JP2012201460A - Crane - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a crane capable of inhibiting the meandering of a trolley on a rail and inhibiting wear caused by contact between a flange of a trolley wheel and the rail, the swing of a suspended load, and the generation of noise in a crane having a cargo handling device (trolley) traveling on the rail.SOLUTION: In the crane having the rail 3 and the cargo handling device 2 traveling on the rail 3, the cargo handling device 2 includes a posture detecting sensor 20 detecting an inclination of the cargo handling device 2 relative to the rail 3 and a control device controlling the speed of the rotation of each wheel 10 of the cargo handling device 2. The posture detecting sensor 20 detects the inclination of the cargo handling device 2 relative to the rail 3 and the speed of the rotation of each wheel 10 is controlled based on the inclination of the cargo handling device 2.

Description

  The present invention relates to a crane having a cargo handling device (trolley) that moves along a rail. In particular, the present invention relates to a quay crane, a portal crane, and an overhead crane that handle marine transportation containers.

  At container terminals such as harbors and inland areas, containers between ships and trailers are handled by quay cranes and portal cranes. FIG. 11 shows a schematic diagram of a quay crane used in a container terminal. The quay crane 1 </ b> X includes a boom 32, a girder 33, and a leg structure 34. In addition, a cargo handling device (hereinafter referred to as a trolley) 2X that handles the container 31 is provided. Here, 30 indicates a container ship 30 and 35 indicates a quay 35.

  FIG. 12 shows a front view of the trolley 2X. The trolley 2X has a cab 4. This cab 4 has a plurality of wheels 10 installed via a drive device (motor) 11X. The wheel 10 has a collar 10a and a tread portion 10b. The trolley 2 </ b> X has a spreader 37 suspended through a wire 36. The spreader 37 is configured to suspend the container 31. The trolley 2X travels along the rail 3 laid on the boom 32 and the girder 33 of the crane 1X (see FIG. 11).

  Similarly, the trolley 2X which moves along the rail 3 is used also for a portal crane, an overhead crane, etc. (for example, refer patent document 1). The crane can handle the container 31 with the trolley 2X.

  However, the above crane has several problems. First, the collar 10a of the wheel 10 installed on the trolley 2X and the rail 3 come into contact with each other, which causes a problem of wear. This problem will be described with reference to FIG. In FIG. 13, the wheel 10 which the trolley 2X has and the plane of the rail 3 are shown typically.

  The wheel 10 moves while rotating on the rail 3 laid on the boom 32 and the girder 33 (see FIGS. 11 and 12) of the crane 1X. Here, the rail 3 is in contact with the tread surface portion 10 b of the wheel 10. When the trolley 2X moves along the rail 3, it is difficult to accurately move the trolley 2X straight or backward along the rail 3. Therefore, a problem (hereinafter referred to as a brim) that the rail 3 and the brim 10a come into contact with each other occurs.

  Specifically, for example, as shown in FIG. 13, a moment (see an arrow) is generated in the trolley 2X, and the trolley 2X is skewed to the left in the traveling direction F. At this time, the rail 3 and the flange 10a are in contact with each other at the flange generating portion P. Next, the trolley 2X is skewed to the right in the traveling direction F due to the reaction force of the swallow, and the swirl occurs again. As described above, the trolley 2X is skewed to the left and right and meanders on the rail 3 while repeating the swallow. Due to this brim, wear occurs in the brim 10a and the rail 3. A great maintenance cost including the replacement of the worn collar 10a and the rail 3 becomes necessary.

  Secondly, the trolley 2X meanders on the rail 3 due to the contact between the rail 3 and the collar 10a, and there is a problem that the suspended load (the container 31 and the spreader 37, etc.) shakes. It is desirable to suppress the swing of the suspended load because it may lead to an accident in which the suspended container 31 or the like collides with another container or a trailer.

  Thirdly, there is a problem that noise is generated by the contact between the rail 3 and the collar 10a.

JP 2010-58929 A

  The present invention has been made in view of the above problems, and an object of the present invention is to suppress meandering of the trolley on the rail in a crane having a cargo handling device (trolley) that travels on the rail. It is an object of the present invention to provide a crane that suppresses the wear caused by the contact between the collar and the rail (the brim), the swing of the suspended load, and the generation of noise.

  In order to achieve the above object, a crane according to the present invention includes a rail and a crane having a cargo handling device that travels on the rail, wherein the cargo handling device detects an inclination of the cargo handling device with respect to the rail. And a control device that controls the number of rotations of each wheel of the cargo handling device, wherein the attitude detection sensor detects the inclination of the cargo handling device with respect to the rail, and It has the structure which controls the rotation speed of a wheel, It is characterized by the above-mentioned.

  With this configuration, the crane can detect the skew of the cargo handling device (trolley) and can correct the skew, so that the trolley can travel in parallel with the rail extension direction. it can. Thereby, meandering of the trolley on the rail can be suppressed, and wear due to contact between the trolley wheel and the rail (swing), swinging of the suspended load, and generation of noise can be suppressed.

  In the crane described above, the posture detection sensor includes at least one of a proximity switch, a roller plunger type limit switch, a roller lever type limit switch, or a hinge lever type limit switch. With this configuration, the same effects as described above can be obtained.

  In the crane described above, a total of four of the posture detection sensors are installed as a pair in the forward direction and the reverse direction on one side of the cargo handling device, or two so as to be positioned on the diagonal of the cargo handling device. A total of four sets are installed as one set. With this configuration, the same effects as described above can be obtained.

  In the above crane, the posture detection sensor includes a rail guide installed in the cargo handling device, and the rail guide is rotatably supported by the cargo handling device via a fulcrum, and the arm A contact part installed at an end of the part, and an elastic body that gives a restoring force so that the contact part and the rail are always in contact with each other. With this configuration, the skew of the trolley can be detected more stably.

  According to the crane according to the present invention, in a crane having a cargo handling device (trolley) traveling on the rail, the meandering of the trolley on the rail is suppressed, and contact between the collar of the wheel of the trolley and the rail (swell) It is possible to provide a crane in which wear, swinging of a suspended load, and generation of noise are suppressed.

It is the top view which showed the rail and wheel of the crane of embodiment which concerns on this invention. It is the top view which showed the rail and wheel of the crane of embodiment which concerns on this invention. It is the top view which showed the rail and wheel of the crane of embodiment which concerns on this invention. It is the top view which showed the rail and wheel of the crane of different embodiment which concern on this invention. It is the top view which showed the rail and wheel of the crane of different embodiment which concern on this invention. It is the top view which showed the rail and wheel of the crane of different embodiment which concern on this invention. It is the top view which showed the Example of the attitude | position detection sensor. It is the top view which showed the Example from which an attitude | position detection sensor differs. It is the top view which showed the Example from which an attitude | position detection sensor differs. It is the top view which showed the Example from which an attitude | position detection sensor differs. It is the schematic which showed the conventional quay crane. It is a front view of the conventional cargo handling apparatus (trolley) of a crane. It is the top view which showed the rail and wheel of the conventional crane.

  Hereinafter, a crane according to an embodiment of the present invention will be described with reference to the drawings. In FIG. 1, the wheel 10 of the trolley (load handling apparatus) 2 of the crane 1 (not shown) of embodiment which concerns on this invention, and the schematic diagram of the plane of the rail 3 are shown. The trolley 2 includes a wheel 10, a posture detection sensor 20, and a control device (not shown) that controls the output of each motor 11. The wheel 10 includes a collar 10a and a tread portion 10b. The posture detection sensors 20 are used in pairs and are arranged so as to sandwich one rail 3 from both sides. A total of four sensors 20 are installed in one set at two locations on one side of the trolley 2 (left side in FIG. 1). A white arrow indicates the forward direction F of the trolley 2.

  Next, control of traveling of the trolley 2 will be described. FIG. 2 shows a state in which the trolley 2 is skewed to the left in the forward direction F with respect to the rail 3. Here, when the trolley 2 travels in the forward direction F, a set of posture detection sensors 20 installed in the forward direction F of the trolley 2 are configured to operate. When the trolley 2 is skewed, the inside of the front posture detection sensor 20 (the sensor shown in black) reacts and transmits a signal to the control device. The control device controls the motor 11 so that the rotation speed nL of the skewed wheel (left wheel) 10 is larger than the rotation speed nR of the right wheel (nL> nR). By this control, a moment is generated in the trolley 2 so that the trolley 2 rotates to the right in the forward direction F.

  Similarly, when the trolley 2 is skewed to the right in the forward direction F, the outside of the front posture detection sensor 20 (the sensor shown in black) reacts and transmits a signal to the control device (see FIG. 3). At this time, the control device controls the rotation speed so that the rotation speed nR of the right wheel is larger than the rotation speed nL of the left wheel (nL <nR).

With the configuration in which the above control is repeated, the trolley 2 is controlled so as to go straight in parallel with the rail 3. That is, the trolley 2 can compare the longitudinal direction of the rail and the traveling direction of the trolley 2 to detect the inclination in these two directions, and correct the inclination to reduce the inclination. For this reason, the crane 1 can suppress wear of the rails 3 and the wheels 10 generated by the skew and swallowing of the trolley 2, shaking of the suspended load (such as the container 31 and the spreader 37), and generation of noise. .

  In FIG. 4, the wheel 10 of the trolley (load handling apparatus) 2a of the crane (not shown) of different embodiment which concerns on this invention, and the schematic diagram of the plane of the rail 3 are shown. The trolley 2a is provided with a posture detection sensor 20 so as to be positioned on the diagonal of the trolley 2a. The trolley 2a travels in the reverse direction R as indicated by an arrow, and skewing occurs toward the right in FIG. At this time, the control device controls the rotation speed of the wheel 10 so that nL <nR. By this control, the skew of the trolley 2a can be suppressed as described above. In addition, you may install the attitude | position detection sensor 20 in the position corresponding to the wheel 10 of the four corners of the trolley 2a, respectively. Further, when the trolley travels, the sensor for detecting the skew may be performed by any installed sensor. Moreover, you may comprise so that skew may be detected from the result detected with the some sensor. With this configuration, for example, even when a failure occurs in one sensor, the skew of the trolley can be detected.

  FIG. 5A is a schematic diagram of a plane of the rail 10 and the wheels 10 of the trolley (loading device) 2b of a crane (not shown) according to another embodiment of the present invention. The trolley 2b is provided with posture detection sensors 20 so as to be positioned at the four corners of the trolley 2b and inside the rail 3.

  When the trolley 2b is traveling straight, the posture detection sensor 20 is not detected (off) (see FIG. 5B). When the trolley 2b is skewed, the posture detection sensor 20 is in a detected (on) state (see FIG. 5C).

  FIG. 6A shows a schematic diagram of a plane of the wheel 10 and the rail 3 of the trolley (loading device) 2c of a crane (not shown) of a different embodiment according to the present invention. The trolley 2c is provided with a posture detection sensor 20 so as to be positioned on one side of the trolley 2c and above the rail 3.

  When the trolley 2c is traveling straight, the posture detection sensor 20 is in a detection (on) state (see FIG. 6B). When the trolley 2c is skewed, any of the posture detection sensors 20 is in a non-detection (off) state (see FIG. 6C).

  7 to 10 show specific examples of the posture detection sensor 20. FIG. 7A shows an example in which the posture detection sensor 20 is configured by a proximity switch 20a. The proximity switch 20a detects the approach of the rail 3 in a non-contact manner, and can adopt an induction type, a capacitance type, an ultrasonic type, a photoelectric type, a magnetic type, or the like (JISC8201-5-2). reference). 7A shows a state where no skew has occurred in the trolley 2, and FIG. 7A shows a state where the skew has occurred in the trolley 2. The same applies hereinafter.

  FIG. 7B shows an example in which the posture detection sensor 20 is configured by a roller plunger type limit switch 20b. The limit switch 20b is configured such that a roller installed at an end thereof is pushed in as the trolley 2 is skewed to detect the attitude of the trolley 2.

  FIG. 8A shows an example in which the posture detection sensor 20 is configured by a roller lever type limit switch 20c. The limit switch 20c is configured such that a lever installed so as to be tilted is brought down when the trolley 2 is skewed and the posture of the trolley 2 is detected.

  FIG. 8B shows an example in which the posture detection sensor 20 is configured by a hinge lever type limit switch 20d. The tilted lever is pushed down when the trolley 2 is skewed, and the posture of the trolley 2 is detected.

  FIG. 9 shows an example of a trolley 2b in which the posture detection sensor 20 is configured by a rail guide 20e. This rail guide 20e gives the restoring force so that the arm part 22 supported rotatably at the fulcrum 21, the contact part 23 installed at the end part of the arm part 22, and the contact part 23 and the rail 3 are always in contact with each other. An elastic body (spring mechanism or the like) 24 is provided. The rail guide 20e is configured to detect the rotation amount of the arm portion 22 around the fulcrum 21 and detect the attitude of the trolley 2b from the rotation amount.

  FIG. 10 shows an example of a trolley 2c in which the posture detection sensor 20 is configured by a load cell 20f. The load cell 20f is configured to detect a thrust force S generated on the wheel 10, the motor 11, and the axle. The load cell 20f can detect the attitude of the trolley 2c by detecting the thrust force S.

  The example of the trolley attitude detection sensor 20 has been described above, but the present invention is not limited to this configuration. The posture detection sensor 20 only needs to have a configuration that can detect how much the trolley 2 is traveling with respect to the longitudinal direction of the rail 3.

DESCRIPTION OF SYMBOLS 1 Crane 2 Handling apparatus, Trolley 3 Rail 10 Wheel 10a Collar 10b Tread part 11 Driving device, Motor 20 Attitude detection sensor 20a Proximity switch 20b Roller plunger type limit switch 20c Roller lever type limit switch 20d Hinge lever type limit switch 20e Rail guide 20f Load cell 21 Support point 22 Arm portion 23 Contact portion 24 Elastic body

Claims (4)

In a crane having a rail and a cargo handling device that travels on the rail,
An attitude detection sensor for detecting an inclination of the cargo handling device with respect to the rail;
Having a control device for controlling the rotation speed of each wheel of the cargo handling device;
The crane having a configuration in which the posture detection sensor detects an inclination of the cargo handling device with respect to the rail and controls the number of rotations of each wheel based on the inclination of the cargo handling device.   2. The crane according to claim 1, wherein the posture detection sensor includes at least one of a proximity switch, a roller plunger type limit switch, a roller lever type limit switch, or a hinge lever type limit switch.   A total of four of the posture detection sensors are installed as a pair in the forward direction and the backward direction on one side of the cargo handling device, or a total of four as a set of two so that they are positioned on the diagonal of the cargo handling device. The crane according to claim 1 or 2, wherein two cranes are installed. The posture detection sensor is composed of a rail guide installed in the cargo handling device,
The rail guide is rotatably supported by the cargo handling device via a fulcrum, a contact portion installed at an end of the arm portion, and a restoring force so that the contact portion and the rail are always in contact with each other. The crane according to claim 1, further comprising an elastic body that gives

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