DE3632264A1 - Telescopic rod - Google Patents

Abstract

A telescopic rod having tubes (2, 3, 4) which engage in one another and having an operating device, which is provided on one end of the rod, for making contact with a conductor of a high-voltage power supply network or for coupling to a device, which is to be operated, in such a network has (for longitudinal displacement of the tubes (2, 3, 4) relative to one another) a cable (9) and a drive device (25) which interacts therewith. One cable end is firmly connected to the end section which forms the upper rod end, and the other cable end is firmly connected to the other end section of the same tube (4). The cable (9) is deflected through 180 DEG in the region of the two end sections of the other tube or tubes (2, 3). The drive device is constructed as a cable transportation device (23) which grips the cable (9) passing through it and selectively moves onwards, in a positive manner, in one direction or the opposite direction. <IMAGE>

Description

The invention relates to a telescopic rod, which has the features of the preamble of claim 1.

A known rod of this type (DE-Gm 70 19 955) is as Er training rod. Your intended work at the top device by means of which the conductor to be grounded is contacted is therefore arranged at the free end of a metal tube, the longitudinally displaceable in an electrically insulating tube ge leads is. At the top of the latter tube is one End of a plastic rope attached, which from here to one Deflection roller is guided at the lower end of the metallic tube, thence to a pulley at the top of the insulating Rohres runs and then down on the outside to egg ner is fixed to the insulating pipe winch. A Such a drive system is when the telescopic rod is off  there must be more than two pipes or rods, not usable. In addition, only one can be moved onto the rod to be moved Force in the sense of an extension of the telescopic rod will.

The invention has for its object to a telescopic rod create which for work in the area of high voltage power supply systems, in particular as actuators or Er extension rod, is suitable and free of the disadvantages of the known rod mentioned above. The This task is solved by a telescopic pole with the characteristics of the An saying 1.

The inventive design of the cable drive enables a version of the telescopic rod with more than two raw ren, resulting in a shorter minimum length at a given maximum length leads. This is not just for storage and transport to work is an advantage. This will also, for example, when grounding a high-voltage free cable from the mast crossbeam carrying it from the transport to the Crosshead and the handling of the rod on the crossbar united fold. A shorter minimum length is also advantageous for example for the actuation of a stationary rod Groundings in high-voltage systems, where the telescopic rod with must be coupled to the lower end of the grounding rod. There with such rod groundings both the level of the lower end of the Grounding rod as well as the required displacement very below can be different, with a telescopic rod, the a bigger difference between the minimum and the maximum len length, the number of telescopic poles to be kept ready to reduce. On the other hand, the solution according to the invention does not allow only an inevitable extension of the telescopic rod, but also an inevitable shortening. The latter allows a Stan gene shortening even if the leadership of the mesh the pipes are a bit stiff or if the rod does not ver  tical stands. Then, for example, with rod earthing a pulling force is exerted on the grounding rod, which in many cases len is desired.

In a preferred embodiment with three tubes, this applies middle tube in the other two tubes so that at min length the middle tube within the other two tubes lies. Such a tube arrangement results in a special ders advantageous rope guide.

If necessary, pre-selected on the top of the rod see working device to be able to transmit a torque, it is advantageous to have a telescopic rod formed from three tubes perform according to claim 3. With dimensions according to claim 4 there is a particularly favorable use of space in the cross cut with at the same time sufficient freedom for the leaders rope.

To simplify rope elongation that occurs over time Way, that is without loosening the connection of the rope ends with the rod to be able to compensate has a preferred embodiment tion form of a rope tensioning device according to claim 5. By a plurality of rope pulleys arranged side by side can be the required readjustment length reali with a small footprint sieren. A pivoting of the axis of rotation of a group of Rope pulleys opposite the axis of rotation of the other group according to An saying 6 allows you to easily the rope cause it to snap off the gutter of one pulley exit and enter the groove of the next pulley can.

The cable transport device is preferably according to claim 7 trained because such Maltese cross-shaped rope roll at least largely slip with little effort allow free rope transport in both directions. To Ver To avoid jams, these pulleys are more appropriate driven synchronously via a gear transmission.  

As a rule, one becomes responsible for the actuation of the drive device provide a hand crank. To the crank on the for your Be It is preferable to be able to set the most convenient height a longitudinally adjustable housing containing the transport device bar clamped to the bar. The training is in detail expediently taken according to claims 10 and 11. The User can then adjust the height without tools Loosen the tensioning screw temporarily and after setting the transport device to the desired one Tighten the height again.

In the following the invention with reference to one in the drawing illustrated embodiment explained in detail.

Show it

Fig. 1 is a view of the embodiment with a minimum length,

2 shows a longitudinal section of the exemplary embodiment with only a minimal length, reflecting only the construction principle,

Fig. 3 is a section corresponding to FIG. 2 at the maximum length,

Fig. 4 shows a longitudinal section of the embodiment at minimum length,

Fig. 5 is a section shown on a larger scale according to the line VV of Fig. 4,

Fig. 6 is a section shown on an enlarged scale taken along the line VI-VI of Fig. 4,

Fig. 7 is a section shown on an enlarged scale taken along the line VII-VII of Fig. 4,

Fig. 8 is a section shown on a larger scale on the line VIII-VIII of Fig. 4,

Fig. 9 shows a section through the longitudinal axis of a set of pulleys of the cable tensioning device,

Fig. 10 is a longitudinal section through the other set of pulleys of the cable tensioning device,

Fig. 11 is a section along the line XI-XI in FIG. 1.

An electrically insulating telescopic rod 1 for actuating a stationary grounding rod in a high-voltage power supply system, as shown in particular in FIG. 3, has a lower tube 2 , a middle tube 3 and an upper tube 4 . The latter, which, like the other two tubes, consists of a glass fiber reinforced plastic, carries at its free end, as shown in FIG. 1, a device 5 connected to this coupling device, by means of which the telescopic rod is positively connected both in the longitudinal direction and with respect to rotation its longitudinal axis can be coupled to the earth rod to be actuated.

The upper tube 4 has a circular cross section and is fixedly connected at its lower end to a guide body 6 , which, as shown in FIG. 7, forms a central cross-sectional guide channel, which penetrates the middle tube 3 with little play, which has a corresponding square outer contour, although, as with the guide channel, the corners are rounded. Therefore, although the upper tube 4 and the middle tube 3 are displaceable in their longitudinal direction relative to one another, both tubes are coupled to one another in a rotationally fixed manner.

At the upper end of the middle tube 3 , this is firmly connected to a guide body 7 , which has a circular cylindrical outer surface and lies with little play in the upper tube 4 . The lower end of the middle tube 3 is also fixedly connected to a guide body 8 , which, as shown in FIG. 8, has a quadra-shaped outer contour and is guided so as to be longitudinally displaceable in the square bottom tube 2 with little play.

As shown in Fig. 7 in particular, the outer diameter of the upper tube 4 is smaller than the smallest inner diameter of the lower tube 2 and the inner diameter of the upper tube 4 is larger than the largest outer diameter of the central tube 3 , the differences being so small that the spaces are sufficient to be able to pass a rope 9 which, in the exemplary embodiment, consists of plastic threads which are good electrical insulators.

To improve the management of the lower end of the middle tube res 3 in the lower tube 2 , an additional guide body 10 ( FIG. 4) is fixed on the middle tube 3 at a distance from its lower guide body 8 , which with the required play on the inner surface of the lower tube 2 abuts.

One end of the cable 9 is connected by means of a compression sleeve with the device 5 forming the upper end of the telescopic rod 1 . From here, the rope 9 is guided through the upper tube 4 and the middle tube 3 and its guide body 7 , 8 and 10 through to the lower end of the lower tube 2 , which is firmly connected here to a metallic foot part 11 , which in turn is around the Longitudinal axis of the telescopic rod 1 is rotatably connected to an articulated body 12 , as shown in FIG. 4. This joint body 12 can be mounted on a pivot pin, not shown, in order to be able to pivot the telescopic rod 1 from a horizontal position into a vertical position and back.

The foot part 11 forms (see FIG. 4) a housing for a rope tensioning device which has two groups of rope pulleys 13 and 14 , respectively. In the exemplary embodiment, as shown in FIGS . 9 and 10, all rope pulleys of the same group are formed in one piece. The Ge steering body 12 closer rope pulleys 13 are rotatably mounted on egg NEM fixed in the foot part 11 and transverse to the longitudinal direction of the telescopic rod 1 bearing pin 15 . For the storage of the rope pulleys 14 , a bearing pin 16 is provided which is in a plane which is parallel to the cross-sectional plane of the foot part 11 containing the bearing pin 15 . However, as FIGS. 9 and 10 show, the bearing pin 16 is rotated by an acute angle with respect to the bearing pin 15 . This angle is chosen so large that the rope 9 can emerge from the grooves of the rope pulleys 14 without kinking and can enter the grooves of the associated rope pulley 13 without kinking, although this rope pulley is offset in the axial direction. The bearing pin 16 is mounted in the two legs 17 'of a U-shaped bearing bracket 17 ( Fig. 4 and 10) which is rotatable, but axially immovable with one end of one extending in the longitudinal direction of the telescopic rod 1 , the threaded bolt 18 is connected. The threaded bolt 18 engages in a threaded bore (not shown) of the foot part 11 and can be locked by means of a nut 19 . By means of the threaded bolt 18 , the distance between the cable pulleys 14 from the cable pulleys 13 can therefore be increased for the purpose of cable tensioning.

The through the inside of the tubes 2 , 3 and 4 to the foot part 11 duri fende rope 9 occurs, as shown in Fig. 4, in the rope pulleys 13 and 14 containing space, then runs around the first Seilrol le 13 around, then wraps around first pulley 14 , passes from here to the second pulley 13 , etc., until it leaves the latter pulley and extends outside of the lower tube 2 to the upper end of the sen. There, as shown in FIGS. 2, 3 and 4, it is deflected by 90 ° in such a way that it passes in the space between the lower tube 2 and the upper tube 4 to the guide body 8 provided at the lower end of the middle tube 3 . In this, as shown in FIG. 8, a deflection roller 20 is rotatably mounted, which deflects the rope by 180 °. It then runs inside the middle tube 3 to the arranged at the upper end of the guide body 7 , in which a deflection roll 21 is rotatably mounted ( Fig. 6). After the deflection by the deflecting roller 21 , the cable 9 runs in the space between the middle tube 3 and the upper tube 4 up to the guide body 6 provided at its lower end, with which it is firmly connected.

The outside of the lower tube 2 extending portion of the les 9 is passed through a laterally next to the lower tube 2 angeord Nete rope transport device, the housing 22 arranged in a Ge arranged Maltese cross rope pulleys 23 have. As shown in FIG. 11, three pulleys 23 , three of which are present in the exemplary embodiment, are identically configured and are arranged in a common plane parallel to the longitudinal axis of the telescopic rod in such a way that they mesh with one another in the manner of cogwheels. In order to ensure that all rope pulleys 23 run synchronously, a gear wheel 24 is connected in a rotationally fixed manner to each rope pulley. These identically designed gears 24 are in pairs with each other. As shown in FIG. 11, the rope 9 runs first over the first rope pulley 23 , then between the latter and the second rope pulley 23 . Then it runs over the second, middle rope pulley, then through the gap between this and the third rope pulley, then wraps around the third rope pulley on a part of its circumference and finally exits through an inlet opening of the housing 22 above the outlet opening. A hand crank 25 is coupled in a rotationally fixed manner to one of the three rope pulleys 23 . If desired or required, a lock can be provided which prevents the rope pulleys 23 from rotating in the closed state.

The housing 22 is integrally formed with an unillustrated acquisition, which forms an adapted to the outer profile of the lower tube 2 , U-like receiving channel. A lid 26 , which also closes the housing 22 , can be tensioned against the receptacle me by means of a clamping screw which has a turning handle 27 . The lid 24 forms a clamp that can be pressed onto the lower tube 2 . In order to be able to set the hand crank 26 in the most convenient height for its actuation on the lower tube 2 , only the clamping screw needs to be loosened by turning the rotary fes 27 until the housing 22 , the receptacle and the cover 26 in Let the longitudinal direction of the lower pipe 2 shift. After reaching the desired position, the clamping screw is then tightened again and thereby the Aufnah me and the lid clamped to the lower tube 2 .

Rotation of the hand crank 25 in one direction inevitably causes the telescopic rod 1 to be extended to the maximum length. Turning the hand crank in the opposite direction results in an inevitable shortening of the telescopic rod 1 to the minimum length. If the lower tube 2 of the telescopic rod 1 is rotated about its longitudinal axis, then the upper tube 4 is rotated accordingly.

All mentioned in the above description as well as the only characteristics that can be inferred from the drawing are white tere embodiments of the invention, even if they not particularly emphasized and especially not in the An sayings are mentioned.

Claims (11)

1. Telescopic rod with at least two interlocking pipes, a rope which is deflected at least in the area of one of the at least one pipe by 180 ° and of which one end is firmly connected to one end section of the one pipe, one to the Rope interacting Antriebsvor direction for a longitudinal displacement of the tubes relative to each other and with a provided at one rod end Arbeitsvorrich device for contacting a conductor of a high-voltage power supply network or for coupling with a device to be actuated A device in such a network, characterized in that

• a) that end section of a tube ( 4 ) to which the one rope end is connected, which forms a rod end,
• b) the other end of the rope is firmly connected to the other end section of the same pipe ( 4 ),
• c) the deflection of the rope ( 9 ) by 180 ° in the region of the two end sections of the other or the other tubes ( 2 , 3 ) is provided, and
• d) the drive device is designed as a rope transport device ( 23 ) which detects the rope ( 9 ) passing through it and optionally inevitably moves further in one or the opposite direction.

2. Telescopic rod according to claim 1, characterized in that it has three tubes ( 2 , 3 , 4 ), of which the middle ( 3 ) engages in the other two tubes ( 2 , 4 ). 3. Telescopic rod according to claim 2, characterized in that the working device ( 5 ) carrying tube ( 4 ) has a round, the two other tubes ( 2 , 3 ) each have a rectangular cross section and that the round tube ( 4 ) in the area of its, the middle tube ( 3 ) overlapping end portion with a Füh approximately body ( 6 ) is fixed, which is rotatably, but longitudinally slidably arranged on the middle tube ( 3 ). 4. Telescopic rod according to claim 3, characterized in that the outer diameter of the round tube ( 4 ) is smaller than the smallest inner diameter of that tube ( 2 ) which forms the end of the rod facing away from the working device ( 5 ), and that the inner diameter of the round tube ( 4 ) is larger than the largest outer diameter of the middle tube ( 3 ). 5. Telescopic rod according to one of claims 1 to 4, characterized in that the rope ( 9 ) over a preferably in the working device ( 5 ) facing away from the telescope rod ( 1 ) arranged rope tensioning device ( 13 to 19 ) leads GE, which has two groups of cable pulleys ( 13 , 14 ) which are adjustable in spacing from one another. 6. Telescopic rod according to claim 5, characterized in that the axis of rotation of one group of rope pulleys ( 13 ) is pivoted so far relative to the axis of rotation of the other group of rope pulleys ( 14 ) that the grooves of the rope pulleys aligned on each other ( 13 , 14 ) aligned. 7. Telescopic rod according to one of claims 1 to 6, characterized in that the rope transport device has at least three Malthese cross-shaped rope pulleys ( 23 ) which are arranged in a plane coaxially in the manner of interlocking gears, and that the rope ( 9 ) is between the engaging rope pulleys ( 23 ) leads. 8. Telescopic rod according to claim 7, characterized in that all Maltese cross-shaped rope pulleys are positively synchronized with a gear mechanism ( 24 ). 9. Telescopic rod according to one of claims 1 to 8, characterized in that the drivable transport device is arranged in a housing ( 22 ) by means of a hand crank ( 25 ) which is clamped in a longitudinally adjustable manner on the telescopic rod ( 2 ). 10. Telescopic rod according to claim 9, characterized in that the housing ( 22 ) of the transport device is arranged next to a cross-sectionally U-shaped receptacle of the tube ( 2 ) which forms the end device facing away from the working device ( 5 ), and that this receptacle, together with a cover ( 26 ) which can be clamped against it, forms a clamping channel for the tube ( 2 ) which runs parallel to the part of the cable ( 9 ) entering and exiting from the cable ( 9 ). 11. Telescopic rod according to claim 10, characterized by a clamping handle provided with a handle ( 7 ) for clamping the receptacle and the cover ( 26 ) together.