RU2322655C2 - Mode of searching leakages (variants) - Google Patents

Abstract

FIELD: mode refers to nondestructive control over industrial articles having free volume.

SUBSTANCE: it is assigned for control over tightness of heat producing elements for atomic reactors with aid of helium leak detector. Mode of searching leakages with aid of helium leak detector in articles having free volume includes preparation of articles for control in controlling installation having vacuum chamber, pumping system of vacuum chamber, leak detector in shape of mass spectrometric leak detector, control-measuring devices, locking accessories and pipelines, loading of articles into vacuum chamber, setting vacuum with aid of pumping system of vacuum chamber, switching of leak detector to vacuum chamber, taking readings of leak detector, evaluation of fitness of articles according to these readings by way of comparison them with admissible leakage. At that according to first variant of mode taking signal of leak detector is made before beginning of equipoise state of controlling installation in moment of time t_c, and for value of admissible leakage they take meaning calculated according to given formula. According to second variant taking signal of leak detector is made in concrete period of time T_c after switching of leak detector and for value of admissible leakage they take meaning calculated along given formula, according to third variant of mode taking signal of leak detector is made in time T_0,9 which they find in given formula and for meaning of admissible leakage they take value equal to 0,9 from normative leakage, according to fourth variant of mode vacuum chamber before switching to leak detector is sustained in closed state during period of accumulation of test gas t_n , and meaning of admissible leakage is defined along given formula.

EFFECT: increases sensitiveness of control over articles.

5 cl, 1 dwg

Description

The method relates to the field of non-destructive testing of industrial products having a free volume, namely, the tightness control of fuel elements for atomic reactors using a helium leak detector.

Mass spectrometric method of tightness control of articles having a closed volume, using helium as a test gas, is widely used in various fields of industry, including nuclear. Products may contain helium as a medium in which they are sealed, or it enters the free volume through possible defects during pressure testing of products with helium before tightness control.

A known method for the search for leaks / "Non-Destructive Testing", volume II, ed. V.V. Klyuyeva, Moscow, Mashinostroenie, 2003 /, which includes preparing the product for inspection, loading it into a vacuum chamber, pumping the vacuum chamber with a pumping system of the vacuum chamber, closing the pumping system of the vacuum chamber, connecting the leak detector to the vacuum chamber, the vacuum in the chamber is maintained by its own pumping system of the leak detector, establishing a stable signal on the scale of the leak detector, that is, achieving the equilibrium state of the control installation, taking the leak detector, comparing the leak detector with the norm Q _n , that is with the maximum allowable leakage value for these products, established by the product developer, deciding on the suitability of the products.

In this case, the leak detector readings are reliable if the measurement was made after the equilibrium state was established, that is, the state when all flows were established and the leakage flow into the system from leaky products is equal to the gas flow taken by the leak detector.

The closest in technical essence and the achieved result is a method for searching for leaks using a helium leak detector according to the patent of the Russian Federation No. 2164359, MKI G21C 17/00, G21M 3/20, 2002 - a prototype according to which leaks are searched for in products containing free volume filled with helium, having the magnitude of the allowable leak at specified pressure and temperature and having a surface leakage flow. The method includes checking the operability of the installation by injecting helium from a standard source during product testing, determining the flow of helium leakage from the product and comparing it with an acceptable leakage value. For each test temperature, the load of the control unit and the amount of allowable leak at a given temperature are determined. The leakage tolerance allowed for the controlled products is adjusted depending on the control conditions. However, the control itself is carried out only in equilibrium, and the sensitivity of the installation is limited by the sensitivity of the leak detector.

The objective of the invention is to develop a method for searching for leaks with increased sensitivity for monitoring products with increased tightness requirements, with high selectivity, the ability to detect test gas in a spurious leakage stream, and high performance.

The problem is solved due to the fact that in the method for searching for leaks using a helium leak detector in products having a free volume, including preparing the products for inspection in a monitoring installation comprising a vacuum chamber, a vacuum chamber evacuation system, a leak detector in the form of a mass spectrometric leak detector, measuring instruments, valves and pipelines, loading products into a vacuum chamber, vacuuming using a pumping system of a vacuum chamber, connecting a leak detector to a vacuum chamber, taking off the display leak detector, assessing the suitability of products according to these indications by comparing them with the allowable leak, according to the claims, the leak detector is removed until the control installation is in equilibrium at time t _k , and the value calculated by the formula (1) is taken as the allowable leak:

where Q _d is the stream, which shows the leak detector through time t _to after it is connected,

Q _n - the normative value of the leakage flow from products,

S ₀ - pumping speed of the leak detector pump,

V is the free volume of the vacuum chamber,

p _VK - pressure in the vacuum chamber before connecting the leak detector,

t _to is the time elapsed after connecting the leak detector to the vacuum chamber until the leak detector signal was taken.

The problem is also solved due to the fact that the leak detector is removed after a specific period of time T _to after the leak detector is connected, and the value calculated by the formula (2) is taken as the allowable leak:

where T _to is the numerical value of the time elapsed after connecting the leak detector to the vacuum chamber until the leak detector signal was taken.

A necessary condition for solving the problem is that the leak detector is removed after a period of time T _0.9 after connecting the leak detector, which is found from formula (3), and for the value of the allowable leak take a value equal to 0.9 from the standard leak.

where T _0,9 is the time elapsed after connecting the leak detector to the vacuum chamber until the leak detector signal was taken, which, when the leakage stream is equal to the standard leakage leakage into the vacuum chamber, takes the value 0.9 of the value of this flow.

The problem is also solved due to the fact that before connecting the leak detector to the vacuum chamber it is kept closed for a period of time of accumulation of the test gas t _n , and the value of the allowable leak is determined by the formula (4):

t _n - the time elapsed after the vacuum chamber was closed, for the accumulation of test gas, before connecting the leak detector to the vacuum chamber and taking the leak detector signal,

k is the coefficient of proportionality.

The problem is solved if the vacuum chamber is kept closed for a period of time during which the leakage of the test gas into the vacuum chamber with a flow equal to the standard value will give a reading numerically equal to the standard leak when the leak detector is connected, and the standard value is taken as the allowable leak.

This problem will be solved if we determine how to measure leakage before the onset of the equilibrium state of the control installation, how to accelerate the onset of this state, how to increase the sensitivity of the control by accumulating test gas without loss of performance.

The specified set of features is new and has an inventive step, since it allows you to take a signal before the onset of equilibrium, that is, until the true leakage value is obtained, and calculate the allowable leakage by recalculating according to formulas derived according to the laws of vacuum technology, depending on the selected control modes.

To determine the magnitude of the leak, a new technique is used - predicting the magnitude of the leak according to the formulas derived for this control method and the initial course of the signal change in the transient mode of the control installation or in the mode of accumulation of test gas.

Various options for choosing the moment of taking the leak detector signal - near the equilibrium point of the control installation, at any current moment or at a specific moment, the methods of accelerating the achievement of the control point by temporary accumulation or pumping of test gas allow expanding the operational capabilities of existing equipment and choosing the most optimal option depending on the design of the products, equipment used, accuracy of determination of leakage flow and other control conditions.

It is possible to determine the amount of leakage before the onset of equilibrium by the dependence of the growth of the leak detector signal, which will be the same under the same conditions for a specific leakage value. Taking the leak detector at the initial moment of signal growth, it is possible to determine its equilibrium value. Such a dependence can be removed experimentally for specific conditions, using Gelit as a source of sample gas with a nominal gas flow value equal to the norm for the controlled products.

For the general case, this dependence can be derived using formulas of the vacuum technique. So, for example, the testimony of a leak detector connected to a vacuum chamber with products at any time t will correspond to formula (1):

where Q _m is the stream that shows the leak detector through time t after it is connected,

Q _u - leakage flow from controlled products, or Gelita,

S ₀ - pumping speed of the leak detector pump,

V is the free volume of the vacuum chamber,

p _CR - the maximum pressure that develops a leak detector pump.

t is the time elapsed after connecting the leak detector to the vacuum chamber until the leak detector signal was taken.

When the vacuum chamber is closed and the test gas is accumulated, the indication of the leak detector connected to the vacuum chamber with the products at any time t will be determined in accordance with formula (4):

where Q _u is the leakage flow from controlled products, or Gelita,

t is the time elapsed after the vacuum chamber was closed until the leak detector was connected to the vacuum chamber and its readings were taken.

k is the coefficient of proportionality.

The figure shows a graph of changes in the leak detector in the output mode of the control installation in equilibrium and in the mode of accumulation of test gas.

Points on the graph mean:

Q _p , T _p - the equilibrium value of the signal of the leak detector and the time of its achievement,

Q _0.9 , T _0.9 - the value of the leak detector signal at the level of 0.9 from the equilibrium and its time

achievements,

Q _to , T _to - the current reading of the leak detector and the point in time, which are taken as control in the transition to the equilibrium value,

On _nak , T _to - the current reading of the leak detector and the time, which are taken as control in the accumulation mode,

Q _n , T _pH - the value of the leak detector signal measured in the accumulation mode, numerically equal to the equilibrium value (and the norm) and the time it was reached,

a - equilibrium (true) indication of the leak detector,

b is the exit point of the leak detector in position 0.9 from the equilibrium value,

C is an intermediate indication of the leak detector as it reaches the equilibrium level,

which can be taken as a control point,

d is an intermediate reading of the leak detector as sample gas accumulates in the retort,

which can be taken as a control point,

e is the output point of the leak detector signal in the accumulation mode, in which it is equal to the standard leakage,

1 - curve of the leak detector readings to the equilibrium state,

2 is a graph of the accumulation of test gas in a vacuum chamber, the growth of the leak detector when connected to a vacuum chamber in the mode of accumulation of test gas,

3 - trajectory of the accelerated output of the leak detector signal to the equilibrium state using accumulation — approaching the equilibrium from below,

4 - trajectory of the accelerated output of the leak detector signal to the equilibrium state using accumulation — approaching equilibrium from above.

The implementation of the method is described by the following examples.

Example 1. A bunch of 320 pieces of fuel rods having a leak rate of 7 · 10 ^-10 MPa / s are heated in a vacuum oven to a temperature of 220 ° C and loaded into a vacuum chamber of 300 liters for hot tightness control. As a leak detector used Varian-948, operating in countercurrent mode. The vacuum chamber is pumped out and the leak detector is connected. After connecting the leak detector after 3 minutes of establishing the signal, it showed 0.4 · 10 ^-10 MPa / s, the signal did not change in the future, therefore, the fuel rods are tight.

After zeroing the signal, Gelit is connected as a source of test gas with a nominal leakage flux equal to the norm for these fuel rods, 7 · 10 ^-10 MPa / s. This causes an increase in the leak detector signal: after 25 minutes to a value of 6.3 · 10 ^-10 MPa / s, after 40 minutes to a value of 7.04 · 10 ^-10 MPa / s. The last value does not change further.

That is, the time to establish equilibrium was 40 minutes, while after 25 minutes it was equal to 90% of the norm. Repeating measurements gives the same result. That is, after 25 minutes the signal is established near the equilibrium, which means true value. By taking a signal at this point in time and multiplying it for accuracy by a factor of 0.9, it is possible to evaluate the leakage flow from the products and decide on their suitability.

It is possible to take the leak detector signal and make a decision on the suitability of the products at an earlier point in time t _k if you know the pattern of the signal change. In this case, this can be done by the experimental curve, in any other case by the calculation method according to the formula (1). Then the condition of validity will be the expression:

The validity condition for the control according to example 1 through t = t _0.9 = 25 minutes in general form will look like:

It is convenient to carry out the monitoring at a fixed moment of time T _to , so as not to determine again every time the permissible leak value, but it is not necessary to wait 25 minutes. In this case, the condition of validity will be a particular form of expression (3):

Example 2

The same bundle of fuel rods is loaded into a vacuum chamber, as in Example 1. After vacuum has been set, the chamber is closed and the test gas is accumulated for 4 minutes. The leak detector after connecting to a vacuum chamber showed a value of 1.4 · 10 ^-10 MPa / s. After the vacuum is re-set in the chamber and closed for gas accumulation, Gelite is connected to it as a source of test gas with a nominal leakage flux equal to the norm for these fuel rods, 7 · 10 ^-10 MPa / s. Then, every 1.5 minutes, the leak detector is connected two more times. As a result, the following indications were obtained.

after 1.5 minutes the signal was 3.6 · 10 ^-10 MPa / s,

after 3.0 minutes, the signal was equal to 7.0 · 10 ^-10 MPa / s,

after 4.5 minutes, the signal was 10.6 · 10 ^-10 MPa / s.

From example 2 it is seen that the accumulation of test gas in a vacuum chamber occurs in proportion to the accumulation time t _n After 3 minutes of exposure, the signal becomes numerically equal to the nominal value of the flow of leakage from Gelit, that is, the true value. This happens only at one moment in time as the gas accumulates, then the signal will grow unlimitedly in a straight line. If you build this line, then it can be used to evaluate the validity of products at any time. They will be unusable if the value of the leak detector signal is higher than this line. In general, the condition of validity will look:

As in the first case, it is more convenient to choose a specific moment of accumulation time T _n and for it calculate the allowable leak value:

It is advisable to take the accumulation time so that the corresponding value of the allowable leakage is equal to the norm Q _m.calc. = Q _n , i.e.

,

,

where k and K are constants depending on the design features of the control installation. Then there is no need to recalculate the existing leak rate.

, для получения более четкого результата. В каждом конкретном случае нужно выбрать оптимальное соотношение между степенью передержки на стадии накопления и риском перебраковки изделий за счет допустимого натекания.Usually suitable products give a signal much smaller than the permissible value, and unsealed ones give a much larger signal. Therefore, it is possible to choose the accumulation time somewhat more than the period

, to get a clearer result. In each particular case, it is necessary to choose the optimal ratio between the degree of overexposure at the accumulation stage and the risk of product rejection due to permissible leakage.

Example 3

Example 3 is a kind of combination of the control principles set forth in Example 1 and Example 2 — the use of accumulation to accelerate the achievement of an equilibrium state after connecting a leak detector.

When performing the control in example 2 after removing the signal after 3 minutes when the leak detector is switched on, its pumping system is connected to the vacuum chamber for several seconds. Watching the leak detector, pumping is performed until the signal becomes equal to 7.0 · 10 ^-10 MPa / s. That is, in an accelerated order, the equilibrium state of the leak detector was achieved by approaching it from above.

When performing the control according to example 2 after the equilibrium level has been reached in 3 minutes, accumulation can be considered as a method of accelerating the achievement of the equilibrium state by approaching from below.

The signal of the leak detector after it is connected to the camera will behave according to one of four options:

First, the leak detector signal has not reached equilibrium value and decreases with time. Products should be considered fit.

Second, the leak detector signal is higher than the reject sign and increases with time. There are leaks.

Third, the leak detector signal has not reached the rejection level and increases over time. The system is on its way to the bottom of the equilibrium point, but it is not known whether it will cross the normal level. There is uncertainty of the first kind, you should wait until the installation comes to equilibrium.

Fourth, the leak detector signal is higher than the reject sign, but decreases with time. The system tends to equilibrium from above, but it is not known whether the norm level will be crossed at that, there is a second kind of uncertainty, you should wait until the installation reaches equilibrium.

In the last two cases, methods can be used to accelerate the reduction of the signal to an equilibrium value by briefly shutting off the vacuum chamber or by connecting a pumping system to it.

The high efficiency of the proposed method for searching for leaks by the most important characteristics of the control operation gives a new effect - the ability to control products with high tightness requirements without the use of new expensive equipment and without reducing production productivity.

Claims (5)

1. A method for searching for leaks using a helium leak detector in products having free volume, including preparing the products for inspection in a monitoring installation comprising a vacuum chamber, a vacuum chamber evacuation system, a leak detector in the form of a mass spectrometric leak detector, instrumentation, and stop valves and pipelines, loading products into a vacuum chamber, vacuuming using a pumping system of a vacuum chamber, connecting a leak detector to a vacuum chamber, taking a leak detector, evaluating the suitability and dely for this indication by comparing them with the permissible leakage, characterized in that the removal of the leak detector signal produced before the equilibrium state of the control installation at time t _k, and permissible value for charge leakage value calculated by the formula (1)

where Q _d - flow, which shows the leak detector through time t _to after it is connected; Q _n - the normative value of the leakage flow from products; S ₀ - pumping speed of the leak detector pump; V is the free volume of the vacuum chamber; p _VK - pressure in the vacuum chamber before connecting the leak detector; t _to is the time elapsed after connecting the leak detector to the vacuum chamber until the leak detector signal was taken. 2. A method for searching for leaks using a helium leak detector in products having a free volume, including preparing the products for inspection in a monitoring installation comprising a vacuum chamber, a vacuum chamber evacuation system, a leak detector in the form of a mass spectrometric leak detector, instrumentation, and stop valves and pipelines, loading products into a vacuum chamber, vacuuming using a pumping system of a vacuum chamber, connecting a leak detector to a vacuum chamber, taking a leak detector, evaluating the suitability and dely for this indication by comparing them with the permissible leakage, characterized in that the removal of the leak detector signal produced over a particular period of time T after the connection _{to the} leak detector, and the magnitude of the permissible leakage take the value calculated by formula (2)

where T _to is the numerical value of the time elapsed after connecting the leak detector to the vacuum chamber until the leak detector signal was taken. 3. A method for searching for leaks using a helium leak detector in products having a free volume, including preparing the products for inspection in a monitoring installation comprising a vacuum chamber, a vacuum chamber evacuation system, a leak detector in the form of a mass spectrometric leak detector, instrumentation, and stop valves and pipelines, loading products into a vacuum chamber, vacuuming using a pumping system of a vacuum chamber, connecting a leak detector to a vacuum chamber, taking a leak detector, evaluating the suitability and dely for this indication by comparing them with the permissible leakage, characterized in that the removal of the leak detector signal produced through the period T _0.9 after connecting the leak detector, which is found from the formula (3) and for the value of the permissible leakage takes a value equal to 0.9 against regulatory leakage

where T _0.9 is the time elapsed after the leak detector was connected to the vacuum chamber until the leak detector signal was taken, which, when a leak stream equal to the normative leakage stream flows into the vacuum chamber, takes the value 0.9 of the value of this stream. 4. A method for searching for leaks using a helium leak detector in products having a free volume, including preparation of products in a control installation containing a vacuum chamber, a vacuum chamber evacuation system, a leak detector in the form of a mass spectrometric leak detector, instrumentation, valves and piping , loading products into a vacuum chamber, vacuuming using a pumping system of a vacuum chamber, connecting a leak detector to a vacuum chamber, taking a leak detector, evaluating the suitability of products according to testimony to them by comparing them with an allowable leak, characterized in that before connecting the leak detector to the vacuum chamber, it is kept closed for a period of time of accumulation of the test gas t _n , and the amount of allowable leak is determined by the formula (4)

where t _n is the time elapsed after the vacuum chamber was closed, for the accumulation of test gas, before connecting the leak detector to the vacuum chamber and taking the leak detector signal, k is the coefficient of proportionality. 5. The method according to claim 1 or 4, characterized in that the vacuum chamber is kept closed for a period of time during which leakage of the test gas into the vacuum chamber with a flow equal to the normative value will give a readout numerically equal to the normative leak when the leak detector is connected , and for the value of the allowable leak take the standard value.