RU177195U1 - CABLE INPUT COMPRESSION UNIT - Google Patents

Abstract

The utility model relates to the field of construction and electrical engineering and can be used to seal cables, pipes, cables and the like products passing through any dividing walls. A compression cable entry unit is proposed, comprising a wedge mechanism with front and rear spacer wedges, movable to and from each other by a screw drive, working wedges located on both sides of the spacer wedges and devices for connecting adjacent working wedges to each other and expansion wedges, providing the ability to move the working wedge relative to an adjacent expansion wedge. The utility model is characterized in that each device for connecting the working wedge and the adjacent spacer wedge includes a cantilever flexible strip, one edge of which is connected to the edge of the working wedge facing the adjacent adjacent spacer wedge, and the second free edge of this cantilever flexible strip is fixed on this adjacent spacer wedge using a detachable locking device. A useful model eliminates wedge distortions when installing the compression unit in the cable entry opening, and wedging of the wedge mechanism, which is typical for the currently used compression blocks. 18 s.p. f-ly, 19 ill.

Description

FIELD OF TECHNOLOGY

The utility model relates to the field of construction and electrical engineering and can be used, as a rule, to completely seal cables, pipes, cables and the like products passing through walls, bulkheads of compartments and cable or other channels, walls of wiring closets.

It should be noted that the term "cable entry" hereinafter should be understood as equivalents, any inserted, fixed, sealed and sealed element: in fact, cable, wire, pipe, rod, cable, rod and other similar structural elements. This is necessary in order to avoid the multiplicity of artificial formulations such as “cable-wire-tube-rod-cable-linear, etc. input ”and any combination thereof, since the initial and predominantly functional purpose of such an input is a cable input, adjusted for possible additions by wire, pipe and / or other elements.

BACKGROUND

A variety of cable entry designs are known using a compression unit to preload the sealing modules. The main problem to be solved during the design and operation of compression units is the provision of the arrangement of the compression unit as a single unit, ready for use.

A known cable entry compression unit comprising a wedge mechanism with two spacer wedges arranged to move to and from each other using a screw mechanism, and one pressure wedge with two symmetrically arranged working surfaces and one pressing surface, while two working the surfaces of the compressible wedges are located in one plane, and two other working surfaces interact (respectively) with the working surfaces of the pressure wedge. In this compression unit, the formation of a single module is ensured by the fact that the pressure wedge of the wedge mechanism on the side of the working surfaces is provided with a longitudinal groove for accommodating the screw in the diluted state of the compressible wedges, while the walls of the groove are made with the possibility of elastic interaction with the screw shaft (see RF patent for invention No. 2551891; IPC H02G 3/22, F16L 5/02; 06/10/2015).

A compression cable entry compression unit is known, comprising a wedge mechanism with two movable spacer wedges located opposite each other and configured to move to and from each other using a screw drive connecting these movable spacer wedges and two pressing wedges located from two the sides of the expansion wedges and interacting with their inclined surfaces with the inclined surfaces of the expansion wedges, and structural elements for connecting to each other wringing wedges. In this compression unit, the formation of a single module is ensured by the fact that the pressure wedges of the wedge mechanism are connected to each other by two elastic elements, ensuring their constant compression in the expansion wedges (see Swedish published application SE 1550561 A1, IPC F16L 5/02 H02G 3/22; 2016-12-06). The use of elastic elements significantly complicates the assembly of the compression unit.

The closest analogue of the claimed compression unit is the compression unit described in the patent of the Russian Federation No. 2137009; IPC F16L 5/02; 09/10/1999. The compression unit contains a wedge mechanism, which includes two movable spacer wedges located opposite to each other and made with the possibility of moving to each other and from each other using a screw drive connecting these movable spacer wedges, pressing wedges located on both sides of the spacer wedges and interacting with their inclined surfaces with the inclined surfaces of the spacer wedges, and structural elements for connecting adjacent pressing wedges to each other and arranged GOVERNMENTAL wedges providing a wedge biasing displaceable relative to an adjacent spacer wedge. In this compression unit, the formation of a single module is ensured by the fact that the expansion and pressing wedges are held together by means of a flexible strip connecting all the wedges with the formation of an integral structure with a closed loop. This design provides a reliable single module in the assembled state, but excludes the possibility of disassembling the assembled module to replace damaged elements and complicates the operation of the cable entry, since when installing the compression unit, it is necessary to glue the free end of the flexible strip to the end spacer wedge.

ESSENCE OF A USEFUL MODEL

The technical problem solved by the claimed utility model is to create a new compression cable entry compression unit with improved operational characteristics, which will ensure extreme simplicity of design, minimum overall dimensions in the initial state, increased working stroke of the pressure wedge, operational reliability and the possibility of multiple mounting-dismounting with the maximum possible screw connection speed.

To solve this problem and achieve the claimed technical result, a compression cable entry unit is proposed that contains a wedge mechanism with two movable front and rear spacer wedges located opposite each other and made with the possibility of moving to each other and from each other using a screw drive connecting these movable expansion wedges, working wedges located opposite to each other on both sides of the expansion wedges and interacting with their inclined surfaces devices with inclined surfaces of the expansion wedges, and devices for connecting adjacent working wedges and expansion wedges to each other, allowing the working wedge to be moved relative to an adjacent expansion wedge, in which each device for connecting the working wedge and an adjacent expansion wedge includes a cantilever flexible strip, one edge of which is connected to the edge of the working wedge facing the adjacent adjacent spacer wedge adjacent to it, and the second free edge of this cantilever flexible strip closes captivity on this adjacent spacer wedge using a detachable locking device.

Moreover, in the proposed compression unit, each working wedge is equipped with two cantilever flexible strips attached to the edges of this working wedge from opposite sides of this working wedge with the formation of a monolithic element.

Moreover, in the proposed compression unit, the rear expansion wedge has a smaller thickness than the front expansion wedge.

In addition, in the proposed compression unit, the detachable locking device includes a recess made in the surface of the spacer wedge housing to accommodate a cantilever flexible strip therein, through holes in the side walls of the recess, a fixing rod passed through these openings and interacting with the flexible cantilever strip.

In addition, in the proposed compression unit, the recess has a depth greater than the thickness of the cantilever flexible strip, while the free edge of the flexible cantilever strip is equipped with a retaining collar interacting with the fixing rod.

Moreover, in the proposed compression unit, the detachable locking device can be made in the form of a hinge loop, while some loop elements are located on the spacer wedge, the loop response elements are located on the free edge of the cantilever flexible strip, and the fixing rod is the axis of the loop.

In addition, in the proposed compression unit, each expansion wedge can be equipped with two locking devices located on opposite sides of the housing of this expansion wedge, while the fixing rods of these fixing devices are connected to each other by a jumper, forming a fixing bracket.

Moreover, in the proposed compression unit, the lintels of the fixing brackets can be recessed in the recesses made in the lateral surfaces of the spacer wedges.

In addition, in the proposed compression unit, the lintels of the fixing brackets on the front expansion wedge may protrude beyond the side surfaces of the front expansion wedge.

In addition, in the proposed compression unit in a flexible cantilever strip can be made at least one slot dividing it into separate languages.

In addition, in the proposed compression unit, the groove can be additionally equipped with a partition located in the slot, while the holes are made in the partition, into which the fixing rod enters.

Preferably, in the compression unit according to the invention, the screw drive includes a working screw with two threaded sections with opposite threads, a first threaded sleeve fixed in the rear expansion wedge and interacting with one threaded section, and a second threaded sleeve fixed in the through hole of the front expansion wedge and interacting with the second threaded section, the working screw extends beyond the compression block from the front working wedge, while the protruding shank of the working Inta equipped operating element for actuating the screw in rotation.

In addition, in the proposed compression unit, the working wedges can be made with contact pads placed opposite each other, limiting the lateral movement of the working wedges in the direction of the thickness of the composite block, while in the contact areas of the working wedges longitudinal grooves are made parallel to the working screw on both sides relative to the rotor for placement of the rotor in them when closing the pads.

In addition, the proposed compression unit may be equipped with one screw drive located along the central longitudinal axis of the compression unit, or the proposed compression unit may be equipped with two screw drives placed in the longitudinal plane of the compression unit symmetrically with respect to its central longitudinal axis.

In addition, in the proposed compression unit, the rear expansion wedge can be divided into separate parts, each of these separate parts being connected to its own screw drive and interacting with its tongue in a flexible cantilever strip.

In the proposed compression unit, the spacer and working wedges can be made of elastic elastic material, while rubber or elastic polymeric materials can be used.

The technical result achieved using the utility model is that the main elements of the compression unit: the front expansion wedge, the rear expansion wedge and the working wedges can be made independently of each other and the compression unit can be completed directly at the installation site of the compression unit in accordance with with specific circumstances, while equipping the edge of the working wedge with a cantilever flexible strip that is part of the device for connecting to each other Mezhno expansible and the working wedges, simplifies the assembly of the compression unit on-site installation of the compression unit as a single unit for installation of the compression unit in the cable entry opening, since it is possible to fix the free edge of the cantilevered flexible strip on an adjacent wedges via a releasable detent connection. In the assembled state, the dimensions of the compression unit are adjusted to the installation conditions using a screw drive that moves the spacer wedges and, accordingly, the working wedges are moved.

Equipping each working wedge with two cantilever flexible strips attached to the edges of this working wedge on opposite sides of this working wedge with the formation of a monolithic element simplifies the assembly of wedges into a single module.

The implementation of the rear spacer wedge of smaller thickness than the front spacer wedge facilitates the installation of the compression unit in the mounting opening of the cable entry.

The proposed design of a detachable locking device makes it possible to place all the elements of the device in the recess on the expansion wedge within the dimensions of the compression unit and reliably fix the free edge of the cantilever flexible strip in the recess on the expansion wedge when assembling a single module of the compression unit.

Combining the two fixing rods into a bracket simplifies the assembly and maintenance of the compression unit when it is mounted in a cable entry.

The division of the console flexible strip into separate languages makes it easy to install the compression unit with a large opening width of the cable entry. At the same time, the presence of a partition in the recess simplifies the assembly of the compression unit.

The proposed design of the screw drive facilitates the assembly of the compression unit into a single module and simplifies the regulation of the size of the compression unit when mounting it in the cable entry opening.

The presence of contact pads on the working wedges simplifies control over the installation of the compression unit in the cable entry opening, while the execution of the longitudinal grooves under the drive screw in the contact areas of the working wedges makes it possible to perform a compression unit with a large range of adjustment of the thickness of the compression unit, which simplifies its installation in the opening cable entry and increases the area for cable entry directly in the cable entry aperture.

The proposed design of the compression unit makes it possible to change the number of screw drives depending on the size of the cable entry opening. At the same time, the separation of the rear spacer wedge into separate parts with an independent screw drive for moving each part simplifies the installation of the compression unit in the cable entry opening and eliminates wedges distortions during installation of the compression unit in the cable entry opening, and jamming of the mechanism, which is typical for compression units other manufacturers who use a special unique tool to eliminate this effect. For example, such a tool is used in compression blocks of the Rockstack company.

The implementation of the expansion and working wedges from an elastic elastic material, for example, from rubber or from elastic polymeric materials provides the necessary flexibility of the working and expansion wedges during assembly and installation, and also provides retention of the fixing rods in the holes of the walls and partitions and in the loop.

BRIEF DESCRIPTION OF THE DRAWINGS

The utility model is illustrated by drawings. The drawings are presented in a volume sufficient for specialists to understand the utility model, and in no way limit the scope of the utility model. In the drawings, like elements are denoted by like reference numerals.

In FIG. 1 shows a three-dimensional image of a General view of the compression unit of the cable entry in assembled form in accordance with the first embodiment of the utility model;

in FIG. 2 shows in an undocked state the relative positioning of the main elements of the cable block in accordance with the first embodiment of the utility model;

in FIG. 3 shows an exploded perspective view of a compression unit in accordance with a second embodiment of the utility model;

in FIG. 4 shows in an undocked state the relative positioning of the main elements of the cable unit in accordance with a second embodiment of the invention;

Fig. 5 is a front view of a compression unit in accordance with a second embodiment of the utility model;

in FIG. 6 is a plan view of a compression unit in accordance with a second embodiment of the utility model;

HB FIG. 7 shows a view along arrow A in FIG. 4 on the lower working wedge;

in FIG. 8 shows a section BB in FIG. 5;

in FIG. 9 shows a cross-section BB in FIG. 6;

in FIG. 10 shows a cross section GG in FIG. 6;

in FIG. 11 is an enlarged view of zone D in FIG. 6;

in FIG. 12 is an enlarged view of zone E in FIG. 6;

in FIG. 13 shows a cross-section II in FIG. 7;

in FIG. 14A-14E show possible embodiments of zone K in FIG. 13;

in FIG. 15 and 16 are three-dimensional images of a compression unit in accordance with a third embodiment of the utility model;

in FIG. 17 and 18 are three-dimensional images of a compression unit in accordance with a fourth embodiment of the utility model.

DESCRIPTION OF EXAMPLES OF IMPLEMENTATION OF A USEFUL MODEL

As shown in FIG. 1 in the General case, the compression unit 1 of the cable entry contains a wedge mechanism, which includes: two movable spacer wedges 2 and 3, located opposite each other and configured to move to each other and from each other using a screw drive 4 connecting these movable expansion wedges; two working wedges 5 and 6, located on two sides relative to the expansion wedges 2 and 3; and devices 7, connecting in pairs with each other adjacent working and spacer wedges.

The following concepts are used in the description of the compression unit. The front spacer wedge is a spacer wedge 2 facing the front surface of the compression unit 1, from which the screw drives 4 protrude. In fact, the front surface of the front spacer wedge 2 is the front surface of the compression block 1. The rear spacer wedge is a spacer 3 located opposite the spacer wedge 2 In fact, the outer surface of the rear spacer wedge 3, located on the opposite side of the compression unit relative to the front surface of the front spacer wedge 2, is the rear surface of the compression unit 1 Axis X in FIG. 1 indicates the longitudinal direction for the compression unit 1 — the direction from the front surface of the front expansion wedge 2 to the outer surface of the rear expansion wedge 3, perpendicular to these surfaces. The y axis in FIG. 1 indicates the transverse direction for the compression unit 1 — the direction along the width of the compression unit 1. The Z axis in FIG. 1 indicates the thickness direction of the compression unit 1, perpendicular to the X-Y plane. It should be understood that the terms “upper”, “lower”, “right” and “left” used in the description below correspond to the image of the compression block in the figures attached to the application, characterize the compression block as an article and should not be interpreted as characterizing the orientation of the block elements on practice.

As shown in FIG. 1 and 2, the compression unit contains four devices 7 for interconnecting the spacer and working wedges. Each device 7 includes a cantilever flexible strip 8 connecting two adjacent wedges, for example, a front spacer wedge 2 and a working wedge 5, and a detachable locking device 9 that holds the cantilever flexible strip 8 on a corresponding spacer wedge, for example, a front spacer wedge 2.

Each working wedge is equipped with two cantilever flexible strips 8 attached to the edges of this working wedge from opposite sides of this working wedge with the formation of a monolithic element. The rear spacer wedge 3 is thinner than the front spacer wedge 2

The edge 9 of the cantilever flexible strip 8 is connected to the edge 10 of the working wedge 5 facing the adjacent adjacent spacer wedge 2, while the cantilever flexible strip 8 is located above the outer surface 11 of the casing of this adjacent spacer wedge 2 and secured to it using a detachable locking device .

The detachable locking device includes a recess 12 made in the surface 11 of the housing of the spacer wedge 2 from the opposite wedge surface of the spacer wedge 3 under the cantilever flexible strip 8 to accommodate this cantilever flexible strip. The recess 12 has a depth greater than the thickness of the cantilever flexible strip 8. In the side walls 13 and 14 of the recess there are holes 15 located above the flexible cantilever strip 8, through which the fixing rod 16 is passed over the flexible cantilever strip, while the free end of the flexible cantilever strip 8 equipped with a retaining collar 17, interacting with the locking rod 16.

The other three fixing devices are arranged in the same way, connecting the expansion wedge 3 and the working wedge 5, the expansion wedge 3 and the working wedge 6, the expansion wedge 2 and the working wedge 6.

For the convenience of working with the compression unit, two fixing rods 16 of the upper and lower fixing devices 7 of the front spacer wedge 2 and the rear spacer wedge 2 are interconnected by a jumper 18, forming a fixing bracket 19.

When assembling the unit, using a screw drive 4, connect the front expansion wedge 2 and the rear expansion wedge 3 to each other and bring them closer to each other at a sufficient distance to attach the working wedges 5 and 6. Flexible cantilever strips 8 are placed in the recesses 12 and insert the fixing the rods 16 of the fixing bracket 18 into the holes 15 in the recess wall 14 and move them over the surface of the flexible cantilever strip 8 to the opposite recess wall 13 and insert them into the holes 15 of the recess wall 13, fixing the flexible cantilever strip 8 on the expansion wedge 2. Anal flexible cantilever strips 8 are carefully connected to the spacer wedge 3, forming a single module of the compression unit, which is mounted in the cable entry aperture. A single module of the compression unit can be formed using not only fixing brackets 19, but also individual fixing rods 16.

Next, with reference to FIG. 3-14, in which the second embodiment of the utility model is shown, the basic elements of the compression unit 1 will be described in detail. When describing the second embodiment of the utility model, a detailed description of the elements of the compression block according to the first embodiment of the utility model will be omitted.

The compression unit 1 contains a front expansion wedge 2 and a rear expansion wedge 3, two working wedges 5 and 6, two screw drives 4 connecting the wedges 2 and 3, and devices 7 for pairwise connection between two adjacent expansion and working wedges.

In contrast to the first embodiment of the utility model, the device 7 for pairwise connecting adjacent wedges, for example, a movable spacer wedge 3 and a working wedge 5, includes a cantilever flexible strip divided into two languages 8a and 8b, edges 9 of languages 8a and 8b of the cantilever flexible strip connected to the edge 10 of the working wedge 5, while the languages 8a and 8b are located above the outer surface 11 of the housing of the adjacent spacer wedge 3. and are fixed on it using a detachable locking device.

In this embodiment, the detachable locking device includes recesses 12a and 12b, separated by a partition 20. The recesses 12a and 12b are made in the surface 11 of the housing of the spacer wedge 3 from the side opposite the wedge surface of the spacer wedge 3, under the console flexible languages 8a and 8b lanes 8 to accommodate languages 8a and 8b. The recesses 12a and 12b have a depth greater than the thickness of the cantilever flexible strip. Holes 15 are made in the side walls 13 and 14 of the recesses, and a hole 21 is made in the partition 20. The holes 15 and 21 are located above the tongues 8a and 8b and the fixing rods 16 are inserted from both sides over the tongues 8a and 8b of the flexible cantilever strip, the free ends of the tongues 8a and 8b of the flexible cantilever strip are equipped with retaining collars 17 interacting with the fixing rods 16.

In this embodiment of the utility model, each expansion wedge is equipped with locking devices located on opposite sides of the housing of this expansion wedge, while the locking rods 16 of these locking devices are connected to each other by a jumper 18, forming a locking bracket 19. Thus, in this embodiment each expansion wedge 2 and 3 is equipped with two fixing brackets 19.

In this embodiment of the utility model, two options are proposed for locating the fixing brackets 19 on the expansion wedges 2 and 3. In the first embodiment, implemented on the rear expansion wedge 3, recesses 22 are located on the side surface of the rear expansion wedge 3 located in the area adjacent to the outer surface spacer wedge 3 (rear surface of compression unit 1). The fixing brackets 19 of the fixing devices 9 of the rear spacer wedge 3 are located in these recesses so that their jumpers 18 do not protrude above the lateral surface of the rear spacer wedge 3, which simplifies the installation of the compression unit in the cable entry opening. In the second embodiment, implemented on the front expansion wedge 2, the jumpers 18 of the fixing brackets 19 protrude above the lateral surface of the front expansion wedge 2 and can serve as a base for orientation of the compression unit 1 in the cable entry opening, for example, protruding jumpers 18 can be used to coordinate the compression unit 1 relative to the front surface of the cable entry opening. It should be understood that the recess 22 can be performed on any of the expansion wedges 2 or 3, or both wedges 2 and 3 can be made without recesses 22.

The screw drive 4 contains a lead screw 23 with two threaded sections 24 and 25 with opposite threads, a first threaded sleeve 26 fixed in the rear spacer wedge 3 and interacting with one threaded section, for example, with a section 24, and a second threaded sleeve 27 fixed in a through hole of the front spacer wedge 2 and interacting with the second threaded section, for example, section 25. The lead screw 23 extends beyond the compression block 1 from the front working wedge 2, while the protruding shank 28 is working of the screw is equipped with a member 29 for driving the lead screw is rotated. In the present embodiment of the utility model, the first threaded section is made with a smaller thread diameter than the second threaded section, which simplifies the assembly of the compression unit, since the lead screw 23 can be passed through the hole in the second threaded sleeve 27 from the front surface of the front spacer wedge. In the present example of implementation of the utility model, the first threaded sleeve 26 is made with a blind threaded hole, but this does not exclude the execution of the first threaded sleeve 26 with a through threaded hole. The first and second threaded bushings are fixed in the front and rear spacer wedges by any known method: gluing, joint molding of the sleeve and the corresponding spacer wedge, fixing with a pin, etc. As an element for bringing the lead screw into rotation, any known solution can be used: a hexagonal head, as in the attached figures, a slot with a slot, as with ordinary screws, a slot on the end of the lead screw, a figured nut, a knob, a handle, a flywheel, etc.

Screw drive 4 provides spatial rigidity of the mechanism. In fact, the metal screw 23, being a stiff and durable axis, makes relative motion in two longitudinal grooves 31, and the spacer wedges 2 and 3, having these guides, are forced to move without distortions and jamming - provided that the wedges are sufficiently strong and stiff 2 and 3 and / or their corresponding metal reinforcement, if polymers with insufficient strength characteristics were used for their manufacture, not metal. This made it possible to increase the physical angle of the wedge and, accordingly, increase the working stroke of the working wedges 5 and 6. However, the main achievement of this design is the impossibility of relative fixing of adjacent surfaces of the wedges when disassembling cable entries - the so-called jamming mechanism

The compression unit 1 can be equipped with one screw drive located along the central longitudinal axis of the compression block or several bit drives, for example, two screw drives placed in the longitudinal plane of the compression block symmetrically with respect to its central longitudinal axis.

It is advisable to divide the rear expansion wedge 3 into separate parts, for example, into two separate parts 3a and 3b, as shown in FIG. 2 and 4, each of these two separate parts being connected to its screw drive. If there is a jumper 20, the partition plane of the rear spacer wedge 3 divides into two parts and the jumper 20 so that each of the parts 3a and 3b interacts with its tongue 8a or 8b of the flexible cantilever strip 8.

The working wedges 5 and 6 are made with contact pads 30 placed opposite to each other, limiting the lateral movement of the working wedges in the direction of the thickness of the composite block, while in the contact areas of the working wedges there are longitudinal grooves 31 located parallel to the lead screw 4 on both sides of the lead screw to accommodate the lead screw in them when closing the contact pads. The walls of the longitudinal groove 31 are made with the possibility of elastic interaction with the lead screw 23 - with its threaded sections 24 and 25.

In addition to the fixing device described above with a retaining collar cooperating with the fixing rod, a fixing device in the form of a hinge loop can be used. In FIG. 14A-14E show embodiments of the free end edge of the flexible cantilever plate 8. On the free end edge, a bounding flange 17 can be formed that projects above the outer surface of the tongue of the flexible cantilever plate 8 (Fig. 14A), symmetrical with respect to the language of the flexible cantilever plate 8 (Fig. 14B ) protruding above the lower surface of the flexible cantilever strip 8 (Fig. 14B). When used in the compression unit fixing in the form of a hinge loop in the retaining flange 8 is a longitudinal hole 32 (see Fig. 14G-14E), which is inserted into the locking rod 16, which is the axis of the hinge loop.

In FIG. 15 and 16 show a third embodiment of a utility model.

This embodiment is characterized in that the flexible cantilever stripes 8 connecting the front spacer wedge 2 to the working wedges 5 and 6 are solid as in the first embodiment, while the flexible cantilever strips 8 connecting the rear spacer wedge 3 to the working wedges 5 and 6 are cut by a narrow slot into two languages 8a and 8b. The same narrow slot divides the rear spacer wedge 3 into two parts 3a and 3b. The slot dividing the rear expansion wedge 3 into two parts coincides with the slot dividing the flexible cantilever strip 8 into two languages 8a and 8b. The fixing device on the front spacer wedge 2 uses one fixing bracket, two fixing rods 16 of which extend over the entire length of the recess 12 of the front spacer wedge 2, holding the flexible cantilever strip 8. The locking device on the rear spacer wedge 3 also uses one fixing bracket, two fixing rods 16 which extend over the entire length of the recess 12 of the rear spacer wedge 3, holding both tongues 8a and 8b of the flexible cantilever strip 8 in the recess 12.

The compression unit 1 is equipped with two screw drives 4 located in the longitudinal plane of the compression unit symmetrically with respect to its central longitudinal axis. In this embodiment, each part of the rear spacer wedge is moved independently by its drive 4.

In FIG. 17 and 18 show a fourth embodiment of a utility model.

This embodiment is characterized in that the flexible cantilever stripes 8 connecting the front spacer wedges 2 and 3 with the working wedges 5 and 6 are cut with wide slots into three languages 8a, 8b and 8c. The front and rear spacer wedges 2 and 3 are solid, as in the first embodiment. The spacer wedges are interconnected by one screw drive 4 located along the central longitudinal axis of the compression unit. In each recess 12 there are two partitions 20 dividing the recess 12 into three sections 12a, 12b and 12c. Languages 8a, 8b and 8c are placed in these sections so that the partitions 22 are placed in wide slots of the flexible strip 8 between the languages 8a, 8b and 8c.

In this embodiment, locking devices of the hinge type are used. In the retaining flanges on the edge of the tongues 8a, 8b and 8c, longitudinal holes 32 are made. On each spacer block 2 and 3 in the fixing device, two fixing brackets are used, placed on two sides of the spacer block. The fixing rods 16 of the fixing brackets are inserted into the holes 15 in the side walls of the recess, into the holes 21 in the partitions 20 and into the holes 32 in the retaining flanges 17 of the languages 8a, 8b and 8c, forming a connection of the tongues of the cantilever flexible strip with a spacer wedge like a hinge loop. The ends of the fixing rods 16 are placed in the hole 32 in the middle tongue 8b

As materials for the manufacture of compression block wedges, depending on the technological requirements for it, various elastic elastic materials are used: rubbers, organosilicon polymers (silicones) and elastomers, generally non-combustible, and typical technological processes are stamping, molding, molding and etc. In particular, for the manufacture of expansion and working wedges, it is preferable to use silicone rubber compounds with high strength characteristics such as the proven mixture PENTASIL 3303 TU 2512-04 3-40245042-2013 (www.penta-91.com) and the like.

Using the utility model, consider the following example. The compression unit 1 can be assembled at the installation site in the form of a single module with maximally dilated expansion wedges 2 and 3 and working wedges 5 and 6, worn with some interference with their longitudinal groove 31 on the threaded sections 24 and 25 of the screw screw 23, forming a compact prism of minimally possible height. If necessary, a sealing compound is applied to the respective surfaces of the block, including the surfaces of the screw 23, which will also serve as a lubricant for the wedge mechanism. If necessary, the compression unit 1 can be delivered assembled in the form of a monoblock with maximally diluted compressible wedges 8 and 9 and a pressure wedge 24, worn with some interference with its longitudinal groove 33 on the threaded part 34 of the screw 32, forming a compact prism of the lowest possible height.

The compression unit 1 is installed in the opening of the cable entry. Rotating the lead screw 23, the distance wedges 2 and 3 are shifted to each other - initially with a small force sufficient to idle the wedges 2 and 3 and the threaded sections 24 and 25 of the lead screw 23 exit the longitudinal groove 31 and then with increasing force, providing further rapprochement of the expansion wedges 2 and 3. A working wedge, for example a working wedge 6, begins to act on the pack of compressible modules in the cable entry opening and this continues until all the gaps between the contacting parts of the pack of compressible modules are selected, and then Compression of compressible modules begins. After bringing all the cable entry elements into working condition, excess sealing compound is removed.

Due to its design and materials used, the cable entry provides reliable fixation, sealing and sealing of the elements being sealed. Prevents the penetration of moisture, gas, fire, rodents, ants and other undesirable environmental factors. Tests have shown that the strength of the obtained joints of cable entry elements with sealed cables, wires, etc. is ensured at a level not lower than the strength properties of the latter, i.e. they cannot be pulled, pressed, or cranked without violating their mechanical integrity or destruction.

Similarly, cable entry is implemented on wiring closets and other similar structures.

As a result of using the utility model, a compression unit was created in which the ultimate simplicity of the design, the minimum number of parts, the minimum overall dimensions in the initial state, the increased working stroke of the spacer wedge, the operational reliability and the possibility of multiple mounting-dismounting with the highest possible speed for a screw drive are provided.

As a result of the implementation of this solution, the compression unit has acquired the smallest possible dimensions during storage, transportation and installation, compactness and fixed structural integrity. In general, the compression unit has become a combination of only four original parts (wedges 2, 3, 5 and 6), two of which - expansion wedges 2 and 3 - are as unified as possible.

The list of positions:

1 - compression unit;

2 and 3 - movable spacer wedges ;,

4 - screw drive;

5 and 6 - working wedges;

7 - a device connecting to each other adjacent working and spacer wedges

8 - cantilever flexible strip;

9 - edge of the cantilever flexible strip;

10 - the edge of the working wedge;

11 - the outer surface of the body of the spacer wedge,

12 - recess;

13 and 14 - side walls of the recess;

15 - hole;

16 - fixing rod;

17 - retaining collar;

18 - jumper;

19 - a fixing bracket;

20 - partition;

21 - hole in the partition;

22 - recess;

23 - lead screw;

24 and 25 - threaded sections;

26 and 27 - threaded bushings;

28 - shank;

29 - element for rotation of the lead screw;

30 - contact area;

31 - a longitudinal groove;

32 - hole for the hinge loop.

Claims (19)

1. A compression cable entry unit comprising a wedge mechanism with two movable front and rear spacer wedges located opposite each other and configured to move to and from each other using a screw drive connecting these movable spacer wedges, working wedges located opposite to each other on both sides of the expansion wedges and interacting with their inclined surfaces with the inclined surfaces of the expansion wedges, and devices for connecting to each other inter working wedges and expansion wedges, providing the ability to move the working wedge relative to the adjacent expansion wedge, characterized in that each device for connecting the working wedge and the adjacent expansion wedge includes a cantilever flexible strip, one edge of which is connected to the edge of the working wedge facing the adjacent to it an adjacent spacer wedge, and the second free edge of this cantilever flexible strip is fixed to this adjacent spacer wedge using a detachable locking device roystva. 2. The compression unit according to claim 1, characterized in that each working wedge is equipped with two cantilever flexible strips attached to the edges of this working wedge from opposite sides of this working wedge with the formation of a monolithic element. 3. The compression unit according to claim 1, characterized in that the rear expansion wedge has a smaller thickness than the front expansion wedge. 4. The compression unit according to claim 1, characterized in that the detachable locking device includes a recess made in the surface of the spacer wedge housing to accommodate a cantilever flexible strip, through holes in the side walls of the recess, a fixing rod passed through these holes and interacting with a flexible cantilever strip. 5. The compression unit according to claim 4, characterized in that the recess has a depth greater than the thickness of the cantilever flexible strip, while the free edge of the flexible cantilever strip is equipped with a retaining collar interacting with the fixing rod. 6. The compression unit according to claim 4, characterized in that the detachable locking device is made in the form of a hinge loop, while some loop elements are located on the spacer wedge, the loop response elements are located on the free edge of the cantilever flexible strip, and the fixing rod is the axis of the loop. 7. The compression unit according to claim 4, characterized in that each expansion wedge is equipped with two locking devices located on opposite sides of the housing of this expansion wedge, while the fixing rods of these fixing devices are connected to each other by a jumper, forming a fixing bracket. 8. The compression unit according to claim 7, characterized in that the lintels of the fixing brackets are recessed in recesses made in the lateral surfaces of the spacer wedges. 9. The compression unit according to claim 7, characterized in that the lintels of the fixing brackets on the front expansion wedge extend beyond the side surfaces of the front expansion wedge. 10. The compression unit according to claim 2, characterized in that at least one slot is made in the flexible cantilever strip dividing it into separate languages. 11. The compression unit according to claim 4, characterized in that the recess is additionally equipped with a partition located in the slot of the flexible cantilever strip, while the holes are made in the partition into which the fixing rod enters. 12. The compression unit according to claim 1, characterized in that the screw drive includes a working screw with two threaded sections with opposite threads, a first threaded sleeve fixed in the rear spacer wedge and interacting with one threaded section, and a second threaded sleeve fixed in the through hole of the front expansion wedge and interacting with the second threaded section, the working screw extends beyond the compression block from the front working wedge, while the protruding shank of the working screw It is equipped with an element for bringing the rotor into rotation. 13. The compression unit according to claim 12, characterized in that the working wedges are made with contact pads placed opposite each other, limiting the lateral movement of the working wedges in the direction of the thickness of the composite block, while longitudinal grooves are made in the contact areas of the working wedges parallel to the working a screw on both sides relative to the working one to accommodate the working screw in them when closing the contact pads. 14. The compression unit according to claim 11, characterized in that it is equipped with one screw drive located along the central longitudinal axis of the compression unit. 15. The compression unit according to claim 11, characterized in that it is equipped with two screw drives located in the longitudinal plane of the compression unit symmetrically with respect to its central longitudinal axis. 16. The compression unit according to claim 15, characterized in that the rear spacer wedge is divided into separate parts, each of these separate parts being connected to its screw drive and interacting with its tongue in a flexible cantilever strip. 17. The compression unit according to claim 15, characterized in that the expansion and working wedges are made of elastic elastic material. 18. The compression unit according to claim 17, characterized in that the expansion and working wedges are made of rubber. 19. The compression unit according to claim 17, characterized in that the expansion and working wedges are made of elastic polymeric materials.

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