RU2110779C1 - Hermetically sealed device - Google Patents

Abstract

FIELD: mechanical and aviation engineering. SUBSTANCE: cover 3 with pipe connection 6 of flowing medium supply is positioned in bore 2 of body 1. Cover 3 is mounted for axial movement relative to body and for fixing in positions. In one position, outlet hole 7 of pipe connection channel communicates with internal cavity of body. In other position, outlet hole is insulated from body cavity. Body is also provided with through hole 9 outgoing on one side to bore cylindrical surface being sealed and on the other, to internal surface of body. Radial seals 4 and 5 are positioned as follows: one seal is placed between through hole outlet to bore cylindrical surface and external surface of body; the other seal is located between through hole outlet and outlet hole of pipe connection channel. Sealing member 12 is arranged between outlet hole of pipe connection channel and internal surface of body. EFFECT: improved test results. 2 cl, 4 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.

 Known sealed device containing a housing with an internal cavity and a filling valve located on the housing [1].

 The disadvantage of this device is the placement of the filling unit on the housing, which increases the mass of the device.

 This disadvantage is deprived of a sealed device containing a housing with a bore, a lid installed in it, radial seals that seal the radial clearance between the bore and the lid on a cylindrical surface and a fitting for a fluid motive with a channel [2], selected as a prototype. 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 this sealed device is the significant axial dimensions of the device case due to the location of the nozzle on the case, as well as the design complexity due to the presence of a small diameter channel in the nozzle. In the case where the cover is in the form of a cylinder with a bottom, an increase in the dimensions of the housing can be compensated by a decrease in the length of the cover. In the case of a flat cover, an increase in the dimensions of the case inevitably leads to an increase in the dimensions of the device, which is unacceptable for products of aviation and space technology. This prevents the use of the prototype in spherical products, such as balloons. An additional disadvantage of the device is the possibility of rupture of the sealing ring when it passes through the edges of the channel outlet onto the sealing surface.

 The technical result of the invention is to reduce the axial dimensions of the housing of the sealed device and simplify the design. This result is achieved due to the fact that in a known sealed device containing a housing with a bore, a cover installed therein, radial seals sealing the radial clearance between the bore and the cover on a cylindrical surface, a fluid supply fitting, the cover being mounted with axial movement relative to the housing and fixing it in positions, at one of which the outlet of the nozzle channel communicates with the internal cavity of the housing, and at the other is isolated from the latter, agree about the invention, the fitting is made in the lid, and in the housing there is a through hole extending from one side to the sealed cylindrical surface of the bore, and from the other to the inner surface of the housing, with one radial seal located between the exit of the through hole to the cylindrical surface and the outer surface of the housing and the second between the exit of the through hole and the outlet of the nozzle channel, while the device is equipped with a sealing element located between the outlet of the channel w Utsera and the inner surface of the housing. The execution of a blind bore and the execution of the outlet channel of the nozzle channel on the inner end of the lid allow, in addition to the specified technical result, to achieve the elimination of ruptures of the sealing rings.

 Since the proposed combination of essential features of the device and method allows to obtain the specified technical result, the proposed device meets the criterion of "inventive step".

 In FIG. 1 shows an example of a specific implementation of a sealed device, a longitudinal section; figure 2 and 3 - the same, with the initial and final positions of the cover in the process of supplying fluid into the cavity of the device and its sealing; in FIG. 4 is an example of a specific embodiment of a sealed device according to claim 2, a longitudinal section.

 The sealed device comprises a housing with a bore 2, a cover 3 installed therein, radial seals 4 and 5, sealing the radial clearance between the bore and the cover on a cylindrical surface, a fluid supply nozzle 6 with a nozzle channel 7. The cover 3 is mounted with the possibility of axial movement relative to the housing 1 having an internal cavity 8, and fixing it in positions, at one of which the outlet of the fitting channel 7 communicates with the internal cavity 8, and at the other is isolated from it. The fitting 6 is made in the lid 3, and in the housing 1 there is a through hole 9 extending from one side to the sealed cylindrical surface of the bore, and from the other to the inner surface 10 of the housing. In the position in which the outlet channel 7 of the fitting communicates with the internal cavity 8, the radial seal 4 is located between the outlet of the through hole 9 on the sealed cylindrical surface and the outer surface 11 of the housing 1, and the seal 5 is between the outlet of the through hole 9 and the outlet of the channel 7 The device is equipped with a sealing element in the form of a disk 12 with a rubber seal 13 held by a spring ring 14. A sealing element 12 is placed between the outlet of the channel 7 and the inner surface with a 10 of the housing 1. The cover 3 is attached to the housing 1 by screws 15. The cover 3 is mounted with the possibility of axial movement relative to the housing 1 and fixing it in two positions. In the initial position, the outlet channel 7 of the nozzle communicates with the internal cavity 8 of the housing 1 through the through hole 9. In the process of supplying fluid to the cavity 8 and sealing the latter, the nozzle 6 is connected to the fitting 16 of the supply line 17, while a gasket is installed between the joints of the fittings 18. A pressure gauge 19 and a valve 20 are connected to the supply line 17. In the final position, the outlet of the channel 7 of the fitting is isolated from the internal cavity 8 of the housing 1.

 The device operates as follows.

 In the initial position of the cover 3 (in which the outlet of the nozzle channel 7 is located between two radial seals 4 and 5), the nozzle 6 communicates with the internal cavity 8 through the outlet of the nozzle channel 7 and the through hole 9. In this position, the cap 3 is fixed with screws 15 , which makes it possible to open the valve 20 and to fill the internal cavity 8 with gas, while the pressure can be controlled by a pressure gauge 19. Upon reaching the set pressure, the valve 20 is closed and then axial movement and fixation are performed of the cover 3 in a position in which the outlet of the channel 7 is located between the radial seal 5 and the sealing element - the disk 12. In this case, the nozzle 6 and the outlet of the channel 7 of the nozzle are isolated from the inner cavity 8 of the housing 1, and the outlet of the through hole 9 is isolated from the outer surface 11 of the housing 1 with seals 4 and 5. This movement can be performed by sequentially tightening the screws 15 until the joint between the housing 1 and the cover 3 is completely closed. After this, the fitting 16 of the supply line 17 can be disconnected from the fitting 6.

 As a result of using the invention, the axial dimensions of the housing of the sealed device are reduced and the design is simplified, since the outlet of the nozzle channel 7, made with a small diameter, is located on the outer cylindrical surface of the cover 3 and is easily accessible for processing. This is very important, as the cutting tool for making small holes usually has a short length and strength. In addition, this embodiment makes it easy to smooth out the sharp edges of the channel outlet, which reduces the possibility of rupture of the sealing rings 4 and 5. In order to completely eliminate such cases, it is possible to implement the device according to claim 2.

 The device in this case is similar to the device described above, but differs in that the bore 2 is blind, and the outlet of the nozzle channel 7 is made at the inner end of the lid. As a sealing element located between the outlet of the channel 7 and the inner surface of the housing 1, the wall 21 of the deaf bore 2 acts.

 This embodiment completely eliminates the contact of the outlet of the channel 7 of the nozzle and the seals 4 and 5, and therefore eliminates the possibility of damage to the seals and allows to increase the diameter of the channel 7.

 In addition, the manufacturability of the lid is significantly increased, since the outlet of the channel 7 can be made with a large diameter and any diameter tolerance and roughness, since there is no contact between the edges of the channel 7 and seals 4 and 5.

 The reduction in size of the device, achieved by using the claimed design, is very important for units of aviation and space technology.

Literature
1. The author's certificate of the USSR N 832379, cl. G 01 M 3/02, 1981.

 2. USSR patent N 1797675, cl. F 04 D 13/06, 1993, prototype.

Claims (2)

 1. A sealed device comprising a housing with a bore, a lid installed therein, radial seals sealing the radial clearance between the bore and the lid on a cylindrical surface, a fluid inlet fitting, the lid being mounted with the possibility of axial movement relative to the housing and fixing it in positions, with one of which the outlet channel of the nozzle channel communicates with the internal cavity of the housing, and with the other, isolated from the latter, characterized in that the fitting is made in the lid, and in the housing you a through hole is filled, extending from one side to the sealed cylindrical surface of the bore, and from the other to the inner surface of the housing, with one radial seal located between the exit of the through hole to the cylindrical surface of the bore and the outer surface of the housing, and the second between the exit of the through hole and the outlet channel of the fitting, while the device is equipped with a sealing element located between the outlet of the channel of the fitting and the inner surface of the housing.  2. The device according to claim 1, characterized in that the bore is made deaf, and the outlet of the fitting channel is made on the inner end of the lid.

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