RU16683U1 - DEVICE FOR INTRODUCING THE CABLE TO THE GUIDE PIPE - Google Patents

Abstract

1. A device for introducing a cable into a guide pipe, made in the form of a pneumatic chamber with a supply pipe, the output channel of which is connected to the guide pipe with a sealant, and the input channel is connected to the cable feed unit containing feed rollers located on both sides using a gate valve from the cable being laid, and a drive connected to at least one of the rollers, characterized in that it is additionally equipped with an automatic control system for supplying air to the pneumatic chamber, containing control and a measuring sensor connected to one of the feed rollers and connected through the control unit to the air supply regulator installed on the supply pipe of the pneumatic chamber. 2. A device for introducing a cable into a guide tube according to claim 1, characterized in that the pneumatic chamber is additionally equipped with a vibration damper coaxially located in it, made in the form of a channel narrowing along the cable, formed of elastic elements made of a material with great internal friction, for example , made of polyurethane. 3. A device for introducing a cable into a guide tube according to claim 1, characterized in that two bobins with threads are additionally coaxially installed in the pneumatic chamber. A device for introducing a cable into a guide tube according to claim 1, characterized in that at least two pressure rollers are located on both sides of the cable to be laid in the pneumatic chamber, and two bobbin with technical tapes, while one of the surfaces of each tape is applied adhesive layer. 5. A device for introducing a cable into a guide pipe according to claim 1, characterized in that as

Description

Device for introducing cable into the guide tube

The invention relates to devices designed to insert a fiber-optic cable into a cable laying cable by using the force generated by a stream of compressed air.

A device for introducing a cable into a cable laying cable made in the form of a pressure chamber with a threading pipe is known, the output channel of which is connected to the cable guide pipe through the seal and the flexible pipe, and the input channel is connected to the cable feed unit including a pair of rubberized drive rollers through the seal. The ratio of the sizes of the output and input channels of the pneumatic chamber ensures the direction of movement of the air flow. (1)

The disadvantage of this device is the high consumption of compressed air in the non-channel, expanding in the direction of cable movement, as well as a limited range of diameters of the laid cables, due to the lack of adjustment of the distance between the feed rollers.

Closest to the claimed one is a device for introducing a cable into a laying pipe made in the form of a pressure chamber with a supply pipe, the output channel of which is connected to the guide pipe with the rating of the amplifier 1, and the input channel is connected to the cable feed unit by means of a gate valve. In this case, the cable feed unit contains at least a pair of grooved rollers located but on both sides of the cable to be transported, equipped with a roller clamp mechanism and a drive connected to at least one of the rollers. (2)

The disadvantages of this device are the high air flow continuously supplied under high pressure, as well as the deformation of an expensive fiber-optic cable in the process of transporting it by corrugated feed rollers and difficult reconfiguration of the clamp mechanism when changing the diameter of the cable being laid. These disadvantages reduce the overall performance of the device.

IPC G 02 at 6/44

The problem, to which the claimed invention is directed, consists in creating a highly efficient device that makes cable laying without cable laying the maximum length with minimum air consumption and maintaining its integrity.

The technical result is depleted due to automatic equalization with a hint of compressed air inflated into the non-camera, depending on the resistance of the feed or the length of the cable inserted into the laying pipe, as well as the reliable and gentle supply of the cable to be laid.

This is achieved by the fact that the device for introducing the cable into the noring pipe, made in the form of a pressure chamber with a threading pipe, the output channel of which is connected to the nano-pipe with the help of the intensifier, and the input channel is connected to the cable feed unit containing the feed rollers, which are located but both sides of the cable being laid down, and the drive connected to at least one of the rollers, are additionally equipped with an automatic system for equalizing the air supply to the non-camera, containing a control meter ritelny sensor coupled to one of the feed rollers, and linked via a control unit unravleniya air nodachi set to Nita natrubke nnevmokamery.

To reduce the oscillation of the cable being laid, the non-camera was additionally equipped with a vibration damper coaxially located in it, made in the form of a channel narrowing along the direction of movement of the cable, formed from other elements made of a material with high internal friction, for example, polyurethane.

In order to increase traction and consequently reduce the flow rate of the inflated air in the pneumatic chamber, two bobbins with threads or, alternatively, two bobbins with technical tapes, on which one of the surfaces of which an adhesive layer is applied, and at least two pressure rollers, are arranged coaxially but both sides of the cable to be laid.

As a control and measuring sensor, either a sensor that records the length of the cable inserted into the guide pipe or a sensor that records the resistance of the cable feed into the guide pipe is used.

to simplify reconfiguration when changing the diameter of the cable being laid, each feed roller is made in the form of two symmetrical parts and is connected to the pneumatic mechanism of their axial movement. To increase the feed force of the cable, the feed unit is equipped with two flexible conveyor belts that cover the feed rollers, this has increased the contact area of the cable with the feed organs.

Reliable sealing and hermetic sealing is ensured by a gate valve made in the form of a pneumatic chamber installed coaxially in the inlet channel with the possibility of axial movement of the split sleeve with an internal conical surface and two elastic half rings located in the sleeve cavity. Simplification of the adjustment of the gate valve for the required cable diameter is achieved by placing two hollow elastic half rings filled with gas under pressure in the pneumatic chamber inlet. In order to increase the durability of elastic half rings, wear resistant rods were coaxially fixed.

A pneumatic turbine with tangential nozzles is used as a drive for the feed rollers.

In order to increase the air flow rate at the outlet of the pneumatic chamber, the guide tube is provided with a second pipe, coaxially located in the first.

The essence of the utility model is illustrated by drawings.

In FIG. 1 shows a general view of a device for introducing a cable into a guide tube; in Fig.2 - an embodiment of a pneumatic chamber with baboons; in FIG. 3- execution of a pneumatic chamber equipped with bastings and pressure rollers; in FIG. 4 - an embodiment of the feed rollers in the form of two symmetrical parts connected to the pneumatic mechanism of their axial movement (transverse section); in FIG. 5- embodiment of a cable feed node with conveyor belts; in FIG. 6- embodiment of a passage gate in the form of a split sleeve with elastic half rings; in FIG. 7 is a longitudinal section through the gate (view along AA, FIG. 1); Fig. 8 is an embodiment of a groove shutter in the form of hollow elastic half rings.

the second pipe 5 is coaxially located. The inlet channel of the pneumatic chamber 1 is connected through the gate valve 6 to the cable feed unit 7. In the pneumatic chamber 1 there is a vibration damper 15, made in the form of a channel narrowing along the direction of movement of the cable formed from elastic elements made of material with high internal friction, for example, polyurethane.

As a variant of constructive execution, in order to braid the cable simultaneously with its roving, two bobbin 16 and 17 with threads 18 and 19, respectively, can be additionally coaxially mounted in the camera 1 (Fig. 2).

The cable to be laid may not be flogged, but glued with technical tape; for this purpose, at least two pressure rollers 20 and 21 located on both sides of the cable to be laid, and two babit1y 22 and 23 with technical tapes 24 and 25 can be additionally installed in the camera 1. accordingly, an adhesive layer is applied to one of the surfaces of each tape (FIG. 3).

The cable feed unit 7 comprises feed rollers 26 and 27 located on both sides of the cable to be laid. The drive of the feed rollers is made in the form of a pneumatic turbine 29 connected to a source of compressed air (not shown in Fig. 1), and tangential nozzles 30 and 31. The drive is connected to at least one of the feed rollers, for example, 26. The feed rollers 26 and 27 equipped with a different shell 32 and 33, respectively.

As an embodiment of the constructive implementation (Fig. 4), each feed roller can be made in the form of two symmetrical} n 1x parts 34 and 35 mounted on the axis 36 in a movable manner and connected to the pneumatic mechanism of their axial displacement, feasible, for example, in the form of a pneumatic cylinder 37, the working plate of which is connected to the pressure line 38, and the cushion 39 with one of the symmetrical parts of the roller, for example, 35. In this case, both one and both simultaneously symmetrical parts can be connected to the pneumatic axial movement mechanism ayunschh rollers.

When laying large diameter cables, the cable feed unit 7 is provided with two flexible conveying mites 40 and 41, which envelope the feed rollers 26 and 27. (Fig. 5)

pievmokamera 1 with the possibility of axial movement and two elastic half rings 43 located in the nostrum of the sleeve 42. (Fig.6,7).

As an embodiment of the structural embodiment, the passage gate 6 can be made in the form of two hollow elastic half rings 45 and 46 filled with gas under pressure, which are located in the inlet channel of the pneumatic chamber 1 (Fig. 8). Wear-resistant pads 44, coaxially rounded on the other rings 43, 45, 46 of the gate 7, increase their durability.

An automatic air supply control system for the air chamber 1, contains a control and measuring sensor 47, which can be used either as a sensor that records the length of the cable inserted into the laying pipe 4, or a sensor that records the resistance of the cable supply when it is inserted into the guide pipe 4. Control and measuring sensor 47 is fixed on one of the feed rollers, nanomer, 27 and through the unit of grafting 48 is connected to the air supply regulator 49, placed on the thread pipe 2.

The device operates as follows.

The air enters the air chamber 1 through the supply pipe 2, passes through the air supply regulator 49, and then through the outlet drip 2 of the air chamber into the laying pipe 4. Using a second coaxially arranged laying pipe 5 allows you to increase the speed of the airy note at the exit of the lower chamber.

The feed rollers 26 and 27 are driven in by means of a pneumatic turbine 29 with tangential nozzles 30 and 31. The torque on the shaft of the feed rollers 26 and 27 changes as the pressure of the air supplied to the pnevmoturbip 29 changes.

Fiber optic cable 50 is inserted into the feed unit 7, and depending on the diameter, the length to be laid, and other technological conditions, it either moves between elastic elastic padded shells 32 and 33 mounted on the feed rollers 26 and 27, or crimped by symmetrical parts 34 and 35 of each feed roller, due to the axial re-milling of one of the parts, for example, 35 with a spindle 39 of a pneumatic cylinder 37. It is advisable to move a large diameter cable that requires more effort to feed using two flexible transporting mites 40 and 41, cat They bend around the feed rollers 26 and 27. In this case, the area increases significantly.

contact between the cable and the conveyor belts, and therefore increases the effort of notch.

Then, the cable 50 is passed through the passage gate 6, and sent to the pneumatic chamber 1. At the same time, the construction of the passage gate 6 prevents air leakage from the pneumatic chamber. The split sleeve 42 is moved in the input channel of the pneumatic chamber 1, as a result of which the spherical half rings 43 located in its nostrum) tightly compress the cable 50.

If the gate valve is made in the form of hollow elastic half rings 45 and 46, then they are filled under pressure with gas and this relieves reliable sealing and sealing of the chamber. Wear-resistant pads 44, coaxially mounted on the elastic rings 43, 45, 46, increase the durability of the groove shutter.

After the pass-through shutter, the cable is passed through an oscillation damper 15, which is a channel that tapers along the cable. Channel-forming) other elements made of material with high internal friction absorb vibration of the cable, which makes it easy to orient it into the guide pipe 4 or 5. As shown above, pipe 5 allows increasing the air flow rate at the outlet of the device.

If baboons 16 and 17 are installed in the pneumatic chamber, then their threads 18 and 19 are fixed at the initial section of the cable 50 to be laid, for example, with glue. At the same time, piti pa baboons should be wound in opposite directions (clockwise and counterclockwise). As the cable advances, the pitts smoothen out from the babin, forming a cruciform notch on the cable, which increases the friction of the air flow against the cable, which ultimately increases traction, reduces the flow rate of the supplied air, and therefore the power of the compressor used. Practical tests have shown that such a braid can increase the length of the cable to be laid from 3 to 6 km, that is, twice.

If bins 22 and 23 with technical tapes 24 and 25 with an adhesive layer on one of the surfaces are installed in the pneumatic chamber 1, then in this case the technical tapes are similarly curled at the initial section of the cable to be laid so that the adhesive layer is facing it, and then, as it moves forward, the cable is crimped by the pinch rollers 20 and 21, which provide gluing of the technical tape to its surface. In this case

the air flow on the cable increases even more, and consequently the traction force also increases.

In the process of moving the cable 50, the control and measuring sensor 47 is fixed to the feed roller, for example, 27 generates a pronorpionic signal either to the length of the cable inserted into the guide pipe or to the force of the cable feed resistance when it is laid in the guide pipe. This signal is amplifying and conversion in the control unit 48 is applied to the controller 49, which in accordance with the signal of the sensor 47 sets the optimal air flow.

Thus, the use of the inventive device in comparison with the prototype allows automatic control of the flow of compressed air supplied to the pneumatic chamber, depending on the length of the laid cable, eliminates the leakage of compressed air from the inlet channel of the pneumatic chamber, provides reliable and gentle supply of laid cable in the laying channel and significantly increases traction created by air flow.

Sources of information:

1.European peptide No. O 108 590, IPC G 02 B 6/44, publ. 11/26/86 analogue.

2. US patent, No. 4 934 662, NKI 254-134.4, publ. 06/19/1990 prototype.

Claims (14)

1. A device for introducing a cable into a guide pipe, made in the form of a pneumatic chamber with a supply pipe, the output channel of which is connected to the guide pipe with a sealant, and the input channel is connected to the cable feed unit containing feed rollers located on both sides using a gate valve from the cable being laid, and a drive connected to at least one of the rollers, characterized in that it is additionally equipped with an automatic control system for supplying air to the pneumatic chamber, containing control and a measuring sensor connected to one of the feed rollers and connected through the control unit to the air supply regulator installed on the supply pipe of the pneumatic chamber.  2. The device for introducing the cable into the guide tube according to claim 1, characterized in that the pneumatic chamber is additionally equipped with a vibration damper coaxially located in it, made in the form of a channel narrowing along the cable, formed of elastic elements made of material with high internal friction , for example, from polyurethane.  3. The device for introducing the cable into the guide tube according to claim 1, characterized in that two bobins with threads are additionally coaxially installed in the pneumatic chamber.  4. The device for introducing the cable into the guide tube according to claim 1, characterized in that the pneumatic chamber additionally has at least two pressure rollers located on both sides of the cable to be laid, and two bobbin with technical tapes, while on one of the surfaces of each adhesive tape applied.  5. A device for introducing a cable into a guide pipe according to claim 1, characterized in that a sensor recording the length of the cable inserted into the guide pipe is used as a control and measuring sensor.  6. The device for introducing the cable into the guide pipe according to claim 1, characterized in that as a control and measuring sensor, a sensor is used that records the force of the cable feed resistance when it is inserted into the guide pipe.  7. The device for introducing the cable into the guide tube according to claim 1, characterized in that the feed rollers are provided with elastic sheaths filled with gas under pressure.  8. The device for introducing the cable into the guide pipe according to claim 1, characterized in that each feed roller is made in the form of two symmetrical parts and is connected to a pneumatic mechanism for their axial movement.  9. The device for introducing the cable into the guide tube according to claim 1, characterized in that the cable feed unit is provided with two flexible conveyor belts located on both sides of the cable to be laid, which envelope the feed rollers.  10. The device for introducing the cable into the guide tube according to claim 1, characterized in that the gate valve is made in the form of a pneumatic chamber installed coaxially in the input channel with the possibility of axial movement of the split sleeve with an internal conical surface and two elastic half rings located in the cavity of the sleeve.  11. The device for introducing the cable into the guide tube according to claim 1, characterized in that the gate valve is made in the form of two hollow elastic half rings installed in the inlet of the pneumatic chamber, filled with gas under pressure.  12. A device for introducing a cable into a guide tube according to claim 1, characterized in that a pneumatic turbine with tangential nozzles is used as a drive of the feed rollers.  13. A device for introducing a cable into a guide pipe according to claim 1, characterized in that the guide pipe is provided with a second pipe coaxially located in the first. 14. A device for introducing a cable into a guide pipe according to claims. 10 and 11, characterized in that on the elastic half rings of the passage through the gate, wear-resistant pads are coaxially fixed.