operation information matching the identification information of the measuring device 7 is received.

  Information obtained by the information acquisition unit 19 is, for example, pressure information and time information. The pressure information is measured pressure data. The time information is elapsed time data from the start of measurement. That is, one piece of pressure information is associated with one piece of time information. The time information may be the time when the pressure information is acquired.

  Next, the control part 11 of the measuring instrument 7 transmits the acquired various information (step 105). For example, the pressure information, time information, and identification information described above are transmitted from the transmission / reception unit 13 and received by the transmission / reception unit 23 of the terminal 9 (step 106). Upon receiving various information, the control unit 21 of the terminal 9 transmits information reception confirmation information from the transmission / reception unit 23 (step 107).

  The control unit 11 of the measuring instrument 7 confirms whether or not reception confirmation information has been received within a predetermined time from transmission of information (step 108), and if reception confirmation information has not been received, stores it as untransmitted information (step 108). 109). Thereafter, the process returns to step 104. If the reception confirmation information is acquired, data acquisition is repeated (to step 104).

  In step 105, untransmitted information is transmitted together. Therefore, after various information is transmitted from the measuring instrument 7, information that has not been confirmed to be received from the terminal 9 is transmitted together. For example, when the distance between the terminal 9 and the measuring instrument 7 is too far and wireless transmission / reception of information has not been performed, the measuring instrument 7 temporarily stores the information and repeats acquisition and transmission of information. In this way, when wireless transmission / reception between the measuring instrument 7 and the terminal 9 becomes possible, various information of the measuring instrument 7 is reliably transmitted to the terminal 9.

  In addition, the control unit 21 of the terminal 9 that has received the various information stores the information in the storage unit 25 and causes the display unit 27 to display the pressure transition and the like. Further, the control unit 21 can change the display content in accordance with the operation of the operation unit 29. The display contents of the terminal 9 will be described later.

  When a measurement end operation is performed by operating the operation unit 29, the control unit 21 transmits a measurement end instruction from the transmission / reception unit 23 to a specific or all of the measuring instruments 7 (step 110). When the measurement end instruction is received by the transmission / reception unit 13 of the measuring instrument 7 (step 111), the control unit 11 ends the measurement (step 112). As described above, the pressure change in each section in the gas pipe 3 can be measured.

  Next, a display screen displayed on the display unit 27 of the terminal 9 will be described. FIG. 5 is a diagram illustrating an example of the display screen 31. On the display screen, for example, the identification number of the measuring instrument 7, the measurement date, the display method, the measurement time, the start pressure, the current differential pressure, and the like can be displayed.

  In the example shown in the figure, the pressure change display method is in the chart paper mode. When the chart paper mode is selected, a circular chart 33 is displayed on the display screen 31. In the circular chart 33, the circumferential direction indicates time, and the radial direction indicates pressure. For example, measurement points are added clockwise as time passes. Moreover, it shows that a pressure is low as it goes to the center, and the measurement point shifts to the center of the circular chart 33 as the pressure decreases.

  The scale of time and pressure of the circular chart 33 can be arbitrarily changed. Therefore, all data can be displayed on one circular chart 33. For this reason, even if it is long-time measurement, data can be displayed within a limited display range, and the visibility is excellent. In the radial direction of the circular chart 33, the pressure can be displayed as a standardized numerical value. For example, the pressure change can be displayed with the starting pressure as 100.

  Further, pressure information of a plurality of measuring instruments 7 can be displayed on one circular chart 33. In other words, pressure changes by a plurality of measuring instruments 7 can be displayed on one circular chart 33 in an overlapping manner. In this case, for example, the color or line type may be changed for each measuring instrument 7. Further, the start point on the circular chart 33 may be shifted in the circumferential direction for each measuring instrument 7. Alternatively, the scale on the circular chart 33 may be changed for each measuring instrument 7 to display a plurality of pressure changes in a concentric manner. In addition, the data of each measuring instrument 7 may be overwritten, and only the data in which the pressure change has become larger than a predetermined value may be distinguished and displayed by color coding or the like.

  By doing in this way, the pressure change in each measurement position can be grasped at once, without switching the display of each measuring instrument 7. In addition, as a display mode, you may display the display by a normal broken line etc., or only a numerical value.

  As described above, according to the present invention, since the measuring instrument 7 that measures pressure and the terminal 9 that displays, stores, and operates pressure changes are separated, each measuring instrument 7 can be downsized. Moreover, since the measurement data can be acquired by the terminal 9 by radio, the measurement data can be acquired at a remote location.

  Further, the terminal 9 can acquire measurement data from a plurality of measuring instruments 7 at a time. For this reason, the measurement result by the some measuring device 7 can be grasped | ascertained at once in the distant place.

  The obtained data can be displayed on the circular chart 33. For this reason, the visibility of data is excellent even within a limited display range.

  As mentioned above, although embodiment of this invention was described referring an accompanying drawing, the technical scope of this invention is not influenced by embodiment mentioned above. It is obvious for those skilled in the art that various modifications or modifications can be conceived within the scope of the technical idea described in the claims. It is understood that it belongs.

  For example, the temperature of the gas pipe 3 may be acquired by the information acquisition unit 19 of the measuring instrument 7. By acquiring the temperature information, the temperature correction of the pressure change in the gas pipe 3 can be performed by a known method. Further, by measuring the temperature using a plurality of measuring instruments 7, for example, temperature information of adjacent gas piping sections and temperature information of the measuring sections are acquired, and these are averaged to obtain the temperature of the measuring section. It can also be obtained with higher accuracy.

  Moreover, the gas pressure measuring device 10 can be used in addition to an airtight test. For example, by connecting a measuring instrument 7 to the gas pipe 3 in each household and acquiring pressure change data over a long period of time, it is possible to know the usage status of the gas.

1 ... Apartment Housing 3 ... Gas Pipe 5 ... Valve 7 ... Meter 9 ... Terminal 10 ... Gas Pressure Measuring Device 11 ... Control Unit 13 ... Transmission / Reception Unit 15 ......... Storage unit 17 ......... Display unit 19 ......... Information acquisition unit 21 ......... Control unit 23 ......... Transmission / reception unit 25 ......... Storage unit 27 ......... Display unit 29 ......... Operation unit 31 ... …… Display screen 33 ……… Circular chart

Claims (6)

A gas pressure measuring device,
A measuring instrument that measures at least the pressure of the gas,
A terminal capable of displaying and storing at least information measured by the measuring instrument;
Comprising
The measuring instrument includes a transmitter that wirelessly transmits the information,
The gas pressure measuring apparatus according to claim 1, wherein the terminal includes a receiving unit that receives the information transmitted from the measuring instrument.   The gas pressure measuring apparatus according to claim 1, wherein the terminal is capable of collecting the information of a plurality of the measuring instruments. The information includes gas pressure information, time information when the pressure information is measured, and temperature information in the measurement unit,
The gas pressure measuring device according to claim 1 or 2, wherein the terminal is capable of correcting the change in the gas pressure by changing the temperature.   The gas pressure measuring device according to any one of claims 1 to 3, wherein the terminal can display a pressure change in a circular chart in which the circumferential direction is time and the radial direction is pressure.   5. The gas pressure measuring apparatus according to claim 4, wherein the terminal can display pressure changes by a plurality of the measuring instruments in a superimposed manner on one circular chart. A gas pipe air-tightness test method using the gas pressure device according to any one of claims 1 to 5,
A predetermined pressure is applied to each section of the gas pipe divided into a plurality of sections, and a pressure change in each section is measured by each of the plurality of measuring instruments attached to each section, and each terminal is connected to the terminal. Send pressure information to the machine,
An airtight test method for a gas pipe, wherein the terminal receives the pressure information and causes the terminal to display a pressure change in each section.

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