KR100841480B1 - Gas meter - Google Patents

Abstract

The present invention relates to a gas meter for measuring the amount (volume) of the gas flowing into the gas pipe to be delivered to the consumer, which can be applied to the measurement of the consumption and volume of various gas amounts under the gas supply system.

The present invention is to provide a gas meter with a small measurement error in temperature and pressure changes, easy to maintain and easy to maintain, in the body divided into a chamber and a loss by the funnel-type diaphragm The body composed of the body rotates freely, and the number of revolutions of the body is made by the gas meter which the electronic counter counts. At this time, the rotation of the measuring device is made through the comb-shaped grooves formed in the measuring head with a plurality of vortex generating holes formed in the cylindrical surface of the measuring body.

According to the present invention, it is possible to measure a large amount of amount, as well as to provide a fine gas meter that can be accurately measured without friction without being affected by changes in gas temperature and pressure. It has a simple structure that reduces the cost, and can provide a gas meter that is easy to clean and easy to inspect.

Gas meter

Description

Gas Meter {GAS METER}

1 is a cutaway perspective view of a gas meter in accordance with an embodiment of the present invention;

2 is a cross-sectional view of a gas meter in accordance with an embodiment of the present invention;

3 is a cross-sectional view of a gas meter in accordance with another embodiment of the present invention;

4 is an internal sectional view showing a part of the counter and the measuring device.

<Description of Symbols for Major Parts of Drawings>

1: gas passage opening 2: gas supply opening

3: gas outlet 4: diaphragm

5: base 6: measuring instrument

7: measuring head 8: measuring body

9: counter 9b: magnetic material

10: comb groove 11: gas supply hole

12: Vortex generating hole 16: Gas passing hole

20: axis 100: main body

110: Hall 120: Loss

The present invention relates to a gas meter for measuring the amount (volume) of the gas flowing into the gas pipe to be delivered to the consumer, which can be applied to the measurement of the consumption and volume of various gas amounts under the gas supply system.

In general, the gas meter is divided into membrane type (diaphragm type), rotary type, drum type, turbine type and the like. As is well known, the simplest, most accurate and inexpensive gas meter is a rotary gas meter. The measurement results depend on the number of revolutions of the vane as it passes through the liquid or gas stream. An example of such a gas meter is shown in Korean Utility Model Registration No. 367763. This type of gas meter is reliable due to the error rate caused by friction and frequency of use in mechanical parts such as bearings, worms, gear shafts and bearings. There is an important drawback that this must fall. For this reason, lubricants should be applied regularly.

On the contrary, there is a gas meter having a membrane-type structure composed of two membranes which operate in sequence for the movement of fluid continuously entering and exiting. Examples thereof include Korean Utility Model Registration No. 447553 and Patent No. 541190. In this gas meter structure, there are many parts such as reduction gears interlocked with each other to reduce the friction force, and are much more complicated than the rotary or turbine type, so the membrane type gas meter has little efficiency when the consumption per unit time is high. There is a drawback that only the appearance becomes large.

In addition, the biggest problem with membrane gas meters is that they have systematic and metrological errors with temperature changes. This error is 0.35 to 0.45% at 1 ° C temperature change. For example, a gas meter would show an error of 12% at a temperature change of 20 ° C. In this connection, the film type gas meter is required to have correction means for correcting the error.

At any rate, the biggest problem with any mechanical gas meter is that the friction between the parts and the gas as it passes through affects the operator and causes errors. The force to overcome the frictional forces that pass through all parts of the gas meter is inevitably short of the force of pressure on the gas flow. In order to overcome this problem, the use of special materials and lubricating oils are added through the study of gas meter parts, which only causes the price of gas meter to increase, and this method does not solve the root cause. On the other hand, other problems arise in service and industrial gas meters, i.e., the gas flow is so large that all parts wear quickly in mechanical gas meters, which is why the gas meters have to be checked and repaired frequently.

In addition, all gas meters should be corrected in a timely manner when the temperature of the gas passing through changes, but there is a limit to the temperature correction itself. All gas meters are set and certified under normal atmospheric conditions and under standard conditions of temperature and pressure (ie 20 ° C and 1 atmosphere). After the installation of the gas meter, the pressure and gas temperature change, and the atmosphere are different from each other and continuously change. Therefore, there is a significant difference between the actual conditions and the reference conditions appearing in the gas and gas pipes delivered to the consumer, and it is necessary to correct the measured values displayed on the gas meter. Therefore, all consumers have no choice but to install two measuring instruments (gas meters and compensators) to pay for the exact consumption, or to install equipment with added calibration to the gas meters. In addition, technical and structural problems will arise.

Accordingly, the present invention has been made to solve the above problems, the object of the present invention is to provide a simple structure with a significant reduction in the number of parts, as well as to measure a large amount of range of gas temperature and pressure It is to provide a fine gas meter that can be measured accurately without being influenced by change, and in particular without friction between components.

In addition, an object of the present invention is to provide a gas meter that is easy to clean and easy to inspect.

The purpose of the above is to allow the measuring device composed of the measuring head and the measuring body to be freely rotated by the pressure difference and the flow of gas in the main body divided into the chamber and the loss by the diaphragm, and the number of revolutions of the measuring device is counted by the electronic counter. By means of a metered gas meter. At this time, the rotation of the measuring device is made through a comb pattern groove formed in the measuring head, with a plurality of vortex generating holes formed in the cylindrical surface of the measuring body.

Hereinafter, the gas meter according to the present invention will be described in more detail with reference to the accompanying drawings.

1 is a cutaway perspective view of a gas meter according to an embodiment of the present invention, Figure 2 is a cross-sectional view.

1 and 2, the gas meter of the present invention is separated into a chamber 110 and a chamber 120 by a diaphragm 4 having a gas passage opening 1 formed therein, and a gas meter in the chamber 110. A sealed main body 100 having a supply port 2 and having a gas outlet 3 in the upper chamber 120; And a measuring head (8) passing through the gas passage opening (1) and the measuring head (7) coupled to the upper portion of the measuring body (8) located in the loss 120, the loss 110 A measurer 6 that rises due to the gas pressure difference between the base and the base 120 and rotates according to the flow of gas; And a counting device 9 for counting the number of revolutions of the measurer 6.

In particular, the diaphragm 4 may be a funnel-shaped diaphragm, and the measuring head 7 may have an inverted cone shape corresponding to the funnel-shaped diaphragm 4, in which case more stable measurement of the flow of gas is possible. Do.

Moreover, the magnetic body 9b is provided in the shaft 20 formed in the upper part of the measuring head, and the rotation speed of a measuring device is counted by the counter.

On the other hand, the gas supply port (2) is in communication with the gas supply hole (11) formed radially on the cylindrical surface (15) of the cylindrical support portion (5) formed protruding on the bottom surface of the base 110; The measurer body (8) is a cylindrical body surrounding the outer periphery of the support (5), the cylindrical surface of the measurer body (8) is formed with a plurality of vortex generating holes 12 in an oblique direction to the cylindrical surface, The measurer is rotated by the flow of gas passing through the vortex generating hole 12.

The vortex generating hole 12 extends in a horizontal direction approximately perpendicular to the calibrator body 8 (ie to the vertical direction) when viewed from the side as shown in FIG. 1, but is viewed from the tangential line of the calibrator body 8 when viewed from above ( That is, on the horizontal plane, and is biased to extend at a predetermined angle rather than a right angle, the measurer 6 obtains the rotational force by the reaction force of the gas ejected through the vortex generating hole 12.

In another embodiment of the present invention, the gas meter may have a plurality of comb-shaped grooves 10 formed on the reverse conical surface of the measuring head 7 so that the flow of gas is inclined in the rotation direction of the measuring device 6.

As the gas flowing in the plurality of comb-shaped grooves 10 collides to push the measuring head 7, the rotation of the measuring device 6 is more reliably made.

In addition, in the state where there is no vortex generating hole 12 in the cylindrical surface of the measurer body 8, a plurality of comb-shaped grooves 10 are formed on the reverse conical surface of the measurer head 7 and the comb-shaped groove 10 It is also possible that the measuring device 6 is rotated by the flow of gas passing through).

3 is a cross-sectional view of a gas meter in accordance with another embodiment of the present invention.

Since the measurer is rotatable by the pressure of the gas to be rotatable without friction with other components, as shown in FIG. 3, the diaphragm 4 is lost in the basement 110 to assist the rise of the measurer. A plurality of gas passing holes 16 through which gas may pass may be formed at 120.

In addition, the gas passage hole 16 may be formed by inclining at a predetermined angle with respect to the direction perpendicular to the diaphragm (4), in which case the vortex is formed in the rotational direction of the measuring device (6) It helps to rotate.

As such, the present invention includes a main body having a gas supply port and a gas discharge port; An inside of the main body, a measuring device which rises by a gas pressure difference between the gas supply port and the gas discharge port and rotates by a flow of gas; It provides a gas meter comprising a counting device for counting the number of revolutions of the measuring device.

Now, the operation of the gas meter according to the embodiment of the present invention configured as described above will be described.

First, when the consumer opens the gas valve, a pressure drop occurs at the gas outlet 3 side of the gas meter, between the chamber 120 connected to the gas outlet 2 and the chamber 120 connected to the gas outlet 3. As the pressure difference occurs, the gauge 6 rises, and a space 14 is formed between the raised gauge head 7 and the diaphragm 4. At the same time as the flow of gas occurs in the meter, new gas enters the gas meter through the gas supply port (2).

The flow of this gas flows from the gas supply port 2 and flows through the radial gas supply hole 11 through the inner space between the pedestal 5 and the measurer body 8 to the basement 110. At this time, in the process of the gas flows into the basement 110, some flows through the gap 13, some flows through the vortex generating hole 12 of the measurer 6, the gas entering the basement 110 The gas passage port 1 of the diaphragm 4 and the gap 14 between the diaphragm 4 and the measuring head 7 flow to the loss chamber 120.

 In this way, the measuring device 6 starts to rotate while discharging the gas in the direction biased from the horizontal plane through the vortex generating hole 12 and is formed on the inclined outer surface of the measuring head 7. As the gas collides with the comb pattern groove 10, the gas is rotated at a speed proportional to the consumption amount of the gas. The gas is then delivered to the consumer through the gas outlet 3.

In more detail, in the gas flow, a gas flow is formed between the loss chamber 120 and the basement 110 to ensure stable and reliable rotation of the measurer 6, and the gas flow on the loss side is measured by the measurer head 7. A gas flow is formed between the diaphragms 4, and the measurer 6 is surely rotated by the plurality of comb-shaped grooves 10. Thereby, not only can the size of the measuring device 6 be increased, but also the sensitivity of the gas measurement can be amplified even at a small consumption amount.

The gas flow on the basement side forms a flow of gas between the measuring body (8) and the cylindrical surface (15) of the support (5) and the measuring body (8), the riser in the gas flow Of course, the gas is discharged through the vortex generating hole 12 formed at a predetermined angle on the horizontal plane, and rotates in a floating state without contacting the fixed parts of the gas meter body.

Changes in the density and stickiness of the gas passing through the gas meter will change the parameters of the gas layers, gaps, and gas distribution equally. And the rotation speed and height of the measuring instrument, which shows the gas volume accurately regardless of the temperature change of the passing gas, can be measured accurately by changing the rotating speed of the measuring instrument.

In our own experiments, we confirmed the high accuracy, efficiency of operation, and high sensitivity at low consumption of the gas meter according to the first embodiment of the present invention.

When the consumption of the gas is stopped, the pressure of the gas discharge port 3 and the gas supply port 2 of the gas meter becomes equal, and the flow of the gas stops while the gauge 6 is lowered by gravity. As the gas flow is stopped, the measurer 6 stops rotating.

3 is a cross-sectional view of a gas meter according to another embodiment of the present invention, which forms a plurality of gas passing holes 16 through which the gas can pass through the diaphragm 4 to assist the rise of the measurer 6. Role.

In addition, the vortex may be generated by drilling the gas passing hole 16 so as to be inclined with respect to the direction perpendicular to the diaphragm. At this time, the rotation of the measurer can be more surely made by matching the direction of the vortex with the rotational direction of the existing measurer. have.

Fig. 4 is a cross-sectional view of the inside of the counting device showing a part of the counting device and the measurer. In general, an electronic counting device 9 for counting the number of revolutions of the shaft is already widely known. The magnetic body 9b is provided on the shaft 20 formed in the measuring device 6, and the reactor 9a of the counting device 9 schematically shows the magnetic body 9b portion. Let's do it.

The counter 9 changes the speed at which the measurer 6 rotates according to the amount of gas passing therethrough, and calculates the number of pulses generated by the magnetic body 9b rotating between the reactants 9a. It will count electronically.

According to the present invention as described above, it is possible to measure a large amount of range, as well as the effect of providing a fine gas meter that can be accurately measured without the friction force without being affected by changes in gas temperature and pressure.

In addition, the simple structure that greatly reduced the number of parts, it is also effective to provide a gas meter that is easy to clean and easy to inspect.

Claims (8)

A hermetic body which is separated into a chamber and a chamber by a diaphragm in which gas passages are formed, the chamber has a gas supply port, and the chamber has a gas outlet; And a measuring head coupled to the upper part of the measuring body and penetrating the gas passage opening, and being positioned at the loss, and rising by the gas pressure difference between the loss and the lower chamber. Rotary measurer; And And a counting device for counting the number of revolutions of the measurer. The method of claim 1, The barrier is a funnel-shaped barrier, The measuring head is a gas meter, characterized in that the inverted conical shape corresponding to the funnel-shaped diaphragm. The method of claim 2, The gas supply port is in communication with the gas supply hole radially formed on the cylindrical surface of the cylindrical base portion protruding from the bottom surface of the base; The measurer body is a cylindrical shape surrounding the base of the support, a plurality of vortex generating holes are formed on the cylindrical surface of the measurer body in an oblique direction to the cylindrical surface, and the measurer rotates according to the flow of gas passing through the vortex generating hole. Gas meter, characterized in that the. The method of claim 3, A gas meter, characterized in that the inverted conical surface of the measuring head, a plurality of comb-shaped grooves are formed so that the flow of gas inclined in the rotation direction of the measuring device. The method of claim 2, A plurality of comb-patterned grooves are formed in the inverted conical surface of the measuring head, and the gas meter is rotated by the flow of gas passing through the comb-coated grooves. The method according to any one of claims 3 to 5, And a plurality of gas through holes formed in the diaphragm to allow gas to pass from the basement to the chamber to raise the meter by the flow of gas. The method of claim 6, The gas metering hole is formed inclined with respect to the direction perpendicular to the diaphragm to form a vortex in the rotational direction of the measuring device. delete

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