RU2698959C1 - Sealed device - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to machine building and can be used in testing cavities of aircraft and rocket equipment, as well as in other fields of engineering. Summary: device comprises housing (1) with inner cavity (2) and bore (3), in which groove (12) is made. Cover (4) is provided in bore (3) provided with fitting for fluid medium (5) with radial outlet (6) extending to cylindrical surface (7) of cover (4). In first (10) and second (11) grooves on cylindrical surface (7) of cover (4) first (8) and second (9) radial sealing rings are arranged, which seal radial clearances between bore (3) and cover (4). Radial outlet (6) of fitting (5) is located between first (10) and second (11) grooves. Cover (4) is axially movable relative to housing (1) and fixed in two positions. At one position of cover (4), radial outlet (6) of fitting (5) channel is interconnected with inner cavity (2) of housing (1), and in the other position – isolated from inner cavity (2). Cylindrical surface (7) of cover (4) and bore (3) have identical diameters. First (8) and second (9) radial sealing rings also have identical diameters. First (10) and second (11) grooves also have identical diameters. At the point of intersection of turnery (12) with bore (3) in housing (1) on both sides of turnery (12) there are conic bevels (13, 14) introduced for sealing rings (8, 9). Note here that distance between intersection of surfaces of conic bevels (13, 14) with bore (3) is less than or equal to distance between closest ends of first and second grooves (10, 11).

EFFECT: technical result is simple design of the device and reduced range of components of its products.

1 cl, 2 dwg

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.

A sealed device is known comprising a housing with an internal cavity and a bore, a lid installed in the bore, equipped with a fluid supply fitting with a radial outlet opening overlooking the cylindrical surface of the lid, first and second radial o-rings, sealing radial gaps between the bore and the lid, and installed in the grooves of the bore of the housing, while the lid is mounted with the possibility of axial movement relative to the housing and fixing it in positions, one of which is glad cial outlet nozzle channel communicates with the interior of the housing, while the other is isolated from the latter (Patent of the Russian Federation №2110779 tml. G01M 3/08, 1998 YG). The cover is mounted with the possibility of axial movement relative to the housing, and the fitting is made on the housing.

The disadvantage of such a sealed device is the low adaptability caused by the presence of two sealing grooves on the housing and an inclined hole between them. The case is usually a complex and expensive part, so the presence of these elements in it increases the possibility of marriage in the manufacture and breakage of the tool due to the removal of the drill when it touches a surface that is not perpendicular to its axis.

This disadvantage is deprived of a sealed device containing a housing with an internal cavity and a bore extending into it, a lid installed in the bore, equipped with a fluid inlet fitting with a radial outlet opening over the cylindrical surface of the lid, the first and second radial o-rings sealing the radial gaps between the bore and a lid located in the first and second grooves of the lid, while the radial outlet of the fitting is located between the first and second grooves, and the lid installed with the possibility of axial movement relative to the housing and fixing it in positions, at one of which the radial outlet of the fitting channel communicates with the internal cavity of the housing, and at the other isolated from the latter (patent of the Russian Federation No. 2655675 according to class G01M 3/00, 2018 .) selected as a prototype.

The disadvantage of this device is the complexity of the design, due to the presence in the design of the bore and the cover of two exact diameters of the sealing surfaces, which increases the number of necessary processing and measuring tools, as well as the excessive range of components - sealing rings.

The technical result achieved by the claimed device is to simplify the design and reduce the range of components.

The technical result is achieved due to the fact that in the known sealed device comprising a housing with an internal cavity and a bore extending into it, a lid installed in the bore, provided with a fluid inlet fitting with a radial outlet opening facing the cylindrical surface of the lid, the first and second radial sealing rings that seal the radial gaps between the bore and the lid, located in the first and second grooves on the cylindrical surface of the lid, while the radial outlet the nozzle is placed between the first and second grooves, and the cover is mounted with the possibility of axial movement relative to the housing and fixing it in positions, at one of which the radial outlet of the nozzle channel communicates with the internal cavity of the housing, and with the other, isolated from the latter, according to the invention, cylindrical the surface of the cap and the bore are made with the same diameters, the first and second radial o-rings, as well as the first and second grooves are made with the same dimensions, a groove is made in the bore with a diameter

D> d ₁ + 2d ₂ ,

where d ₁ is the inner diameter of the grooves,

d ₂ - the diameter of the cross section of the radial sealing rings,

at the intersection of the groove with the bore in the body, conical chamfers for the sealing end are made on both sides of the groove, while the distance between the intersection of the conical surfaces of the chamfers with the bore is less than or equal to the distance between the ends of the first and second grooves closest to each other.

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 with an internal cavity 2 and a bore 3 emerging into it. A cover 4 is installed in the bore 3, equipped with a fluid supply fitting 5 with a radial outlet 6 extending onto the cylindrical surface 7 of the cover 4. The first 8 are installed in the grooves of the cover 4 and the second 9 radial o-rings, sealing radial gaps between the bore 3 and the cover 4. The cover 4 is mounted with the possibility of axial movement relative to the housing 1 and fixing it in positions, one of which is the radial nd an outlet spout 6 5 communicates with the inner cavity 2 of the housing 1 (FIG. 1), and in isolation from the other of the latter (FIG. 2). The first 8 and second 9 radial sealing rings are located in the first 10 and second 11 grooves made on the cylindrical surface 7 of the cover 4, and the radial outlet 6 of the nozzle 5 is placed between the first 10 and second 11 grooves. The cylindrical surface 7 of the cover 4 and the bore 3 are made with the same diameters. The first 8 and second 9 radial sealing rings, as well as the first 10 and second 11 grooves are made with the same dimensions, respectively. The inner diameter of the grooves 10 and 11 is made equal to d _{b the} diameter of the cross section of the radial sealing rings 8 and 9 is made equal to d ₂ . In the bore 3, a groove 12 is made with a diameter of D> d ₁ + 2d ₂ . At the intersection of the groove 12 with the bore 3 in the housing 1, conical chamfers 13 and 14, inlet for the sealing end, are made on both sides of the groove 12, which serve to prevent cutting of the sealing rings 8 and 9 when the cover 4 is installed in the initial and final position. The distance A between the intersection of the conical surfaces of the chamfers 13 and 14 with the bore 3 is less than or equal to the distance B between the ends of the first 10 and second 11 grooves closest to each other. The cover 4 is attached to the housing 1 with screws 15.

The sealed device operates as follows: to the initial position shown in FIG. 1, the cover 4 is placed by tightening the screws 15 by an amount that will seal the gap between the cylindrical surface 7 of the cover 4 and the bore 3 by means of the first radial sealing ring 8, but the second radial sealing ring 9 is not in contact with the surface of the groove 12, providing an output message the radial hole 6 of the fitting 5 with the inner cavity 2 of the housing 1 through the radial clearance between the outer surface of the second sealing ring 9 and the surface of the groove 12. This message is guaranteed is determined by the choice of dimensions in accordance with the inequality D> d ₁ + 2d ₂ , since the maximum size of the second radial sealing ring 9 installed in the groove 11, as can be seen from the figures in FIG. 1 of sizes, it will just be equal to the value of d ₁ + 2d ₂ , which ensures the passage of the test medium into the gap between the second ring 9 and the groove 12. The specific excess value can be any and is calculated by conventional design methods. In this position, through the nozzle 5, a fluid (for example, a helium-air mixture) is supplied into the cavity 2 from the test equipment, which is docked to the nozzle 5 (not shown in the illustrations). Then, without disconnecting the test equipment from the nozzle 5 and keeping the test pressure in it by technological means, fully tighten the screws 15. Thus, the cover 4 will move to the position shown in FIG. 2, when the second ring 9 seals the gap between the cylindrical surface 7 of the cover 4 and the bore 3, isolating the inner cavity 2 from the radial outlet 6 of the nozzle 5. Since the first ring 8 seals the gap between the cylindrical all the time while moving the cover 4 from the original to the final position surface 7 of the cover 4 and the bore 3, there is no leakage of the test medium from the cavity 2. In this position, it is possible to disconnect the supply line from the nozzle 5, the tightness test of the cavity 2 filled with the tester environment, and further operation of the device for its intended purpose. The sign “the distance between the intersection of the conical surfaces of the chamfers with the bore is less than or equal to the distance between the ends of the first and second grooves closest to each other” is necessary in order to ensure a seal between the groove 12 and the surrounding medium in the entire range of movement of the cover 4, which will not allow the test flow through the nozzle 5, the hole 6 and the groove 12 into the environment. For a given ratio of sizes A and B in the final position of the device, the groove 12 is isolated both from the cavity 2 and from the environment surrounding the device, which makes it possible to undock the test equipment from the nozzle 5, having previously shut off the pressure supply to it. The presence of lead-in chamfers 13 and 14 allows you to ensure the integrity of the second ring when moving the cover 4 from the original to the final position, since first the ring 5 leaves the bore 3 through the chamfer 13 into the groove 12, providing a hole 6 with the cavity 2, and then enters through the chamfer 14 deforming into a bore 3 between the groove 12 and the cavity 2. The angular and linear dimensions of the inlet chamfers are well known and are given in the standards for radial seals.

As a result of the use of the invention, simplification of the design of the sealed device is achieved, since only one exact surface (the inner diameter of the bore and the outer diameter of the cylindrical surface of the lid) is made in the case and on the lid instead of the two in the prototype (the surface of the steps of the bore and the lid), which reduces the required range processing and measuring tools. In addition, the collectability of the device is improved, since it is guaranteed to be ensured when performing the boring and the cylindrical surface of the lid within the specified tolerances. In the prototype, it was necessary to withstand very tight tolerances on the alignment of the steps of the bore and the lid - otherwise the assembly would be impossible. It also reduces the range of components - instead of two sizes of o-rings in the prototype, two rings of the same size are used, which reduces the dependence on suppliers of components. These advantages allow us to recommend the claimed invention for widespread use in the manufacture and operation of rocket and space technology products.

Claims (5)

A sealed device comprising a housing with an internal cavity and a bore extending into it, a lid mounted in the bore, provided with a fluid inlet fitting with a radial outlet opening over the cylindrical surface of the lid, first and second radial o-rings, sealing radial gaps between the bore and the lid, placed in the first and second grooves on the cylindrical surface of the cover, while the radial outlet of the fitting is placed between the first and second grooves, and the bore is mounted with the possibility of axial movement relative to the housing and fixing it in positions, at one of which the radial outlet of the nozzle channel communicates with the internal cavity of the housing, and at the other, isolated from the latter, characterized in that the cylindrical surface of the lid and the bore are made with the same diameters , the first and second radial sealing rings, as well as the first and second grooves are made with the same dimensions, respectively, in the bore there is a groove with a diameter D> d ₁ + 2d ₂ , where d ₁ is the inner diameter of the grooves, d ₂ - the diameter of the cross section of the radial sealing rings, at the intersection of the groove with the bore in the body, conical chamfers for the sealing rings are made on both sides of the groove, while the distance between the intersection of the conical surfaces of the chamfers with the bore is less than or equal to the distance between the ends of the first and second grooves closest to each other.

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