RU2611565C1 - Device for fatigue testing of spools and seats of shut-down valves - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: device comprises a body with inlet and outlet branches, a seat and a spool interacting with the seat, installed in the body opening, and a stock and a loading device. The loading device comprises a frame, the body is secured to the base. Electric drive is secured to the frame side, on its output shaft an eccentric is secured, it is located in the slot of a slide installed with possibility of axial movement in openings of the frame ribs. One end of stock is connected with the slider, and another end interacts with the spool. A washer is installed on the stock, the washer rests against the stock shoulder. A calibrated spring rests by one end against the washer, its another end contacts with strip. The strip is installed with possibility of axial movement on studs installed in the frame base. The strip position is locked using nuts installed on free ends of studs. Pointer of scale divisions is secured on the strip. The scale is secured on the frame side. The spool and seat are made replaceable.

EFFECT: possibility of estimation and adjustment of force created on sealing surfaces of spools and seats with different configuration.

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Description

The invention relates to mechanical engineering, to tests and test benches, in particular, can be used for fatigue tests of spools and seats of shut-off valves.

From the prior art, a stand for hydraulic and pneumatic testing of pipe fittings PKTBA-SI-6-4 is known, which makes it possible to conduct life tests of shut-off valves and, as a result, fatigue tests of spools and seats (product catalog of the Penza Valve Design and Technology Bureau CJSC. Official website in the information and telecommunication network "Internet": http://pktba.ru/catalog/product/36.html). It has a housing, a clip for installing the test shut-off valve, inlet and outlet piping for supplying pressure to the shut-off valve, and operates as follows. After installing the shut-off valve on the stand and applying pressure to the shut-off valve with the standard handle of the shut-off valve, the set number of cycles is generated. In this case, the force created on the sealing surfaces of the valve spool and seat of the shutoff valve depends on the force applied to the handle of the shutoff valve by the tester, as well as on the friction that occurs in the nodes of the shutoff valve. If it is necessary to test the seats and valve spools with a different configuration of the sealing surfaces or with a different sealing diameter or from another material, it is necessary to install a new shut-off valve with the corresponding seat and spool.

The disadvantages of this stand for hydraulic and pneumatic testing of pipeline valves are:

1. The impossibility of assessing the magnitude of the force created on the sealing surfaces of the spool and seat.

2. The inability to adjust this effort.

3. The impossibility of testing spools and seats with different configurations of sealing surfaces, with different sealing diameters, from various materials.

The closest in essence and the technical result achieved is a shut-off valve (Calculation and design of pipeline valves. Gurevich DF, M. - L .: Engineering, 1964, p. 111, Fig. 16 g), consisting of a housing with inlet and outlet nozzles, a saddle and a spool interacting with the saddle, installed in the opening of the housing, as well as the rod and the loading device. The immediate purpose of this shut-off valve is to execute a process program by opening or closing the valve, but it can also be used as a fatigue test device for spools and seats. For this, after mounting the inlet and outlet pipes and supplying pressure, it is necessary to make a specified number of cycles while rotating the handle, while controlling the amount of leakage in the closed position of the valve, as an indicator for assessing the state of sealing surfaces. In the absence of defects on the sealing surfaces caused by fatigue failure of the surfaces, the joint is tight. In this case, the force created on the sealing surfaces of the valve spool and valve seat will depend on the force applied to the handle by the tester. The shut-off valve described is adopted as a prototype.

However, the disadvantages of this shut-off valve are also:

1. The impossibility of assessing the magnitude of the force created on the sealing surfaces of the spool and seat.

2. The inability to adjust this effort.

3. The impossibility of testing spools and seats with different configurations of sealing surfaces, with different sealing diameters, from various materials.

The objectives of the invention are:

1. Providing the ability to assess the magnitude of the force generated on the sealing surfaces of the spool and seat.

2. Providing the ability to adjust this effort.

3. Providing the ability to test spools and seats with different configurations of sealing surfaces: conical with a different angle of inclination of the sealing surfaces of the seat and spool, as well as flat; with various sealing diameters; from various materials.

The problem is solved by creating the design of a device for fatigue testing of spools and seats of shut-off valves, consisting of a housing with inlet and outlet nozzles, a saddle and interacting with the valve spool installed in the housing bore, as well as a rod and a loading device. The loading device consists of a frame, to the base of which a housing is attached. An electric drive is attached to the side of the frame, on the output shaft of which an eccentric is mounted, which is located in the groove of the slider. The slider is installed with the possibility of axial movement in the holes of the ribs of the frame. One end of the stem is connected to the slider, and the second end of the stem interacts with the spool. A washer is mounted on the stem, resting on a stem ledge. The calibrated spring rests on the washer at one end, the second end of the calibrated spring is in contact with the bar. The bar is installed with the possibility of axial movement on the studs, which are screwed into the base of the frame. The position of the strap is fixed with nuts screwed onto the free ends of the studs. A scale divider is attached to the bar. The scale is fixed on the side of the frame. Moreover, the spool and saddle are interchangeable.

The essence of the invention is illustrated by drawings. In FIG. 1 shows a sectional view of a device for fatigue testing of spools and seats of shut-off valves. In FIG. 2 is a left view of FIG. 1. In FIG. 3 is a view A of FIG. 1 (seat and spool with tapered sealing surfaces). In FIG. 4 is a view A of FIG. 1 (seat and spool with flat sealing surfaces).

In FIG. 1-4 the following notation:

1 - body, 2 - inlet pipe, 3 - outlet pipe, 4 - seat, 5 - spool, 6 - rod, 7 - o-ring, 8 - frame, 9 - base, 10 - sidewall, 11 - electric drive, 12 - output shaft, 13 - cam, 14 - slider, 15 - rib, 16 - washer, 17 - calibrated spring, 18 - strap, 19 - pin, 20 - nut, 21 - index of divisions, 22 - scale, 23 - O-ring, 24 - pin, 25 - pin, 26 - nut, α - angle of inclination of the sealing surfaces of the seat and spool, D - diameter of the seal.

The device for testing the fatigue of the spools and seats of the shut-off valves consists of a housing 1 with an inlet pipe 2 and an outlet pipe 3. A replaceable saddle 4 and a spool 5 are installed in the opening of the housing 1. Replaceable saddle 4 and a spool 5 provide the ability to test spools and seats with different configurations sealing surfaces: conical with a different angle of inclination of the sealing surfaces of the seat and spool α (Fig. 3), as well as flat (Fig. 4); with various sealing diameters D; from various materials (carbon steel, stainless steel, bronze, titanium, polymeric materials). With the spool 5, the stem 6 interacts and a loading device consisting of a frame 8, a base 9, a sidewall 10, ribs 15, a washer 16, a calibrated spring 17, a strap 18, studs 19 and nuts 20. A housing 1 is attached to the base 9 of the frame 8 with studs 25 and nuts 26. The sealing of the cavity of the housing 1 relative to the external environment is carried out using a sealing ring 23. The sealing ring 4 is used to seal the connection between the seat 4 and the housing 1. An electric drive 11 is attached to the sidewall 10 of the frame 8, an eccentric is fixed to the output shaft 12 of it 13 which is located in the groove of the slider 14. The slider 14 is mounted axially movable in the holes of the ribs 15 of the frame 8. One end of the stem 6 is connected to the slider 14 using a pin 24, and the other end of the stem 6 interacts with the spool 5. A washer 16 is mounted on the stem 6, resting on the ledge of the rod 6. A calibrated spring 17 is supported on the washer 16 by one end, the second end of the calibrated spring 17 is in contact with the bar 18. The bar 18 is mounted with axial movement on the studs 19, which are screwed into the base 9 of the frame 8. The position of the bar 18 is fixed o with the help of nuts 20, screwed onto the free ends of the studs 19. On the bar 18, the index of divisions 21 of the scale 22 is fixed. The scale 22 is fixed on the sidewall 10 of the frame 8. The compression ratio of the tared spring 17 is adjusted using the nuts 20 and is determined by the index of divisions 21 of the scale 22 that makes it possible to assess the magnitude of the force created on the sealing surfaces of the seat 4 and the spool 5 and to provide the ability to adjust this effort.

The device for testing the fatigue of the spools and seats of shut-off valves is as follows. After installing the test saddle 4 and the spool 5 in the hole of the housing 1, the tared spring 17 is adjusted for the specified force at which the fatigue test will be performed. Moreover, between the eccentric 13 and the slider 14 there is a gap of 1-2 mm, which ensures that the spool 5 is in the closed position and the force transmitted by the calibrated spring 17 is transmitted through the spool 6 to the spool 5. After setting up the device, the pressure of the test medium is supplied to the inlet pipe 2 check the tightness between the sealing surfaces of the seat 4 and the spool 5. The condition of the sealing surfaces is assessed by the amount of leakage. In the absence of defects on the sealing surfaces caused by fatigue failure of the surfaces, the joint is tight. After checking the tightness of the connection, the set number of loading cycles is run. This operating time is carried out in several stages, equal in the number of loading cycles. After each step, the tightness of the connection is checked. The number of loading cycles is set by adjusting the actuator 11 and is performed automatically after switching on.

The device for testing the fatigue of the spools and seats of the shut-off valves is designed to create variable forces on the sealing surfaces of the seat 4 and the valve 5. During operation, the device for testing the fatigue of the spools and seats of the shut-off valves is alternately in the closed and open positions. With the device closed, the sealing surfaces of the seat 4 and spool 5 are pressed against each other with a given force. The force on the sealing surfaces of the seat 4 and spool 5 is created using a calibrated spring 17 through the stem 6. The force on the sealing surfaces of the seat 4 and spool 5 is adjusted by adjusting the compression value of the calibrated spring 17 using studs 19 and nuts 20. The compression value of the calibrated spring 17 is determined according to the index of divisions 21 of the scale 22, mounted on the sidewall 10 of the frame 8. In this position, there is a gap between the eccentric 13 and the slider 14. When the output shaft 12 of the electric drive 11 is rotated, the eccentric 13 moves the slider 14 in the axial direction, thereby moving the rod 6 in the axial direction through the pin 24. In this case, the calibrated spring 17 is compressed and the spool 5 is released from the axial force. Due to the pressure of the working medium supplied to the inlet pipe 2, the spool 5 moves in the direction of movement of the rod 6 and a gap is formed between the sealing surfaces of the seat 4 and the spool 5 (device for testing the fatigue of the spools and saddles goes into the open position). Subsequent rotation of the output shaft 12 of the electric drive 11 leads to axial movement of the slider 14 in the opposite direction. In this case, the spool 5 is pressed against the seat 4 by the force created by the calibrated spring 17 through the stem 6. When the fatigue testing device of the spools and valve seats of the shut-off valves moves from the closed position to the open and back, the force on the sealing surfaces of the seat and spool changes from the maximum value to zero and back respectively. This cyclically changing force causes fatigue failure of the sealing surfaces of the seat 4 and spool 5.

After performing a certain number of loading cycles from a given volume, the drive 11 is automatically turned off, while the device for testing the fatigue of the spools and seats is in the closed position. The tightness of the connection of the spool 5 and the seat 4 is checked. If there is no leakage in the connection, it is concluded that fatigue failure has not occurred and the fatigue test continues by turning on the electric drive 11 and operating a certain number of loading cycles. Otherwise, when a leak occurs in the connection, the device is disassembled with the seat 4 and valve 5 removed. The sealing surfaces of the seat 4 and valve 5 are analyzed for fatigue cracks, peeling, and surface chipping. After that, a new seat 4 and spool 5 are installed in the device and the fatigue test is repeated.

The design of this device for fatigue testing of spools and seats of shut-off valves provides the following technical results. Due to the fact that the compression ratio of the calibrated spring is regulated and determined by the index of the special scale, it is possible to assess the magnitude of the force created on the sealing surfaces of the tested seats and spool, and also provides the ability to adjust this force. Due to the fact that the device provides for the installation of replaceable saddles and spools in the housing opening, it is possible to test spools and saddles with different configurations of sealing surfaces: conical - with a different angle of inclination of the sealing surfaces of the saddle and spool, as well as flat - with different sealing diameters; from various materials.

Claims (1)

The device for fatigue testing of spools and seats of shut-off valves, consisting of a housing with inlet and outlet nozzles, a saddle and a spool interacting with the saddle installed in the opening of the housing, as well as a rod and a loading device, characterized in that the aforementioned loading device consists of a frame, to the base of which the aforementioned case is attached, and an electric drive is attached to the side of the frame, on the output shaft of which an eccentric is mounted, which is located in the groove of the slide installed with By axial movement in the holes of the frame ribs, one end of the aforementioned stem is connected to the slider, the second end of the stem interacting with the spool, a washer mounted on the stem resting on the ledge of the stem, a calibrated spring resting on the washer at one end, the second end of the calibrated spring in contact with the bar, which is installed with the possibility of axial movement on the studs that are screwed into the base of the frame, and the position of the strap is fixed with the help of nuts, screwed onto the free ends of the studs, fixed to the strap the index of the scale divisions is fixed, which is fixed on the side of the frame, and the aforementioned spool and saddle are interchangeable.

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