巴西专利BR112013018733B1 device to recognize the need to dispose of a high strength fiber cable in use in lifting equipment a

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专利摘要:
APPLIANCE TO RECOGNIZE THE STATE OF DISPOSAL OF A FIBER ROPE WITH HIGH RESISTANCE IN USE IN THE LIFTING GEAR. The present invention relates to the lifting gear, such as cranes that use high strength fiber ropes instead of steel ropes. In this regard, the present invention relates in particular to an apparatus for recognizing the disposal status of a high strength fiber rope in use in such a lifting gear which comprises a detection device for detecting at least one parameter of rope as well as it comprises an evaluation unit to evaluate the rope parameter and to provide a discard signal depending on the evaluation of the rope parameter. According to the invention, the detection device of the apparatus for recognizing the state of disposal comprises a plurality of detection means configured differently for the magnetic, mechanical, optical and / or electronic detection of a plurality of different string parameters. which can be assessed by the assessment unit individually and / or in combination with each other to recognize the state of disposal.
公开号:BR112013018733B1
申请号:R112013018733-6
申请日:2012-01-24
公开日:2020-12-08
发明作者:Mupende ILAKA；Horst Zerza
申请人:Liebherr-Components Biberach Gmbh；
IPC主号:

专利说明:

[0001] The present invention relates to lifting equipment such as cranes which use fiber cables with high strength instead of steel cables. In this regard, the invention relates in particular to an apparatus for recognizing the need to dispose of a high strength fiber cable in use in such lifting equipment which comprises a detection device to detect at least one cable parameter as well as comprising an evaluation unit to evaluate the cable parameter and to provide a discard signal depending on the cable parameter evaluation.
[0002] In recent times, tests have been carried out with cranes for the use of high strength fiber cables, made of synthetic fibers such as aramid fibers (HPMA), aramid / carbon fiber mixtures, module polyethylene fibers high (HMPE) or depo-li fibers (pphenylene-2,6-benzobisoxazole) (PBO) instead of the proven steel cables used for several years. The advantage of such high strength fiber cables is their low weight. These high strength fiber cables are considerably lighter than the corresponding steel cables in the same cable diameters and with equal or greater extensible strength. In particular, with tall cranes and consequently with long cable lengths, greater weight reduction is therefore achieved which enters the crane's deadweight load and consequently results in more payloads with an unmodified construction model of the crane.
[0003] However, a disadvantageous property of such high strength fiber cables is their tendency to break or fail without substantially long preliminary signs. While the wear is clearly visible on the steel cables and it signals a failure in advance for a longer period of time, for example, through the breaking of individual steel wires and a corresponding widening which is easily noticed, the cables high strength fibers clearly show any signs of excessive wear, which would be easily noticeable to the naked eye and which would be clearly shown for a longer period of time before the actual failure. In this regard, intelligent monitoring measurements are necessary to recognize the need to dispose of fiber cables with high weather resistance.
[0004] An apparatus is known from DE 199 56 265 B4 for monitoring the operation of hoisting winches on cranes, which monitors the rope force of the hoisting rope and the lever arm of the hoisting rope on the hoisting winch. cable and determines from it the applications of the load acting on the cable winch, which are stored in a load spectrum counter. This load spectrum counter is integrated with the lift winch to keep the lift winch history detectable during removal and reinstallation of the lift winch. In addition, a load spectrum counter is known from EP 0 749 934 A2 which determines the load changes that occur, determines the cable force acting on the hoist at each load change, calculates the spectrum of load from them and calculates and displays the remaining life of the hoist winch while considering the so-called Wohler curves.
[0005] However, such lifting winch monitoring measurements may not reliably provide the remaining life or the need to dispose of a high strength fiber cable as high strength fiber cables are subject to a variety of stretches and weaknesses which influence wear and are independent of winch stretching, for example, deflection and flexing stretches in pulley blocks, external motions and strikes on the cable, contamination on the surface of the components contacting the cable, etc. On the other hand, inflexible life standards for high strength fiber cables are practically incompatible with regard to the economical use of the current service life and the observation of the required safety since the life and wear of the fiber cable with high resistance can fluctuate a lot depending on the conditions of use and external influences on the fiber cable with high resistance.
[0006] Based on this, the underlying objective of the present invention is to provide an improved device to determine the need to dispose of high strength fiber cables, which avoids the disadvantages of the prior art and still develops the latter in an advantageous way . A reliable and accurate determination of the need for disposal should preferably be obtained, which economically uses the remaining life of the fiber cable without putting safety at risk and manages this purpose with simple detection devices which also operate in a manner reliable in difficult-to-use conditions for construction machinery.
[0007] Therefore, according to an advantageous aspect of the present invention, it is not proposed that the determination of the need for disposal be based on only a single criterion, but the opposite, to avoid the problems of early signs that can only be detected with difficulty and in such a way that different relevant parameters of the fiber cable monitor for changes and the need for disposal is determined in a major change of an individual parameter or in a plurality of minor changes of a plurality of parameters. According to the invention, the device detection device for recognizing the need for disposal comprises a plurality of detection means configured differently for the magnetic, mechanical, optical and / or electronic detection of a plurality of cable parameters different, which can be evaluated by the evaluation unit individually and / or in combination with each other to recognize the need for disposal. The use of different cable parameters such as said compressive transverse hardness and transverse change or, alternatively or in addition to this, the elongation of the cable and the magnetic properties of the cable or other mechanical, optical and / or electronic parameters of the cable cable for determining the need for disposal is based on the consideration that depending on the stretch and the effects on the fiber cable, it may be a different parameter in each case, which displays the cable wear or signals the need for disposal or the need for disposal may not be exhibited by a really greater change in just a single parameter, but by the minor changes in a plurality of parameters.
[0008] In a further development of the invention, said evaluation unit is configured in such a way that a discard signal is provided when at least one of the detected cable parameters or its change exceeds / falls below an associated threshold value and also when an indirect cable parameter or its change derived from all detected cable parameters or from a subgroup of the detected cable parameters exceeds / falls below an associated threshold value.
[0009] In a further development of the invention, said evaluation unit is configured in such a way that not only a plurality of cable parameters per se is detected and examined for the respective changes or is compared with the limit values, but the dependencies among the plurality of cable parameters are also taken into account. For example, the permitted changes and / or the permitted limit values for a cable parameter can be changed or changed when a different cable parameter has undergone a predefined change. In particular, more complex phenomena of fatigue or damage can be detected in this way and the need for disposal can be recognized. If, for example, it is considered that an increase in cross compressive hardness is accompanied by a decrease in the cable diameter, the limit value for the cable diameter can be decreased and / or the desired range for the permitted cable diameter can be decreased during the detection of an increase in transversal compressive hardness performed by the evaluation unit. If the measurement then determines that the cable diameter is below the decreased cable diameter limit value and / or has left the desired reduction range, a discard signal can be sent. In a similar, alternative or additional way, other dependencies between the most varied cable parameters can be taken into account by the evaluation unit, for example, the aforementioned dependence between the cable hardness and the cable elongation, for example , in such a way that, at a higher bending hardness, an increasing cable length is expected and is taken into account by the corresponding limit values.
[00010] In this regard, in further development of the invention, different cable parameters can be used. In accordance with yet another aspect of the present invention, it is proposed to monitor a change in compressive transverse hardness or the cross section of the cable and use it as an indicator of the need for disposal. The detection device for detecting changes in the cable may in particular have means for determining the compressive transverse hardness and / or means for determining the transverse compressive hardness or the cross-section of the cable, in which the evaluation unit monitors the hardness compressive cross section or cable cross section determined for changes and provides a discard signal when needed.
[00011] It can be shown in long-term tests carried out on high strength fiber cables that as the stretching and the number of flexion cycles increase, the transversal compressive hardness changes in a characteristic way, in particular, it presents an increase . Therefore, the degree of change in the cross compressive hardness can also be used advantageously to fix the disposal time. In this regard, an increase in cross compressive hardness may be accompanied by a reduction in the diameter of the cable. It can be given to the cable it can be a greater flexural hardness and / or a permanent and measurable cable elongation can occur. A dependence on the change in transverse compressive hardness in relation to the change in cable diameter can be detected in particular, in which in particular, an increase in transverse compressive hardness can be detected in dependence on the diameter of the cable which decreases in size. Alternatively or additionally, a dependence on the change in cable hardness in relation to the change in cable length can be determined, in which in particular, an increase in cable hardness depending on an increase in cable length can be determined. Generally, the discharge signal can be sent in this respect depending on the monitored compressive hardness or on the cable cross section. However, a more accurate determination of the need for disposal can advantageously occur taking into account the different cable parameters.
[00012] Generally, the transversal compressive hardness of the cable can be determined in this respect in several ways. In another advantageous development of the invention, the calculated data of cylinder diameter, cable diameter, cable specification and extensible force can be used as a basis for measurement, or the measurement process can be controlled depending on the said data calculated from the cylinder diameter, the cable diameter, the cable specification and the extensible force, and the corresponding measurement parameters can be defined. The transversal compressive hardness can be realized in particular, while it acts on the cable with the predefined extensible load, in which the predefined extensible load can be advantageously selected in the range of the extensible loads currently present in the operation of the lifting equipment. according to its proposed use. Damage or fatigue phenomena of the cable can best be determined by determining the compressive transverse hardness under an extensible cable load.
[00013] In a further development of the invention, a cable portion or a plurality of cable portions can be activated by a respective predefined transverse force, it can in particular be fixed to determine the transverse compressive hardness at which the diameter change and / or the change in cross-section of the cable is detected or determined, which is adopted under a transverse force. In this respect, with a predefined transverse force, the change in cross section or the diameter that is adopted can be measured and / or alternatively, the transverse force required to obtain a predefined change in cross section and / or diameter can be measured. Alternatively or additionally, varying transverse forces can be applied and the change in cross-section or diameter adopted depending on the variant transverse force can be determined and / or alternatively, the transverse forces required to obtain different section changes transverse or diameter can be measured.
[00014] In another advantageous development of the invention, the cable can be introduced to determine its cross compressive hardness between two mutually opposite clamping jaws, which can advantageously have a cable groove and can be clamped by the clamping jaws such that they are moved towards each other by a suitable adjustment device.
[00015] Generally, in this regard, the cable cross section can be detected in different ways. Advantageously, said transverse cable determination means may comprise diameter detection means for detecting the cable diameter in at least two different planes and for determining the transverse area of the cable from said two determined cable diameters. Such detection of the cable portion or a plurality of cable portions in a plurality of planes can also be provided in determining the transverse compressive hardness mentioned above, for example, such that the respective cable portion is fixed simultaneously or sequentially by a plurality of pairs of clamping jaws, which are positioned associated with each other in different planes. Generally, it would also of course be conceivable to determine or derive the cable cross-sectional area from just one cable diameter, which was determined in one plane. However, advantageously, the cable cross section or the cable cross area is determined from two cable diameters, which were determined in different planes and are approximately perpendicular to each other, since these changes and / or deformations in the cross section, which are not detrimental to the strength of the fiber cable, can be taken into account and premature wear conclusions can be avoided. Highly resistant fiber cables have oval transverse changes under transverse loads as can occur, for example, in the cable rollers or the cable winch, that is, the cross section that is circular per se in the initial state is changed towards the pressed section, which per se is not detrimental to the durability or strength of the fiber cable. However, if the cable cross-section changes in such a way that the cross-sectional area decreases, this is advantageously considered as a sign of incipient wear. In particular, the evaluation device can provide a discard signal when the cable cross section shows a predefined taper or if the reduction in size of the cable cross area exceeds a predefined measure.
[00016] The diameter determination can occur in this respect in different ways. For example, an optical sample made by means of light radiation and an associated sensor to detect the shadow width could be provided. However, in another advantageous development of the invention, mechanical sampling of the cable takes place from the opposite sides to determine the diameter of the cable. At least one pair of elastically pre-loadable clamping means can preferably be provided, preferably in the form of cable cylinders, which can be pressed against the cable or the clamping jaws which have cable grooves to which the control unit Distance measurement is associated to measure the distance between the fastening means in the state applied to the cable.
[00017] In another advantageous development of the invention, the determination of the compressive transverse hardness and the determination of the cable cross-section or the determination of the diameter can be carried out by the same pair of fastening means or the same pair of fastening means in such a way that it is possible to reduce the measurement time and that different fixings can be avoided. For example, a pure determination of diameter or cross section can occur under sufficiently small transverse compression forces, which can then be increased to carry out the transverse compressive hardness measurement.
[00018] In order not to prejudice the determination of diameter due to deviations of the cable, said sampling means can be suspended in a mobile way so that they can participate in the movements of the cable, in particular, in the transversal movements of the cable, in the applied state cable. In particular, the preloadable fastening means mentioned above in the form of cable cylinders can be moved relative to each other, on the other hand, they can be moved together transversely and / or parallel to the longitudinal length of the cable, on the other hand, to be able to determine the cable diameter exactly even with unwanted cable deviations.
[00019] The cable measurement takes place advantageously in at least two planes in order to eliminate the deviations of the cable cross section from the circular shape when determining the cross area. For this purpose, for example, two pairs of cable cylinders or clamps can be provided, which are arranged in planes perpendicular to each other and each being elastically fixed against the other.
[00020] In a further development of the invention, in an alternative or additional way to said compressive transverse hardness or to the transverse area or to the transverse shape, other parameters other than cable can be used. According to a further aspect of the present invention, the change of an indicator section which is incorporated in the fiber cable and which comprises a material different from the cable fibers is advantageously monitored in this regard. The change in fibers or fiber filaments of the fiber cable itself, which can only be detected with too much stretch, can be avoided by means of such an indicator section, which can be incorporated into the core of the filament or which also can be arranged between the fiber strands of the fiber cable, in particular, when the indicator section is selected in terms of its configuration and / or in relation to its material in such a way that the indicator section shows changes more quickly than the fiber filaments of the fiber cable and / or that such changes can be detected more easily. The monitoring of such an indicator section on the fiber cable can also, in this respect, bring special advantages only per se only without monitoring other parameters.
[00021] In particular, the indicator section may comprise a material, preferably a continuous metal section, which influences a magnetic field and / or is magnetically conductive and / or magnetizable. The detection means are advantageously configured in this regard as magnetically operable means, in which in particular, a magnetic field sensor can be provided and by means of which the magnetic properties of said indicator section can be determined. The magnetic properties of the indicator section change in particular, with a disruption of the indicator section in such a way that a corresponding change in the magnetic flux or magnetic field can be easily detected and can be used as a wear indicator. If a break in the magnetically conductive indicator section occurs, it can be recognized by magnetically inductive monitoring or it can be detected by a corresponding break in the magnetic field.
[00022] Alternatively or in addition to such a magnetically operational configuration of the indicator section and associated detection means, changes in said indicator section can also optionally be monitored differently and other monitoring principles can also be used. For example, the indicator section can be configured as an electrically conductive section and the electrical conductivity of the fiber cable or the indicator section provided therein can be monitored using, accordingly, the configured detection means. Alternatively or additionally, the thermal conductivity of said indicator section could also be monitored, in this case, the indicator section is advantageously configured from a material that has good thermal conductivity, for example, from a material made of silver thread.
[00023] Said indicator section which is incorporated in the fiber cable and which comprises a material different from the cable fibers is advantageously configured to be more fragile than the fiber cable in relation to its resistance capacity in relation to the strains - ments, elasticity, tension, bending, torsion, UV radiation, water absorption and / or cable temperature, such that the indicator section fails considerably faster than the fiber cable or its fiber filaments. In this way it is ensured that a change in the indicator section can be determined in time before a fiber cable failure occurs. A break in said indicator section still has no real effect on the strength of the fiber cable itself, however, it can be easily determined and can be detected in time before the cable failure occurs.
[00024] In a further development of the invention, the detection device monitors which portion of the cable the change of cable occurs, which is used to determine the need for disposal and to be able to identify the worn or damaged portion of the cable and optionally to be able to continue using the rest of the cable, for example, so that the damaged part is removed. In a further development of the invention, the detection means for the cable path and / or cable position, which determine the covered cable path or the position of the monitored cable portion for changes, can be associated with the means detection methods mentioned above. Said detection means for the cable path and / or cable position can detect, in particular, a cable winch position, which is present when the cable portion is to be examined for changes, is found exactly on region of the corresponding detection device and is currently being monitored for changes. It is then possible to calculate again, on the evaluation device and from said winch position of the cable, which portion of cable is worn or damaged.
[00025] According to yet another advantageous aspect of the present invention, in an alternative or additional way to said magnetically inductive monitoring of an incorporated indicator section, an elongation of the fiber cable can also be monitored and used to determine the need for disposal. The monitoring of the fiber cable elongation starts from the consideration that an increasing wear or damage to the fiber cable or the approach to the need for disposal is accompanied by an extension of the fiber cable in relation to its original state in such a way. that monitoring of fiber elongation can be used as an indicator of the need for disposal. For this purpose, the detection device may have means for determining the elongation of the fiber cable, in which the evaluation unit compares the elongation determined with a maximum allowable elongation. Once the elongation exceeds a predefined measure, the need for disposal can be indicated.
[00026] In this regard, several procedures can be followed in determining the elongation. In particular, in a first operational mode, the elongation of the cable or the fully charged portion of the cable can be determined and monitored. Alternatively or additionally, in a second operational mode, the elongation of the fiber cable can be examined portion by portion to determine whether and to what extent the predefined portions of the fiber cable have extended.
[00027] According to an advantageous embodiment of the invention, the determination means for determining the elongation may have a position sensor for detecting the position of a predefined cable portion as well as a cable winch position sensor for detecting the position of the winch adopted during the trip to the predefined cable position. Said position sensor can, for example, detect when an upper disconnection point for the load hook is reached and / or when a signal applied to the cable, for example, in the form of a marking, reaches a predefined location on the path the cable. The cable winch position sensor detects the position of the winch cable present at this time or upon reaching said position in such a way that the evaluation unit can determine the elongation of the cable from a change in the adopted winch position. If the winch position deviates too much from a desired position when reaching the predefined position of the predefined point on the cable, the need for disposal can be considered or a disposal signal can be sent.
[00028] Alternatively or additionally, the fiber cable can be equipped with a plurality of signalers distributed along its length, for example, in the form of markings, transponders, signal reflectors or the like, and thus it can be divided into a plurality of portions in length. The determining means for determining the cable elongation determines the distance of two respective flags from which the evaluation unit can determine the length of the corresponding cable portions and can monitor them for changes. If stretching phenomena occur in one or more cable portions which, individually or viewed together, exceed a respective limit value for the permitted stretching, the evaluation unit can send a discard signal.
[00029] In a further development of the invention, said detection device can be configured, in this respect, so that a measuring device, for example, an electronic measuring device, detects the passage or occurrence of said signal at a point along the cable path and measure the distance length to the next beacon with a preferably constant cable speed. Thereby, the cable length can be separated or divided into any desired number of measuring points and any desired cable portions so that the cable stretching stroke can be determined along the total cable length and so that you can be evaluated, in the evaluation device, in which cable section the limit value was obtained and if the cable has to be discarded, if possible, if it has to be discarded shortened by the discard region, that is, by the stretched cable region too much.
[00030] The elongation examination is advantageously carried out under predefined conditions, in particular, on a predefined cable load, for example, by fixing a test load to eliminate any discrepancy in the test results due to varying conditions.
[00031] In accordance with yet another advantageous development of the invention, the load spectrum acting on the cable can also be used to determine the need to dispose of the fiber cable, in particular, the extensible load acting on the cable and flexion cycles acting on the cable. A load spectrum counter can be provided for this purpose which detects at least the tension of the extensible cable and the number of flexing cycles as the load spectrum acting on the fiber cable. The determination and evaluation of said measured data is possible through the determination means or corresponding detection means or sensors whose measured data are processed and evaluated in the evaluation device. The load sensor can detect, in particular, the current stretching of the cable through the operating time of the cable. A rotary encoder on the cable winch cylinder can determine the length of the cable which is stretched to determine bending cycles. The load data and data on the cable path and bending cycles can be crossed on the evaluation device to determine the load spectrum, which can be compared with a maximum allowed and predefined load spectrum. If the maximum permissible load spectrum number is obtained, the evaluation unit can send a corresponding discard signal.
[00032] Generally, it is possible to make use of different analytical approaches in determining the calculation of the load spectra acting on the cable. In this regard, the consideration forms the starting point for drawing a conclusion about different levels of damage based on a calculated accumulation of damage in different load spectra and for storing them in the control system. With a specific preset of load changes, it is then possible to make a conclusion by calculating the damage to the cable that is arising at the moment, in which a limit value can be fixed, which allows an estimate of the need for disposal.
[00033] For example, a counting process can be used in the evaluation of the charge spectra that occur, in which the amplitude of the charges that occur, for example, it can be presented through the sum frequency. Since in the normal case the fiber cable is not only subjected to an equal and always recurring load with a constant amplitude, but it is also subjected to the load that changes in quantity, the load spectrum that results in practice can be divided, by example, or organized in stages in the rectangular and individual spectra with a respective constant charge and a partial charge cycle criterion. For example, according to the method known per se of linear damage accumulation, partial damage can then be calculated for each partial spectrum so that the partial load cycle criterion is divided by the maximum load cycle criterion that can be tolerated. The partial damage of all partial spectra, which results in this way, can be added up and used as an indication of the total damage of the fiber cable. This linear damage accumulation approach can also be modified in a number of ways in a manner that is also known per se, for example, so that partial spectra whose charge amplitudes are below the long-term resistance limit are not taken into account. consideration or are only taken into account in a limited way.
[00034] In a further development of the invention, monitoring of the changes mentioned above in the fiber cable, in particular, the magnetic change of an indicator section, the change in the cable elongation and / or the change in the diameter of the cable can occur through comparing the parameters subsequently detected or determined with the parameters previously detected or determined. The corresponding reference values for the corresponding parameters, in particular the magnetic conductivity or the property of the indicator section, the original cable length or the cross-sectional area of the cable can occur in particular in a reference detection mode with a fiber cable new or not yet damaged, for example, in such a way that the procedures previously described procedures are carried out using a test weight when placing the load during the crane operation and that the parameters determined in this process are stored in a reference value memory. In another operation of the crane or lifting equipment, these parameters are then monitored continuously or cyclically and are compared with the reference values initially stored for them. If one or more of these parameters deviate from the corresponding reference value that exceeds an allowable amount of deviation, the evaluation device can provide a discard signal. Alternatively or additionally, said evaluation device can also provide the discard signal when it is found that none of the said parameters has individually exceeded its value or allowed deviation value of change, but that the parameters have too high a deviation from the sum reference values when viewed in the sum. If, for example, all the parameters determined reach 90% of the permitted deviation from the reference value, each value could still be viewed individually; however, the need for disposal can be indicated since not just one parameter, but all parameters, have almost reached their permitted limits of change.
[00035] The present invention will be explained in more detail below in relation to a preferred modality and the associated drawings, in which:
[00036] Fig. 1 is a schematic representation of the lifting equipment according to the invention in the form of a crane with a rotating tower according to an advantageous embodiment of the invention whose lifting cable and / or whose risers for the articulated boom can be configured as fiber cables;
[00037] Fig. 2 is a schematic representation of a crane with a rotating tower similar to Fig. 1 in a modified mode according to which the lifting cable does not extend over the tip of an articulating boom, but rather, on a mobile pulley along the boom;
[00038] Fig. 3 is a schematic representation of the detection means for the magnetically inductive monitoring of changes in an indicator section incorporated into the fiber cable;
[00039] Fig. 4 is a schematic representation of the detection means for detecting an elongation of the fiber cable; and
[00040] Fig. 5 is a schematic representation of the detection means for detecting transverse changes in the fiber cable.
[00041] Fig. 1 shows, as an example for lifting equipment according to an advantageous embodiment of the invention, a crane in the form of a crane with a rotating tower 20 which rotates on top and whose tower 21 is supported on a car or on a stationary base. The boom 23 is pivotally connected to the tower 21 in an articulating manner around a horizontal geometric axis in a manner known per se and is guided through a tie rod composition 24. Said tie rod composition 24 can have a varying length through a lifter winch 25 such that the operating angle of the boom 23 can be changed. For this purpose, a tie rod 26 extends over said tie rod winch 25. Tie rod 26 or tie rod composition 24 is guided at a pivot point of the boom 23 near the tip of the boom 23, for example, through the pulley blocks 27 on the tie rod 50 shown or at one end of the tower.
[00042] As Fig. 2 shows, the slewing tower crane 20 can also naturally be supplied with a pulley boom. The crane with a rotating tower 20, which rotates in the same way on the top and whose tower 21, which is anchored in the base 22 with ballast, has the boom 23 which is horizontal in the operational position, which is in particular, horizontally aligned and which is guided through the tensioning means with tie rod, for example, in the form of the bars with tie rod 52, at one end of the tower 51, in which the counter-spear 53 with ballast is also guided through the tensioning means tie rod 54 at said end of tower 51. A pulley 55 is movably supported on the aforementioned boom 23, in which said pulley 55 can be moved by means of a pulley cable, for example, which can be guided through the tip of the boom through the pulley blocks.
[00043] The slewing tower crane still comprises the lifting cable 28 which, in the mode illustrated in accordance with Fig. 1, can be lowered from the tip of the boom through the pulley blocks at the tip of the boom and there it it is connected to a crane hook 29 or, in the mode according to Fig. 2, it can extend outwards through said mobile pulley 55 and the pulley blocks provided there, and it can be connected to the crane hook 29 Said lifting cable 27, in both cases, extends over a lifting winch 30 which, like the lifter winch 25 of the modality according to Fig. 1, is disposed in the ballast frame region or in another counterbalance support part 53.
[00044] Said lifting cable 28 and / or the tie 26 can, in this respect, be configured as the fiber cable which can comprise synthetic fibers, such as aramid fibers or a mixture of aramid fiber / fiber carbon.
[00045] In order to monitor or detect the parameters of said fiber cable, those relevant to the need for disposal, a detection device 2 is provided which can be disposed on the crane and which, together with an evaluation device 3 that evaluates the detected parameters, can be connected or integrated to the crane's electronic control unit 31.
[00046] As Figures 3 to 5 show, said detection device 2, in this respect, advantageously comprises different detection means for detecting different parameters of fiber cable 1 in different ways. According to Fig. 3, said detection device 2 can magnetically comprise the operational detection means 2a which detects changes in an indicator section 4 which is incorporated in the fiber cable 1 and which is configured as a magnetically section conductive or influencing a magnetic field or as magnetizable and which can also be incorporated into the cable. For example, said indicator section 4 can be arranged in or between the filament core, in which said indicator section 4 can generally have any desired cross shapes and can advantageously be provided with a round cross section. Said indicator section 4 can in particular be formed from a continuous metallic material such as a wire, in which the indicator section 4 is advantageously constituted so that it is configured with less resistance in relation to cable loads, stretching, tension , bending, torsion, temperature and other relevant properties than the fibers of the fiber cable 1 or the fiber cable 1 itself, so that indicator section 4 fails before a fiber cable 1 failure occurs.
[00047] Said magnetic detection means 2a, which can influence a magnetic field sensor, detect, for example, changes in a magnetic field that acts on said indicator section 4 or that is generated by it. In this regard, a disruption of said indicator section 4 results in particular in changes in said magnetic field 32 such that a conclusion can be drawn from the detection of the corresponding change in characteristic magnetic field in a disruption of indicator section 4 and , in turn, based on the need to dispose of the fiber cable 1.
[00048] In order to be able to determine in which region of the fiber cable 1 the rupture of the indicator section 4 occurs, the cable path measurement can be associated with the detection device 2 or its magnetic detection means 2a and it is carried out by means suitable for detecting the path of the cable 5, for example, so that a rotational position sensor 7 associated with the cable winch, cf. Fig. 4, indicate the rotational position of the cable winch or so that the position sensors 6, cf. Fig. 4, detect sections of cable marked in a specific position in which said magnetic detection means 2a report the defective location. The evaluation device 3 can determine exactly where the defective site has been determined from the known position of the detection means 2a. The length of time required to dispose of fiber cable 1 is advantageously displayed, for example, on the crane control monitor, based on the remaining residual life of the high strength fiber cable. If disposal does not take place within the stipulated time, the crane control unit 31 can automatically disable the crane for safety reasons.
[00049] As shown in Fig. 4, the aforementioned detection device 2 advantageously further comprises the detection means 2b for determining an elongation of the fiber cable 1 that occurs gradually during operation. In this regard, the fiber cable 1 can travel in a specific position, for example, on a direct route to the upper disconnection point at which the load hook 29 has reached the widest possible position and which can be detected, for example. for example, by a limit switch or another position sensor 6. If said position sensor 6 reports to detection means 2b that a predefined cable position has been obtained, the position of the cable winch is detected or determined by a sensor of the winch position of the cable 7. This measurement is first carried out at the first load placement during crane operation. If a different cable winch position is adopted in the last measurements when a predefined and desired position is being traversed, the deviation in the cable cylinder position for travel at the same point on the cable becomes a measure of the elongation of the fiber cable 1 that occurred. The test cycles are preferably carried out using a predefined load on the load hook 29, for example, using a known test load, in such a way that no variant conditions influence the measurement accuracy.
[00050] In this method of detecting cable elongation by measuring the increasing cylinder revolution to the disconnection point, it should be noted that this measurement is an average value of the cable elongation. The length of the cable is dependent on the load and the duration of the load. If the load is moved, for example, elevated, the region of the cable that is not wrapped around the cable cylinder always has the longest and most complete stretch until the load is removed again. The tension of the cable and thus also the stretching of the load, decreases continuously in the region of the cable that is wound on the cylinder. In this way, the cable stretch outside the cable cylinder will extend approximately steadily and will always have the maximum stretch. In the cable that is wound on the cylinder, the existing extensible load decreases continuously since the load of the cable under tension decreases to approximately zero after a few gusts of wind. The allowed elongation limit can be determined in this method using a stretch distribution factor in relation to the total length of the cable to obtain sufficient security when the fiber cable 1 needs to be discarded.
[00051] Another method to test cable elongation in relation to the need for disposal is based on flags 8 or indicators which send signals in an active or inactive manner. These indicators are fixedly integrated into the cable at approximately equal intervals. A measuring device, for example, an electrical / electronic measuring device, for example, in the form of a 6 position sensor, detects the point of the indicator and measures the distance from the length to the next indicator at a constant cable speed. In this way, the cable length can be divided by any desired measurement points and an evaluation is obtained using this method on the extension of the cable stretching along the total cable length and is recognized using a measuring device , in which cable region the limit value was obtained and the cable is discarded or, when possible, is shortened in the discard region, that is, in the cable region too stretched.
[00052] The measuring device is defined at the first load placement during operation. A predefined lifting motion is carried out using, for example, the "cable test" mode. In this regard, travel is carried out at a constant lifting speed from the lowest position of the load hook 29 within the highest position. In this procedure, the distance lengths of said plurality of indicators 8 are detected and stored. In a last time interval, the procedure is repeated after a corresponding period of use and the difference in length difference from the first measurement is calculated and displayed. The measuring device forwards the values to the crane control unit and the memory module; a routing carried out by means of remote data transfer can be done by the crane control unit or the crane operator is notified of the cable status on the crane monitor. When an unauthorized stretch is obtained, a safety mode becomes active and if it is not observed, alerting and system shutdown occur after a period of remaining allowed use. For safety reasons, the system can no longer be put into service if it has been taken out of service. The reason for the suspension is also displayed on the monitor and can also be accessed by remote data transmission.
[00053] As shown in Fig. 5, the detection device 4 can also advantageously comprise the detection means 2c for determining changes in the cable cross section and / or in the compressive cross resistance of the fiber cable 1. advantageously, said detection means 2c detect, for this purpose, the cable diameter or the compressive transverse hardness in at least two planes which, advantageously, can be raised perpendicularly in relation to each other in order to also be able to determine the cross-sectional area of the cable from the plurality of cable diameters with changes in the cross-sectional shape of the cable not harmful per se. This is based on the fact that fiber cables with high resistance 1 tend to become oval in cross section under transverse loads such as in pulley blocks 27 or in cable winches 25 or 30, the so-called ovalization per se does not cause , however, no damage to the resistance cable. However, it becomes critical when the cross-sectional area of the cable decreases.
[00054] In the mode according to Fig. 5, for this purpose, the cable diameters are mechanically arranged in sample and in mutually perpendicular planes using pairs of fixing means in the form of cable cylinders 10, which are pressed against the surface of the fiber cable 1 from opposite sides so that the space between the fastening means in the form of cable rolls 10 is a measure for the corresponding diameter of the cable.
[00055] As shown in Fig. 5, the detection means 2c are supported in a totally transverse manner in the longitudinal direction of the cable in such a way that the transverse movements of the fiber cable 1 have no effect on the measurement result. In the illustrated embodiment, in this respect, the entire apparatus is suspended transversely movable through a pivot frame or a connection with pivot lever 33, cf. Fig. 5.
[00056] Advantageously, the measuring device has at least two rollers in the front region and two rollers in the rear in a plane in which the respective lower roll easily fixes the cable 1 through the springs 34 and thereby detects the diameter the cable. One of these sustained rollers 10 has a axis of rotation and a lever 35 through which the measured diameter of the cable is transferred to a position sensor 36 and is thereby evaluated. The measuring unit also has lateral guide rollers for the cable so that the measuring unit is guided by the cable and so that possible vibrations of the cable do not affect the measured values. The measuring unit is swiveled by a lever on the crane's steel construction to compensate for its movements. The cable measurement takes place advantageously with 90 ° deviation on at least two planes in such a way that the cable diameter is tested in four regions. Another diversion provision, for example, for six regions, is possible. The measurement in 2 - 4 - 6, etc. regions can be provided constructively in a measuring unit or by arranging a plurality of measuring units.
[00057] Another possibility arises through the use of optical testing units, which recognize and evaluate the diameter of the change in the cable in relation to the circumference. In the event of an excess or drop to less than the permitted diameter deviation, a warning signal is provided and the position is stored via the cylinder speed sensor 7.
[00058] In order to also be able to precisely determine the cross compressive hardness using the measuring unit previously shown in accordance with Fig. 5, in a further development of the invention, an adjustment device can be associated with the clamping jaws or the clamping rollers 10 and a force with a variable and / or sufficiently high transverse load on the cable can be generated using this apparatus, that is, the rollers 10 can be pressed transversely against the cable with sufficient force. In that regard, the respective applied transverse force can be advantageously measured by a suitable force measuring device. The cable deformation adopted 1 is measured by the position sensor 36, in which the initially explained changes in force adjustment and / or the transverse deformation can be carried out in one or more measurement cycles.
[00059] If the warning signal is not observed, it is not observed, alert and the system shutdown occurs advantageously after a period of permitted use. For safety reasons, the system can no longer be put into service if it has been taken out of service. The reason for the suspension is also displayed on the monitor and can also be accessed by remote data transmission.
[00060] Furthermore, said detection device 2 can also advantageously comprise the detection means for detecting the load spectrum acting on the respective fiber cable 1, in this case at least the extensible load acting on the cable and the number of bending cycles, but also advantageously other parameters that influence long-term strength such as multilayer winding, environmental influences, temperature, transverse stretches and others, can be advantageously detected here.
[00061] To determine said parameters, said detection means 24 comprise corresponding sensors whose signals occur in said evaluation unit 3. The load sensor can detect in particular the load in progress through the cable's operating time. In addition, a rotary encoder on the respective winch cylinder can measure the length of the cable to which it is stretched. In short, a load spectrum can be determined from this, for example, in the form of a Wohler curve, which can be compared with a maximum allowed and predefined load spectrum for fiber cable 1. If the maximum number of load spectra, which is a specific number of bending cycles under the influence of a specific load and / or specific load peaks, an alert and / or the moment at which the cable change has to occur, is obtained, is displayed.

权利要求:
Claims (17)
[0001]
1. Apparatus to recognize the need to replace a high strength fiber cable (1) in use in lifting equipment, in particular a crane, comprising a detection device (2) to detect at least one cable parameter as well as it comprises an evaluation device (3) to evaluate the cable parameter and to provide a discard signal depending on the evaluation of the cable parameter, characterized by the fact that the detection device (2) comprises a means of detection devices configured differently (2a, 2b, 2c) for the magnetic, mechanical, optical and / or electronic detection of different cable parameters, which can be evaluated by said evaluation device (3) individually and / or in combination one with the other to recognize the need for disposal.
[0002]
2. Apparatus according to claim 1, characterized by the fact that the evaluation device (3) sends a discard signal when at least one of the detected cable parameters or its change exceeds / falls below a well associated limit value such as when an indirect sum parameter or its change derived from some or all of the detected cable parameters exceeds / falls below an associated threshold value.
[0003]
Apparatus according to claim 1 or 2, characterized by the fact that the detection device (2) has means of determining transverse compressive hardness and / or means of transverse determination (2c) for determining transverse compressive hardness and / or transverse area and / or transverse shape of the cable and the evaluation unit (3) evaluates the discard signal depending on the transverse compressive hardness and / or transverse area and / or determined transverse area of the cable.
[0004]
4. Apparatus according to claim 3, characterized by the fact that the evaluation device (3) monitors the cross compressive hardness and / or the cross area and / or the cross shape of the cable for changes and also provides the signal of discard in case of excess of a predefined change and / or compare the transverse compressive hardness and / or the determined transverse area with a predefined limit value for the transverse compressive hardness and / or transverse area and provide the discard signal in case of excess so / drop to less than the limit value.
[0005]
Apparatus according to claim 4, characterized by the fact that the means of determining transverse compressive hardness and / or the means of transverse determination (2c) have as means of detection (9) at least a pair of means of detection elastic pre-loadable fixation, being clamping clamps or cable cylinders (10), which can be pressed against the fiber cable (1) and which are suspended in a movable and transversal way in the longitudinal direction of the cable and the means of distance measurement (36) for measuring the distance between the fixing means.
[0006]
Apparatus according to any one of claims 1 to 5, characterized by the fact that the means of determining transverse compressive hardness (2c) are configured in such a way that the cable (1) can be subjected to the extensible load preset in the determination of transverse compressive hardness, in which the cable (1) under the predetermined extensible load can be activated by a transverse force acting transversely in the longitudinal direction of the cable and the transverse deformation and / or cable deformation diameter (1) arising inside / through the action of the transverse force can be determined.
[0007]
7. Apparatus according to any one of claims 1 to 6, characterized in that the evaluation unit (3) provides the discard signal in the event of the occurrence / excess of a predefined increase in the transversal compressive hardness and / or in case of obtaining / exceeding a predefined transversal compressive hardness limit value.
[0008]
Apparatus according to any one of claims 1 to 7, characterized in that the transverse compressive hardness determination means and / or the transverse determination means (2c) comprise detection means (9) for detecting the compressive hardness transverse and / or the cable diameter in at least two different planes and determines the transverse compressive hardness and / or the transverse cable area from at least two transverse compressive hardnesses and / or determined cable diameters.
[0009]
Apparatus according to any one of claims 1 to 8, characterized in that the detection device (2) comprises detection means (2a) for detecting a change in an indicator section (4) which is incorporated in the fiber cable (1) and comprises a material other than cable fibers.
[0010]
10. Apparatus according to claim 9, characterized in that the detection means (2a) are configured as magnetically operational means, in particular, include a magnetic field sensor and the indicator section (4) comprises a material, being a continuous metallic section that influences a magnetic and / or magnetically conductive and / or magnetizable field.
[0011]
11. Apparatus according to claim 9 or 10, characterized by the fact that the indicator section (4) has a more fragile configuration than the fiber cable (1) and that its cable fibers in relation to its capacity of resistance to cable stretching, stretching, tension, bending, torsion, UV radiation, water and / or temperature absorption such that the indicator section (4) fails, in particular, breaks or tears, before a cable failure fiber (1) occurs.
[0012]
Apparatus according to any one of claims 1 to 11, characterized in that the detection device (2) has detection means (2b) for detecting an elongation of the fiber cable (1) and the evaluation device (3) compares the determined elongation with a maximum allowed elongation and provides the discard signal in case of excess of the maximum allowed elongation.
[0013]
Apparatus according to claim 12, characterized in that the detection means (2b) have a position sensor (6) to detect a predefined point of the cable at a predefined position, in particular, an upper point of disconnection for the load hook, as well as the cable winch position sensor (7) to detect the winch position adopted during the journey to a predefined point of the cable position and the evaluation device (3) monitors the change of the winch position adopted and provides the discard signal when the winch position change exceeds a predefined amount.
[0014]
14. Apparatus according to claim 12 or 13, characterized by the fact that the detection means (2b) have flags (8), for example, in the form of markings, transponders, signal reflectors or similar distributed over the length of the fiber cable (1) to detect elongation in the fiber cable and to have the means of determining the distance between the two respective flags (8) and the evaluation device (3) evaluates the change in the determined distance between the two respective flags (8) and provides the discard signal in case of excess of a predefined distance change.
[0015]
Apparatus according to any one of claims 1 to 14, characterized in that the detection device (2) has a load spectrum counter to detect the load spectrum comprising the extensible cable tension and the number of flexion cycles acting on the fiber cable (1).
[0016]
Apparatus according to any one of claims 1 to 15, characterized in that the detection means (2) have means for detecting the cable path and / or means for detecting the position of the cable (5) to determine the cable sections in which changes in the detected cable parameter occur associated with them and the evaluation device (3), together with the discard signal, provides a cable section signal which indicates which cable section is in a disposal status.
[0017]
17. Crane, in particular a slewing tower crane, a mobile crane, a mobile mooring crane, a ship crane or a vehicle jib crane, characterized by the fact that it has an apparatus as defined in any of the preceding claims .

类似技术:

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同族专利:

公开号 | 公开日

HUE026346T2|2016-05-30|

EP2740705A3|2014-07-30|

RU2562821C2|2015-09-10|

EP2740705A2|2014-06-11|

HUE026347T2|2016-05-30|

EP2740703A3|2014-07-30|

BR112013018733A2|2016-10-25|

ES2526602T3|2015-01-13|

CN105217467A|2016-01-06|

EP2740702A2|2014-06-11|

EP2668127A1|2013-12-04|

HUE026263T2|2016-06-28|

JP5932840B2|2016-06-08|

US20160236913A1|2016-08-18|

PL2668127T3|2015-03-31|

HUE026348T2|2016-05-30|

EP2740703A2|2014-06-11|

EP2740705B1|2015-09-09|

PL2740704T3|2016-01-29|

US9335318B2|2016-05-10|

EP2740702A3|2014-07-30|

ES2555170T3|2015-12-29|

ES2555502T3|2016-01-04|

CN103476697A|2013-12-25|

PL2740703T3|2016-02-29|

CN103476697B|2015-10-21|

EP2740702B1|2015-09-02|

EP2740704A3|2014-07-30|

JP2014503441A|2014-02-13|

ES2554465T3|2015-12-21|

PL2740702T3|2016-01-29|

ES2554466T3|2015-12-21|

RU2013139182A|2015-03-10|

PL2740705T3|2016-02-29|

EP2740704B1|2015-09-02|

EP2740703B1|2015-09-09|

EP2668127B1|2014-10-01|

US10011464B2|2018-07-03|

CN105217467B|2018-11-13|

DE202011001846U1|2012-04-30|

US20140027401A1|2014-01-30|

EP2740704A2|2014-06-11|

WO2012100938A1|2012-08-02|

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法律状态:
2018-12-18| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

2020-01-28| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

2020-06-02| B06A| Patent application procedure suspended [chapter 6.1 patent gazette]|

2020-09-01| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

2020-12-08| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 24/01/2012, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

申请号 | 申请日 | 专利标题

DE202011001846U|DE202011001846U1|2011-01-24|2011-01-24|Device for detecting the Ablegereife a high-strength fiber rope when used on hoists|

DE202011001846.6|2011-01-24|

PCT/EP2012/000311|WO2012100938A1|2011-01-24|2012-01-24|Device for detecting the state of wear of a high-strength fiber rope during use on lifting gear|

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