WO2017033517A1 - ロープの劣化検出装置およびロープの劣化検出装置を備えたエレベータ装置 - Google Patents
ロープの劣化検出装置およびロープの劣化検出装置を備えたエレベータ装置 Download PDFInfo
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- WO2017033517A1 WO2017033517A1 PCT/JP2016/065916 JP2016065916W WO2017033517A1 WO 2017033517 A1 WO2017033517 A1 WO 2017033517A1 JP 2016065916 W JP2016065916 W JP 2016065916W WO 2017033517 A1 WO2017033517 A1 WO 2017033517A1
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- deterioration
- rope
- bending
- reaction force
- deflection
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B66—HOISTING; LIFTING; HAULING
- B66B—ELEVATORS; ESCALATORS OR MOVING WALKWAYS
- B66B7/00—Other common features of elevators
- B66B7/12—Checking, lubricating, or cleaning means for ropes, cables or guides
- B66B7/1207—Checking means
- B66B7/1215—Checking means specially adapted for ropes or cables
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N3/00—Investigating strength properties of solid materials by application of mechanical stress
- G01N3/20—Investigating strength properties of solid materials by application of mechanical stress by applying steady bending forces
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N2203/00—Investigating strength properties of solid materials by application of mechanical stress
- G01N2203/02—Details not specific for a particular testing method
- G01N2203/026—Specifications of the specimen
- G01N2203/0262—Shape of the specimen
- G01N2203/0278—Thin specimens
- G01N2203/028—One dimensional, e.g. filaments, wires, ropes or cables
Definitions
- the present invention relates to a rope deterioration detection device for detecting a rope deterioration state in a stage before the wire breakage and an elevator apparatus equipped with the rope deterioration detection device.
- the former visual visual inspection is a method in which an operator visually inspects surface wear, wire breakage, and the like.
- this method takes an enormous amount of time and cannot determine the internal state.
- the latter diameter measurement is a method for estimating the deterioration of the core and the internal wear state between the strands from the measurement result of the diameter.
- this method since the surface of the wire rope is uneven, the measurement variation is large, and if the operator's skill level is insufficient, the error is further increased, so that it is difficult to accurately inspect.
- a magnetic flaw detector has been used as a non-destructive inspection method that is not a human method.
- This magnetic flaw detector observes leakage magnetic flux by magnetizing a wire rope. Thereby, the damage which produces a leakage magnetic flux, ie, the strand break inside and outside a rope, can be detected (for example, refer patent document 1).
- the conventional techniques have the following problems.
- the wire rope undergoes deterioration such as a decrease in the oil content and internal wear between the strands.
- these events do not produce leakage flux. Therefore, the technique according to Patent Document 1 has a problem that deterioration cannot be detected until the wire breaks.
- the present invention has been made to solve the above-described problems, and can accurately detect the decrease in the oil content and the internal wear between the strands, which are deterioration before the strand breaks.
- An object of the present invention is to obtain a rope deterioration detecting device and an elevator device equipped with a rope deterioration detecting device.
- the wire rope deterioration detection device includes a pair of support portions that support the rope to bend the rope, and a bend imparting portion that imparts a bend to the rope supported by the pair of support portions.
- a tension adjusting unit for adjusting the tension of the rope
- a reaction force acquiring unit for acquiring a reaction force in a state where the bending is applied by the bending applying unit, and a deflection amount in a state where the bending is applied by the bending applying unit.
- a deflection acquisition unit, a reaction force acquisition unit, and a deterioration determination unit that calculates a deterioration determination parameter from the relationship between the reaction force and the amount of deflection acquired by the deflection acquisition unit and determines the deterioration state of the rope.
- the rope is a rope constituting the elevator apparatus
- the support part is a pulley or a shackle constituting the elevator apparatus
- the bending imparting part is It is provided between pulleys or shackles.
- the deterioration determination parameter is calculated from the hysteresis loop of the reaction force-deflection relationship obtained by bending the rope, thereby reducing the elemental content due to the decrease in the oil content and the internal wear between the strands. It has a configuration that can detect the deterioration state that occurs before the line breaks.
- a wire rope deterioration detecting device and an elevator equipped with a rope deterioration detecting device capable of accurately detecting the decrease in oil content and the internal wear between the wires, which are deterioration before the wire breaks. A device can be obtained.
- FIG. 5 is a diagram showing a reaction force-deflection relationship 1 acquired by a reaction force-deflection relationship acquisition unit 6 according to Embodiment 1 of the present invention. 5 is a graph showing a change in reaction force-deflection relationship accompanying the progress of rope deterioration in Embodiment 1 of the present invention.
- 6 is a graph showing a reaction force-deflection relationship 2 when bending is applied up to an upper limit deflection amount X with respect to a rope of a degradation reference product in Embodiment 1 of the present invention. It is a flowchart showing the specific procedure of the deterioration diagnosis in Embodiment 1 of this invention. 6 is a graph showing a reaction force-deflection relationship 3 when bending is applied up to an upper limit deflection amount X with respect to a rope to be deteriorated in the first embodiment of the present invention.
- Embodiment 5 is a graph showing a difference in hysteresis loop between a reaction force-deflection relationship of a healthy rope and a reaction force-deflection relationship of a deteriorated reference rope according to Embodiment 1 of the present invention.
- Embodiment 1 of this invention it is the graph which normalized the maximum reaction force as 1 with respect to the hysteresis loop of FIG.
- It is a graph showing the difference of the area of the normalized hysteresis loop in Embodiment 2 of this invention.
- 10 is a graph showing the relationship between the inflection point of the reaction force-deflection relationship and the upper limit deflection amount X in Embodiment 3 of the present invention.
- FIG. FIG. 1 is a configuration diagram of a wire rope deterioration detection apparatus according to Embodiment 1 of the present invention.
- the rope 1 is provided with a support portion 2a and a support portion 2b that support the rope at both ends of the diagnosis target range.
- the bending provision part 3 which provides a bending with respect to the rope 1 supported by the support part 2a and the support part 2b is provided in the intermediate point of the support part 2a and the support part 2b.
- the tension adjusting unit 4 is provided at an arbitrary position outside the diagnosis target range. In FIG. 1, the case where the tension adjustment part 4 is provided above the support part 2a is illustrated.
- a diagnostic unit 5 which receives as input the reaction force and deflection amount generated in the bending imparting unit 3.
- the diagnosis unit 5 includes a reaction force-deflection relationship acquisition unit 6, an upper limit deflection amount storage unit 7, a deterioration reference product information storage unit 8, and a deterioration determination unit 9 that determines a deterioration state.
- the reaction force-deflection relationship acquisition unit 6 acquires the reaction force and deflection generated by the bending imparting unit 3 as input.
- the upper limit deflection amount storage unit 7 stores an upper limit value of the deflection given to the rope 1.
- the deterioration reference product information storage unit 8 stores a deterioration reference.
- the deterioration determination unit 9 performs a process of calculating a parameter serving as an indicator of the deterioration state using the reaction force and deflection acquired by the reaction force-deflection relationship acquisition unit, and is stored in the deterioration reference product information storage unit 8.
- a deterioration criterion is used to determine the state of deterioration.
- FIG. 2 is a flowchart showing a flow of rope deterioration diagnosis using the wire rope deterioration detection apparatus in Embodiment 1 of the present invention.
- step S201 which is a process for obtaining a deterioration criterion before the operation of the rope
- step S202 which is a process for diagnosing deterioration by comparing the deterioration criterion with the result measured by the actual machine during the operation of the rope
- S203 is included.
- step S201 the degradation detection device prepares a degradation standard product rope and acquires a degradation criterion.
- the deterioration reference product is a rope that has reached a deterioration state to be detected.
- the procedure for acquiring the deterioration criterion will be described later with reference to the flowchart of FIG.
- step S202 and step S203 the deterioration detection device periodically performs a wire rope deterioration diagnosis in a period determined according to the rope usage method. The procedure of deterioration diagnosis will be described later using the flowchart of FIG.
- step S204 the deterioration detection device continues using the rope if it is determined that the rope 1 is in a healthy state, and performs rope replacement if it is determined that the rope exceeds the deterioration standard.
- FIG. 3 is a flowchart showing a specific procedure for acquiring the degradation criterion in the first embodiment of the present invention.
- step S301 a rope having the same configuration as that of the diagnosis target rope and in the state of the deterioration determination criterion is prepared as a deterioration reference product.
- the wire rope deterioration detection apparatus shown in FIG. 1 is applied to the deterioration reference product.
- the tension is adjusted by the tension adjusting unit 4 so that the rope tension becomes a predetermined measurement tension.
- FIG. 4 is a diagram showing the reaction force-deflection relationship 1 acquired by the reaction force-deflection relationship acquisition unit 6 according to Embodiment 1 of the present invention.
- Reaction force-deflection relationship 1 can be obtained by applying a bend to the degradation standard product so that the change in the inclination caused by the complete slippage of the internal strands can be detected, and then removing the load. Reaction force-deflection relationship.
- a straight line portion 1 indicated by a range A is a range in which the internal strands do not slip each other
- a straight line portion 2 indicated by a range C is a range in which the internal strands completely slip
- the inflection part shown by the range B is a transition area where the part where internal strands do not slip and the part which slides are mixed.
- the object of wire rope deterioration detection in the first embodiment of the present invention is a decrease in oil content and internal wear between strands.
- the oil content decreases, the friction coefficient inside the rope increases, and the frictional force against bending increases.
- the contact state which is a point contact, shifts to a surface contact, and the frictional resistance due to bending increases.
- FIG. 5 is a graph showing a change in the reaction force-deflection relationship with the progress of rope deterioration in the first embodiment of the present invention.
- the reaction force-deflection relationship of the rope which is a healthy product, is indicated by a broken line, and the reaction force-deflection relationship of the rope after deterioration is indicated by a solid line.
- the diagnosis unit 5 determines the upper limit deflection amount X from the reaction force-deflection relationship 1 obtained using the deterioration reference product, and stores it in the upper limit deflection amount storage unit 7.
- the upper limit deflection amount X is determined to be a certain deflection amount in the range B in the reaction force-deflection relationship 1, as shown in FIG.
- the reaction force-deflection relationship 1 is approximated by two straight lines with a straight line in the range A and a straight line indicated by the range C, and the intersection of the two straight lines is defined as the upper limit deflection amount X.
- step S304 by applying a bending up to the upper limit deflection amount X at the bend imparting unit 3 to the degradation standard product, the load is unloaded, so that the reaction force-deflection relationship 2 is changed to the reaction force-deflection relationship. Obtained by the obtaining unit 6.
- FIG. 6 is a graph showing a reaction force-deflection relationship 2 when bending is applied up to the upper limit deflection amount X with respect to the rope of the deterioration reference product in the first embodiment of the present invention.
- step S 305 the deterioration determination unit 9 calculates the deterioration reference parameter ⁇ ′ from the reaction force-deflection relationship 2 and stores it in the deterioration reference product information storage unit 8.
- the deterioration reference parameter ⁇ ′ is made dimensionless by dividing the difference between F a ′ and F b ′ by the maximum reaction force F X ′.
- FIG. 7 is a flowchart showing a specific procedure for deterioration diagnosis in the first embodiment of the present invention.
- the deterioration detection apparatus shown in FIG. 1 is configured for the rope 1 to be diagnosed.
- the interval between the support portion 2a and the support portion 2b is set to be the same as the interval at the time of obtaining the deterioration reference.
- the rope tension set by the tension adjusting unit 4 is also set to the same tension as when the deterioration standard is acquired.
- step S702 the rope to be diagnosed is unloaded after being loaded up to the upper limit deflection amount X determined at the time of acquisition of the deterioration criterion by the bend imparting unit 3, thereby removing the reaction force-deflection relationship 3 as a reaction force- Obtained by the flexure relationship obtaining unit 6.
- FIG. 8 is a graph showing a reaction force-deflection relationship 3 when bending is applied up to the upper limit deflection amount X with respect to the deterioration diagnosis target rope according to the first embodiment of the present invention.
- the deterioration determination unit 9 calculates the deterioration determination parameter ⁇ from the reaction force-deflection relationship 3.
- the deflection amount X 1 for determining F a and F b the value determined when the deterioration standard is acquired is used. That is, the reaction force when the reaction force when the deflection in the load process is X 1 is F a, the deflection at unloading process becomes X 1 is F b. The reaction force when the deflection becomes X is F X.
- step S704 the deterioration determination unit 9 compares the deterioration determination parameter ⁇ with the deterioration reference parameter ⁇ ′, and determines whether the rope is in a healthy state or exceeds the deterioration reference.
- the deterioration determination unit 9 proceeds to step S705 when ⁇ > ⁇ ′, determines that the rope is in a healthy state, and proceeds to step S706 when ⁇ ⁇ ⁇ ′.
- the rope is determined to be in a state where the deterioration standard is exceeded.
- FIG. 9 is a graph showing the difference in hysteresis loop between the reaction force-deflection relationship of the healthy rope and the reaction force-deflection relationship of the deteriorated reference rope according to the first embodiment of the present invention.
- the hysteresis loop of the reaction force-deflection relationship of the rope, which is a healthy product is indicated by a broken line
- the hysteresis loop of the reaction force-deflection relationship of the rope after deterioration is indicated by a solid line.
- FIG. 10 is a graph in which the maximum reaction force is normalized to 1 for the hysteresis loop of FIG. 9 in Embodiment 1 of the present invention.
- FIG. 10 is obtained.
- the deterioration determination parameter ⁇ and the deterioration reference parameter ⁇ ′ have the relationship shown in FIG. 10, and ⁇ > ⁇ ′ is satisfied if the rope is in a healthy state.
- the deterioration determination parameter ⁇ and the deterioration reference parameter ⁇ which are height information of the normalized hysteresis loop, are used to reduce the oil content rate and the internal wear between the strands, which are factors that increase the frictional force between the inner strands. By comparing ', it can be detected reliably.
- the reason for normalizing here is to remove the influence of the reaction force change due to the difference in the degree of diameter reduction, particularly in a state close to the deterioration standard.
- the change in the magnitude of the frictional force between the internal strands of the deterioration diagnosis target rope and the deterioration reference product represents the reaction force-deflection relationship. Detect using the normalized hysteresis loop height information. As a result, it is possible to detect quantitatively and accurately the decrease in the oil content and the internal wear between the strands, which cause an increase in the frictional force between the strands.
- the two terminal portions are respectively supported by the support portion 2a and the support portion. The same effect can be obtained without providing a new support portion.
- a rope having the same structure as that of the diagnosis target may be used in an actual device, and a deterioration detection state may be used, or the same structure as that of the diagnosis target may be used.
- a rope that has been subjected to a deterioration test with a single rope and that has reached a deterioration state to be detected may be used.
- the deflection amount X 1 is determined in advance, and instead of obtaining the reaction force-deflection relationship 3 in step S702, the values of F X and F a and F b can be obtained. In this case, in step S703, it is possible to calculate the parameter ⁇ from only the values of F X and F a and F b without using the reaction force-deflection relationship 3. As a result, the amount of information to be acquired can be reduced.
- Embodiment 2 the case where the normalized hysteresis loop height information is used as an index for deterioration diagnosis has been described.
- the normalized hysteresis loop area is used as an indicator for deterioration diagnosis instead of the normalized hysteresis loop height information will be described.
- FIG. 11 is a graph showing the difference in the area of the normalized hysteresis loop in the second embodiment of the present invention.
- the hysteresis loop of the reaction force-deflection relationship of the rope that is a healthy product is indicated by a broken line
- the hysteresis loop of the reaction force-deflection relationship of the rope after deterioration is indicated by a solid line.
- the normalized hysteresis loop area of the deterioration reference product is set as the deterioration reference parameter ⁇ ′.
- the area of the normalized hysteresis loop obtained with the rope to be diagnosed is set as the deterioration determination parameter ⁇ .
- the deterioration state can also be quantitatively determined by using the area of the hysteresis loop instead of the height information of the hysteresis loop as an index for deterioration diagnosis. Furthermore, the use of the area, it is possible to suppress the variation due to choice deflection amount X 1.
- Embodiment 3 In the first and second embodiments described above, the case where the height or area based on the normalized hysteresis loop is used as an index for deterioration diagnosis has been described. On the other hand, in the third embodiment, a case will be described in which a certain amount of deflection X 0 within the range of the inflection part at the time of load is used for determination instead of the hysteresis loop.
- FIG. 12 is a graph showing the relationship between the inflection point of the reaction force-deflection relationship and the upper limit deflection amount X in the third embodiment of the present invention.
- the reaction force-deflection relationship of the rope which is a healthy product, is indicated by a broken line, and the reaction force-deflection relationship of the rope after deterioration is indicated by a solid line.
- the deterioration determination unit 9 determines that X 0 has reached the upper limit deflection amount X and thus is in a state that exceeds the deterioration reference. That is, in the flowchart of FIG. 7, ⁇ is the inflection portion X 0 when loaded, and ⁇ ′ corresponds to the upper limit deflection amount X.
- the diagnosis unit it is possible to determine the deterioration based on only the information at the time of loading without using the information of the hysteresis loop. As a result, the configuration of the diagnosis unit can be simplified.
- the amount of deflection within the range of the inflection part may be measured at the time of loading or at the time of unloading, and the same effect can be obtained.
- reaction force and deflection are acquired.
- the amount of deflection at which the amount of change in the reaction force decreases can also be calculated as X 0 by moving the bend imparting section so that the rate of change in deflection is constant and measuring the time variation of the reaction force.
- the reaction force needs to be acquired, and the configuration can be further simplified.
- Embodiment 4 FIG. In the fourth embodiment, a case where the number of times of bending of the wire rope is used as an indicator for deterioration diagnosis will be described.
- FIG. 13 is a graph showing the relationship between the number of bendings and the deterioration determination parameter ⁇ in Embodiment 4 of the present invention.
- the wire rope deterioration detection apparatus according to the fourth embodiment prepares a new rope in a process for obtaining a deterioration reference, deteriorates the new rope to a deterioration reference product, and sequentially measures the deterioration determination parameter ⁇ in this process.
- the relationship of FIG. 13 is acquired and stored in the deterioration reference product information storage unit 8 together with the deterioration reference parameter ⁇ ′.
- FIG. 13 shows the state and the number of bendings associated with each other.
- the transition state with respect to the number of bendings of the deterioration determination parameter ⁇ is indicated by a solid line
- the deterioration reference parameter ⁇ ′ is indicated by a broken line.
- the fourth embodiment it is possible to obtain durability data based on the number of times of bending of a new rope in advance and monitor the number of times of bending related to the rope to be diagnosed.
- the internal wear between each other can be detected accurately and quantitatively.
- the deterioration is detected by the difference in deflection when the internal strand starts to slide when the rope is bent.
- tension or torsion is applied instead of bending, it is possible to detect deterioration by detecting the difference in the start of sliding of the internal strands.
- the same deterioration diagnosis as that of the present invention can be performed by constructing a device that grips the rope by the support portion 2a and the support portion 2b and applies tension or torsion.
- Embodiment 5 FIG.
- the case where the result of continuously measuring the reaction force and the change in deflection when the rope is bent is used as an index for deterioration diagnosis has been described.
- the fifth embodiment a case where a rope deterioration diagnosis is simply performed using only the instantaneous value of the reaction force when the rope is bent to a predetermined deflection amount will be described. .
- the deterioration diagnosis of the fifth embodiment has a larger error than the deterioration diagnosis of the first to fourth embodiments due to the influence of the phenomenon of reducing the bending rigidity of the rope as the rope progresses.
- the calculation cost for calculating the criterion is lower in the deterioration diagnosis of the fifth embodiment than in the first to fourth embodiments. Therefore, the deterioration diagnosis according to the fifth embodiment is preferably used as a simple diagnosis.
- the degradation state can be easily determined by using the reaction force when the rope is bent to the upper limit deflection amount as an index for degradation diagnosis.
- Embodiment 6 FIG. In the sixth embodiment, a case where the wire rope deterioration detection device of the present invention is applied to a rope of an elevator apparatus will be described.
- FIG. 14 is a configuration diagram when the wire rope deterioration detection apparatus according to the sixth embodiment of the present invention is applied to a 1: 1 roping elevator apparatus.
- FIG. 15 is a configuration diagram when the wire rope deterioration detection apparatus according to the sixth embodiment of the present invention is applied to a 2: 1 roping elevator apparatus.
- FIG. 14 showing a 1: 1 roping elevator apparatus, a car 12 is provided via a shackle 11a and a counterweight 13 is provided via a shackle 11b at both ends of the rope 1 hung on the pulley 10a and the pulley 10b. It is attached.
- FIG. 15 representing an elevator apparatus of 2: 1 roping
- the rope 1 hung on a number of pulleys 10c to 10h supports the car 12 and the counterweight 13, and at the end via the shackle 11c and the shackle 11d. It is fixed.
- the rope in the sixth embodiment is not uniform in the number of times of bending depending on each place of the entire length. Therefore, it is necessary to diagnose deterioration at a location where the number of bending is large.
- a bend imparting portion 3 for imparting a bend to the rope is provided at an intermediate point between the pulley 10a and the pulley 10b corresponding to the support portion 2a and the support portion 2b in the first to fifth embodiments.
- the tension adjusting unit 4 is provided at an arbitrary position outside the diagnosis target range.
- a diagnosis unit 5 is provided that receives the reaction force and deflection amount generated in the bending applying unit 3 as inputs. The tension adjusting unit 4 and the diagnostic unit 5 are not shown.
- the portion between the pulley 10c and the pulley 10d is a portion where the number of times of bending is high and the workability is good. For this reason, it is optimal to configure the wire rope deterioration detection device using the pulley 10c and the pulley 10d as the support portion 2a and the support portion 2b, and perform the deterioration diagnosis.
- the bending portion 3 for bending the rope is provided at an intermediate point between the pulley 10c and the pulley 10d corresponding to the supporting portion 2a and the supporting portion 2b in the first to fifth embodiments.
- the tension adjusting unit 4 is provided at an arbitrary position outside the diagnosis target range.
- a diagnosis unit 5 is provided that receives the reaction force and deflection amount generated in the bending applying unit 3 as inputs. The tension adjusting unit 4 and the diagnostic unit 5 are not shown.
- the bend imparting unit 3 may be any place as long as it can apply tension to the rope in addition to the places illustrated in FIGS. 14 and 15. However, in order to determine the deterioration at an early stage, it is preferable to perform the deterioration diagnosis by providing the bend imparting portion 3 at a location where the rope is bent frequently, such as between the pulley and the pulley.
- the sixth embodiment when measuring a place where the number of times of bending is the largest, it is possible to specify a place where the number of times of bending is the largest within the entire length of the rope from the data that the elevator apparatus is activated in advance.
- the portion identified as the most bent portion is arranged between the support portion 2a and the support portion 2b. By doing so, it is possible to perform the deterioration diagnosis of the portion where the number of times of bending is the largest.
- the sixth embodiment when a place where the number of times of bending is large is not taken into consideration, a diagnosis using a pulley or a shackle as the support portion 2a and the support portion 2b is possible.
- the shackle 11a and the pulley 10a, or the pulley 10b and the shackle 11b may be used as the support portion 2a and the support portion 2b.
- Embodiment 7 FIG. In the seventh embodiment, a method for remotely diagnosing the rope of the elevator apparatus shown in the sixth embodiment will be described.
- FIG. 16 is a configuration diagram for performing remote diagnosis of the rope of the elevator apparatus in the seventh embodiment of the present invention.
- FIG. 16 shows an information center 15 and a remote diagnosis control unit 16 as a configuration for performing a remote diagnosis together with the diagnosis unit 5 and the elevator apparatus control panel 14.
- the information center 15 is provided at a remote location, outputs a diagnosis command to the remote diagnosis control unit 16, and collects a diagnosis result as a response.
- the remote diagnosis control unit 16 receives an instruction from the information center 15 and outputs an execution command for making a diagnosis to the diagnosis unit 5 and the elevator apparatus control panel 14. Receives diagnostic results from. Further, the remote diagnosis control unit 16 returns the diagnosis result of the diagnosis unit 5 to the information center 15.
- FIG. 17 is a flowchart showing a specific procedure for executing remote diagnosis of the elevator apparatus according to Embodiment 7 of the present invention.
- the information center 15 outputs a command for diagnosing the rope of the elevator apparatus to the remote diagnosis control unit 16 based on the operation input by the remote diagnosis operator.
- step S1702 the remote diagnosis control unit 16 outputs a command to the elevator apparatus control panel 14 so that the bend imparting unit is arranged at a location where the number of times of bending is the largest in the entire length of the rope.
- the rope diagnosis position is adjusted by operating the elevator apparatus.
- step S1703 the remote diagnosis control unit 16 outputs a deterioration diagnosis execution command to the diagnosis unit 5.
- the deterioration diagnosis is executed according to the flowchart of FIG. 7, and the result determined by the deterioration determination unit 9 is returned to the remote diagnosis control unit 16.
- step S1704 the remote diagnosis control unit returns the deterioration diagnosis result received from the diagnosis unit to the information center 15.
- the seventh embodiment it is possible to execute the diagnosis of the rope of the elevator apparatus based on the operation input by the worker from a remote place and to return the diagnosis result to the remote place. .
- remote diagnosis can be easily performed.
- Embodiment 8 FIG. In the eighth embodiment, a method of automatically diagnosing a rope of an elevator apparatus by applying the rope deterioration detection apparatus according to the present invention will be described.
- FIG. 18 is a configuration diagram for performing automatic diagnosis of the rope of the elevator apparatus in the eighth embodiment of the present invention.
- FIG. 18 shows an information center 15 and an automatic diagnosis control unit 17 as a configuration for performing an automatic diagnosis together with the diagnosis unit 5 and the elevator apparatus control panel 14.
- the information center 15 is provided at a remote location and collects diagnostic results. Further, the automatic diagnosis control unit 17 periodically outputs a diagnosis execution command to the diagnosis unit 5 and the elevator apparatus control panel 14, and receives a diagnosis result from the diagnosis unit 5 as a response. Further, the automatic diagnosis control unit 17 returns the diagnosis result of the diagnosis unit 5 to the information center 15.
- a rope diagnosis cycle is set in advance.
- the automatic diagnosis control unit 17 performs the deterioration diagnosis at the set diagnosis timing in the same flow as steps S1702 to S1704 described in FIG. 17 in the previous embodiment 7.
- self-diagnosis can be executed periodically and the diagnosis result can be transmitted to the information center 15 at a remote location.
- the rope of the elevator apparatus can be periodically diagnosed, and the diagnosis result can be transmitted to a remote place as necessary. As a result, automatic diagnosis can be easily performed.
- diagnosis period of the rope does not need to be constant, and may be a variable period such that the period becomes shorter as the state of the rope approaches the deterioration standard.
- the rope diagnosis method when executing the rope diagnosis method according to the seventh and eighth embodiments, it may be configured such that the rope deterioration determination is not performed by the diagnosis unit.
- measurement results of reaction force and deflection are transmitted to the information center as diagnosis execution results, and deterioration determination is performed at the information center.
- the transmission information to the information center becomes large, but the configuration of the deterioration diagnosis device can be simplified.
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Abstract
Description
図1は、本発明の実施の形態1におけるワイヤロープの劣化検出装置の構成図である。ロープ1には、診断対象範囲の両端にロープを支える支持部2aおよび支持部2bが設けられている。
α’=(Fa’-Fb’)/FX’ (1)
α=(Fa-Fb)/FX (2)
先の実施の形態1では、劣化診断の指標として、正規化したヒステリシスループの高さ情報を使用する場合について説明した。これに対して、本実施の形態2では、正規化したヒステリシスループの高さ情報の代わりに、正規化したヒステリシスループの面積を劣化診断の指標として用いる場合について説明する。
先の実施の形態1、2では、劣化診断の指標として、正規化したヒステリシスループに基づく高さまたは面積を用いる場合について説明した。これに対して、本実施の形態3では、ヒステリシスループの代わりに、負荷時の変曲部の範囲内のあるたわみ量X0を判定に用いる場合について説明する。
本実施の形態4では、ワイヤロープの曲げ回数を劣化診断の指標として用いる場合について説明する。
実施の形態1から4では、劣化診断の指標として、ロープに曲げを付与した時の反力とたわみの変化を連続的に測定した結果を用いる場合について説明した。これに対して、本実施の形態5では、あらかじめ定めたたわみ量までロープに曲げを付与した時の反力の瞬間値のみを用いて、簡易的にロープの劣化診断を実施する場合について説明する。
本実施の形態6では、エレベータ装置のロープに対して、本発明のワイヤロープの劣化検出装置を適用する場合について説明する。
本実施の形態7では、実施の形態6に示したエレベータ装置のロープを遠隔診断する方法について説明する。
本実施の形態8では、本発明に係るロープの劣化検出装置を適用して、エレベータ装置のロープを自動診断する方法について説明する。
Claims (15)
- ロープに曲げを付与するために前記ロープを支持する一対の支持部と、
前記一対の支持部により支持された前記ロープに対して曲げを付与する曲げ付与部と、
前記ロープの張力を調節する張力調節部と、
前記曲げ付与部により前記曲げが付与された状態の反力を取得する反力取得部と、
前記曲げ付与部により前記曲げが付与された状態のたわみ量を取得するたわみ取得部と、
前記反力取得部および前記たわみ取得部で取得された前記反力および前記たわみ量の関係から劣化判定パラメータを算出し、前記ロープの劣化状態を判定する劣化判定部と
を備えたロープの劣化検出装置。 - 前記劣化判定部は、前記曲げ付与部により曲げが付与された負荷過程および曲げを負荷した後の除荷過程の少なくともいずれか一方における反力-たわみ量線図から前記劣化判定パラメータを算出し、前記ロープの劣化状態を判定する
請求項1に記載のロープの劣化検出装置。 - 前記劣化判定部は、前記負荷過程あるいは前記除荷過程における前記反力-たわみ線図を2直線近似し、2直線の交点として得られる変曲点に対応するたわみ量を前記劣化判定パラメータとし、前記ロープの劣化状態を判定する。
請求項2に記載のロープの劣化検出装置。 - 前記劣化判定部は、あらかじめ設定した上限たわみ量となるまで曲げを付与する際の前記負荷過程および前記除荷過程における前記反力-たわみ線図のヒステリシスループから前記劣化判定パラメータを算出し、前記ロープの劣化状態を判定する
請求項2に記載のロープの劣化検出装置。 - 前記劣化判定部は、前記ヒステリシスループの上限たわみ量での反力を1に正規化して得られるヒステリシスループから、0よりも大きく、前記上限たわみ量よりも小さい中間たわみ量における負荷時と除荷時の反力差を前記劣化判定パラメータとし、前記ロープの劣化状態を判定する
請求項4に記載のロープの劣化検出装置。 - 前記劣化判定部は、前記ヒステリシスループの上限たわみ量での反力を1に正規化して得られるヒステリシスループの面積を前記劣化判定パラメータとし、前記ロープの劣化状態を判定する
請求項4に記載のロープの劣化検出装置。 - 前記上限たわみ量は、診断対象のロープに対して曲げを付与する際の条件と同一条件で、劣化基準品に対して曲げを付与した時の前記負荷過程における前記反力-たわみ線図の変曲点に対応するたわみ量と一致する
請求項4から6のいずれか1項に記載のロープの劣化検出装置。 - 前記劣化判定部は、あらかじめ設定した上限たわみ量となるまで曲げを付与した時の反力の値、または、あらかじめ設定した最大反力となるまで曲げを付与した時のたわみ量の値から前記劣化判定パラメータを算出し、前記ロープの劣化状態を判定する
請求項1に記載のロープの劣化検出装置。 - 前記曲げ付与部は、圧縮ばねを介して前記ロープに曲げを付与し、
前記劣化判定部は、反力の値の代わりにばね長の値を用いて前記劣化判定パラメータを算出し、前記ロープの劣化状態を判定する
請求項8に記載のロープの劣化検出装置。 - 前記曲げ付与部は、たわみの変化速度が一定となるように曲げを付与し、
前記劣化判定部は、反力の時間変化率が減少するたわみ量を前記劣化判定パラメータとし、前記ロープの劣化状態を判定する
請求項1に記載のロープの劣化検出装置。 - 診断対象のロープに対して曲げを付与する際の条件と同一条件で、劣化基準品に対して曲げを付与して得られる劣化基準パラメータを記憶しておく劣化基準品情報記憶部をさらに備え、
前記劣化判定部は、前記劣化判定パラメータの値が前記劣化基準品情報記憶部に記憶された前記劣化基準パラメータの値に到達した場合に、ロープが劣化状態に達したと判定する
請求項1から10のいずれか1項に記載のロープの劣化検出装置。 - 診断対象のロープに対して曲げを付与する際の条件と同一条件で、劣化基準に至る前であり、かつ、すでに曲げられた回数が既知であるロープに対して、曲げを付与する動作を劣化基準に至るまで繰り返すとともに、前記劣化判定パラメータを逐次算出することで得られる、前記劣化判定パラメータが劣化基準に到達したことを判定するための劣化基準パラメータに至るまでの遷移状態と曲げ回数との対応関係を記憶しておく劣化基準品情報記憶部をさらに備え、
前記劣化判定部は、診断対象のロープの運用時において、曲げ回数をカウントした累積値に対応する劣化判定パラメータを前記劣化基準品情報記憶部に記憶された前記対応関係から抽出し、抽出した前記劣化判定パラメータが前記劣化基準パラメータに至る曲げ回数に到達することで、ロープが劣化状態に達したと判定する
請求項1から10のいずれか1項に記載のロープの劣化検出装置。 - 請求項1から12のいずれか1項に記載のロープの劣化検出装置を備えたエレベータ装置であって、
前記ロープは、前記エレベータ装置を構成するロープであり、
前記支持部は、前記エレベータ装置を構成する滑車あるいはシャックルであり、
前記曲げ付与部は、前記滑車間または前記シャックル間に設けられる
ロープの劣化検出装置を備えたエレベータ装置。 - 遠隔地に設置された情報センターから遠隔診断指令を受信した場合には、前記ロープの劣化検出装置に前記ロープの劣化診断を実施させるとともに、前記劣化診断の実施結果を返答として受信し、前記実施結果を前記遠隔診断指令の送信元である前記情報センターに返信する遠隔診断制御部
をさらに備える請求項13に記載のエレベータ装置。 - あらかじめ定められた周期ごとに、前記ロープの劣化検出装置に前記ロープの劣化診断を実施させるとともに、前記劣化診断の実施結果を返答として受信する自動診断制御部
をさらに備える請求項13に記載のエレベータ装置。
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