RU2614347C2 - Potted circuit - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: device comprises a casing (1), at the end (2) of which there is a hollow (3) communicated with the inner cavity (4) of the casing (1). A catch pin (5), the entire outer surface (6) of which is cylindrical, and two radial sealing rings (7, 8) of elastomeric material are located in the hollow (3). Wherein one of the sealing rings (7) is placed in a groove (9). On the casing (1) a union (10) for fluid supply is located with channel (11) outgoing to cavity of the boring (3) at area between the sealing rings (7, 8). The catch pin (5) is provided with a chamfer (13) and mounted with the ability of axial movement relative to the casing (1) and fixing in two positions: in initial, when channel (11) of the union (10) is connected with internal cavity (4) of the casing (1), and final, when the channel (11) of the union (10) is isolated from the internal cavity (4). A stop (15) is made to limit axial movement of the pin (5) in the device. A dual stage bore back (15) is made in the hollow (3) on the end (2) side of the casing (1). The width of the first stage (16) of the bore back (15) is equal to the width of the hollow (3) groove (9) and the diameter of the first stage (16) is equal to the groove (9) outer diameter. The diameter of the second bore back (15) stage (17) opening onto end (2) of the casing (1) is greater than the diameter of the first stage (16). Stopper (18) with the thrust into a throat (19) between the stages (16, 17) of the bore back (15) is arranged inside the second stage (17) of the bore back (15) coaxially to the hollow (3). The sleeve (18) is provided with a lock (20) of the axial position placed outside the cylinder (21) formed by the surface of the hollow (3). The inner diameter of the stopper (18) is equal to the diameter of the hollow (3). The second O-ring (8) is located inside the first stage (16) of the hollow (15).

EFFECT: increase of device manufacturability with repeated usage.

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Description

The invention relates to mechanical engineering and can be used in testing cavities of devices of aviation and rocket technology, as well as in other fields of technology.

It is known a sealed device containing a housing, from the end of which there is a bore communicated with the internal cavity of the housing, a finger located in the bore, two radial sealing rings of elastomeric material, sequentially installed in the sealing grooves of the boring with the possibility of contact with the finger along its cylindrical surface, placed on the body of the fitting for supplying fluid with a channel extending into the internal cavity of the bore in the area between the first and second sealing grooves, while the finger is mounted with the possibility of axial movement relative to the housing and its fixation in two positions - the initial one, in which the nozzle channel is in communication with the internal cavity of the housing, and the final one, in which the nozzle channel is isolated from it (patent of the Russian Federation No. 2488789, IPC: G01M 3/00 July 27, 2013). Fixation of the finger in both positions is carried out by radial finger protrusions placed in one of the two corresponding grooves of the housing.

The disadvantage of such a sealed device is the design complexity due to the need to manufacture radial protrusions on the finger and grooves under them in the housing and significant dimensions and weight, which is undesirable in the products of rocket and space technology.

The sealed device selected as a prototype is deprived of this drawback, comprising a housing, from the end of which there is a bore communicated with the internal cavity of the housing, a finger located in the bore, two radial o-rings of elastomeric material installed in series in the first closest to the inner cavity and the second the sealing grooves of the bore with the possibility of contact with the finger along its cylindrical surface, a fitting for supplying a fluid medium with a channel exiting into the bore cavity in the area between the first and second sealing grooves, while the finger from the end face closest to the inner cavity is chamfered and mounted with the possibility of axial movement relative to the body and its fixation in two positions - the original, in which the nozzle channel is in communication with the inner cavity of the body, and the final, in which the channel of the fitting is isolated from it, as well as an emphasis to limit the axial movement of the finger in its final position (application of the Russian Federation No. 2013152577, IPC: G01H 3/00, publ. June 10, 2015). The entire outer surface of the finger is cylindrical, the stop to limit the axial movement of the finger in its final position is made in the bore and placed between the first sealing groove and the internal cavity, the end of the finger farthest from the internal cavity is made flat and perpendicular to the cylindrical surface of the finger.

The disadvantage of such a sealed device is its low-techness during repeated use, which is required for a certain range of rocket and space technology units during, for example, periodic checks of units during their storage, since if each subsequent use of the device is necessary, removing the finger entails cutting off the nearest the end face of the o-ring housing, followed by its replacement with a new one.

The problem solved by the claimed device is to increase the manufacturability of the device with repeated use.

The technical result is achieved due to the fact that in a sealed device containing a housing, from the end of which there is a bore communicated with the internal cavity of the housing, a finger located in the bore, two installed in the bore with the possibility of contact with the finger along its cylindrical surface, radial elastomeric o-rings material, the first of which is placed in the groove of the bore, a fitting for supplying a fluid medium with a channel extending into the internal cavity of the bore in the area between first and second radial o-rings, the finger from the end closest to the inner cavity is chamfered and mounted with the possibility of axial movement relative to the housing and its fixation in two positions - the original, in which the nozzle channel is in communication with the internal cavity of the housing, and the final, in which the nozzle channel is isolated from it, as well as an emphasis to limit axial movement of the finger, according to the invention, a two-stage groove is made in the bore from the side of the housing end, the width of the first stage is made p the same width of the bore groove, the diameter of the first step is equal to the outer diameter of the groove of the bore, and the diameter of the second step of the two-step groove facing the end of the body is larger than the diameter of the first step of the groove, a sleeve is placed coaxially with the bore coaxially with the bore between the steps of the two-step groove grooves, while the sleeve is equipped with an axial position lock located outside the cylinder formed by the surface of the bore, and a second o-ring mescheno inside the first stage two-stage bore, and an inner diameter of the sleeve is made equal to the bore diameter.

In FIG. 1 shows an example of a specific embodiment of the device in its initial position, a longitudinal section, in FIG. 2 - the same in the final position.

The sealed device contains a housing 1, from the end 2 of which there is a bore 3, connected with the inner cavity 4 of the housing 1. In the bore 3 there is a finger 5 with an outer cylindrical surface 6, two radial sealing rings 7 and 8 of elastomeric material, installed with the possibility of contact with finger 5 along its cylindrical surface 6. The first 7 o-ring is placed in the groove 9 of the bore 3. On the body 1 there is a fitting 10 for supplying a fluid with a channel 11 extending into the internal cavity of the bore 3 in the area between the sealing rings 7 and 8. The finger 5 from the end face 12 closest to the inner cavity 4 is provided with a chamfer 13 and is mounted with the possibility of axial movement relative to the housing 1 and its fixation in two positions - the initial one, in which the channel 11 of the nozzle 10 is in communication with the inner cavity 4 of the housing 1 (shown in Fig. 1), and the final one, in which the channel 11 of the fitting 10 is isolated from it (shown in Fig. 2). A stop 14 is made in the bore 3 between the groove 9 and the internal cavity 4 to limit the axial movement of the finger 5 in its final position. A two-stage groove 15 is made in the bore 3 from the side 2 of the body 1, the width of the first stage 16 is made equal to the width of the groove 9 of the bore 3, the diameter of the first stage 16 is equal to the outer diameter of the groove 9 of the bore 3, and the diameter of the second stage 17 facing the end of the body the two-stage groove 15 is made larger than the diameter of the first stage 16 of the two-stage groove 15. Inside the second stage 17 of the two-stage groove 15, a sleeve 18 is placed coaxially to the bore 3 with an emphasis on the ledge 19 between the steps of the two-stage groove, while 18 is provided with an axial position lock 20, in this example in the form of a snap ring. The axial position lock 20 is located outside the cylinder 21 formed by the surface of the bore 3. The second 8 o-ring is placed inside the first stage 16 of the two-stage groove 15, and the inner diameter of the sleeve 18 is equal to the diameter of the bore 3. When using the device, it is connected to the filling line 22 with valve 23 and a manometer 24. Similarly to the prototype device, the length of the finger L is made greater than or equal to the distance h from the stop 14 to the far end 25 of the groove 9, but less than or equal to the distance g from the stop 14 to t pocket 26 of the first stage 16 of the two-stage groove 15. The length b of the cylindrical outer surface 6 of the finger 5 is made greater than or equal to the distance w between the end 27 of the groove 9 closest to the cavity 4 and the step 19. The end 28 of the finger 5 farthest from the inner cavity 4 is made flat and perpendicular to the cylindrical surface of 6 fingers.

A sealed device operates as follows. In the starting position shown in FIG. 1, the finger 5 is placed by its axial movement by technological means, for example, with a stop (not shown). The sealing ring 8 is placed in the cavity formed by the first stage 16 of the two-stage groove 15 and the end face of the sleeve 18. Since the geometrical dimensions of this cavity are equal to the geometrical dimensions of the groove 9 (the dimensions of the sealing grooves are standardized), the ring 8 works as if it were not in "Composite", as in the claimed technical solution, but in a conventional, made according to standards, sealing groove. Since the sealing mechanism in radial seals is ensured by tightening the sealing ring to the outer diameter of the groove and to the outer diameter of the sealing sleeve (see, for example, “Seals and sealing technique: Reference book” / L.A. Kondakov, L.I. Golubev, V. .B. Ovander, etc. Under the general editorship of A.I. Golubev, L.A. Kondakova. - M .: Mashinostroenie, 1986, pp. 112-113, Fig. 3.4.), Then there is a gap between the ledge 19 and the end face of the sleeve 18 does not affect the normal operation of the sealing ring 8, since this gap has a value not greater than the gap I’m waiting for a bore 3 and a cylindrical surface 6 of the finger 5, and the test medium (when refueling in the initial position from the line 22) is separated by the material of the ring 8, pressed to the surface of the first stage 16 and to the cylindrical surface 6, from the end of the sleeve 18 nearest to it. O-ring 7 does not come in contact with the cylindrical surface 6, which ensures that the channel 11 communicates with the internal cavity 4. In this position, a fluid (for example, a helium-air mixture) is supplied through the channel 11 to the cavity 4. Then, having closed the valve 23, it falls The ax 5 is axially moved to the end position shown in FIG. 2. The sealing ring 7 seals the cylindrical surface of the finger 5, separating the channel 11 with the cavity 4. Since the length of the finger L is less than or equal to the distance g, the channel 11 is separated from the atmosphere only by the annular gap between the bore 3 and the finger 5, the sealing ring 8 in this the finger does not seal the position, since it does not come into contact with its outer cylindrical surface 6. In this position, it is possible to disconnect the supply line from the fitting 10, test the tightness of the cavity 4 filled with the test medium, and further luatatsiya device for its intended purpose. In this case, the reverse axial movement of the finger in the direction from the cavity 4 is limited by a sealing ring 8 of elastomeric material. Since the cross-sectional diameter of the elastomeric O-ring 8 is larger than the depth of the groove 9 (and this is always true for elastomeric rings and is the basis for their proper functioning as seals, then after the outer cylindrical surface 6 of the finger 5 leaves when moving it to its final position from contact with the ring 8, the cross section of the ring 8 will return to the original state not deformed by the finger 5 and will take the configuration shown in Fig. 2, that is, it will protrude inside the bore 3. This same ring 8, which serves as the sealing in the initial position, now acquires in the final position the function of the retainer of the finger 5 from moving it in the direction from the cavity 4 to the position where the surface 6 can come out of contact with the sealing ring 7, which would lead to the depressurization of the inner cavity 4 through the channel 11. Since the end 28 of the finger 5, which is farthest from the inner cavity 4, is made flat and perpendicular to the cylindrical surface 6, the axial reverse movement of the finger 5 is possible only after its right angle between the flat end 28 and the outer cylindrical surface 6 will cut off the part of the sealing ring 8 that protrudes into the bore 3, and this requires significant axial force on the finger 5, which simply has nowhere to come from. Indeed, the diameter of the bore 3 is chosen as small as possible, but providing the possibility of processing the groove 9. With a bore diameter of d-6 mm, this requirement is easily met. The test pressure supplied to the cavity 4, usually does not exceed the value of p = 2 kg / cm ² (absolute pressure). Therefore, the maximum force of the pressure of the medium in the cavity 4 on the finger 5 is achieved only when the device is operating in an external vacuum. And in this worst case, the pressure force F will be about

F = p⋅π⋅d ^2/4 = 0.565 kg.

At the same time, the force required to cut off the protruding inward part of the ring 8 is tens of kilograms. The implementation of a finger of length L greater than or equal to the distance h is necessary so that in the final position of the finger, the outer surface 6 of the finger 5 is always sealed with the ring 7, and the execution of the cylindrical outer surface 6 of the finger 5 of length b greater than or equal to the distance w is necessary so that during the axial movement of the finger 5 and the deformation of the ring 7 at the same time until the cylindrical surface 6 of the finger 5 completely overlaps the groove 9, which is a condition for normal sealing by the ring 7, tighten noe ring 8 to the sealing surface 6 fingers to avoid message inner space 4 to the atmosphere during the process of the finger to the cavity 4. The presence of the chamfer 13 is necessary to ensure non-destruction rings 7 and 8, with the finger movement is required and standards. The specific value of the diameter of the bore 3 and the pressure in the cavity 4, at which the normal operation of the device is ensured, is ensured by the usual design methods, the sizes of the rings 7 and 8, the grooves 9 and the chamfers 13 are standardized. If it is necessary to reuse or reuse the device, remove the latch 20 (retaining ring) from the two-stage groove 15, then remove the sleeve 18, ring 8 and pin 5 (securing, for example, a blind threaded hole made at its end - not shown). Accordingly, the ring 8 does not lose its integrity and can be reused or reused. After that, the ring 8, the sleeve 18 and the retainer 20 are reinstalled and the pin 5 is set to the original one shown in FIG. 1, position. Reuse is performed according to the above algorithm. The placement of the axial position lock outside the cylinder formed by the surface of the bore, allows the installation of the finger 5 in the bore 3.

As a result of using the invention, its manufacturability is increased with repeated use, since however, ring 8 is not cut off (which is inevitable in the prototype) and its replacement with a new one is not required, which leads to lower costs and independence from the supply of components. These advantages allow us to recommend the claimed invention for use in the manufacture and operation of rocket and space technology products.

Claims (1)

A sealed device containing a housing from the end of which there is a bore communicated with the internal cavity of the housing, a finger located in the bore, two installed in the bore with the possibility of contact with the finger along its cylindrical surface, radial o-rings of elastomeric material, the first of which is placed in the groove of the bore placed on the body of the fitting for supplying fluid with a channel extending into the internal cavity of the bore in the area between the first and second radial sealing rings, p In this case, the finger from the end face closest to the internal cavity is chamfered and mounted with the possibility of axial movement relative to the housing and its fixation in two positions: the initial one, in which the nozzle channel communicates with the internal cavity of the body, and the final one, in which the nozzle channel is isolated from it, and also an emphasis to limit axial movement of the finger, characterized in that a two-stage groove is made in the bore from the side of the body end, the width of the first stage is equal to the width of the groove of the bore, the diameter of the first stage made equal to the outer diameter of the groove of the bore, and the diameter of the second step of the two-step groove facing the end of the body is made larger than the diameter of the first step of the two-step groove; inside the second step of the two-step groove, a sleeve with a stop in the ledge between the steps of the two-step groove is placed, while the sleeve is equipped with a latch axial position, placed outside the cylinder formed by the surface of the bore, and the second sealing ring is placed inside the first stage two hundred step grooves, and the inner diameter of the sleeve is made equal to the diameter of the bore.

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