LT4094B - Testing device for fluid-tightness of hydraulic systems - Google Patents

Abstract

Invention is dedicated to hydraulic system sealing control and may be used in diagnostic and monitoring systems of the equipment used in oil and chemistry industry as well as in power, etc. equipment.The hydraulic system sealing control unit consists of serial circuits of the following: the reference volume (1), a unit for transforming leakages into discrete power impulses (3), and a time interval measurement and impulse reading unit (9). The new thing introduced in the unit is that unit for transforming leakages into discrete power impulses consists of a calibrated nozzle (4) and a piezoelectric element (5), situated in a thin elastic shell (6) and installed in the frame body (7) a certain distance down from the calibrated nozzle (4). Further, the piezoelectric element (5) is electrically connected to the amplifier inlet (8), whose outlet is connected to the time interval measuring and impulse reading unit (9).

Description

The invention can be included in the field of control of airtightness of hydraulic systems and used in diagnostic, quality assessment and monitoring systems of movable and fixed joints.

Hydraulic leak tightness control devices are known in which the size of a leak is measured directly by volume, weight, pressure increment methods or derivative (combined) methods [see kn .: Cpe / jCTBa κοΗτροη »repMeTHUHOCTu: B 3 ~ x t. / floo peo. A.C. 3axnrHHa.-T. 1,2, - M.: MauniHOCTpoeHue, 1976]. All of these devices have a narrow measuring range, low accuracy for extremely low leakage measurements, and cannot be used in remote leakage control, diagnostic and monitoring systems. There are also known leakage control devices, in which the amount of leakage is estimated indirectly by electrical, capacitive, ultrasonic, acoustic, laser, chemical and others. methods [see Kn .: Ba6xHH B.T., 3afineHKO A.A., AneKcaHąpoB B.B. repMeTHUHOCTb HenoąBnXHbix coe / øiHeHufi rHąpaBJTHHecKnx cncTeM.— M.: MauiHHOCTpoeHHe, 1977.-120 c.]. These devices can be used for remote leakage control, diagnostics and monitoring, but they also have a number of drawbacks: they are low in reliability, complex and expensive in design, and provide only qualitative information on leakage size.

There is also known a device for measuring the size of a gas leak [see: Authorization No. 1769034 (USSR), GO1M 3/00, 1992], which is selected as a prototype of the present invention. This unit includes a controlled and reference volume interconnected tube, a unit for transforming leakage into discrete electrical pulses, and a unit for measuring time intervals and counting pulses. The leakage transforming unit into discrete electrical signals consists of a differential pressure transducer and a limiting unit interconnected in series and connected to an electromagnetic shut-off valve control channel. The unit for measuring time intervals and counting pulses consists of a reference signal generator, a counter and an indicator; it is connected to the output of the boundary block. A differential pressure transducer and a solenoid shut-off valve are connected in series to the pipe connecting the controlled and reference volumes. In the event of gas leakage, a differential pressure is created between the controlled and reference volumes measured by a differential pressure transducer. When this pressure difference reaches a certain threshold value, the boundary block generates an electrical pulse and transmits it to the time interval measurement and pulse counting unit, as well as to the control channel of the solenoid valve. The amount of gas leakage is judged by the size of the time intervals between the pulses, the time intervals recorded in the unit and the pulse counting unit. When an electrical pulse enters the control channel of an electromagnetic shut-off valve, this valve opens briefly, connects the controlled volume to the reference, and then closes again; this will prepare the unit for the next gas leak measurement cycle.

The gas leakage measuring device described above can be used for remote control, diagnostics and monitoring of airtightness, but its design and construction is rather complicated and its reliability and sensitivity are low. Because the magnitude of the gas leakage is not directly measured, but by the rate of pressure drop in the control volume, the accuracy of the leakage measurement is low and the measurement range narrow. In addition, the device described cannot be used to measure the amount of fluid leakage due to its operating principle.

The object of the present invention is to increase the accuracy of the leak tightness control of hydraulic systems and to extend the range of measurement of fluid leakage.

The object is achieved by the fact that, in the proposed device, consisting of a series of interconnected control volume, time interval measurement and pulse counting unit and leakage transformed discrete electrical pulse unit, the latter consists of a calibrated nozzle and piezo element housed in an elastic thin-walled casing vertically below the calibrated tip in the common housing and electrically connected to the amplifier via a time interval measurement and pulse counting unit.

The novelty of the presented solution, as compared to the prototype, lies in the original design of the fluid leakage transform into discrete electrical pulses, its element arrangement and interaction, as well as the method of connection with the time interval measurement and pulse counting unit. Comparing this technical solution with others, it can be seen that the newly introduced elements, their arrangement, connection and interaction with other elements add new features to the proposed technical solution, which increases the accuracy of the hydraulic hermetically sealing control and extends the measuring range.

The schematic block diagram of the hydraulic tightness control device is shown in the drawing.

The leakage control device of the hydraulic systems (see Fig.) Consists of a control volume 1, hermetically connected to a leakage transforming discrete pulse unit 3 by a tube 2, comprising a calibrated tip 4 and a piezo element 5 housed in an elastic thin-walled casing 6. the vertical distance below the calibrated nozzle 4 in the common housing 7. The vertical distance between the calibrated nozzle 4 and the piezo-cell 5 depends on the physical properties of the fluid entering the control volume 1 and the characteristics of the piezo-cell 5. The piezo element 5 is electrically connected to the input of the amplifier 8 and the output of the latter is electrically connected to a time interval measuring and pulse counting unit 9 comprising a reference signal generator 10, a counter 11 and an indicator 12. The control volume 1 is hermetically connected to the hydraulic system under investigation. an assembly, assembly, or joint that is controlled for airtightness. Instead of the control volume 1, the drainage cavity of the hydraulic unit, which collects the working fluid leakage, can be used. Instead of the pipe 2 connecting the control volume 1 to the discrete electrical impulse block 3, the drainage line of the hydraulic system or a separate unit thereof can be used. Openings are made in the lower part of the housing 7

13th

The proposed hydraulic tightness control device works as follows. The leakage of the fluid to be sealed through the movable or immovable connections of the hydraulic system enters the control volume 1 (see Fig.) And is directed by a tube 2 to the leakage transforming unit 3 into discrete electrical signals. gradually a drop of sealable fluid is formed. When the drop mass reaches a critical value, it breaks away from the calibrated tip 4 and bounces vertically downward against the surface of the piezoelectric element 5 coated with a resilient thin-walled shell 6. This impact produces a pulsed electrical signal on the surface of the piezoelectric element 5, which is amplified in the amplifier 8 and transmitted to the pulse counting and time interval measuring unit 9. This block 9 counts the electrical pulses generated by the piezoelectric element 5 sealing device, the number of drops and, at the same time, directly proportional to the volume of leakage. Block 9 also measures the time intervals between each of two successive electrical pulses; the duration of these time intervals is inversely proportional to the leakage rate of the fluid to be sealed. The volume and mass of the drop of fluid to be sealed at break from the calibrated nozzle 4 is dependent upon the physicochemical properties of the liquid, the dimensions and shape of the calibrated nozzle 4, and is stable under constant conditions. In this way, the measurement of the leakage volume of the fluid to be sealed does not exceed one drop volume. Since the maximum duration of drop formation is practically unlimited, the lower limit of the proposed device leakage flow measurement range is zero, i.e. The device described above can be used to measure infinitely small leakage rates. The upper limit of the leakage flow measurement range is reached when the time interval between the two pulses generated by the piezoelectric element 5 approaches zero, i.e., when the leakage of the pressurized fluid from individual drops turns into a continuous flow. The accuracy of the measurement of the leakage rate throughout this range depends only on the accuracy of the measurement of the volume and time intervals of the individual liquid drop, which can be achieved sufficiently high. A drop of liquid, bounced on a piezo-cell 5 coated with a resilient thin-walled shell 6, drains into the lower part of the housing 7 and is led through the apertures 13 to the environment or to the drainage system.

The developed hydraulic leakage control device is fully proven in practice due to its extremely high leakage flow measurement accuracy and its ability to control leakage over a very wide range without any additional adjustment or adjustment. Another positive feature of the developed device is that it can be connected directly to the drainage line of the hydraulic unit or connection under investigation without any structural changes, special stopping and disassembly. The proposed device can be used in both periodic control mode and continuous monitoring mode.

Claims (1)

DEFINITION OF INVENTION Hydraulic leak tightness control unit consisting of a series of connected control volume, leakage transforming discrete electrical pulse block and time interval measurement and pulse counting unit, characterized in that the fluid leakage discrete electrical pulse blocking unit consists of a calibrated nozzle and a piezo element in a thin-walled housing, positioned at a certain distance in a vertical direction below a calibrated tip in a common housing, and electrically coupled to a time interval measurement and pulse counting unit via an amplifier.