SU10709A1 - Device for testing and calibrating manometers and vacuum gauges - Google Patents

Description

The present invention relates to a device for testing and checking manometers and vacuum gauges, which, through the combined use of a reference mercury manometer, a distribution chamber and an ejector, can serve to npOBepiBH devices that determine pressure as above, so below atmospheric.

In FIG. 1 depicts the device cxei; FIG. 2 and 4 schemes of modifications of the same device; FIG. 3 is a detail of the circuit of the device according to FIG. 2

The reference mercury manometer 2, mounted on a wooden partition board 16, is used for comparison with the test manometer or vacuum gauge 4 mounted on a stand 3. The distribution chamber 1, mounted on table 12, is connected using a tube 18 with one arm of a mercury manometer 2 and using a tube 19 with the device under test 4. An ejector b, intended to create a pressure higher than atmospheric in chamber 1 when testing a manometer or vacuum when testing a vacuum gauge, is connected to a water tap 5, and tube 15 is connected with a distribution chamber 1. This latter has four inlets equipped with taps 7,

8, 9, 10, of which the bottom valve 10, connected to the ejector b, serves to control the vacuum and pressure during the test, while the middle valve 8 is designed to communicate the chamber 1 with the atmosphere.

When calibrating vacuum gauges, the water, which is passed from the water tap 5 through the ejector b with a jet pressure of about 2 W / cm, produces a vacuum in the distribution chamber 1. Valves 7, 9, 10 and 11 should be open and valve 8 locked. The vacuum value can optionally be increased or set at a certain point with the help of a crane 10. From the chamber, the vacuum is transmitted to all internal cavities of the device communicated with it, and causes mercury to overflow from the left knee of the mercury gauge to the right, and in the vacuum tester the corresponding deviation . By comparing the readings of the mercury manometer with those of the vacuum gauge being tested, it is determined for the last amendment. When calibrating the pressure gauges, the valve 11 is closed and the water, passed through the ejector b, flows through the tube 15, the valve 10 into the distribution chamber 1 and, filling it, compresses the air in it. Pressure is distributed

across all instrument cavities reported

With the camera, and merges mercury. From the right knee of the mercury manometer to the left. The pressure determined by the difference in heights of the pillars of mercury in both bends of the mercury manometer is recorded and at the same time the test is recorded; manometer. By gradually opening and closing the faucet 5, the water filling the chamber can be supplied and set at the desired level.

In the modified device (Fig. 2) of the device between the distribution chamber 1 and the connecting tubes 18 and 19 going to the pressure gauges, an additional smaller chamber 21 is included. A three-way valve 22 is installed in the pipeline connecting the distribution chamber 1 to the chamber 21. The modified connection scheme makes it possible to accumulate pressure or vacuum in the distribution chamber 1, and by gradually opening the three-way valve 22, this pressure or vacuum can be used as needed. In the first scheme, gradual rarefaction and its installation at certain points was achieved by gradual opening of the lower valve 10 with the constant full action of the ejector. Now, the same vacuum in the distribution chamber 1 can be accumulated with a short action of the ejector, and then spent as needed. On the other hand, the three-way valve 22 makes it possible, without changing the pressure in the large chamber, to set the zero point on the mercury and test devices, which is achieved by connecting the small chamber 21 through the three-way valve 22 to the outside air.

In order to allow a smoother increase and decrease in pressure and greater reliability of the constipation, valve taps can be used in the device, of which the upper valve 23 separates the distribution chamber 1 and the chamber 21; side valve 24 connects the small chamber with outside air; the lower valve 25 has the same function as the valve 10 in the previous schemes. The operation of the device with valve taps is no different from what is described with a three-way valve (Fig. 3).

In order to be able to check the pressure gauges for high pressures, a mercury pressure gauge in the form of several serially connected siphon tubes can be used in the proposed device. All tubes up to half the height are filled with mercury and can be connected to each other using taps 27, 276, etc. (Fig. 4).

Dimeters of the tubes are selected so that when all the tubes are put into operation, with an increase in pressure, the mercury columns rise simultaneously and to the same height in all the left knees of each siphon tube. The stand 3 for the pressure gauge to be tested is equipped with a tap 24a, allowing the zero point in the test and mercury instruments to be set independently of the internal pressure in the distribution chamber 1, and the tap 24 has a valve 26 serving to connect the device to the compressed gas cylinder or to air injection pump.

For ease of use of the device (Fig. 1), preliminary recordings of the position of mercury columns are made at many points with increasing pressure and dilution, and a special table of instrument readings is made for them — for pressure — for menuscus mercury in the right knee and for vacuum — for the left knee. tube. Using this table, you can make only one sample instead of two. This latter circumstance simplifies the calibration and makes the scale suitable both for different positions of the zero level of mercury and for the case of replacement of glass tubes and requires only the preliminary compilation of the table in each of the specified cases. Due to the special arrangement of the chamber of the tubes and taps, all verification is carried out by air, and not by liquids, thus eliminating those irregularities in the readings that could have occurred when the tubes were blocked with plugs from liquids. The appliance, being connected to the water supply network, works under the pressure of the water in the latter and does not require the expenditure of any effort and does not distract the attention of the tester.

The subject of the patent.

1. A device for testing and calibrating manometers and vacuum gauges, characterized by the combined use of a) a reference mercury gauge 2, which is used for comparison with the test gauge or vacuum gauge 4; b) a distribution chamber 1 communicating with a tube 18 with one arm of a mercury manometer 2 and a tube 19 with test device 4, and c) an ejector b connected with tube 15 to a distribution chamber 1 and designed to pressurize the latter when the valve 11 is closed atmospheric, for the purpose of checking or testing manometers, and with open valve 11, to create a vacuum in it, for the purpose of checking or testing vacuum gauges.

2. The modification of the device described in paragraph 1, characterized in that between the distribution chamber 1 and the connecting tubes 18 and 19, going to the pressure gauges, is included

Fig1.

additional, smaller, chamber 21 and a three-way valve 22 are installed on the pipe connecting chamber 1 and 21,

3. the device described in pp. 1 and 2, instead of simple taps 22 and 10, valve taps 23, 24 and 25.

4. In the device described in pp. 1-3, use a mercury manometer in the form of several serially connected by means of taps 27c, 276 .... siphon tubes, in order to calibrate the manometers to high pressures.

5.B characterized in paragraphs. 1-4, the device is used in a stand 3 for a tested manometer, tap 24a, in order to establish zero points in the test and mercury manometers, regardless of the pressure in chamber 1.

6.B characterized in clauses. 1-5, the device uses valve 26 in valve 24 to connect the system to a cylinder with compressed gas or to an air injection pump.

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