RU2475910C1 - Three-layer cable input - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: three-layer cable input contains layers formed by mutually conjugated mated plates with coaxial attachment holes, the layers sandwich-bonded, with an intermediary layer made of elastic sealing material. Each plate is equipped with at least one element for the cable hole formation (hereinafter referred to as the "element") which elements are arranged coaxial to each other in each layer, their position ensuring the possibility to form at least one cable hole within the assembled cable input, such hole reproducing the shape of the cable put in. Each element of each layer represents a group of holes made so that to enable adaptation by way of removal of part of the material under the cable being lead. In the external layer plates the holes are made through, in the shape of notches with connective straps equipped with a pair of grooves that are crosswise relative to the notches while in the intermediary layer plates the holes are made as blind slots in the shape of groves so that to provide for undamaged integrity of the material.

EFFECT: device is universally suitable for a wide range of cable diameters requiring no modification of the device design when the number and diameter of the cables being lead are altered.

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Description

The invention relates to electrical engineering, in particular to the design of means for providing cable entry, for example, in a wiring closet. It can be used as part of an electrical cabinet or other equipment for the sealed supply of power cables, including for street use.

Known means bushings for cables or pipes (RF patent for the invention No. 2319057, F16L 5/02, 2006), containing an external frame with at least one sealing module, covering the cable or pipe with a gap and a node extensions. Each of the sealing modules is formed by peelable elastic sheets to adapt the area of its channel with a cable or pipe and is divided into two halves in the longitudinal direction. The incision is inclined relative to the longitudinal direction of the sealing module or relative to the longitudinal axis of the channel, while the inclination is selected taking into account the thickness of the peeled sheets. Tightness is achieved by pressing the expansion unit of the sealing modules against each other and the frame. The indicated inner and outer peeling thin sheets can be manually separated. The tool provides a sealed connection with a cable or pipe, however, the presence of an external frame and an expansion unit complicates the design and installation of the tool, which leads to an increase in the cost of the product. In addition, the overall dimensions of the frame limit the number and size of the sealing modules used and, accordingly, the diameter range of the input cables.

The closest in essence is a sealed inlet (USSR author's certificate for the invention No. 1081672, 06/16/1980), containing pressure discs spaced apart from each other with cable holes, a seal located between them and a fastener (studs) tightening the disks. The cable entry is equipped with connecting plates located on the disks, and the clamping disks are made in the form of interconnected sectors with grooves aligned on the mating sides, forming holes for cables, while the connecting plates overlap the sectors. The device protects the cable entry from the ingress of liquid or gas, however, the device has a complex structure that complicates installation. In addition, when changing the number of cables, it is necessary to refine the design, and when depressurization occurs, the problem of collecting the sealant, i.e. not intended for dismantling.

The technical result consists in the creation of a design that allows the cable entry to be adapted to the diameter of the input cable, allowing hermetically to lead the cables and dismantle the cable entry without disconnecting the cables.

The technical result is achieved by the fact that the three-layer cable entry contains external layers stacked on top of each other: the upper, lower and intermediate layers (sealant), fastened together through mounting holes, coaxial in each layer, according to the “sandwich” type. Each of the layers is formed by paired pairs of plates, each of which is equipped (when combined with each other), at least one element for forming a cable hole (hereinafter referred to as the element), made coaxially with each other in each layer with a specific location, allowing to form in the assembled cable entry at least one cable hole, repeating the shape of the input cable. Each element of each layer represents a group of holes made with the possibility of changing the size depending on the size of the input cable, and for the outer layers the group of holes is through, and for the inner layer the group of holes is blind. A group of through holes is formed by grooves, for example, in the form of arcs located on a plate with a discrete increasing pitch between adjacent arcs of at least 1 mm, with jumpers equipped with a pair of transverse arcs of grooves located on the side of the plates adjacent to the outer layer and adjacent to the intermediate layer (sealant). A group of blind holes are slots in the form of continuous grooves located on the plate like grooves with a discrete increasing pitch between adjacent continuous grooves of at least 2 mm, with the formation of undisturbed integrity of the material with a thickness of not more than 1 mm.

In order to form a cable hole in the assembled cable entry in the outer layers, jumpers are cut through the grooves corresponding to the size of the cable or slightly larger than which allows unhindered cable routing. In the sealant, the integrity of the material is violated by the slots of a smaller size than the size of the input cable, and in this way a hole with a size of a smaller cable size is obtained, this ensures the best coverage and sealing of the cable. The plates of the outer layers are made of soft metal, which makes it easy to break out the jumpers, and the plates of the sealant are made of elastic sealing material that ensures the cable passes through the cable hole, its coverage and reliable sealing. In addition, for ease of installation of the cable entry, for example, to the cabinet wall, the plates of the lower layer are additionally provided with mounting holes, while the lower layer is made to protrude beyond the dimensions of the other layers to ensure the location of the mounting holes.

The essence of the invention is illustrated by the following drawings.

Next, the cable entry will be described by the example of summing a round cable in a preferred embodiment.

In Fig.1 shows a three-layer cable entry with spaced layers in the preferred embodiment, Fig.2 is a cable entry assembly of the type of "sandwich", Fig.3 shows a cross section AA of the cable entry in assembled form, made in the center 4, a view of B — cross-section A-A (cross-section B) of the cable entry in an enlarged view, which shows the configuration and arrangement of elements of complex shape, allowing to form a cable hole in the assembled cable entry.

The three-layer cable entry shown in figure 1, contains paired plates of the upper and lower 1, 2 layers, equipped with elements made in the form of grooves 3, paired plates of the intermediate 4 layer - sealant, equipped with elements made in the form of slots 5 with the formation of intact integrity material (minimum residual uncut material thickness).

Figure 2 shows a three-layer cable entry assembly, while the plates of the upper 1, lower 2 and intermediate 4 layers are stacked on each other and fastened together by the type of “sandwich”, through the mounting holes 6 made along the perimeter of the plate layers coaxially in each layer and designed to combine when connecting the layers and fastening, for example, screws. The plates of the lower 2 layer are provided with additional fixing holes 7, made on the part of the lower 2 layer that protrudes beyond the dimensions of the other layers, intended for mounting a three-layer cable entry, for example, to the wall 8 of the wiring closet. Each element in each layer, i.e. slot 3 and slot 5 (figure 1), are made in layers coaxially with each other, with the possibility of education in the assembled cable entry, at least one cable hole 9.

As shown in Fig. 4, the notches 3 are preferably made, for example, in the form of concentric arcs separated by jumpers 10 and located on a plate with a discrete increasing pitch between adjacent arcs of at least 1 mm, and their number is determined by the size and shape of the input cable. In the case of the formation of the smallest possible hole for the input cable, the size of which is equal to or slightly smaller (provided that the sealing is provided) of the central slot, the size of the hole is determined by the distance to the first arc from the center, which is located so that when carrying out the smallest cable it is not necessary to break out the jumpers . In the case of a larger cable, the jumpers 10 are provided with a pair of transverse arcs of grooves 11 made on the outer side of the plates adjacent to the intermediate 4 layer, and their presence narrows the thickness of the plate, making it possible to break out the jumpers 10 and, accordingly, form a cable hole 9. In a preferred embodiment the optimal width of the jumpers 10 for the convenience of breaking out is not more than 1 mm, and the depth and width and location on the jumper 10 of the grooves 11 is calculated so as to ensure ease amyvaniya.

In a preferred embodiment, the seal plates 4 are provided with slots 5 made in the form of circular (concentric) continuous grooves with a discrete increasing pitch between adjacent continuous grooves of at least 2 mm, while the optimal thickness of the undisturbed integrity of the material is not more than 1 mm, and the number of continuous grooves is due to geometry of the driven cable. In the case of the formation of the smallest possible hole for the lead-in cable (provided that sealing is provided), the integrity of the material is violated through the first slot from the central one. Slots 3 are formed on stamping, laser or EDM equipment with a width of 2 mm and a discretely increasing pitch of 3 mm in the preferred embodiment. Slots 5 are formed on a stamping machine with a width of at least 1 mm.

For this implementation, the plates of the outer layers 1, 2 are made of soft metal, for example aluminum or its alloys, of such grades as AD0, AD1, D1, D16 GOST 4784-97, etc., with an optimum thickness of at least 1 mm, sufficient for breaking out jumpers 10. As a sealant 4, plates of elastic sealing material, for example rubber of hardness grade “M” (GOST 7338-90), rubber with an optimum thickness of at least 5 mm, which provide reliable sealing of the cable in the hole and cable entry, can be used.

Due to the variable opening adjustable for the cable size, the cable entry can be used to enter cables of various configurations (shapes and sizes). In addition, it is possible to make other options for holes in the form of a bundle, braid, casing, for example, oval, square shape.

Assembly and installation and devices are as follows.

It is more convenient to assemble the cable entry in parts, and then connect it to the device during installation. For this, between the plates of the upper 1 and lower 2 layers, a sealant plate 4 of the “sandwich” type is laid and fastened together through fixing holes 6, for example, with screws, to form part of the cable entry. Further, depending on the shapes and sizes of the cable, a cable hole 9 is formed, while the minimum possible hole for the corresponding cable size for the outer layer is the first from the center of the arc, and for the inner layer the first from the center slot. To form a larger cable hole in the outer layers, jumpers 10 are broken out through the grooves 11 to form a passage hole corresponding to the diameter of the cable or slightly larger, while ensuring unhindered cable routing. The integrity of the seal 4 is violated until receiving holes corresponding to a smaller diameter of the hole than the diameter of the input cable, and thus get a hole with a diameter of a smaller diameter of the cable, while ensuring the best coverage and sealing of the cable. Similarly, another part of the cable entry is assembled. Then, the part of the cable entry is mounted on the wall 8 of the cabinet, for example, by screws through the mounting holes 7 of the protruding part of the lower 2 layer. Next, the cable is fed, covered with another part of the cable entry, crimped and mounted on the cabinet wall and fastened, for example, with screws through the mounting holes 7 of the protruding part of the lower 2 layer.

The design of the team facilitates the installation of the cable entry, cable entry, simplifies the work of sealing, eliminates the need to disassemble the entire structure for installation and does not require disconnecting the cables during dismantling. The cable entry is adapted to the diameter of the input cable by changing the size of the hole for supplying the cable due to the location of the slots with a step that allows you to approximate the diameters of the input cable and the hole for cable entry.

Cable sealing is provided by the difference in cable diameters and openings in the seal.

The design allows you to get several cables of various diameters without unnecessary effort.

Thus, the proposed device is universal for cables of a wide range of diameters, which does not require modification of the design of the device when changing the number and diameter of the input cables.

Claims (3)

1. A three-layer cable entry, comprising pairwise-formed paired plates with coaxial mounting holes, each of which is provided with at least one element for forming a cable hole (hereinafter referred to as the element), layers bonded to each other like a “sandwich”, with an intermediate layer of elastic sealing material, characterized in that the element is made coaxially with each other in each layer with an arrangement that enables the formation of at least one cable in the assembled cable entry a white hole that repeats the shape of the input cable, with each element of each layer being a group of holes adapted to be removed by removing part of the material for the input cable, and in the plates of the outer layer the holes are made through in the form of grooves arranged with a discrete incrementing step with jumpers equipped with a pair of grooves transverse to the grooves on the outer and adjacent to the intermediate layer of the sides, and in the plates of the intermediate layer there are blind cuts in the form of ditches k, disposed with a certain discrete step between adjacent grooves to form the unbroken integrity of the material. 2. The three-layer cable entry according to claim 1, characterized in that the lower layer is made protruding beyond the dimensions of the other layers, providing the location of the mounting holes. 3. The three-layer cable entry according to claim 1, characterized in that the plates of the outer layers are made of soft metal.

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