DE3934654A1 - Break testing of continuous carrier belt - using carrier strands in non-conducting strap interconnected to form continuous conducting body - Google Patents

Abstract

A continuous carrier belt (5) consists of parallel electrically conducting strands (12-12h) which take up strain forces and are enclosed by a non-conducting strap (11). At least one of the carrier strands is so formed w.r.t. the strap at the ends of the belt as to form an electrically conducting connection point. The strands are electrically connected together in pairs at both ends of the belt so that they are connected in series to form a single electrical conductor. USE/ADVANTAGE - Conveyors and lifting machines. Belt is modified to enable continuous breakage monitoring during operation.

Description

The invention relates to a finite shoulder strap with the Features of the preamble of claim 1 and a ver drive to test a finite under load Carrying strap with the features of the generic term of the An Proverbs 5

In numerous conveyors, hoists, handling machines finite carrying straps, for example in the form of  Flat or toothed belts, as train-transmitting machines elements used. Many of these machines are the carrying straps used safety-critical components, because you may fail in the form of a break or through tearing, for example, to drop a valuable cargo or but endanger the operating personnel could.

Conventional finite shoulder straps in the form of flat or Timing belts usually consist of several, essentially Lichen arranged parallel to each other, the tensile forces taking strands that are usually made by one Plastic existing belt body are surrounded. Partially are the mentioned standard flat or toothed belts still provided with a plastic fabric or the like, for example To keep abrasion low. The belt body itself in the form of a Plastic jacket is only used for shaping, in the case of Timing belt especially the shape of the individual teeth. The longitudinal force to be transmitted by the carrying belt becomes full constantly from the strands embedded in the strap taken.

Especially with carrying straps that are within a hoist are arranged so that they are guided over a pulley after a longer period of time and through the associated many rollovers that a Strand after strand breaks. Generally one of the Outside of the strap a higher load sets, which is why the strand next to this edge as first breaks. The next to the middle of the belt The strands then have the entire longitudinal force of the broken one Take over the strand, which leads to the earlier breakage of additional strands leads. This leads to successive tearing or breaking of the individual strands until the strap breaks.  

The complete tearing of a strap and with it connected falling of the load is already from above to avoid reasons explained. But there even with shoulder straps, the outer belt body of one there is a milky transparent plastic, a broken one Litze does not immediately identify as such who the safety-critical carrying strap i. a. either overdim based or exchanged early. Both solutions are, especially because of the associated higher Ko most, unsatisfactory.

From circulating, endless conveyor belts it is known Arrange conductor loops in the belt body and to use, the penetration of foreign bodies in the moving belt display or by triggering a signal the drive switch off the motor, especially for conveyor belts with only in the longitudinal direction wire or Avoid dreaded slits. From the DE-PS 17 56 660 it is also known, for example, in the För the belts of the inserted conductor loops so that an impermissible elastic expansion of the conveyor belt right is recognized early.

The proposal is known from DE-AS 19 40 945, already Conveyor belts in use with electrical conductors retrofit, which in prefabricated, in shape and Molded rubber or molded fittings are embedded from hardened plastic material. The Conductor loops are removed in a correspondingly or cut out part of the top or running layer of the appropriate conveyor belt used and by way of cold vulcanization or gluing connected to the conveyor belt.

Endless funding is available in both of the cited references described tapes with additional conductor loops  be retrofitted, which exclusively the Serve the purpose of acting as signal indicators. This ladder Grinding therefore has no main task. The current through The ability of the additional conductor loops to function preferably by inductive or capacitive means Fixed scanning elements checked because of a galvanic Coupling problematic due to the rotating conveyor belt is.

In the methods known from the prior art So additional components are required, which can be added later Conveyor belts or the like are attached. This is one hand associated with additional costs, on the other hand it is numerous commercially available carrying straps for construction reasons height etc. not possible to add additional conductor loops bring. In addition, the known methods of Disadvantage that the integrity of the load-bearing elements is only checked indirectly. It is extremely difficult the arrangement and dimensioning of the additional conductors Grind to be designed so that a load-bearing strand breaks is reliably recognized. With a conceivable unfortunate one Coincidence of different tolerances can lead to this men that a supporting strand has already broken, though the electrical values of the additional indicators conductor loops are still unchanged. Is a break therefore not always reliably recognizable.

The invention is based on the object, one end Lichen, preferably commercially available shoulder straps so modi that a continuous, safe check for breakage of individual or all load-bearing Stranding is made possible. The invention lies further on based on a method for checking a finite Strap on breakage of individual strands during the To specify the company.  

The problem is solved with a generic, finite shoulder strap described above according to the invention in that at least one of the suspension strands at the two ends of the strap relative to the belt body is that an electrically conductive connection point is created.

A particularly advantageous embodiment of the invention is that at the two ends of the strap Traglitze each electrically connected in pairs are that they are connected in series and a total of one form a single electrical conductor. Regarding the ver driving part of the task is the solution fiction according to the characteristics of the characterizing part of the An given 5.

The particular advantage of the invention is that commercially available flat or toothed belts can be used who only need to be prepared accordingly chen. In this way, it becomes extremely cost-effective Opportunity created, conti nuously and, above all, reliably to break check.

It is also extremely easy to create existing ones Hoists or the like for continuous fracture testing of the tooth or convert flat belts. This is just the one to be installed toothed belts slightly longer than this was the case so far, and then at both ends as it were "stripping". This can be done in pairs ses connecting the strands, whereupon a Test voltage is applied.

The invention will now be described with reference to the drawing explained. Show in the drawing  

Fig. 1 is a schematic representation of a flat belt out with an inventive upgraded linear hoist,

Fig. 2 shows a cross section through an inventive flat belt and

Fig. 3 is a perspective view of a commercially available, according to the invention prepared th flat belt.

The linear hoist shown schematically in FIG. 1 essentially consists of a hydraulic cylinder 2 with a piston rod 3 , which carries a deflection roller 4 . A finite flat belt 5 runs around the deflection roller 4 and is firmly clamped at one end 5 a between two clamping jaws 6 and 7 . At its other end 5 b, the Flachrie men is firmly connected to a carriage 8 which is movable up and down along a guide rail 9 . The Schlit th 8 is moved together with a load 10 lying on it by the piston rod 3 and with it the Umkenk roll 4 by appropriate pressurization of the hydraulic likzylinders 2 is moved. The carriage 8 moves in the vertical direction by twice the distance as the piston rod 3 .

The flat belt 5 is primarily stressed by the weight of the load 10 and the carriage 8 . The tensile forces to be absorbed by the flat belt in hoists that are operated at high speed, for example in production lines or the like, can be a multiple of the weight of the carriage 8 with the load 10 . In the area of the flat belt 5 adjacent to the deflection roller 4 , this is additionally claimed for bending. Since another area of the flat belt comes to rest on the deflecting roller when the hoist is moved, the bending load is an alternating load. As a result of misalignments etc. and the resulting slightly asymmetrical load, this alternating load, that is to say alternating compressive and tensile stresses in the individual strands, often affects one of the outer strands in particular.

In Fig. 2, a flat belt is shown in section. In a belt body 11 made of plastic, eight strands 12 a to 12 h consisting of wire are embedded in the present exemplary embodiment. If there is a break in one of the outer strands 12 a or 12 h as a result of numerous roll-overs of the flat belt, then the strands 12 b and 12 g are at risk. If these breaks are not recognized in time, then - as with a series of dominoes falling over one after the other - there is a successive break in the individual strands until the tensile forces can no longer be transmitted and the load 10 falls. With a drop of the load 10 may be the one of an accident, on the other hand, the load is 10 likely to be damaged or corrupted by their falling down other parts.

In order to be able to recognize a broken wire in good time and to be able to replace the flat or toothed belt in good time, a commercially available flat or toothed belt is prepared, as is shown in perspective in FIG. 3. In the area of the ends 5 a and 5 b of the flat belt 5 , the belt body 11 is stripped, so to speak, so that the load-bearing wire strands 12 a to 12 h are exposed. At the end of 5 b, two wire strands are connected to each other in pairs from the edge, starting from the edge. The electrical connection of two strands can be done in different ways. It is conceivable, for example, a soldering of two strands, a jamming by means of a cable lug, etc. At the other end 5 a of the flat belt, the middle six strands are each connected in pairs, so that there is a series connection of the individual strands one after the other this way form a single electrical conductor. The ends of the outer strands 12 a and 12 h protruding at the stripped end 5 a of the flat belt form the end pieces of this conductor. These end pieces are connected to a test voltage source 13 and an ammeter 14 connected to it. Through the test voltage source 13 , a current is driven through the belt body consisting of the individual strands, which is shown by the ammeter 14 .

If a strand breaks now, the test current is interrupted at the same time, which is indicated by the ammeter 14 . If the entire belt breaks or breaks, it can be replaced and consequential damage avoided.

It is immediately obvious to the average specialist that the ammeter is the worst of all possible over is security devices and only around the schematic cal representation of the principle of invention chosen has been. Instead of the ammeter, of course an electronic circuit can be installed, which at a Interruption of the test current, for example an acoustic signal triggers, automatically stops the operation of the hoist or similar. A short-term interruption can also be used of the test current can be recognized as they are, for example if a strand is already broken, the But temporarily touch the broken ends. Within the electronic circuit can, for example, the series connection  the individual strands in turn with the base resistance of a transistor connected in emitter circuit in series be switched. Then from this emitter circuit diverse other switching stages can be controlled.

As can be seen from Fig. 3, with a finite shoulder strap, which has been prepared according to the invention, each end is given at which the test voltage source must be connected. In a flat belt, which a li nearen hoist - as shown in Fig. 1 - arranged such that one end is moved while the other end ( 5 a) is stationary, one is preferably at the latter end, the connection of the voltage source provide.

Reference symbol list

1 hoist
2 hydraulic cylinders
3 piston rod
4 pulley
5 flat belts
5 a end of 5
5 b end of 5
6 jaws
7 jaw
8 sledges
9 guide rail
10 load
11 belt body
12 a- 12 h strands
13 voltage source
14 ammeter

Claims (7)

1. Finite carrying strap, consisting of several tensile forces absorbing, essentially parallel strands made of an electrically conductive material; and a belt body surrounding the support strands made of an electrically non-conductive material, characterized in that at least one of the support strands ( 12 a - 12 h) at the two ends ( 5 a, 5 b) of the support belt ( 5 ) relative to the belt body ( 11 ) is so formed that an electrically conductive connection point is ent. 2. Carrying strap according to claim 1, that at the two ends ( 5 a, 5 b) of the carrying belt ( 5 ), the strands ( 12 a - 12 h) are each electrically connected to each other so that they are connected in series and overall form a single electrical conductor. 3. Finite shoulder strap according to claim 1 or 2, characterized in that the shoulder strap ( 5 ) consists essentially of a known, commercially available flat belt, which is further processed by the strands ( 12 a- 12 h) by removing the belt body ( 11 ) exposed and, if necessary, connected in pairs. 4. Finite shoulder strap according to claim 1 or 2, characterized in that the shoulder strap ( 5 ) consists essentially of a known, commercially available toothed belt, which is further processed by the strands ( 12 a- 12 h) by removing the belt body ( 11 ) exposed and possibly connected in pairs. 5. A method for testing a finite support belt under load with the features of the preamble of claim 1 for breakage of at least one strand, characterized in that at least one of the strands ( 12 a- 12 h) at the two ends ( 5 a, 5 b) of the support belt ( 5 ) is removed by removing the belt body ( 11 ), that a test voltage is applied to the two exposed ends of the strand, that the electrical current generated by the test voltage in the strand is detected by a corresponding circuit, and that the possible interruption of this current is detected by suitable means. 6. A method for testing a finite support belt under load with the features of the preamble of claim 1 for breakage of at least one strand, characterized in that the strands ( 12 a- 12 h) at the two ends ( 5 a, 5 b ) of the support belt ( 5 ) by removing the belt body ( 11 ) that the support strands ( 12 a - 12 h) are electrically connected in pairs so that they are connected in series and form a single electrical conductor the two ends ( 12 a, 12 h) of the resulting electrical conductor, a test voltage is applied, that the electrical current generated by the test voltage in the conductor is detected by a corresponding circuit, and that the possible interruption of this current by suitable Means is detected. 7. The method according to claim 6, characterized in that the circuit is a machine in which the trolley to be tested men as a machine element, when interrupted the electricity turns off.