RU2386936C1 - Controlled check leak - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: controlled check leak comprises tight impermeable body filled with sample substance and permeable element tightly built into body and arranged in the form of tube. Inside permeable element there is an impermeable tube installed, which is tightly adjacent to inner walls of permeable element and moves along its whole length, thus, controlling flow of sample substance. Flow of sample substance may be assessed, depending on the length of open part in permeable element, by the following ratio:

, where G - flow of sample substance through permeable element, r/s; d - inner diametre of permeable element tube, cm; δ - thickness of permeable element wall, cm; P - permeability of tube material, g·cm/s·kg; ΔP - pressure drop, kg/cm²; l - length of the open part of permeable element.

EFFECT: expansion of sample substance control flows range produced by a single check leak.

1 dwg

Description

The invention relates to the field of testing equipment, in particular to control leaks, and can find application in those areas of technology where the tightness of products is monitored to obtain quantitative characteristics of leakage, tuning, sensitivity determination and metrological support of gas analytical equipment are performed.

Known adjustable mechanical control leak (OST 92-2125-87. Control leaks. Technical conditions), made in the form of a shut-off valve, which has a needle leak, designed to fine-tune the flow of the control substance. The linear movement of the needle within the valve seat provides high accuracy of the amount of flow of the control substance. However, the flows of the control substance are quite large, have a turbulent or laminar flow and do not provide flows with micro- and nano-values.

Known diffusion source of gas microflow (RF patent No. 2111460, G01F13 / 00, publ. 05.20.98) containing a sealed gas-tight housing filled with dosed gas in the liquid phase and a diffusion assembly sealed to the housing made in the form of a closed capillary placed inside the housing the cavity of which is filled with a rigid gas-permeable element, providing a diffusion-type microflow. The disadvantage is that the source has only one value of the flow of the dosed gas, in addition, the outflow of gas through the diffusion node occurs continuously, which leads to a relatively rapid decrease in the test substance inside the source and, therefore, the interruption of the diffusion source of the gas microflow.

Closest to the proposed technical solution is an adjustable control leak (AS USSR No. 1577484, G01M 3/02, publ. 28.08.88), which contains a housing with a permeable element made in the form of a diaphragm and a working fluid in the form of a liquid column, overlapping aperture, adjustable heat source. The control flows are controlled by setting the leak with the permeable element up or down. Additional flow control is achieved by choosing a fluid, changing its temperature, cooling the permeable element, and also changing the angle of the leak. However, the disadvantage of this leak is that the gas and liquid vapor stream can have only maximum or minimum values depending on the upper or lower location of the diaphragm. Flow control by changing the temperature of the diaphragm or liquid technically complicates the design of the control leak, requires maintaining and monitoring with high accuracy the temperature of the diaphragm and liquid during the leak test.

The aim of the present invention is to expand the range of control flows of the test substance reproduced by one control leak.

To achieve this technical result, an adjustable control flow comprising a sealed impermeable casing filled with a test substance and a tightly permeable tube-shaped element inside the casing according to the invention has an impermeable tube installed inside the permeable element tightly adjacent to the inner walls of the permeable element and capable of move along its entire length, thereby regulating the flow of the test substance, which can be estimated depending on the open length that portion of the permeable element by the relation:

where G is the flow of the test substance through the permeable element, g / s;

d is the inner diameter of the tube of the permeable element, cm;

δ is the wall thickness of the permeable element, cm;

P - the permeability of the tube material, g · cm / s · kg;

ΔP is the pressure drop across the permeable element, kg / cm ² ;

- длина открытой части проницаемого элемента, см.

- the length of the open part of the permeable element, see

The proposed leak design with an adjustable flow of the test substance is presented in the drawing. The main element of the leak is an impermeable housing 1, which serves as a container for filling with a test substance 6, for example, a control fluid. After filling the body cavity with the control liquid 6, a permeable element 2 is inserted into the central hole in the form of a tube with sealing elements 5. On the one hand, the permeable element tube is closed by a plug 7, and on the other hand, an impermeable tube 3 is inserted into the permeable element. caused by the pressure of saturated vapors diffuse through the permeable element, falling into the channel of the impermeable tube. When loosening the nut 4, the impermeable tube 3 can move inside the permeable element 2, thereby regulating the flow of the test substance, which can be estimated depending on the length of the open part of the permeable element, according to the ratio:

where G is the flow of the test substance through the permeable element, g / s;

d is the inner diameter of the tube of the permeable element, cm;

δ is the wall thickness of the permeable element, cm;

P - the permeability of the tube material, g · cm / s · kg;

ΔP is the pressure drop across the permeable element, kg / cm ² ;

- длина открытой части проницаемого элемента, см.

- the length of the open part of the permeable element, see

The free side of the impermeable tube 3 may be connected to a test system or to a diluent gas source.

The control leak is pre-calibrated at a certain position of the impermeable tube l = l _k (cm) in order to obtain the necessary permeability P (g · cm / s · kg) of the material of the permeable element in the ratio:

where G _to is the vapor flow of the control fluid obtained during calibration, g / s.

When storing the control leak, the impermeable tube is pushed into the permeable element until it stops, i.e. is in position l = 0, the permeable element is completely closed and, accordingly, there is no vapor flow of the control liquid.

During operation, depending on the required vapor flow of the control fluid G _m (g / s), it is necessary to extend the impermeable tube in the position l = l _x (cm), which is determined by the ratio:

Thus, changing the position of the impermeable tube relative to the permeable element, you can change the value of the vapor flow of the control fluid. Using an adjustable control leak allows you to expand the range of control flows of the test substance from one leak. In addition, during storage, by blocking the permeable element with an impermeable tube, it is possible to reduce the vapor flow of the control liquid to almost zero, i.e. increase the duration of operation of the control leak.

The proposed adjustable control leak has been field tested. The control leak, the structural diagram of which is shown in the drawing, was charged with freon. At various positions of the impermeable tube relative to the permeable element, i.e. different values of l, the vapor flow of the control fluid was calibrated. The results of the tests confirmed the possibility of regulating the vapor flow of the control liquid in the range from 10 ^-9 to 10 ^-7 g / s.

Claims (1)

An adjustable control leak, comprising a sealed impermeable casing filled with a test substance and a tightly permeable element inside the casing, made in the form of a tube, characterized in that an impermeable tube is installed inside the permeable element, tightly adjacent to the inner walls of the permeable element and able to move along its entire length , thereby regulating the flow of the test substance, which can be estimated, depending on the length of the open part of the permeable element, according to the ratio:

where G is the flow of the test substance through the permeable element, g / s;
d is the inner diameter of the tube of the permeable element, cm;
δ is the wall thickness of the permeable element, cm;
P - the permeability of the tube material, g · cm / s · kg;
ΔP is the pressure drop across the permeable element, kg / cm ² ;
l is the length of the open part of the permeable element, see