DE1481709C3 - Pressing device for the tensile loading of traction means - Google Patents

Description

The invention relates to a measuring device for the tensile load of traction means, in particular of conveyor ropes for shaft hoisting systems, with an essentially hollow cylindrical, radially compressible, along a surface line in its entire length slotted measuring body in one at the end of the traction mechanism provided intermediate harness is installed, the between a middle plate (first plate group) and two outer plates (second plate group) clamped is and the inner bore is filled with a cylindrical filler, the slot width as Measure for the tension means load on a length measuring device, preferably a dial gauge, can be read off

Measuring devices of the type described above are used where the load a traction device, such as. B. a rope or a chain, possibly also the load on a lever or a tab connection, is to be measured during operation. Have a special meaning Such measuring devices in shaft hoisting systems, especially in multi-rope hoisting systems, those due to the advancement of mining into greater depths and with a view to the endeavor to achieve greater depths To lift loads per conveying stroke are used to an increasing extent. This is the case with certain types of intermediate harness of multi-rope conveyor systems useful, measuring devices for the tensile load of individual Provide hoisting ropes in order to continuously monitor the load distribution on the individual hoisting ropes to enable. This measure prevents any uneven load distribution that may occur on the conveyor ropes detected in good time and can therefore - for example by shortening the ropes or by adjusting the length of the intermediate harness - can be corrected.

A known type of measuring device of the type presupposed at the beginning (DT-PS 8 30 422) has one of the shape of a pair of pliers approximated ring body, which is slotted between a central tab and two Outer tabs of an intermediate harness under

additional top and bottom support clamped on fitting pieces and pan-shaped counter bearings is. The support on the pan-shaped counter-bearings takes place on the outside of the ring body arranged, diametrically opposite upper and lower cutting edges. The ring body is on one long side is flattened and slotted over the entire length in the middle height area. Above and below the slot are radially or horizontally from the jaws delimiting this slot Tongues protrude, which on the one hand for receiving, for example, a dial gauge and on the other hand as a counter bearing serve for the dial gauge. The slot width is used as a factor in determining the size of the rope load.

However, this known type of measuring device is tied to several requirements. It is necessary, that the outer tabs and the center tab must be slotted so that on the one hand the measuring body and on the other hand, the fitting pieces and the pan-shaped counter bearings can be accommodated. the axial alignment of the fitting pieces, the pan-shaped counter bearing and the measuring body leads to a considerable increase in the total length of the intermediate harness. In terms of practice, it should be move this by an amount of about one meter. This great length in the direction of the traction means has in particular then result in a significant disadvantage if an existing conveyor system for an intermediate harness shorter design is designed. In this case, a longer intermediate harness cannot easily be used to be used. It is no longer possible to maintain the safety distance prescribed by the mining authorities to be observed between the rope binding and the sheave when the conveyor cage or the conveying vessel the has reached the highest operating position This means that the subsequent installation of such a long intermediate harness - Due to the considerable axial expansion of the known measuring devices - not more is possible. Consequently, the known measuring device can no longer be retrofitted to such Shaft hoisting systems can be installed. But also with newly erected shaft hoisting systems where the known measuring device is to be used, its installation is associated with disadvantages. With regard to on the required longer intermediate gear, it is then necessary to move the headframe by at least to be measured one meter higher than if a conventional, shorter intermediate harness is to be used. the Raising a headframe by one meter means a considerable increase in manufacturing costs and in terms of material.

The invention is based on the object of providing a measuring device of the type described at the beginning that can be integrated directly into intermediate harnesses of the usual length without any additional structural effort can.

According to the invention, this object is achieved in that the measuring body as a cylindrical joint and Coupling sleeve formed and in a common, perpendicular to the main load direction of the traction device extending bore of the outer plates and the central plate is mounted that at least one of the two groups of tabs forms an intermediate harness section and that the filler piece consists of a joint and coupling sleeve over the entire axial length with play penetrating the two outer plates interconnecting bolts consists.

With the design of the measuring body according to the invention, a structurally simple element has been created, which is therefore not tied to a specific design of an intermediate harness. Much more it is now possible wherever there is an articulated connection between parts of the intermediate harness or is present between the intermediate harness and the rope binding or the conveyed goods carrier, in place this articulated connection to use the measuring body according to the invention. In view of this broad-based The measuring body takes on two functions in a relatively small space, namely a connection and a measurement function. That means, on the one hand, it ensures the articulated connection of the Outer plates with the middle plate and serves on the other hand to measure the rope load. Due to the Spatially limited combination of different functions is the total effort for the inventive Measuring device significantly less than the cost of the known measuring devices. from It is particularly important that long intermediate harnesses no longer need to be used. Furthermore, there is the advantage with the design according to the invention that when new multi-rope shaft conveyor systems are to be created the headframe is at least one meter lower than when using the known Measuring devices are designeditajin.

In the context of the embodiment of the invention, it is in a measuring device for the tensile load of Ropes, it is conceivable that a group of tabs is (are) the retaining tab (s) of the rope binding. It can also with a measuring device for conveyor systems be advantageous that a group of tabs the retaining tab (s) of the Conveyed goods carrier is (are).

It is also advantageous that the measuring body in the common bore of the tabs in bearing bushes is mounted from a plain bearing material. Such a plain bearing material can be bronze, gunmetal, brass or be sintered metal. By such a storage of the measuring body is achieved that between his Surface and the tabs only have a low frictional force, which is not subject to any significant torsional stress of the measuring body. This has the further advantage that the measurement result does not go through Torsional stresses on the measuring body can be falsified.

As a rule, it is recommended that the axial length of the measuring body is slightly larger than the Total thickness of the interconnected tabs is dimensioned and that the measuring body mitteis to the Axle holder attached to the outer tabs is held in the hole. that the measuring device can not rotate within the bore of the tabs, so that at any time perfect reading of the measuring device, for example designed as a dial gauge, is possible.

In this context, a further advantageous embodiment of the invention is characterized in that that on an end face of the measuring body in the region of the slot immediately above and below the same one approach is attached, one of which as a holder for a length measuring device and the other as Stop is designed for this measuring device. The approaches can be detachable or non-detachable on the end face be attached to the measuring body.

According to a further embodiment of the invention, it can also be recommended that the bolt on an end section has a disk-like head with a larger outer diameter than the measuring body

sits and that the bolt head has a recess in the area of the lugs of the measuring body through which the approaches protrude through to the outside. In this context, it is also advantageous that the bolt has an external thread on its end section facing away from the bolt head for receiving a Has nut which has a retaining washer designed in a manner similar to that of the bolt head against the outer surface on the outer flap.

The arrangement of the bolt is an additional safeguard, since the measuring body is already in the The situation is, under normal stress, the forces that occur from the outer link plates to the center link plate or to transfer the other way around. If, however, the measuring body breaks under extreme loads come, the bolt takes over the transmission of the forces in place of the measuring body. pers. A falling out of the bolt from the inner bore of the measuring body is not possible because the nut is expediently also secured with a split pin.

In a further embodiment of the invention, both the disk-like bolt head and the retaining disk have one recess each into which the end sections protruding beyond the outer surface of the outer plates engage the measuring body.

Furthermore, it can be recommended that both the disk-like bolt head and thus the bolt itself as well as the retaining disk are secured against rotation by the axle brackets.

According to another advantageous embodiment of the invention is on the disk-like bolt head Protective cover for the measuring device attached. Such a, preferably releasably attached protective hood protects the Measuring device against mechanical damage, dirt, and when closed, in the area of the scale transparent protective hood also against moisture.

Finally, it can be advantageous that the measuring body has a length which is approximately its outer diameter is equivalent to.

The invention is described in more detail below with reference to an exemplary embodiment shown in the drawings illustrated. It shows

F i g. 1 the measuring body within the hole in the tabs,

F i g. 2 the measuring body in a perspective view,

F i g. 3 the built-in measuring device in side view,

F i g. 4 the built-in measuring device partially in section.

In Fig. 1, 1 denotes an end section of an outer plate of an intermediate harness, behind which - in FIG. 1 cannot be seen - a second, identically designed end section of an outer plate 1 a is arranged at a small distance from the first. Between the two outer plates 1 and 1 a, a middle plate 2 is provided, the thickness of which corresponds to the distance between the two outer plates 1 and Xa. In a bore drilled through the outer plates 1 and 1 a and through the middle plate 2, a measuring body 4 is mounted, which is essentially annular or sleeve-shaped and has a slot 5 on the side along its entire axial length. The longitudinal slot 5 of the measuring body 4 is shown above all in FIG. 2 clearly visible. In contrast to the representation in this figure, the measuring body 4 is usually designed as a longitudinally slotted sleeve with an axial length corresponding approximately to its outer diameter. In addition, in FIG. 1 and 2 the eccentric arrangement of the inner bore denoted by 6 can be seen, which results in a favorable stress distribution when the measuring body 4 is subjected to pressure and enables the smallest possible diameter of the measuring body. The inner bore 6 also extends over the entire axial length of the measuring body 4. The end faces of the measuring body 4 each have a gradation 7 in the form of a segment of a circle, the deeper subsections of the end faces being arranged so that the axial distance between the two lower end face sections of the Graduations 7 approximately equal to the total thickness of the outer plates 1 and 1 a and the middle plate 2 is dimensioned.

In the F i g. 3 and 4 the measuring device is shown in the assembled state. The arrangement of the The measuring body 4 within the bore of the outer or middle tab is shown in particular in FIG. 4 clearly too recognize. In the bore 6 of the measuring body 4, a bolt 8 is arranged with sufficient play, the one has a greater axial length than the measuring body 4. The bolt 8 has one at one end portion disk-like bolt head 9, which is formed in one piece with the other parts of the bolt 8. The BoI-zenkopf 9 has a larger outer diameter than the measuring body 4 and has a recess 10 in which is the end portion of the measuring body protruding by a small amount beyond the outer surface of the outer plate 1 4 intervenes. The bolt 8 has an external thread on its end section facing away from the bolt head 9 11, which serves to receive a nut 12, which is designed in a manner similar to that of the bolt head 9 Retaining disk 13 both against the bolt shank and against the outer surface of the outer plate la presses. The nut 12 is designed as a castle nut and is secured by a split pin 14. the Measuring body 4 also protrudes a small amount over the outer surface of the outer plate la and engages in the same way In the same way as on the opposite end section, it enters a recess 10a in the holding disk 13. As in particular in FIG. 4, the measuring body is in the common bore of the tabs 1, 1 a and 2 in bearing bushes 15 made of a plain bearing material, such as ζ. Β. Bronze, gunmetal, brass or sintered metal, stored. Of course, the use of other plain bearing materials, such as. B. plastic, possible.

On the outer plates 1 and la axle holders 16 are arranged by means of axle holder screws 17, which are inserted into the frontal gradation 7 of the measuring body 4 and in a corresponding recess of the bolt head 9 or the retaining disk 13 engage. Thus, both the disk-like bolt head 9 and thus the bolt 8 are itself as well as the retaining disk 13 secured against rotation by the axle holder 16.

The disk-like bolt head 9 has a recess 18 in the region of the longitudinal slot 5 of the measuring body 4. The recess 18 is dimensioned so that on the disk-like bolt head 9 facing The end face of the measuring body 4 is one shoulder 19 each immediately above and below the slot 5 and 20 can be releasably attached, of which the extension 19 is used as a holder for a measuring device 21, for example a dial gauge, and the other approach 20 is designed as a stop for this measuring device 21. Both approaches 19 and 20 protrude through the recess 18 of the disk-like head 9 to the outside. To the

disk-like bolt head 9, a protective hood 22 for the measuring device is detachably attached by means of screws.

When the traction means, not shown, is loaded, the outer plates 1 and la are opposite to the Center plate 2 loaded in opposite directions. As a result, the measuring body 4 is subjected to pressure, with the result that the width of the slot 5 is reduced in a corresponding manner. the A reduction in the width of the slot also causes the stops 19 and 20 to overlap by the same amount to be moved, the change in distance being displayed by the measuring device 21. The amount of change in distance is also a measure of the load on the traction device, e.g. B. hoisting rope. Before the Use of the measuring device is the measuring body with respect to its resilient deformation under load tested on a testing machine. Here, the measuring body is subjected to several different large compressive forces loaded, which can be precisely adjusted on the testing machine. The resulting from the individual loads Slit widths of the measuring body are measured and the measurement results are dependent on the respective Load recorded as a calibration curve. If such a calibration curve is available for the measuring device With the help of the dial gauge display determined during operation, the effective Load on the traction device, e.g. B. a hoisting rope can be determined. However, it is also perfectly possible to Instead of making a calibration curve, the scale of the measuring device 21 - for example a dial gauge - directly in a unit of force, such as B. Kilopond or Megapond, to be calibrated. In this case it is possible to change the respective The tensile load of the traction device can be read off directly on the measuring device 21.

For this purpose 2 sheets of drawings

609 617/10

Claims (12)

Patent claims: 1. Measuring device for the tensile load of traction means, in particular of hoisting ropes for shaft hoisting systems, with an essentially hollow cylindrical one that can be subjected to radial compression and is slotted along a surface line over its entire length Measuring body, which is installed in an intermediate harness provided at the end of the traction mechanism, which zwisehen a middle plate (first plate group) and two outer plates (second plate group) clamped is and the inner bore is filled with a cylindrical filler, the Slot width as a measure of the tensile load on a length measuring device, preferably a dial gauge, can be read, characterized in that the measuring body (4) as a cylindrical joint and Coupling sleeve formed and in a common, perpendicular to the main load direction of the Pulling means running bore of the outer plates (1, la) and the middle plate (2) is mounted, that at least one of the two groups of tabs (1, la and 2) forms an intermediate harness section, and that the filler piece consists of a joint and coupling sleeve over the entire axial length with play penetrating, the two outer plates (1, la) connecting bolts (8). 2. Measuring device according to claim 1 for the tensile load of ropes, characterized in that a group of tabs (1, 1a or 2) is (are) the retaining tab (s) of the rope binding. 3. Measuring device according to claim 1 for conveyor systems, characterized in that a group of tabs (1, la or 2) the retaining strap (s) of the conveyed goods carrier is (are). 4. Measuring device according to claim 1 or one of the following, characterized in that the Measuring body (4) in the common bore of the tabs (1, la, 2) in bearing bushes (15) from one Plain bearing material is stored. 5. Measuring device according to claim 1 or one of the following, characterized in that the axial length of the measuring body (4) by a small amount greater than the total thickness of each other connected straps (1, la, 2) is dimensioned and that the measuring body (4) by means of the outer straps (1, la) attached axle holder (16) is held in the bore. 6. Measuring device according to claim 1 or one of the following, characterized in that on an end face of the measuring body (4) in the region of the slot (5) immediately above and below the same one approach (19, 20) is attached, one of which (19) as a holder for a length measuring device (21) and the other (20) is designed as a stop for this measuring device (21). 7. Measuring device according to claim 1 or one of the following, characterized in that the Bolt (8) at one end section has a disk-like head (9) with a larger outer diameter than the measuring body (4) and that the bolt head (9) in the area of the lugs (19, 20) of the measuring body (4) has a recess (18) through which the lugs (19, 20) protrude to the outside. 8. Measuring device according to claim 7, characterized in that the bolt (8) at its dem The end section facing away from the bolt head (9) has an external thread (11) for receiving a nut (12) possesses, which is designed in a manner similar to the bolt head (9) retaining washer (13) against the Press the outer surface of the outer flap (la). 9. Measuring device according to claim 7 or 8, characterized in that both the disk-like Bolt head (9) as well as the retaining washer (13) each have an external rotation (10) in which the over engage the outer surface of the outer tabs (1, la) protruding end portions of the measuring body (4). 10. Measuring device according to claim 9, characterized in that both the disk-like bolt head (9) and thus the bolt (8) itself and the retaining washer (13) from the axle holders (16) against Rotation are secured. 11. Measuring device according to claim 7 or one the following, characterized in that a protective hood on the disk-like bolt head (9) (22) is attached to the measuring device (21). 12. Measuring device according to claim 1 or one of the following, characterized in that the> » Measuring body (4) has a length which corresponds approximately to its w outer diameter.