JPH09188496A - Wire rope damage detecting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wire rope damage detecting device for reducing the size, weight, and cost, and have high detecting sensitivity. SOLUTION: A line of a magnetic force emanating from the N-pole of a permanent magnet 3 forms a magnetic circuit crossing a jib derricking wire rope 1 and returning to an S-pole. When damage 1a occurs to the jib derricking wire rope 1, magnetic resistance of a damage spot is increased and the line of a magnetic force is bent in the damage spot. As a result, the number of lines of a magnetic force exerted on a hall IC 4 arranged in the magnetic circuit is decreased, and magnetic flux density B exerted on the hall IC 4 is reduced. This constitution reduces the voltage level of a hall voltage VH and detects the damage 1a of the jib derricking wire rope 1.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wire rope damage detecting device for detecting damage to a wire rope used in a construction machine or the like.

[0002]

2. Description of the Related Art Conventionally, a wire rope damage detecting device of this type has been used, for example, for detecting damage occurring on a jib undulating wire rope of a crane. The magnetic flaw detection method is generally adopted as the detection principle of this conventional wire rope damage detection device. In this magnetic flaw detection method, damage to the wire rope is detected by locally magnetizing the wire rope in the longitudinal direction and allowing leakage flux generated on the surface of the wire rope due to wire breakage to pass through the coil. That is, the surface layer portion of the wire rope is brought into a saturated magnetization state by the electromagnet, and the coil is fixedly provided near the surface layer portion. The jib undulating wire rope moves along these electromagnets and coils by being wound and unwound on a drum. When the wire rope damaged due to the wire breakage is brought into a saturated magnetization state by the electromagnet, the magnetic flux crossing the wire rope is disturbed, and leakage magnetic flux is generated in the damaged portion of the wire rope. When this leakage flux crosses the coil as the wire rope moves, electromotive force is generated at both ends of the coil according to Lenz's law. Damage to the wire rope is detected by detecting this electromotive force.

[0003]

However, in the wire rope damage detection device using the above-mentioned conventional magnetic flaw detection method, it is necessary to magnetize the wire rope considerably strongly in order to bring the wire rope into the saturated magnetization state. Therefore,
A large capacity electromagnet is required, and the rope magnetizer becomes quite large. Moreover, in such a large-capacity electromagnet, heat generation due to the current increases, which makes it difficult to operate for a long time. Further, in order to prevent heat generation due to this current, it is conceivable to use a permanent magnet in the rope magnetizing device instead of the electromagnet. However, since a large permanent magnet that produces a strong magnetic force is expensive, it is not cost-effective to use the permanent magnet in the rope magnetizing device.

Further, the magnitude of the wire rope damage detection signal corresponds to the electromotive force induced in the coil, and this electromotive force depends on the speed at which the above-mentioned leakage flux crosses the coil, that is, the moving speed of the wire rope. Therefore, in order to detect the damage of the wire rope with high sensitivity, it is necessary to keep the moving speed of the wire rope constant and measure the data in a state where the damage detection signal is obtained at a constant level. However, when the wire rope is wound on the drum in several layers, the winding radius varies depending on the layers, and the winding speed of the wire rope changes. Further, the winding speed of the wire rope also changes due to fluctuations in the rotation of the engine that drives the drum. Furthermore, winding of wire rope,
The movement speed of the wire rope decreases when starting and stopping the unwinding. Therefore, it is difficult to always keep the moving speed of the wire rope constant.

Further, the voltage level of the electromotive force generated at both ends of the coil is not sufficient only by increasing the moving speed of the wire rope, and it is necessary to electrically amplify the damage detection signal by a measuring amplifier or the like. However, measurement amplifiers are generally expensive, and the use of expensive measurement amplifiers has been an obstacle to lowering the cost of the device.

Further, in the conventional wire rope damage detection device, if the wire rope vibrates or pulsates while detecting the damage to the wire rope, the wire rope will be damaged even if it is not damaged. Disturbances occur in the intersecting magnetic flux. Therefore, the conventional wire rope damage detection device may erroneously detect the disturbance of the magnetic flux as damage to the wire rope.

[0007]

The present invention has been made in order to solve such a problem, and is a magnetizing means for intersecting a magnetic field with a wire rope and a magnetic sensitive element to which a magnetic field intersecting with the wire rope is applied. And a signal detection circuit for detecting an electric signal appearing in the magnetic sensitive element according to the magnetic field, and thus a wire rope damage detection device is configured.

Further, the magnetizing means and the magnetic sensitive element are
The wire rope was provided on the outer peripheral surface of the bobbin made of a non-magnetic material.

Further, two magnetic sensing elements are arranged side by side on the same strand of the wire rope at a pitch, and the signal detection circuit differentially amplifies each electric signal detected by each magnetic sensing element. And

Further, two magnetic sensitive elements are arranged in parallel along the direction on the same strand of the wire rope, and the signal detection circuit differentially amplifies each electric signal detected by each magnetic sensitive element. And

In such a structure, the magnetic field lines emitted from the N pole of the magnetizing means intersect the wire rope and S of the magnetizing means.
Form a magnetic path that returns to the pole. When the wire rope is damaged and a space is created at the damaged part, the magnetic resistance of the space part in the middle of this magnetic path becomes high. Therefore, when the wire rope is damaged, the lines of magnetic force are bent at the damaged portion, and as a result, the magnetic flux passing through the magnetically sensitive element, for example, the Hall element provided in the magnetic path changes. That is, when the wire rope is damaged, the electric signal detected by the magnetically sensitive element changes according to the change in the magnetic flux. For example, when the magnetic sensitive element is a Hall element, the Hall voltage detected by the Hall element changes according to the change in the magnetic flux. Therefore, the change of the electric signal detected by the magnetic sensitive element,
For example, the damage of the wire rope can be detected by detecting the change in the Hall voltage appearing in the Hall element.

In a magnetic sensitive element such as a Hall element, a detected electric signal such as a Hall voltage greatly changes in response to a slight change in magnetic flux passing through. Further, since the detection level of the detection electric signal such as the Hall voltage is high, the voltage level of the wire rope damage detection signal can be easily increased without using an expensive measurement amplifier. Also, the damage of the wire rope is
The damage detection signal is detected by a change in the detected electric signal such as a change in the Hall voltage of the Hall element due to a change in the magnetic resistance of the magnetic path, and the magnitude of the damage detection signal does not depend on the moving speed of the wire rope.

Further, when two magnetic sensitive elements are arranged in parallel on the same strand of the wire rope at a pitch and the detected electric signals of the respective magnetic sensitive elements are differentially amplified, it is caused by disturbance such as vibration of the wire rope. Each detected electrical signal change is canceled. That is, when one magnetic sensitive element detects the signal change due to the wire rope damage by superimposing on this signal change caused by the disturbance, and the other magnetic sensitive element detects only the signal change caused by the disturbance, When the detection signals of the magnetic sensitive element are differentially amplified, the respective signal changes caused by the disturbance are subtracted from each other in this differential amplification processing, and are offset to become zero.

If two magnetic sensitive elements are arranged in parallel on the same strand of the wire rope and the detected electric signals of these magnetic sensitive elements are differentially amplified, disturbances such as wire rope vibrations occur. Each detected electrical signal change is similarly canceled. Further, since the magnetic sensitive elements are close to each other along the twist direction of the same strand, the wire rope is worn, and this wear changes the distance between the magnetic sensitive element and the rope surface to change the detected electric signal. However, the influence is similar to each magnetic sensitive element.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION Next, a first embodiment in which the wire rope damage detecting device according to the present invention is applied to detect damage to a jib undulating wire rope of a crane will be described.

FIG. 1 shows a schematic structure of a wire rope damage detection device according to this embodiment. The jib undulating wire rope 1 is wound between a bridle and a bail (not shown), and is also wound on an undulating drum (not shown).
When the jib undulating wire rope 1 is wound around the undulating drum, the jib pivotally supported in front of the crane is pulled backward, and the jib is undulated. This jib undulating wire rope 1
A strand in which the strands are twisted together is further twisted around the core wire. The cylindrical bobbin 2 is made of a non-magnetic material and is formed of, for example, a vinyl chloride pipe. The bobbin 2 has a hollow portion through which the jib undulating wire rope 1 passes.

A plurality of permanent magnets 3 are provided on the outer peripheral surface of the bobbin 2.
A plurality of Hall ICs 4 are provided along the surface layer of the jib undulating wire rope 1. Each permanent magnet 3 crosses a magnetic field on the surface layer portion of the wire rope 1, and each Hall IC 4 is acted on by a magnetic field crossing the jib undulating wire rope 1. Each Hall IC 4 is electrically connected to the signal amplifying device 5, and operates by receiving power supply from the signal amplifying device 5. Further, the wire rope damage detection signal output from each Hall IC 4 is given to this signal amplifying device 5 and amplified by an internal amplifying circuit. The signal amplifying device 5 constitutes a signal detecting circuit for detecting the Hall voltage V _H appearing in the Hall IC 4.

FIG. 2 is a perspective view showing the operating principle of the Hall IC 4 made of a semiconductor thin piece. During the operation of the Hall IC 4, the control current IC is constantly applied between the terminals a and b. In this state, when a magnetic field acts perpendicular to the flow of the control current IC,
The Hall voltage V _H appears in the direction perpendicular to the current IC and the magnetic field. This Hall voltage _VH is generated by the Hall effect of the semiconductor thin piece, and its magnitude is proportional to the product IC · B of the current IC and the magnetic flux density B and is detected between the terminals c and d of the Hall IC 4. Therefore, power is supplied from the signal amplifying device 5 and the control current IC is supplied to the Hall IC 4,
The Hall IC 4 generates a magnetic field that intersects the surface layer of the wire rope 1.
Change in the magnetic flux density B caused by the damage of the jib undulating wire rope 1 is caused by the Hall voltage V _H.
Can be detected as a change in

FIG. 3 shows the damage detection principle of the wire rope damage detection device according to this embodiment. In this figure, the same parts as those in FIG. 1 are denoted by the same reference numerals, and the description thereof will be omitted. As shown in (a) of the same figure, the magnetic force lines from the N pole of each permanent magnet 3 return to the S pole, and the jib undulating wire rope 1
To form a line of magnetic force that passes through the Hall IC 4 from the lower surface to the upper surface. Further, the signal amplifying device 5 allows the hall I
The above-mentioned control current IC is applied to C4. With the wire rope damage detection device set in this way, the jib undulating wire rope 1 is wound or unwound on an undulating drum and moves in the bobbin 2. Therefore, the surface layer portion of the jib undulating wire rope 1 is uniformly magnetized by each permanent magnet 3 by this movement.

Here, a part of the wire constituting the jib undulating wire rope 1 is broken and, for example, the damage 1 shown in FIG.
It is assumed that a occurs on the jib undulating wire rope 1. A magnetic line of force emerging from the N pole of the permanent magnet 3 forms a magnetic path that intersects the jib undulating wire rope 1 and returns to the S pole. When the jib undulating wire rope 1 is damaged as described above, a space is created in the magnetic path at the position where the damage 1a is generated,
The magnetic resistance of the damaged part is high. Therefore, when the damage 1a occurs in the jib undulating wire rope 1, the lines of magnetic force are shown in FIG.
As shown in (1), it is bent at the place where the damage 1a occurs. As a result, the number of magnetic lines of force acting on the Hall IC 4 provided in the magnetic path is reduced as compared with the case without the damage 1a, and the magnetic flux density B acting on the Hall IC 4 changes.

That is, when the damage 1a occurs in the jib undulating wire rope 1, the Hall voltage V _H detected by the Hall IC 4 decreases in proportion to the decrease in the acting magnetic flux density. Therefore, in the wire rope flaw detection apparatus according to the present embodiment, by detecting a decrease in the voltage level of the Hall voltage V _H, it is possible to detect damage 1a of jib hoist wire rope 1.

In this Hall IC 4, as shown in the graph of FIG. 4, the Hall voltage V _H changes greatly with a slight change in the magnetic field. The horizontal axis of the graph is the magnetic flux density [KG], and the vertical axis is the Hall output voltage V _H [mV]. As shown in the graph, in the range of the magnetic flux density of 0 to about 1 [KG], the Hall output voltage V _H is large in the range of 0 to about 150 [mV] with respect to a slight change in the magnetic flux density. Change. Therefore, even if the magnetic field applied to the Hall IC 4 is weak, the change in the Hall voltage V _H can be sufficiently detected. That is, unlike the conventional wire rope damage detection device using the magnetic flaw detection method, a magnetic field that is strong enough to bring the wire rope into a saturated magnetization state is not required, and a small permanent magnet 3 can be used as the magnet of the magnetization device. I can.

Therefore, according to the present embodiment, there is provided a wire rope damage detecting device which is much smaller and lighter than the conventional wire rope damage detecting device which requires a large-capacity magnetizing device. Further, since the small-capacity and small-sized permanent magnet 3 can be obtained at a low price, the device can be realized at a low price, and the cost is also profitable. In addition, conventionally, the current supplied to the electromagnet to generate a strong magnetic field is no longer necessary,
Therefore, heat generation due to Joule heat does not occur. Therefore, it is possible to operate for a long time, and it is possible to continuously monitor the damage of the wire rope.

Further, since the detection level of the hall voltage V _H is high, the voltage level of the wire rope damage detection signal can be easily increased without using an expensive measurement amplifier. In other words, in the conventional wire rope damage detection device, since the weak electromotive force induced at both ends of the coil is used as the damage detection signal, the signal voltage level is low, and therefore, the expensive detection measurement is required to amplify the damage detection signal. An amplifier was needed.
However, the wire rope damage detection device according to the present embodiment can obtain a damage detection signal having a sufficient voltage level without using such an expensive measurement amplifier.

Further, the damage 1a of the wire rope 1 is detected by the change of the Hall voltage V _H of the Hall IC 4 due to the change of the magnetic resistance of the magnetic path, as described above, and the magnitude of the damage detection signal is as large as that of the wire rope 1. It does not depend on the moving speed. That is, in the conventional wire rope damage detection device, since the electromotive force of the coil is used for damage detection, it is necessary to cause the leakage flux generated by the damage of the wire rope to traverse the coil at a constant speed. Therefore, in the conventional wire rope damage detecting device, in order to detect damage with high sensitivity, it is necessary to keep the moving speed of the wire rope constant. However, since the wire rope damage detection device according to the present embodiment detects the damage by the change of the Hall voltage V _H as described above, the damage 1a of the wire rope 1 is detected without being restricted by such rope speed. It can be detected with high sensitivity.

Next, a wire rope damage detecting device according to a second embodiment of the present invention will be described with reference to FIG. In the figure, parts that are the same as or correspond to those in FIG. 1 are assigned the same reference numerals and explanations thereof are omitted.

In this embodiment, as shown in FIG. 1A, two Hall elements 4a and 4b are arranged side by side on the outer circumferential surface of the bobbin 2 with a strand pitch p on the same strand 1s of the wire rope 1. Has been done. The permanent magnets 3a and 3b apply a magnetic field to the Hall elements 4a and 4b as in the first embodiment described above. Further, the signal amplification device 5 is provided with a differential amplification circuit (not shown). The Hall voltages V _Ha and V _Hb detected by the Hall elements 4a and 4b are input to the differential amplifier circuit.

In the wire rope damage detecting apparatus according to the present embodiment, even if a disturbance is applied to the wire rope 1 due to vibration or pulsation of the wire rope 1 during rope inspection, such disturbance is It is possible to accurately detect damage to the wire rope 1 without being affected.

That is, when a disturbance is applied to the wire rope 1, the distance d between the Hall elements 4a and 4b and the surface of the wire rope 1 shown in FIG. In addition, FIG.
Is a vertical sectional view of FIG. In addition, each Hall element 4
The Hall voltage V _H detected by a and b greatly depends on this distance d and is proportional to d ⁻² . Therefore, when the distance d changes due to disturbance, the detected Hall voltage V _H changes even if the wire rope 1 is not damaged. Therefore, when no measures are taken, this voltage change is detected by the signal amplification device 5, and the wire rope 1
It is erroneously detected that there is damage to the.

However, in this embodiment, as described above, the pitches p are separated on the same strand 1s of the wire rope 1, and the Hall elements 4a,
Since two b are arranged side by side and the Hall voltages V _Ha and V _Hb detected by the Hall elements 4a and 4b are differentially amplified, a signal change amount generated in each detection signal due to disturbance due to vibration of the wire rope 1 or the like. ΔV _a and ΔV _b cancel each other out. That is,
One Hall element 4a detects the signal change V due to the wire rope damage 1a by superimposing on this signal change amount ΔV _a caused by the disturbance, and V + Δ as a change in the Hall voltage V _Ha.
It is assumed that V _a is output (ΔV _Ha = V + ΔV _a ). Also,
The other Hall element 4b detects only the signal change ΔV _b caused by the disturbance, and ΔV is detected as the change in the Hall voltage V _Hb.
It is assumed that _b is output (ΔV _Hb = ΔV _b ).

In this case, when the signal amplifying device 5 differentially amplifies the detection signals of these Hall elements 4a and 4b, first,
Each of these detection signals is subtracted as in the following equation to calculate the variation Δ. Here, each Hall element 4a, b is caused by disturbance.
It is assumed that the signal changes ΔV _a and ΔV _b appearing at are equal (ΔV _a = ΔV _b ).

Δ = ΔV _Ha −ΔV _Hb = (V + ΔV _a ) − (ΔV _b ) = V

Therefore, each Hall element 4a,
The respective signal changes ΔV _a and ΔV _b appearing in _b are subtracted from each other in this differential amplification processing in the signal amplification device 5, and are canceled out to become zero. Therefore, only the signal change V due to the wire rope damage is amplified and output, and the wire rope 1
The rope damage can be detected with high accuracy without being affected by the external disturbance.

Next, a wire rope damage detecting device according to a third embodiment of the present invention will be described with reference to FIG. In the figure, parts that are the same as or correspond to those in FIG. 1 are assigned the same reference numerals and explanations thereof are omitted.

In the present embodiment, as shown in FIG. 2A, two Hall elements 4c and 4d are arranged on the outer surface of the bobbin 2 on the same strand 1s of the wire rope 1 along the twist direction of the strand. It is set up. Also in this embodiment, the permanent magnets 3c and 3d apply a magnetic field to these Hall elements 4c and 4d as in the first embodiment. Further, the signal amplification device 5 is provided with a differential amplification circuit (not shown), and each of the Hall elements 4c,
The Hall voltages V _Hc and V _Hd detected at d are input.

Also in the wire rope damage detecting device according to the present embodiment, even if a disturbance such as rope vibration is applied to the wire rope 1 like the above-mentioned second embodiment, it is not affected by the disturbance. It is possible to accurately detect damage to the wire rope 1.

That is, when a disturbance is applied to the wire rope 1, the distance d between the Hall elements 4c and 4d and the surface of the wire rope 1 shown in FIG. In addition, FIG.
FIG. 3 is a partially cutaway sectional view of FIG. The Hall voltage V _H detected by each of the Hall elements 4c and 4d is proportional to d ⁻² as described above. Therefore, if the distance d changes due to a disturbance, the detected Hall voltage V _H changes even if the wire rope 1 is not damaged, and it is erroneously detected that the wire rope 1 is damaged. .

However, also in this embodiment, as described above,
On the same strand 1s of the wire rope 1, two Hall elements 4c and d are juxtaposed along the twist direction of the strand, and the Hall voltages V _Hc and V detected by the Hall elements 4c and d, respectively.
_{Since Hd} is differentially amplified, the amount of signal change Δ that occurs in each of these detection signals due to disturbances such as vibration of the wire rope 1
V _c and ΔV _d are canceled in the same manner as in the above embodiment. Therefore, also in this embodiment, only the signal change V due to the wire rope damage 1a is amplified and output, and the rope damage is accurately detected without being affected by the disturbance applied to the wire rope 1.

Further, in this embodiment, each Hall element 4 is
Since c and d are provided closer to each other along the twist direction of the same strand 1s, even if the wire rope 1 is worn, the distance d between each Hall element 4c and d and the surface of the strand 1s is It is kept almost the same. That is, even if the wire rope 1 is worn so that it cannot be regarded as rope damage and the distance d becomes large, the influence of the change in the detected Hall voltage due to the increase in the distance d affects both of the Hall elements 4c and 4d. Almost evenly. Therefore, each Hall element 4c, d
By differentially amplifying the output of the above as described above, the distance d
The effects of the increase in

On the other hand, when the hall elements 4a and 4b are arranged side by side at the pitch p as in the damage detecting apparatus according to the second embodiment described above, the wear of the wire rope 1 causes each hole to be broken. The distances d between the elements 4a, b and the surface of the wire rope 1 may be different. For example, FIG.
The wear 1b of the wire rope 1 shown by the dotted line in (b) increases the distance d between the Hall element 4a and the surface of the wire rope 1 from d to d ′, while the distance between the Hall element 4b and the surface of the wire rope 1 increases. The distance d between may not change.

Therefore, when the hall elements 4a and 4b are arranged in parallel at a certain distance of the strand pitch p, the state of the strand 1s passing under the hall elements 4a and 4b is different even if no disturbance occurs. Each Hall element 4
Differences occur in the changes in the Hall voltages V _Ha and V _Hb detected in a and b. Therefore, when the outputs of the Hall elements 4a and 4b are differentially amplified, a considerably large level of detection signal may appear in the output of the signal amplifying device 5 even for the wear 1b which cannot be regarded as damage. Therefore, in the wire rope damage detection device according to the second embodiment described above, even if the signal changes ΔV _a and ΔV _b caused by the disturbance can be canceled,
In some cases, the amount of signal change based on the difference in the distance d cannot be offset.

However, as in the wire rope damage detecting device according to the present embodiment, by arranging the Hall elements 4c and 4d close to each other along the twist direction of the strand 1s,
Both the signal change caused by the disturbance such as rope vibration and the signal change caused by the difference in the degree of wear of the strand rope are canceled as described above. Therefore, according to the wire rope damage detection device of the present embodiment, it is possible to detect rope damage with higher accuracy.

In each of the above-described embodiments, the case where the present invention is applied to the damage detection of the jib undulating wire rope of the crane has been described, but the present invention is not limited to this and the damage detection of other wire ropes is performed. It is also possible to apply to. Even in this case, the same effect as that of each of the above-described embodiments can be obtained.

[0044]

As described above, according to the present invention, even if the magnetic field applied to the magnetic sensitive element such as the Hall element is weak, the detected electric signal change such as the Hall voltage change can be sufficiently detected. Therefore, a wire rope damage detection device that is much smaller and lighter than the conventional wire rope damage detection device that requires a large-capacity magnetizing device is provided.

A small-capacity and small-sized magnetizing device can be obtained at a low price, and the magnitude of the damage detection signal can be easily increased without using an expensive measuring amplifier. Therefore, the wire rope damage detection device can be realized at low cost.

Further, since an electromagnet that generates heat due to Joule heat is not required, it is possible to operate for a long time, and it is possible to continuously monitor the damage of the wire rope.

Further, since the damage to the wire rope is detected by the change in the detected electric signal such as the change in the Hall voltage, the damage to the wire rope can be detected with high sensitivity without depending on the moving speed of the wire rope.

When two magnetic sensitive elements are arranged in parallel on the same strand of the wire rope at a pitch and the detected electric signals of these magnetic sensitive elements are differentially amplified, it is caused by disturbance such as vibration of the wire rope. Each detected electrical signal change is canceled. For this reason, the influence of the disturbance applied to the wire rope can be suppressed to a minimum, and the rope damage can be accurately detected.

When two magnetic sensitive elements are arranged in parallel on the same strand of the wire rope and each detected electric signal of each magnetic sensitive element is differentially amplified, it is caused by disturbance such as vibration of the wire rope. Each detected electric signal change is canceled out, and each detected electric signal change caused by the difference in the degree of wear of the wire rope is also canceled out. Therefore, the rope damage can be detected more accurately without being affected by the disturbance applied to the wire rope and without being affected by the difference in the degree of wear of the wire rope.

[Brief description of the drawings]

FIG. 1 is a diagram showing a schematic configuration of a wire rope damage detection device according to a first embodiment of the present invention.

FIG. 2 is a perspective view showing the operating principle of a Hall IC used in the wire rope damage detection device according to the first embodiment.

FIG. 3 is a diagram showing a damage detection principle of the wire rope damage detection device according to the first embodiment.

FIG. 4 is a graph showing changes in Hall output voltage with respect to changes in magnetic flux density of a Hall IC used in the wire rope damage detection device according to the first embodiment.

FIG. 5 is a diagram showing a schematic configuration of a wire rope damage detection device according to a second embodiment of the present invention and a longitudinal section thereof.

FIG. 6 is a diagram showing a schematic configuration of a wire rope damage detection device according to a third embodiment of the present invention and a partially broken cross section thereof.

[Explanation of symbols]

 1 ... Jib undulating wire rope 2 ... Bobbin 3 ... Permanent magnet 4 ... Hall IC 5 ... Signal amplification device

Claims (5)

[Claims] 1. A magnetizing means for intersecting a magnetic field with a wire rope, a magnetic sensitive element to which the magnetic field intersecting the wire rope is applied, and a signal detection for detecting an electric signal appearing in the magnetic sensitive element according to the magnetic field. A wire rope damage detection device configured by including a circuit. 2. The magnetizing means and the magnetically sensitive element,
The wire rope damage detecting device according to claim 1, wherein the wire rope is provided on an outer peripheral surface of a bobbin made of a non-magnetic material which penetrates the wire rope. 3. The two magnetic sensitive elements are arranged in parallel on the same strand of the wire rope with a pitch, and the signal detection circuit differentially amplifies each electric signal detected by each magnetic sensitive element. The wire rope damage detection device according to claim 1 or 2, characterized in that. 4. The two magnetic sensitive elements are arranged in parallel along the direction on the same strand of the wire rope, and the signal detection circuit differentially amplifies each electric signal detected by each magnetic sensitive element. The wire rope damage detection device according to claim 1 or 2, characterized in that. 5. The wire rope damage detection device according to claim 1, wherein the magnetic sensitive element is a Hall element.