RU2029903C1 - Sealing leading in unit - Google Patents

Abstract

FIELD: mechanical engineering. SUBSTANCE: flexible torus-like shell is filled with a filler and positioned inside the housing of an article to be sealed. A radial seal is provided on the outer surface of the shell. The seal is pressed to the housing with a tension member. A space is provided in the thickening. The space is in communication with the shell space and the atmosphere through a valve. From one side of the thickening the wall of the shell is corrugated. EFFECT: enhanced reliability. 2 cl, 5 dwg

Description

 The invention relates to a sealing technique, in particular for sealing a product wall when various elements in the form of rods are inserted through it, and can be used in various sectors of the national economy.

 A joint seal is known for parts containing abutting parts in which an annular gasket is installed with an internal cavity, and channels for communicating the internal cavity of the gasket with a sealing medium (2) are made in the projections of the gasket from the high pressure side at the place of the connector of the abutted parts. This design cannot be used for elements introduced into the product being sealed, since the design is intended only for compaction of stationary parts relative to each other.

 A device for introducing a group of elements (group gland for cables, drawing. 649-03.225, OST5.6024-75), containing an elastically deformed seal located between the rigid strips, means for tightening the seal on the sealed product, coaxial holes are made in the strips and elastically deformable seal input elements, and the diameter of the holes in the seal is less, and in the strips more than the diameter of the elements. The combination of the function of the tightening means both for sealing the stuffing box on the product and for sealing the input elements in the stuffing box makes the seal stationary, and the ratio of the diameters of the holes in the elastically deformable seal, the slats and the diameters of the elements to be sealed make it possible to seal only the diameters of elements defined in size in a particular hole, which narrows the area of use of the device.

 A seal is known comprising two coaxially arranged and interconnected corrugated elements that form a closed airtight cavity (4). The device is not designed to seal the hole when removing the input element, because one (inner) of the corrugated elements in contact with the input element forms an open hole when removing this element.

 As a prototype, a sealing device (5) is adopted, containing a toroidal elastic shell filled with a filler, which is placed in a clip coaxially placed with a window in the wall of the product being sealed.

 The prototype has the following disadvantages. Sealing is complicated by the presence of a cage (bearing cage), which is designed to hold the toroidal elastic shell in place during operation of the sealing device. The device is deprived of the ability to control the pressure of the filler in a toroidal elastic shell, which narrows the size range of the elements introduced into the product, as well as the scope of use of the device itself. The device is limited to sealing only one element and is not intended to work with a group of elements introduced into the product.

 The aim of the invention is to simplify the sealing of the product wall and expand the functionality of the device.

 This goal is achieved by the fact that in the known device containing an elastic toroidal shell filled with filler, an outwardly protruding bulge is made in the wall of the shell in its diameter, which is pressed by the tightening means of the seal. In the thickening, a cavity communicated with the internal volume of the shell is made, and the device is equipped with a valve connecting the cavity with the external environment. The device is made with a thickening, the cavity in which is communicated with the internal volumes of the group of shells. Corrugations are formed on one side of the thickening in the wall of the shell.

 The sealing of the product wall by means of gaskets pressed by means of sealing is well known, however, the gasket in the form of a thickening of the wall of the toroidal shell by the author was not found in the studied materials. This design of the sealing input device makes it possible to avoid the presence of a cage, and the introduction of the element being sealed (and then removing it from the product being sealed) is provided with an elastic toroidal shell to the required size for the element inlet, as can be seen from the description of the device. This simplifies the device.

 The presence of a cavity in the gasket of the thickening type and its communication with the sealing medium are known (2), however, the resolution of the sealing medium in the elastic toroidal shell with the message of its volume with the cavity in the gasket is not known. The presence of this makes it possible to use the device for sealing elements moving relative to each other, and in combination with a valve connecting the cavity with the external environment, it allows you to adjust the filling of the shell, which makes it possible to introduce elements of various configurations and the device itself can be used more widely.

 The sealing of the group of input elements is known (see dash. 649-03.225), however, the presence of a group of elastic toroidal shells having a common developed thickening, the cavity in which is in communication with the internal volumes of the shells is not known, and it makes it possible to densify the group of movable input elements, and the sizes of the elements may differ from each other when introduced through the same shell alternately. This extends the functionality of the device.

 The presence of corrugations in the wall of the shell is known (4), however, their presence only on one side of the thickening in the wall of the elastic toroidal shell is not known. This design allows you to get a hole seal when removing the input element, which is inherent in an elastic toroidal shell, by compressing the corrugations (which makes the seal of the hole more reliable) while ensuring that the end of the sealed element extends beyond the shell by stretching the corrugations, in addition, the protrusion of the element beyond shells at the end of the introduction process can be carried out without first collecting the walls of the shell in folds.

 In FIG. 1 is a sectional perspective view of a sealing insertion device; in FIG. 2 - remote element I in FIG. 1 (cavity in thickening); in FIG. 3 is a sectional perspective view of a sealing introduction device for a group of sealing elements; in FIG. 4 - the same, with greater rigidity of the wall on one side of the thickening in the section; in FIG. 5 - the same, with corrugations in the wall of the shell on one side of the thickening in the section.

 The sealing lead-in device comprises an elastic toroidal shell 1 (see Fig. 1) filled with a filler, for example air, in the wall of which a thickening 2 is made in its diameter, a means for tightening the seal, consisting, for example, of fasteners 3 and a rigid frame 4. The device is fixed on the product to be sealed 5. A sealing element 6 is introduced into the product to be sealed 5 through a sealing lead-in device, which may be of various cross-sectional configurations.

 A cavity 7 is made in the thickening (see Fig. 2), which communicates with channel 8 with the internal volume of the elastic toroidal shell 1 and, through valve 9, with the external medium.

 Developed thickening 2 (see Fig. 3) contains a cavity 7, communicating with the internal volumes of the group of elastic toroidal shells 1.

 On one side of the thickening 2 (see Fig. 4), the wall 10 of the shell 1 is made of greater rigidity than the other on a length of a quarter to three quarters of the length of the shell, the outer wall of the shell can be assembled with folds 11. An increase in stiffness can be achieved by thickening the wall making it from a more rigid material or reinforcing the wall.

 The most effective is reinforcing with threads along the axis of the shell, since the longitudinal stiffness increases with the same lateral stiffness, which, on the one hand, facilitates the folding of the other wall into folds, and on the other hand, does not increase the resistance to collapse of the wall material when it is compressed in the center hole of the shell.

 The increased rigidity of the wall of the shell on one side of the thickening can also be performed in a device having a thickening cavity connected to the internal volume of the shell, and a valve connected to the outside atmosphere (see Fig. 2). Increased rigidity of the wall of the shell on one side of the thickening can also be performed in any shell with a common developed thickening and cavity communicated with the internal volumes of each shell (see Fig. 3).

 Corrugations 12 are formed on one side of the bulge 2 (see Fig. 5) in the wall of the shell 1. The corrugations can be formed in a device, the bulge of which contains a cavity in communication with the inner volume of the shell on one side and with the outside atmosphere through a valve on the other, as shown in FIG. 2. Corrugations can be formed in any shell of a device containing a group of shells with a common developed thickening and cavity communicating with the internal volumes of each shell, as shown in FIG. 3.

 The corrugations can be formed in the wall of the shell on one side of the thickening, and on the other the wall of the shell can be made more rigid (see Fig. 4) than the rest of the wall not occupied by the corrugations.

 Without collecting the wall of the shell into folds, the entry of element 6 into the product 5 beyond the shell 1 is achieved by the presence of corrugations 12 (see Fig. 5) formed in the outer wall of the shell on one side of the thickening 2.

The size of the protrusion of the input element 6 l is determined by the dependence
l = 0.5 a (k - 1) L design dimension A from the product wall 5 to the required final position of the inserted element 6 is determined by the dependence
A = [1 + a (k-1)] L, the length of the wall B covering the input element 6 at the end of its introduction into the product 5 is determined by the dependence
B = [1 - 0.5 a (k + 1)] L, where:
and - part of the length of the shell 1 occupied by unstretched corrugations 12 in relative units;
k is the ratio of the stretching of the corrugations 12 in relative units;
L is the length of the shell 1 with unstretched corrugations 12 in units of length.

 The initial length is the required length l. The smallest lengths A and L can be obtained with the largest value of the coefficient k, which will determine the characteristic of the corrugations, since the multiplicity of stretching determines the height and number of corrugations, as well as the resistance of the material to stretching.

 The height of the corrugations may be structurally limited by the external diameter of the device.

 It is advisable to have the stiffness of the corrugations greater in the longitudinal direction (along the axis of the device) than in the transverse, for example, due to reinforcement with longitudinal threads.

 It is advisable to have the most elastic wall to the length of the sheath in order to achieve the best compaction with the smallest B.

 The device operates as follows.

 In the pre-sealed product 5, the compression of the thickening 2 by means of the fasteners 3 and the rigid frame 4 introduces the sealed element 6 through the central hole in the elastic toroidal shell 1. To allow the end of the sealed element 6 to exit from the shell 1 at the beginning of the operation, the shell is collected by folds 11 (see Fig. .4), for this, the material of the wall of the shell can be made of an elastic material, for example, rubber, or inelastic, for example, a wall of airtight polyvinyl chloride, and the shell itself is incomplete, i.e. should be lethargic. In this case, the protrusion of the sealing element will be equal to the value of the preliminary reduction in the length of the shell as a result of collecting it in folds.

 The resistance of the stiffer part of the wall keeps the casing from moving when a fold forming force is applied. As you enter the sealed element 6, the inner wall of the shell 1 moves together with the element 6 without relative displacement (without friction), experiencing resistance to crushing of the material of the shell 1 while dragging it by the element 6 behind itself. Thus, the element 6 will be sealed, having reached the necessary input boundary with a sealed product. When removing the sealing element 6, the product 5 remains sealed either by excessive pressure inside the shell 1, or when the flaccid shell is not accessible through the central hole in the toroidal shell 1 (due to its lethargy or using a special clamp, which is not shown).

 In pursuit of the goal of facilitating the insertion of various elements 6 with different configurations and cross-sectional values, the pressure inside the shell 1 can be controlled by a valve 9 (see FIG. 2) connecting the cavity 7, which communicates with the inner volume of the shell 1 by channel 8, with the external environment. The same dimensions of the input can provide a seal of different input elements.

 At the same time or at different times, the group of elements 6 is introduced through the shell 1 into the sealing product 5 (see Fig. 3) as described above.

 In the presence of corrugations (see Fig. 5), following the portion of the wall of the shell 1 free from corrugations 12, along with the element 6, the wall with corrugations also moves, which, stretching, provide the movement of the inserted element 6 inside the sealed product 5, while the wall of the shell 1 breaks away from the element 6 and passes from the region of the central hole to the end, and then to the outer part of the shell. This ensures the protrusion of the element 6 outside the shell 1.

 Compared with the prototype, the inventive sealing introduction device is simpler, because product sealing is carried out stationary with the help of the formed thickening pressed by the sealing means, which does not require a specially prepared holder bed, as provided by the prototype.

 Compared with the prototype of the inventive device can be used more widely for input sealing elements in the form of rods of various sizes and configurations of the cross section, because it has the ability to adjust the pressure inside the shell due to its different filling using a valve connecting the external environment with a cavity in the thickening, which is in communication with the internal volume of the shell.

 Compared with the prototype, the device allows you to simultaneously seal the group of input elements, because the thickening contains a cavity communicated with the internal volumes of the group of shells, while the prototype solution requires a separate bed for each shell.

 These differences, in addition to the above, allow you to expand the scope of use of the device itself.

Claims (2)

 1. SEALING INPUT DEVICE, comprising a housing of the product being sealed, an elastic toroidal shell filled with filler and placed in the body, characterized in that a radial thickening is made on the outer surface of the shell, tightened by means of a tightening means to the body of the sealed product, and a cavity communicating with the cavity of the shell and through the valve - with the external environment.  2. The device according to claim 1, characterized in that on one side of the thickening, the wall of the toroidal shell is made with corrugations.

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