JP2007022765A - Wire breaking detection tool for wire rope and wire breaking detection method for wire rope - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wire breaking detection tool for a wire rope, having a simple and inexpensive structure and capable of confirming presence/absence of breaking of wire by simple operation. <P>SOLUTION: This wire breaking detection tool for the wire rope 4 is provided with a frame member 22 having an approximately U-shaped opening part 21 into which the wire rope 4 is inserted and with a plurality of flexible filament bodies 24 stretched across the opening part 21 so as to be pressed against the outer peripheral face of the wire rope 4 inserted into the opening part 21. At least two of the plurality of filament bodies 24 are stretched to intersect with each other when the opening part 21 is viewed from the insertion direction of the wire rope 4. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a wire rope strand break detector and a wire rope strand break detection method. In more detail, the detector of the wire rope used for an elevator etc. detects whether a cutting part exists, and the element of various wire ropes, such as the wire rope for elevator raising / lowering in an elevator type parking device The present invention relates to a method for detecting a line break.

  Conventionally, wire ropes are used in various devices such as cargo handling, transportation, and lifting. For example, a wire rope having a structure shown in FIG. That is, a strand 63 formed by bundling a plurality of (for example, 19) strands 62 around a core steel (fiber core or rope core) 61 is twisted in a spiral shape (for example, eight). ing.

  And, for example, in passenger elevators, elevator parking devices, multi-level warehouses, crane devices, aerial work platforms, etc., periodic maintenance inspections are obligatory, and surveys on whether wire ropes are broken are also inspection items. include. In general, grease is applied as a lubricant to the surface of such a wire rope, and the surface of the strand 63 is covered with mud. Therefore, even if the entire wire rope is illuminated, it is difficult to detect a broken wire by visual inspection. If the muddy grease is carefully wiped off with a waste cloth or the like over the entire length of the wire rope, it may be possible to detect the breakage of the wire by visual inspection. However, this requires a lot of time and effort, and there is a concern of damaging the operator's fingers.

  Therefore, various devices for detecting wire strand breakage have been proposed. For example, magnetic flaw detectors disclosed in Patent Document 1 and Patent Document 2 are known. In this apparatus, a pair of magnetic poles (N pole and S pole) are arranged in the longitudinal direction of the wire rope, and a magnetic detection piece or a magnetic display body is arranged between the magnetic poles. Then, the wire rope is passed through the magnetic field of this device in a state where the magnetic flux passes through the wire rope, and the wire breakage is detected by detecting the change in the magnetic flux.

  An apparatus that electrically detects a broken wire is also known (see Patent Document 3 and Patent Document 4). The apparatus of patent document 3 installs the movable body connected with the thin conducting wire in the passage position of a wire rope. When the wire cut-out portion that jumps outward (referred to as a cocoon by those skilled in the art) hooks and moves the movable body along with the movement of the wire rope, it electrically detects that the conductor has been pulled. This is an attempt to detect wire breakage. The apparatus of patent document 4 arrange | positions a pair of electrode close to a wire rope in the movement path | route of a wire rope. The wire breakage is detected by detecting conduction when the protruding portion of the wire breakage contacts both electrodes during the movement of the wire rope.

  Furthermore, a pressure sensor type strand break detection device has also been proposed (see Patent Document 5). This device is composed of a funnel-shaped cylinder divided into two parts and a holder provided outside through a pressure sensor. When the wire rope is inserted and moved into the funnel-shaped cylinder, the cut portion of the wire protruding to the outside of the wire rope drags the funnel-shaped cylinder, and this is detected by operating the pressure sensor. It is said that.

  Also, an optical sensor type wire breakage detection device has been proposed (see Patent Document 6). In this apparatus, a projector and a light receiver are arranged at opposing positions so as to be orthogonal to the axis of the moving wire rope. Then, a change in the amount of received light caused by the passage of the part of the broken wire that protrudes outward is detected to detect the broken wire.

  However, the magnetic flaw detection apparatus (Patent Documents 1 and 2) can detect not only the surface of the wire rope but also the internal wire breakage, but it is large and expensive. A large space is required to install a large-scale device.

In addition, the electrical type (Patent Literatures 3 and 4), the pressure sensor type (Patent Literature 5), and the optical sensor type (Patent Literature 6) detection devices all inspect the surface state of the wire rope. If there is a wire break, it is assumed that the part has protruded outward from the wire rope surface. Accordingly, it is not possible to detect a state in which the wrinkles of the cut portion of the strand are pushed into the strand. Furthermore, since these detection devices are equipped with peripheral devices such as a detector main body and measurement devices, as in the case of electromagnetic flaw detection devices (Patent Documents 1 and 2), it is difficult to install in a narrow space or at a high place. It becomes.
Japanese Patent Laid-Open No. 5-18939 Japanese Patent Laid-Open No. 11-230947 Japanese Utility Model Publication No. 6-73071 JP 2001-151433 A JP-A-8-119539 JP-A-11-325844

  The present invention has been made in order to solve such problems, and has a simple configuration and is inexpensive, and a wire rope strand breakage detection tool that enables efficient strand breakage detection and simple work. An object of the present invention is to provide a wire rope breakage detection method capable of detecting a breakage of strands.

The wire breakage detector of the wire rope of the present invention is
A frame member formed with an opening through which the wire rope is inserted;
And a flexible linear body stretched across the opening so as to be pressed against the outer peripheral surface of the wire rope inserted through the opening.

  With this configuration, in a state where the striate body is pressed against the outer peripheral surface of the wire rope inserted through the opening, the striate member is slid along the axis of the wire rope so that the striate body becomes the element of the wire rope. Since the impact force when caught by the cut part of the wire is transmitted to the hand, it is possible to easily detect the breakage of the wire.

  The opening may be formed to have a substantially U shape, and the linear body may be stretched across the left and right legs of the frame member that defines the U-shaped opening.

  A plurality of the above-mentioned striates are stretched, and at least two of them can be stretched so as to intersect when the opening is viewed in the insertion direction of the wire rope. The reason for stretching in this way is to press the striatum against as much of the outer peripheral surface of the wire rope as possible.

  A plurality of frame members on which the linear members are stretched are disposed at intervals, and these frame members can be fixedly connected to each other by a connection member. In this way, the wire breakage inspection can be performed in a superimposed manner on the outer peripheral surface of the wire rope by a single sliding operation.

  The striatum can be formed from a piano wire. In this way, a long life can be expected. Further, when the filament is caught on the cut end portion of the strand, the strand breakage may be determined by the sound of the piano wire being played.

The method for detecting the wire breakage of the wire rope of the present invention,
A method of detecting wire breakage by relatively sliding the wire rod and the wire rope along the longitudinal direction of the wire rope in a state where the flexible wire rod is pressed against the wire rope. It is.

  In the elevator parking apparatus, the wire rope may be an elevator lifting wire rope having one end connected to the elevator and the other end connected to a counterweight and hung around a drive sheave of the lifting drive.

The elevator parking device has an entry / exit floor on the bottom floor, and an elevator lift drive device is installed on the top floor. This lift drive device is a portion of the wire rope that hangs around the groove of the drive sheave. Is driven up and down by frictional force,
Of the wire rope, when the elevator is on the entry / exit floor, the wire rod and the wire rope are slid relative to the priority inspection target range that is the portion that is hung around the drive sheave and the vicinity thereof. Can be moved.

  Relative sliding of the striatum and wire rope on the entry / exit floor with respect to the above-mentioned priority inspection target range when the counterweight is lowered to the lowest position by raising the elevator to the top floor Can do.

In the above strand break detection method, in order to press the flexible linear body against the wire rope, prepare the strand break detector of any one of the wire ropes described above,
Hold the strand breakage detector so that the wire rope is inserted into the opening of the detector, and the strand breakage detector and the wire rope in a state where the above-mentioned filament is pressed on the outer peripheral surface of the wire rope. Are relatively slid along the longitudinal direction of the wire rope.

  The wire rope strand breakage detector of the present invention has a simple configuration, is compact overall, and is easy to handle. Therefore, even when a large number of wire ropes are gathered and the space is narrow, the wire breakage inspection can be easily performed. Further, the wire rope breakage detection method of the present invention does not require a large and expensive device, and can perform a strand break inspection by a simple operation.

  An embodiment of a wire breakage detection tool (hereinafter simply referred to as a detection tool) of the present invention and an embodiment of a method for detecting wire breakage of a wire rope will be described with reference to the accompanying drawings.

  FIG. 1 is a cross-sectional view showing an example of an elevator parking device (hereinafter simply referred to as a parking device) to which the wire break detection tool and the wire break detection method of the present invention can be applied. FIG. 2 is a view taken along the line II-II in FIG.

  Inside the parking device 1, an elevator 3 for raising and lowering a pallet 2 for mounting on a vehicle is suspended by a wire rope 4, and a drive device for raising and lowering the elevator 3 by winding and feeding the wire rope 4 ( Winding device) 5 and counterweight 6 are provided. On both sides of the hoistway 7 of the elevator 3, a multi-stage parking rack 8 for accommodating the vehicle M is disposed. A rail 8a on which the pallet 2 can traverse is disposed on each parking shelf 8 (see FIG. 2), and the pallet 2 is placed on the rail 8a.

  The elevator 3 moves up and down between the parking shelves 8 on both sides, moves to the parking shelf 8 of the called pallet 2, receives the pallet 2, and transports it to the entry / exit floor E. Further, the pallet 2 on which the vehicle M is placed is transferred from the loading / unloading floor E to the designated parking shelf 8 and deposited. In this parking apparatus 1, the entry / exit floor E is the lowest floor (first floor). The elevator 3 is provided with rails 3a for traversing the pallet (see FIG. 2). When the elevator 3 reaches the position of the parking rack 8 for delivery of the vehicle M, the rails 3a and 8a face each other. Further, the elevator 3 is provided with a transfer device 9 for receiving and returning the pallet 2 from the parking shelf 8 (see FIG. 2).

  1, 3 and 4 show a drive device 5 for the elevator 3 described above. 3 is a perspective view taken along the line III-III in FIG. 1, and FIG. 4 is a perspective view schematically showing the elevator 3 and the counterweight 6. As shown in FIG. The elevator 3 is connected to a counterweight 6 by a wire rope 4. Reference numeral 10 denotes an elevator guide rail for the elevator 3, and only a part thereof is shown. The intermediate portion of the wire rope 4 is wound around the driving sheave 11 and the turning sheave 12 of the driving device 5 and the turning pulley 13. One end of the wire rope 4 is connected to the four corners of the substantially rectangular elevator 3 through a plurality of turning pulleys 13 that exit from the drive sheave 11. Further, the other end of the drive sheave 11 is connected to the counterweight 6 after coming out in the reverse direction and wound around the turning sheave 12. A drive motor 15 is connected to the drive sheave 11 via a speed reducer 14. Reference numerals 16a and 16b are couplings.

  The drive sheave 11 is rotated by the drive motor 15, and the elevator 3 is lifted by pulling the wire rope 4 by the frictional force of the drive sheave 11. The weight of the counterweight 6 makes the ascending force and the descending force of the driving device 5 uniform. In this embodiment, three sets of wire ropes 4 are connected to each of the four corners of the elevator 3, so that each rope 11 is wound around each sheave 11, 12 so that each rope 4 is wound around. A groove 17 is formed. Of course, the twelve rope portions between the sheaves 11 and 12 are each linear without sagging due to tension. In this portion, each rope 4 engages with the groove 17 of the sheaves 11 and 12 and is stretched by tension, so that the rope 4 is aligned without being displaced in the direction perpendicular to the longitudinal direction (the cross-sectional radial direction of the rope). is doing. FIG. 5 shows a cross section of the wire rope 4 engaged with the grooves 17 of the sheaves 11 and 12.

  As a method for detecting the cut portion of the wire 62 of the wire rope 4, the wire rope 4 is made of a piano wire or a synthetic resin (nylon, polyester, etc.) in a direction perpendicular to the axis of the wire rope 4. The wire body is slid relatively in the axial direction of the wire rope in a state where the wire body is pressed. For example, the operator holds both ends of the wire rod with both hands, extends in a direction orthogonal to the axis of the wire rope 4, and presses the outer surface of the wire rope 4 in that state. The wire rod may be slid while being pressed against the outer peripheral surface of the wire rope 4 as it is, or the wire rod is stationary while pressed against the wire rope 4, and the wire rope 4 is moved in the axial direction. May be.

  In this case, if there is a cut portion in the wire rope strand, the filament is caught on the cut end of the strand, so that the strand flips the cut end of the strand or the cut end is a wire. Play the striatum. Then, since the impact when caught is transmitted to the operator's hand, it is possible to detect the cutting of the strand. Also, when caught, a striated sound of the striatum or cut end is heard. It is possible to detect a broken wire. In the present embodiment, a piano wire having a cross-sectional diameter of about 0.5 mm is used for a wire rope using a strand having a cross-sectional diameter of about 0.8 to 1.0 mm. However, it is not limited to this dimension.

  In this way, when sliding the wire rod on the outer peripheral surface of the wire rope, the muddy grease attached to the surface of the wire rope is peeled off. Is exposed visually. Therefore, when a broken wire is detected due to an impact transmitted from the striatum, it is possible to reconfirm the broken wire portion by visual inspection and immediately apply a marking with a coloring tool. Become.

  As an example of the subsequent countermeasures, the number of broken wire portions with colored marks as in the eight-strand wire rope 4 shown in FIG. 6 is counted, and one twist pitch (one turn of one strand 63 is counted. In light of the inspection criteria, the total number of broken wires in the wire rope with a diameter of 12 mm is about 78 mm. Judgment is made. Depending on the judgment, for example, request for reporting and monitoring of records to related departments of the company, proposals for replacement to customers, emergency replacement, prohibition of use of the machine until replacement, etc. are performed.

  In the case of the wire rope for raising and lowering the elevator in the elevator parking device 1 described above, an effective range is naturally determined if the wire breakage is inspected intensively. The range is a section of A to B close to the counterweight 6 of the wire rope 4 as shown in FIG. The sections A to B are wound around the turning sheave 12 from the portion wound around the drive sheave 11 of the wire rope 4 when the elevator 3 is stopped at the entry / exit floor E, which is the lowest position. It is the range to the part which is done. This range A-B of the wire rope 4 is a part with the highest frequency of engaging with the groove 17 of the sheaves 11, 12, since the entry / exit floor E is the lowest position. This is because the elevator 3 normally stands by at the entry / exit floor E when there is no entry / exit operation.

  In particular, in the lifting device, the wire rope is bitten into the groove of the sheave (see, for example, FIG. 5), and a propulsive force for sending the wire rope is generated by contact friction between the groove surface of the sheave and the outer peripheral surface of the wire rope. As a result, it is known that the wire in the portion of the wire rope that comes into contact with the groove surface of the sheave is easily worn and has a higher possibility of cutting than the other portions. Therefore, when a broken wire is found at one location, experience has shown that there may be a broken wire at another position on the straight line in the axial direction of the wire rope including that location. ing. Therefore, among the wire ropes, the range in which the frequency of engaging with the sheave groove is highest during the driving period of the parking apparatus 1, that is, the range A to B in which the possibility that the strand break is most likely to occur is focused. It turns out that it is efficient to perform the inspection.

  However, in the case of a general elevator parking device, as described above, four sets of wire ropes (for example, one set of three) that suspends the four corners of the elevator 3 pass through the turning pulleys 13 and then gather on the drive sheave 11. Further, the counterweight 6 is connected together via the turning sheave 12. Accordingly, when the counterweight 6 rises to the vicinity of the driving device 5 on the top floor, or when waiting for that, the wire rope ranges A to B arranged in the sheaves 11 and 12 are the most wire ropes. It becomes a dense part. With regard to such a part, it is difficult not only to arrange the device so as to face the wire rope with the above-described conventional techniques (magnetic flaw detection type, electric type, optical type, etc.), but also the operator can use both hands It is not easy to have a physical examination.

  In such a case, as indicated by a two-dot chain line in FIG. 4, the counterweight 6 is submerged in the pit P on the entry / exit floor E (see also FIG. 1) by raising the elevator 3 to the top floor. . If it does so, the said range AB of the wire rope 4 will be located in the entering / exiting floor E just. In this state, the operator can inspect the above-mentioned ranges A to B of the wire rope with a comfortable posture on the boarding / exiting floor of the wide entrance / exit floor E having a margin. Of course, it is not limited to the entry / exit floor E. Even in other floors, if there is a large space that allows the operator to inspect with a comfortable posture, the counterweight may be moved to the vicinity of the floor and inspected. This is also true for parking devices provided on the top floor and intermediate floors, where the entry / exit floor E is not at the lowest position.

  Next, a wire breakage detector (hereinafter simply referred to as a detector) 20 shown in FIG. 7 will be described. By using this detection tool 20, the wire breakage is easily detected even when the focus inspection target range of the wire rope 4 is located in the vicinity of the driving device 5 (when the above-described wire ropes are densely packed). It can be performed.

  As shown in FIG. 7, the detection tool 20 includes a plate-shaped frame member 22 having a substantially U-shaped outer shape in which a substantially U-shaped opening 21 through which the wire rope 4 is inserted is formed. The frame member 22 includes a left leg portion 23a and a right leg portion 23b located on the left and right sides of the opening portion 21, and a back portion 22a connecting the both leg portions 23a and 23b. Further, a linear body 24 is provided which is stretched across the opening 21 from one leg 23a (23b) to the other leg 23b (23a).

  The material of the frame member 24 is not particularly limited as long as the material has necessary strength and hardness, such as metal, synthetic resin, and wood. In this embodiment, a piano wire is used as the striate body 24, but a synthetic resin such as polyester may be used. As illustrated, in the present embodiment, the two filaments 24 are stretched so as to intersect when the opening 21 is viewed in the insertion direction of the wire rope 4. Specifically, one linear body is obliquely stretched on one surface of the frame member 22, and one linear body is stretched obliquely in the opposite direction on the other surface. As shown in FIG. 8, when the wire rope 4 is inserted into the opening 21, the linear body 24 is brought into contact with the outermost surface of the wire rope 4 (outer circle of the cross section) as much as possible. This is to make it happen. An end of the linear member 24 is passed through an attachment hole 25 formed in the frame member 22 and a clasp 26 is attached thereto. By doing so, the linear member 24 is prevented from coming out of the attachment hole 25 and is firmly attached to the frame member 22. Of course, the end of the linear member 24 may be directly fixed to the frame member 22 by welding or the like.

  As shown in FIG. 7, the operator grips the back portion 22a of the detection tool 20 with fingers, and connects the leg portions 23a, 23b to the wire rope so that the wire rope 4 is inserted into the U-shaped opening 21. 4 is straddled. And the detection tool 20 is pressed so that the filament 24 may be pressed by the outer peripheral surface of the wire rope 4. FIG. In this state, the detector 20 is slid in the axial direction of the wire rope 4. Alternatively, the wire rope 4 is slowly moved in the axial direction while the detection tool 20 is stationary.

  As shown in FIG. 9, when the cutting part C of the strand 62 exists on the surface of the wire rope 4 at this time, the filament 24 is caught by the cutting part C of the strand 62. It is determined that the cut portion C exists due to the impact. Along with the above-mentioned catch, the cut end of the strand 62 and / or the wire 24 may be emitted. The presence of the cut portion C can also be recognized by recognizing the generated sound. Even if the mud-like grease G adheres to the cut portion C, the linear body 24 peels it off, so that the detection of the cut portion C is not affected.

  Since this detector 20 can be handled with one hand of the operator, it can be easily used in the vicinity of the driving device 5 arranged on the top floor of the parking device 1 described above, that is, in a narrow place where as many as 12 wire ropes are concentrated. Inspection of wire breakage can be performed. The treatment after the wire breakage is detected by the detector 20 has the same contents (marking and evaluation) as described above.

  The number of the striate bodies 24 is not limited to two. As shown in FIG. 10 (a), it may be a detector 27 having a single filament 24 attached thereto. However, from the viewpoint of bringing the filament 24 into contact with the widest possible range of the outer peripheral surface of the wire rope 4, it is better that the number of filaments is large. For example, as shown in FIG. 10 (b), a detection tool 28 having three filaments 24 attached thereto is preferable. Moreover, you may provide a linear body more than four directions.

  FIG. 11 shows another detection tool 29. The detection tool 29 is obtained by connecting the two detection tools 20 shown in FIGS. 7 to 9 with a connection member 30 in a state of being separated from each other so that the surfaces of the frame members 22 are parallel to each other. The connecting member 30 and each detector 20 may be detachable with screws or the like. When this detection tool 29 is viewed in the insertion direction of the wire rope 4, the two detection tools 20 are arranged so that both the openings 21 coincide. According to the detection tool 29, the wire breakage inspection can be performed in a superimposed manner on the outer peripheral surface of the wire rope 4 by a single sliding operation, and the detection accuracy of the wire breakage is improved. Although this detector 29 uses two detectors 20 having two filaments 24, it is not limited to this configuration. For example, two or three or more of the detection tool 20 and the other detection tools 27 and 28 described above may be selected and connected, and a detection tool having four or more striate bodies may be used. You may mix.

  The frame member 22 of the detectors 20, 27, 28, 29 is not limited to the shape described above. Any shape may be used as long as it is suitable as a frame member such as a horseshoe shape. Moreover, you may use the partial cylinder of the shape (the cross section becomes a semicircle shape or C shape) which cut off a part of cylinder along the axial direction. When a striated body is stretched at each part spaced along the axial direction of the partial cylindrical shape, a detection tool that performs the same function as the detection tool 29 shown in FIG. 11 is completed.

  As an application target of the strand break detection method and the strand break detection tool, in the above embodiment, an elevator lifting wire rope having a counterweight connected to the other end is taken as an example, but the present invention is not limited to this. The present invention can also be applied to an elevating device that winds and feeds a take-up drum without using a counterweight.

  Moreover, although the said embodiment demonstrated the elevator raising / lowering apparatus in an elevator type parking apparatus as an example, this invention is not limited to this. The present invention can be applied to an apparatus that uses a wire rope, such as an elevator lift for a normal person, a crane, and the like.

  According to the present invention, the wire rope wire breakage inspection can be easily and efficiently performed, and the cost for the inspection work is low. Therefore, the present invention is not limited to the lifting device, and can be applied to wire rope wire breakage inspection in a wide field such as transportation and cargo handling.

It is sectional drawing which shows an example of the elevator type parking apparatus which can apply the strand break detection tool and strand break detection method of this invention. It is the II-II arrow directional view of FIG. It is a top view which shows the drive device of the elevator in the parking apparatus of FIG. 1, and is the III-III arrow directional view of FIG. It is a perspective view which shows roughly the elevator and counterweight in the parking apparatus of FIG. FIG. 4 is a cross-sectional view showing a wire rope in a state of being engaged with a groove of a drive sheave in the drive device of FIG. 3. It is a side view which shows an example of the wire rope which is the object of strand break detection, and one of the strands. It is a perspective view which shows one Embodiment of the strand break detection tool of this invention. It is a front view which shows the strand break detection tool of FIG. It is the IX-IX sectional view taken on the line of FIG. 8 which shows an example of the strand break detection operation | work by the strand break detector of FIG. 10 (a) and 10 (b) are perspective views showing another embodiment of the wire breakage detection tool of the present invention. It is a perspective view which shows other embodiment of the strand break detection tool of this invention. It is a side view which shows an example of the wire rope which is the object of strand break detection.

Explanation of symbols

1 ... Parking device
2. Pallet
3 ... Elevator
4 ... Wire rope
5 ... Drive device
6. Counterweight
7 ... hoistway
8. Parking lot
11. Drive sheave
12 ... Turn sheave
13 .... Turning pulley
14 ... Reducer
15 ... Drive motor
16a, 16b ... Coupling
17 ··· (groove)
20 ··· (Wire breakage) detector
21... Opening
22... Frame member
23a, 23b ... Legs
24...
25 .... Mounting hole
26 ... Clasp
27 ··· (Wire breakage) detector
28 .... (Wire breakage) detector
29 ··· (Wire breakage) detector
C ··· (Cut end)
E ... Entry / exit floor
G ... Grease
M ・ ・ ・ ・ Vehicle
P ... Pit

Claims (10)

A frame member formed with an opening through which the wire rope is inserted;
A wire rope breakage detection tool comprising: a flexible linear body stretched across an opening so as to be pressed against an outer peripheral surface of the wire rope inserted through the opening.   The wire rope according to claim 1, wherein the opening is substantially U-shaped, and the linear body is stretched so as to cross between the left and right leg portions of a frame member defining the U-shaped opening. Wire breakage detector.   The wire rope element according to claim 1, wherein a plurality of said linear bodies are stretched, and at least two of them are stretched so as to intersect when the opening is viewed in the wire rope insertion direction. Wire break detector.   The wire rope according to claim 1, wherein a plurality of frame members on which the linear members are stretched are arranged at intervals, and further includes a connection member for fixing and connecting the frame members to each other. Wire breakage detector.   2. The wire rope strand break detector according to claim 1, wherein the filament is formed from a piano wire.   In a state where the flexible striated body is pressed against the wire rope, a wire rope breakage in which the striated body and the wire rope are relatively slid along the longitudinal direction of the wire rope is detected. Method.   7. The elevator rope parking apparatus is an elevator lifting / lowering wire rope having one end connected to the elevator and the other end connected to a counterweight and hung around a drive sheave of the lifting / lowering driving device. To detect a break in the wire rope. The entry / exit floor of the elevator type parking device is formed on the lowest floor, the elevator drive device is installed on the top floor, and the lift drive device is a portion of the wire rope that hangs around the groove of the drive sheave Is driven up and down by frictional force,
Of the wire rope, the wire rod and the wire rope slide relative to the target inspection range, which is the portion of the wire sheave around the drive sheave when it is on the entry / exit floor and the vicinity of it. The method of detecting the strand breakage of the wire rope of Claim 7.   A request to slide the striate body and the wire rope relative to each other on the entry / exit floor with respect to the priority inspection target range when the counterweight is lowered to the lowest position by raising the elevator to the top floor. Item 9. A method for detecting wire breakage of a wire rope according to Item 8. In order to press the flexible linear body against the wire rope, a wire rope breakage detector according to any one of claims 1 to 5 is prepared,
The wire breakage detection tool and the wire rope are held in such a state that the wire breakage detection tool is held so that the wire rope is inserted into the opening of the detection tool, and the linear body is pressed on the outer peripheral surface of the wire rope. The method of detecting the breakage of the wire rope according to any one of claims 6 to 9, wherein the wire rope is slid relatively along the longitudinal direction of the wire rope.

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