• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to methods for producing welded tubes of small diameter for cable sheaths of optical fibers. The purpose of the invention is to improve the quality of the light guide - the cable. In the manufacture of pipe (t) 13 of tape 2, the last after washing in installation 3 and trimming in unit 4 is molded in device 5, welded in welding multi-arc device 9 with protective atmosphere, cooled in tank 14, reduced by drawing in matrix 15 and reeled up in riots. The edge shear disk shears 4, the roll tool of the forming device are driven into rotation by an adjustable drive — DC motors. The metal blank strip is selected with an optimal ratio of geometrical parameters in order to ensure high performance properties: the cable and the technological strength of T 1: 3 during its manufacture. In addition, in order to avoid distortion of the profile and the destruction of T 13, the latter is cooled directly behind the Welding Zone, ensuring contact of cooling liquids with at least 60% of the T 13 surface. Using the invention, it is possible to manufacture high-quality light-guiding cables during installation and operation. 2 sec. and 5 hp f-ly, 6 ill.
    公开号:SU1715200A3
    申请号:SU884356358
    申请日:1988-09-07
    公开日:1992-02-23
    发明作者:Цимек Герхард;Шташевски Харри;Гунниа Эвальд
    申请人:Кабельметал Электро Гмбх (Фирма);
    IPC主号:
    专利说明:

     73 B3 W TTTT TTTf 16 //f / / f / f / f fff ff f
    The invention relates to the manufacture of welded pipes of small diameter for cable sheaths of optical fibers.
    The aim of the invention is to improve the quality of the light guide cable.
    The essence of the method is. that for the manufacture of a metal pipe serving as a cable sheath, a metal tape 15 to 80 mm wide and 0.3 to 2.5 mm thick is used, with a preferred ratio between the width and thickness of the tape being 15 to 50. The metal strip in front of the weld is set in motion with the possibility of adjustment.
    In the weld zone, the pipe is cooled directly behind the weld zone to ensure contact of the coolant with at least 60% of the circumferential surface (with the exception of the weld).
    Since the pipe in the weld zone is intensely cooled, the wall section heated as a result of the application of welding energy is limited exclusively to the weld. It is preferable to cool at least 60% of the circumferential surface of the pipe. The weld can not be cooled directly with coolant, as there is a danger of welding defects in the weld, for example, in the form of gas bubbles. The cooling can be carried out by spraying or, which is preferred, by passing the pipe through a water bath. A combination of both cooling methods is also possible.
    In order to avoid installing an additional drive unit before the welding site, the tape during trimming is driven according to a preferred embodiment of the invention. Since so-called roller shears are used for trimming, only one of the rollers or both rollers of the roller shears can be set in motion. When using metal strips of large thickness, it is necessary that during the process of forming a pipe from a tape, first, the edge sections of the metal tape are formed to ensure parallelism of the welded end surfaces of the metal tape. For this purpose, it is advisable to use molding rollers.
    In order to increase the productivity of the installation, it is advisable to carry out at least one roller with a drive roller, and to expose the pipe after welding to reduce its diameter. With the same ratio of diameter and thickness
    pipe walls emanate from a larger belt width. In a device for carrying out the method, the trimming device consists of a roller shear, one of the rollers
    driven by an adjustable DC motor, the first molding section is a roller tool, one of the rollers being driven by an adjustable
    0 dc motor. Immediately behind the weld, a coolant tank is installed through which the pipe is led, while the coolant level is set so that the coolant covers the pipe at 60% of its circumference.
    To accommodate different pipe sizes, it is advisable to carry the coolant tank with
    0 ability to adjust its height. The tank is equipped with a lid; a nozzle is installed on the lid for connecting the tank to the suction pump, thereby in the space above the coolant
    5, a vacuum is created which prevents the penetration of vapor of coolant into the welding device located proximate; 1 in front of the coolant tank. Between welding
    0 and removable devices installed annular exhaust matrix, which serves to reduce the diameter of the pipe.
    Due to the use of several electrodes for welding with a tungsten electrode in an inert gas environment, the welding current can be distributed over a long-length weld.
    The invention can most effectively be applied to the production of optical cables with a metal sheath inside which are placed radiation-sensitive waveguides. The ratio between the diameter and wall thickness is 5-30. The material used is
    5 metal with high electrical conductivity, such as copper or aluminum, as well as alloys of these metals.
    FIG. 1 shows the device, the profile. in fig. 2-5 - the same, fragments; in fig. 6 - electrical conductor.
    With the help of the feeding device 1c of the roll, the winding is made of aluminum tape 2, 25 mm wide and 1.1 mm thick. In the car wash
    5 3 tape degreased and cleaned. Edge trimming 4 is used to trim the edges, as a result of which the tape width is reduced to 21 mm, which ensures the same diameter of the seam pipe throughout its length. In addition, the surface free of oxides comes to the welding device. On passing the trimmer 4, the tape 2 enters the molding device 5, where in several molding sections a suture pipe 6 is formed from it. The first molding section is a roller tool, and the subsequent molding sections are conical pipes and rings located behind them. . Before the first molding section 7, beam waveguides 8 are inserted into the still open billet,
    Behind the molding device 5 there is a welding device 9, for welding with tungsten electrodes 10-12 in an inert gas environment. A welded pipe 13, directly behind the welding device, is introduced into tank 14 with a float where it is cooled. After cooling, the pipe 13 is pulled through an annular drawable matrix 15, which reduces the outer diameter of the pipe 13. Preferably, a removable collet device 16 consisting of several collet pairs exciting and releasing the pipe 13 is used as a detachable device. These collet pairs are reinforced on an endless drive chain. The finished suture tube 13 is then wound onto a drum 17 for the finished product. At the same time, the aluminum tape 2 or the suture tube 13 tons of chickpeas through the entire installation by means of forces emanating from the collet removable device 16.
    In the production of thick-walled pipes of small diameter, the strain forces during the processing of thick bands are so high that the small cross-section of such a pipe is insufficient to transfer the forces acting in front of the welding zone, i.e., the welding device 9, which can lead to rupture of the pipe. Therefore, the trimmer 4 as well as the first molding section 7 are provided with a drive that provides the metal strip 2 in front of the welding device 9 with advance-forward compensation of force, and the cooling device 14 contributes to the fact that not all of the pipe section is heated by the supplied welding current, since the heating limited to the weld zone.
    FIG. 2 shows a profile projection of a trimmer 4, consisting of two rollers 18 and 19, between which an aluminum tape is passed 2. The roller 18 is provided with two cutting edges 20 and 21, which cut off side strips 22 and 23 from the tape 2, which are wound in a further known manner - Movie 19
    is provided on one side with a V-belt pulley 24. Through the V-belt pulley 24 and the V-belt 25, the roller 19 is driven by an adjustable DC motor 5-5.
    FIG. 3, the edge trimmer 4 is shown in the direction of movement of the metal strip. FIG. 4, the first molding section 7 is also represented in
    0 the direction of movement of the belt 2. These molding section consists of a calibration roller 27 and two support rollers 28 and 29. The calibration roller 27 has, at the ends of the curvature 30 and 31, a radius of curvature
    5 which corresponds to the radius of curvature of the seam pipe 13. The outer lateral surface of the support rollers 28 and 29 is made accordingly concave. Notch 32 in the center of the circumferential surface of the gauge
    0 roller 27 makes it possible to install ray-shaped waveguides 8 in front of the molding device 5. When the metal strip 2 passes through the first molding section, the calibration roller 27
    5 and the support rollers 28 and 29 communicate the required bending to the edge portions 33 and 34 of the metal tape 2. When welding the surface of the cut edges of the metal strip 2, lie parallel to one another, touching all along its length. When using thick metal bands, this optimum position is unattainable. In this case, one resorts to mowing the edges after the tape passes the edge of the cutter (not shown).
    Since the bending of the edge sections 33 and 34 of large-thickness ribbons with a small radius of curvature requires the application of large forces, the sizing roller 27 is driven by an adjustable DC motor 35. The motors 26 and 35 are controlled according to the drive speed of the collet removable device. By adjusting the increased accuracy, the mismatch between the speeds of the drive rollers 18 and 27 and the metal strip 2 is prevented.
    Fig. 5 shows a welding device 9, as well as a cooling device attached to it 14. A welding torch with three consecutive tungsten electrodes 10-12 is used as a welding device. Such an arrangement of the electrodes makes it possible to distribute the large current required for welding the walls of a large thickness onto three electrodes, as a result of which an elongated shape welding bath occurs.
    Next, the pipe 13 enters the water tank 36 provided with a supply pipe 37 for supplying cooling water and an overflow pipe 38 for heated cooling water. The cooling water flowing through the overflow pipe 38 flows into the second cooling water tank 39, from which it returns to tank 36 depending on temperature or flows through the overflow pipe 40. In the cooling water tank cover 36 there is a nozzle 41, to which the pump is connected, creating a slight vacuum over the coolant. Due to this, water-vapor through the inlet 42 is prevented from entering the area of the electrodes 10-12.
    In order to cool the pipe 13, it is necessary that as much of the surface of the pipe as possible comes into contact with the cooling water, however, it must be ensured that the weld does not come into contact with the water. In order to ensure an accurate installation of the cooling water mirror, the tank 36 is adjustable in height, and the overflow pipe 38 is adjustable in height. The cooling water tank 36 is located near the electrode 12 so that the pipe 13 in the area of the electrodes 10-12 is optimally cooled. The water level is set so that at least 60% of the circumferential surface of the pipe 13 is covered by water.
    The electrical conductor consists of a thick-walled pipe 43 connected by a longitudinal weld 44. The pipe 43 is made of aluminum, its wall thickness is 0.8 mm, diameter is 8 mm. Inside the tube 43 are beam waveguides 45, which are located adjacent to the film 46. These film tapes are arranged one above the other and are all twisted together around their longitudinal axis so that during the heating or cooling the beam waveguides can freely expand or contract.
    The invention has great advantages, since there is no danger of overheating of the radiation waveguides 45. In this form of execution, the tube 43 has high mechanical properties, such as compressive strength or tensile strength, and fulfills the task of supplying current to the pulse amplifiers. Pipe 43 may be equipped with armor or a coating of synthetic material. In the coaxial cable, the pipe 43 serves as an inner conductor and can be surrounded by a layer of synthetic material and another metallic outer conductor, the cables are made of almost infinite length and provide a high level of mechanical properties.
    权利要求:
    Claims (7)
    [1]
    1. A method of manufacturing a light guide cable, which is a metal tube with optical fibers located in it, in which the metal tape is continuously wound from a coil, cut off its longitudinal edges,
    0 gradually form a tape in a slotted tube with a hem of the edge sections in the first molding section consisting of molding rollers, light guides are introduced into the open slot of the tube, weld a longitudinal seam on the tube and transport the welded tube with a diverting device that seizes the tube after the welding section through technological Installation, characterized in that, in order to increase
    The quality of the light guide cable, metal tape, is made 1580 mm wide, 0.3-2.5 mm thick, and the preferred ratio between the width and thickness 15-20, which during trimming of the edges during the passage of the first molding section and in front of the welding zone the movement is controlled by an actuator, and the heat-affected zone of the welded pipe is cooled directly behind the welding zone with a liquid, thereby contacting at least 60% of the perimeter of the pipe with the liquid.
    [2]
    2. A method according to claim 1, characterized in that the pipe after welding is subjected to extraction to reduce the diameter.
    [3]
    3. Method according to paragraphs. 1 and 2, I differ in that the edges of the tape are cut after cutting.
    [4]
    4. A device for the manufacture of a 0 light guide cable, consisting of
    metal tape accumulator, trimmer, forming device for forming a pipe from a metal tape, made in the form
    5 several sections, a welding device for welding a longitudinal seam of the pipe, as well as a removable device gripping the pipe after welding the seam, characterized in that the edge-cutting device is made in the form of roller shears, one of the rollers of which is driven by an adjustable DC motor, at least At least the first molding section is made as a multi-roll
    5 tools, at least one of which is driven by an adjustable direct current electric motor, and a coolant tank with a lid and a suction pump is installed behind the welding device, and a nozzle for connecting the suction pump is installed on the tank lid.
    [5]
    5. The device according to any one of claims 4, 4, of that, with the fact that the coolant tank is mounted for movement in a vertical plane.
    [6]
    6. The device according to paragraphs. 4 and 5, that is, with the fact that between the cooling tank. a fluid ring and a removable device are installed.
    [7]
    7. The device according to claim 4, in which the welding device is made in the form of a multielectrode head for welding tungsten electrodes in an inert gas environment.
    39
    Phie, b
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    同族专利:
    公开号 | 公开日
    JP2609300B2|1997-05-14|
    DK590188D0|1988-10-24|
    CA1314016C|1993-03-02|
    EP0313896A1|1989-05-03|
    KR970006326B1|1997-04-25|
    DE3736123A1|1989-05-03|
    FI88468C|1993-05-25|
    KR890006349A|1989-06-13|
    CN1013742B|1991-09-04|
    FI884927A|1989-04-27|
    CN1032758A|1989-05-10|
    FI884927A0|1988-10-25|
    AT69751T|1991-12-15|
    DE3866510D1|1992-01-09|
    DK590188A|1989-04-27|
    ES2028235T3|1992-07-01|
    EP0313896B1|1991-11-27|
    IN169680B|1991-11-30|
    DK167962B1|1994-01-10|
    FI88468B|1993-02-15|
    US4811888A|1989-03-14|
    JPH01122691A|1989-05-15|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    DE19873736123|DE3736123A1|1987-10-26|1987-10-26|METHOD AND DEVICE FOR PRODUCING THICK-WALLED TUBES OF SMALLER DIAMETER|
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