JP2021066553A - Torque controller - Google Patents

Abstract

To provide a torque controller capable of accurately controlling the torque of a cable reel 8 which delivers a power feeding cable 9 to, for example, a crane hanging tool 7 by being able to accurately calculate the cable length delivered from a cable reel 8.SOLUTION: A torque controller controls the torque of a cable reel 8 based on the wound diameter of a cable 9 corresponding to the integrated rotation angle from the origin of the cable reel 8, based on the delivery length of the cable 9 corresponding to the integrated rotation angle of the cable reel 8 and to the winding diameter of the cable 9, based on the weight of the delivered cable 9 corresponding to the delivery length of the cable 9, and based on the weight of the delivered cable 9 and on the winding diameter of the cable 9.SELECTED DRAWING: Figure 1

Description

The present invention relates to, for example, a torque control device for a cable reel that feeds a power supply cable to a crane hanger.

Conventionally, as shown in FIG. 1, for example, the torque control of the cable reel 8 for feeding the power feeding cable 9 to the crane hanger 7 is performed by setting the tension of the power feeding cable 9 delivered from the cable reel 8 as a predetermined value. It is desirable that the power cable 9 is not loosened and that an unnecessary load is not applied to the power supply cable 9.

Then, as disclosed in Patent Document 1, this torque control method includes the weight of the feeding cable 9 that has been fed out, and the metal fittings and the like necessary for fixing the feeding cable 9 to the crane hanger 7. Some are controlled based on the total weight of the cable accessories.

The weight of the crane hanger 7 itself and the crane bucket 7a suspended from the crane hanger 7 is supported by the wire cable 10 instead of the power supply cable 9.

Japanese Patent No. 5442314

The weight of the delivered power feeding cable 9, which is the weight required for torque control of the cable reel 8 for feeding the power feeding cable 9 as described above, is proportional to the length of the fed power feeding cable 9. The length of the fed power supply cable 9 that has been fed out can be calculated based on the rotation angle of the cable reel 8.

However, the length of the extended power supply cable 9 is not proportional to the rotation angle of the cable reel 8. This is because the power supply cable 9 is wound on the cable reel 8 so as to overlap with each other, so that the winding diameter of the power supply cable 9 changes depending on the wound length.

Therefore, in order to accurately calculate the length of the fed power supply cable 9 that has been fed out, it is necessary to correctly grasp the winding diameter of the power supply cable 9. In this regard, in the conventional torque control method disclosed in Patent Document 1, since the winding diameter of the power feeding cable 9 is not correctly grasped, the extended length cannot be calculated accurately, and as a result, the cable reel The torque control of No. 8 could not be performed accurately.

Therefore, the present invention has been proposed to solve the problems of the above-mentioned torque control method. For example, the torque control of the cable reel for feeding the power supply cable to the crane hanger is delivered from the cable reel. It is an object of the present invention to provide a torque control device that can be accurately calculated by accurately calculating the length.

The present invention has been proposed to solve the above problems, and the first invention (the invention according to claim 1) is suspended and supported by a wire cable and moved up and down by winding and unwinding the wire cable. An angle that detects the rotation angle of the cable reel, which is a torque control device that controls the torque of the cable reel that feeds out the cable in order to set the tension of the cable whose lower end is connected to the hanging tool to be operated to a predetermined value. A detection means, a drive means capable of varying the take-up torque of the cable reel, and a control means for acquiring a detection angle from the angle detection means and controlling the drive means to control the take-up torque of the cable reel. The control means sets the final winding position of the cable to the cable reel as the origin position of the cable reel, and the control means of the cable in the cable reel corresponding to the integrated rotation angle from the origin position of the cable reel. Based on the winding diameter, based on the integrated rotation angle of the cable reel and the feeding length of the cable corresponding to the winding diameter of the cable, and based on the weight of the feeding cable corresponding to the feeding length of the cable. It is characterized in that the torque of the cable reel is controlled based on the weight of the cable and the winding diameter of the cable.

The torque control device according to the first invention controls the torque of the cable reel based on the integrated rotation angle of the cable reel and the feeding length of the cable corresponding to the winding diameter of the cable.

The second invention (the invention according to claim 2) includes the origin detecting means for detecting the ascending limit of the hanging tool in the first invention, and the control means is detected by the origin detecting means. The rising limit is set to the origin position of the cable reel.

In the torque control device according to the second invention, the origin position of the cable reel can be easily determined.

Further, in the third invention (the invention according to claim 3), in either the first or second invention, the cable is wound on the cable reel by being stacked in the radial direction of the cable reel. The winding diameter is changed according to the feeding length from the cable reel.

In the torque control device according to the third invention, even if the cables are stacked and wound in the radial direction of the cable reel and the winding diameter changes according to the feeding length, the torque control of the cable reel is performed. Can be done accurately.

Further, a fourth invention (the invention according to claim 4) is a cable in which the cable is arranged in parallel in a predetermined number of rows in the axial direction of the cable reel in the cable reel in the third invention. The rows are stacked and wound in the radial direction of the cable reel, and the change in the winding diameter of the cable according to the feeding length from the cable reel corresponds to the change in the number of stages of the stacking of the cable rows. It is characterized by a stepwise change.

In the torque control device according to the fourth invention, parallel cable rows are stacked and wound in the radial direction of the cable reel, and the winding diameter is stepped according to a change in the number of stages of the cable rows. Even if it changes, the torque control of the cable reel can be accurately performed.

Further, in the fifth invention (the invention according to claim 5), in any one of the first to fourth inventions, the angle detecting means is attached to the drive shaft of the drive means, and the control means is the control means. The torque control of the drive means is performed by vector control using an inverter, and the inverter is characterized in that the detection angle signal from the angle detection means is relayed to the control means.

In the torque control device according to the fifth invention, the angle detecting means is also used for detecting the rotation angle of the cable reel and calculating the feeding length of the cable, thereby simplifying the device configuration. Can be done.

Further, in the sixth invention (the invention according to claim 6), in any one of the first to fifth inventions, the crane suspension is a crane suspension that suspends and supports the crane bucket. The cable is characterized in that it is a power supply cable that supplies power to the crane bucket.

The torque control device according to the sixth invention can be applied to a crane in which a crane bucket is suspended and supported by a crane hanger.

According to the torque control device according to the first invention (the invention according to claim 1), for example, the torque control of the cable reel for feeding the power supply cable to the crane hanger can be accurately controlled by the length fed from the cable reel. By being able to calculate, it can be done accurately.

Further, according to the torque control device according to the second invention (the invention according to claim 2), the origin position of the cable reel can be easily determined.

Further, according to the torque control device according to the third invention (the invention according to claim 3), the cables are stacked and wound in the radial direction of the cable reel, and the winding diameter changes according to the feeding length. Even so, the torque control of the cable reel can be accurately performed.

Further, according to the torque control device according to the fourth invention (the invention according to claim 4), the parallel cable rows are stacked and wound in the radial direction of the cable reel, and the cable rows are stacked. Even if the winding diameter changes stepwise according to the change in the number of stages, the torque control of the cable reel can be accurately performed.

Further, according to the torque control device according to the fifth invention (the invention according to claim 5), the angle detecting means is also used for detecting the rotation angle of the cable reel and calculating the feeding length of the cable. Therefore, the device configuration can be simplified.

Further, according to the torque control device according to the sixth invention (the invention according to claim 6), it can be applied to a crane in which a crane bucket is suspended and supported by a crane suspender.

It is a side view which shows the structure of the crane to which the torque control device which concerns on this invention is applied. It is a block diagram which shows the structure of the said torque control device. It is sectional drawing which shows the structure (one row winding) of the cable reel of the said crane. It is a graph which shows the relationship (1 row winding) of the cable feeding length and the integrated rotation angle of a cable reel. It is sectional drawing which shows the structure (the plurality of rows winding) of the cable reel of the said crane. It is a graph which shows the relationship (multiple row winding) of the cable feeding length and the integrated rotation angle of a cable reel. It is a graph which shows the relationship between the cable feeding length and the required winding torque. It is a flowchart which shows the operation of the said torque control device.

Hereinafter, the torque control device according to the present invention will be described in detail with reference to the drawings.

In the torque control device according to the present invention, the cable is unwound in order to set the tension of the cable whose lower end is connected to the hanger which is suspended and supported by the wire cable and which is lifted and lowered by winding and unwinding the wire cable. It is a device that controls the torque of the cable reel.

FIG. 1 is a side view showing a configuration of a crane to which the torque control device according to the present invention is applied. The torque control device according to this embodiment is an application of the present invention to a crane, and as shown in FIG. 1, the above-mentioned suspension tool is a crane suspension tool 7 that suspends and supports the crane bucket 7a. The cable is a power supply cable 9 that supplies power to the crane bucket 7a.

In the crane 11, the weight of the crane hanger 7 itself and the crane bucket 7a suspended from the crane hanger 7 is supported by the wire cable 10 instead of the power supply cable 9. The crane hanger 7 is suspended and supported by the wire cable 10, and is lifted and lowered by winding and unwinding the wire cable 10.

Further, the lower end of the power supply cable 9 is connected to the power input unit of the crane hanger 7, and the power supply necessary for operations such as opening and closing of the crane bucket 7a is supplied to the power input unit. Further, the cable drum 5 for winding the wire cable 10 and the cable reel 8 for winding the power supply cable 9 are rotatably installed on the trolley 6 movably installed on the crane girder 3. There is.

Then, this torque control device controls the torque of the cable reel 8 that winds up and unwinds the power supply cable 9 to the crane hanger 7 in the crane 11. The torque control of the cable reel 8 does not cause slack in the power supply cable 9 by setting the tension of the power supply cable 9 unwound from the cable reel 8 as a predetermined value, and is unnecessary for the power supply cable 9. This is done so as not to give a heavy load.

Then, the torque control device includes the weight of the power supply cable 9 unwound from the cable reel 8 and the weight of cable accessories such as metal fittings required to fix the power supply cable 9 to the crane hanger 7. The rotational drive torque of the cable reel 8 is controlled based on the total of the above.

FIG. 2 is a block diagram showing the configuration of the torque control device. As shown in FIG. 2, the torque control device 1 includes an inverter 2 and a position converter 4 serving as a control means. The position converter 4 has a storage device (ROM) 4a. Further, the position converter 4 operates according to the control program stored in the storage device 4a by using the arithmetic expression and the numerical value table stored in the storage device 4a.

Further, the torque control device 1 includes a pulse generator (PLG) 12 as an angle detecting means and an electric motor 13 as a driving means. The pulse generator 12 is a rotary encoder. Further, the electric motor 13 is a drive source for rotating the cable reel 8, and the winding torque of the cable reel 8 can be changed. The pulse generator 12 is attached to the drive shaft of the electric motor 13 and outputs a detection angle signal that detects the rotation angle of the cable reel 8.

Then, the detection angle signal output from the pulse generator 12 is relayed by the inverter 2 and sent to the position converter 4. The position converter 4 acquires the detection angle from the pulse generator 12, calculates it, and inputs an analog control signal to the inverter 2 to control the electric motor 13 to obtain the take-up torque of the cable reel 8. Control. Further, the position converter 4 controls the torque of the electric motor 13 by vector control using an inverter 2 capable of controlling the torque current with high accuracy.

The pulse generator 12 is also used for calculating the feeding length of the power feeding cable 9, which will be described later. The pulse generator 12 is also used for detecting the rotation angle of the cable reel 8 and calculating the feeding length of the power feeding cable 9, which simplifies the device configuration of the torque control device 1. ing.

The torque control device 1 includes a position sensor 14 that serves as an origin detecting means for detecting the ascending limit of the crane hanger 7. The position converter 4 sets the ascending limit detected by the position sensor 14 as the origin position of the cable reel 8. With this position sensor 14, the origin position of the cable reel 8 can be easily detected.

FIG. 3 is a cross-sectional view showing the configuration (single row winding) of the cable reel of the crane. As shown in FIG. 3, the power feeding cable 9 is stacked and wound on the cable reel 8 in the radial direction of the cable reel 8. At this time, assuming that the diameter of the power supply cable 9 is φd, the center-to-center distance Δd of the power supply cables 9 adjacent in the radial direction of the cable reel 8 is [Δd = φd], and the radius of the cable reel 8 is R0. Then, the winding diameter (radius) R1 of the first power feeding cable 9 is [R1 = R0 + φd / 2], and the winding diameter (radius) R2 of the second power feeding cable 9 is [R2 = R1 + φd]. ], And the winding diameter (radius) Rn of the nth power feeding cable 9 is [Rn = R (n-1) + φd (∵n is an integer of 2 or more)].

FIG. 4 is a graph showing the relationship (single row winding) between the cable feeding length and the integrated rotation angle of the cable reel. Note that FIG. 4 is calculated assuming that the diameter of the winding core of the cable reel 8 is 30 cm, the unwinding speed of the cable reel 8 is 0 to 26 rotations, and the diameter of the power feeding cable 9 is 1 cm. In this case, the winding diameter of the power feeding cable 9 changes every time the cable reel 8 rotates 360 ° (1 rotation) according to the feeding length from the cable reel 8. Therefore, as shown in B in FIG. 4, the rate of change (inclination of the graph) of the rotation angle of the cable reel 8 with respect to the cable feeding length changes according to the feeding length of the power feeding cable 9 from the cable reel 8. To do.

In addition, A in FIG. 4 is a case where the winding diameter of the power feeding cable 9 does not change depending on the feeding length from the cable reel 8, that is, "one-stage multiple row winding" (all cables 9 are cable reels). It shows the proportional relationship between the feeding length and the integrated rotation angle in the case where the reels are wound side by side in the axial direction of 8 and not overlapped in the radial direction of the cable reel 9.

FIG. 5 is a cross-sectional view showing the configuration (multi-row winding) of the cable reel of the crane. In this embodiment, the power feeding cable 9 is arranged in parallel in a predetermined number of rows in the axial direction of the cable reel 8 in a state of being wound around the cable reel 8, as shown in FIG. The cable rows are stacked and wound in the radial direction of the cable reel 8. Here, assuming that the diameter of the power supply cable 9 is φd, the center-to-center distance Δd of the power supply cables 9 adjacent in the radial direction of the cable reel 8 is [Δd = φd · sin 60 ° = φd · (√3) / 2≈0.866 · φd], and assuming that the radius of the cable reel 8 is R0, the winding diameter (radius) R1 of the first-stage power supply cable 9 is [R1 = R0 + φd / 2], and the second The winding diameter (radius) R2 of the power feeding cable 9 in the stage is [R2 = R1 + 0.866 · φd], and the winding diameter (radius) Rn of the power feeding cable 9 in the nth stage is [Rn = R (n). -1) +0.866 · φd (∵n is an integer of 2 or more)].

In the state where the power supply cable 9 is wound around the cable reel 8, the number of cable rows differs between the even-numbered stages and the odd-numbered stages. Under this condition, the unwinding length of the power feeding cable 9 whose winding diameter and the number of stages increase or decrease from the total length of the power feeding cable 9 to the final winding position is calculated for each stage.

FIG. 6 is a graph showing the relationship (multi-row winding) between the cable feeding length and the integrated rotation angle of the cable reel. In FIG. 6, the winding core diameter of the cable reel 8 is 30 cm, the unwinding rotation speed of the cable reel 8 is 0 to 26 rotations, and the diameter of the power supply cable 9 is 4 cm. Is calculated assuming that the number of rows of the power supply cable 9 is alternately 4 and 5 and the number of stages is 6. In this case, the winding diameter of the power feeding cable 9 changes according to the change in the number of stacks of the cable rows. Therefore, as shown in B in FIG. 6, the rate of change (inclination of the graph) of the rotation angle of the cable reel 8 with respect to the cable feeding length is the change in the number of stages of the cable rows of the power feeding cable 9 (winding diameter). At the change point), it changes stepwise. Needless to say, since the winding diameter of the power feeding cable 9 does not change between the winding diameter change point and the next winding diameter change point, the rate of change of the rotation angle of the cable reel 8 with respect to the cable feeding length (slope of the graph). Is constant (straight line in FIG. 6). In addition, A in FIG. 6 is a case where the winding diameter of the power feeding cable 9 does not change depending on the feeding length from the cable reel 8, that is, "one-stage multiple row winding" (all cables 9 are cable reels). It shows the proportional relationship between the feeding length and the integrated rotation angle in the case where the reels are wound side by side in the axial direction of 8 and not overlapped in the radial direction of the cable reel 9.

As described above, in the number of winding steps calculated from the diameter of the power feeding cable 9 and the winding width of the cable reel 8, the winding diameter also changes stepwise as the number of winding steps of the power feeding cable 9 changes. To do. Therefore, in this torque control device 1, the rotational torque of the cable reel 8 is controlled in consideration of the relationship between the feeding length of the power feeding cable 9 and the number of winding steps of the power feeding cable 9.

FIG. 7 is a graph showing the relationship between the cable feeding length and the required winding torque. As shown in FIG. 5, the power feeding cables 9 are arranged in parallel in a predetermined number of rows in the axial direction of the cable reel 8, and the parallel cable rows are stacked and wound in the radial direction of the cable reel 8. In this case, as shown in FIG. 7, the relationship between the feeding length of the power feeding cable 9 and the required winding torque of the cable reel 8 is determined by the change in the number of stages of the cable row stacking (winding diameter change point). , It will change stepwise. The required take-up torque is a rotational torque of the cable reel 8 so that the power feeding cable 9 does not loosen and an unnecessary load is not applied to the power feeding cable 9. The required take-up torque is determined by the weight of the power feeding cable 9 that has been fed out corresponding to the feeding length of the power feeding cable 9 and the winding diameter of the power feeding cable 9. According to FIG. 7, the winding diameter changes stepwise at the change in the number of stages (winding diameter change point), and this change affects the required winding torque, and the winding diameter is different in each stage. It can be seen that the rate of change (inclination of the graph) of the required winding torque with respect to the feeding length of the cable 9 is different.

The required take-up torque is a torque in which the sum of the weight of the power feeding cable 9 unwound from the cable reel 8 and the weight of cable accessories such as metal fittings and the tension generated by the rotational torque of the cable reel 8 are balanced. Is. Therefore, the required take-up torque can also be calculated based on the winding diameter and tension of the power feeding cable 9.

Further, in the position converter 4, first, the final winding position of the power supply cable 9 to the cable reel 8 is set as the origin position of the cable reel. Next, the position converter 4 calculates the winding diameter of the power feeding cable 9 in the cable reel 8 corresponding to the integrated rotation angle from the origin position of the cable reel 8. Then, the position converter 4 calculates the feeding length of the power feeding cable 9 corresponding to the integrated rotation angle of the cable reel 8 and the winding diameter of the power feeding cable 9. Further, the position converter 4 calculates the weight of the power feeding cable 9 that has been fed out corresponding to the feeding length of the power feeding cable 9. Then, the position converter 4 calculates the required take-up torque based on the weight of the feeding cable 9 and the winding diameter of the feeding cable 9, and controls the torque of the cable reel 8.

It is not necessary to perform all the calculations by the position converter 4 each time, and if the calculations are performed in advance and stored as a numerical table (that is, the graph shown in FIG. 7 is created and stored). If this is done), only the integrated rotation angle of the cable reel 8 can be obtained, and the required winding torque corresponding to the integrated rotation angle can be determined from the numerical table (or graph). In this way, the position converter 4 determines the required take-up torque based on the input integrated rotation angle, and inputs the required take-up torque to the inverter 2 in analog quantities such as voltage and current.

Further, the feeding length of the power feeding cable 9 is calculated by integrating the rotation angles from the origin with the final winding position as the origin by the pulse generator 12 attached to the drive shaft of the electric motor 13. Since the final winding position is the ascending limit of the crane hanger 7, the rotation angle error can be corrected by initializing the integrated rotation angle in accordance with the detection of reaching the ascending limit. It is desirable to correct the integrated rotation angle under predetermined conditions because an error may occur due to external factors such as vibration and backlash of gears.

FIG. 8 is a flowchart showing the operation of the torque control device. As an example of the operation of the position converter 4, when the operation is started in step st1, as shown in FIG. 8, the number of winding steps and the number of winding steps are determined from the relationship between the total length and diameter of the power feeding cable 9 and the winding width of the cable reel 8. Determine the number of columns for each column.

Here, the total number of stages is three. In the following description, "COUNT" is the integrated value of the pulse count from the pulse generator 12, "L3-2" is the count value that enters the third to second stages, and "L2-1" is the count value from the second stage. This is the count value that rushes into the first stage. [0 <L3-2 <L2-1 <“COUNT” at the time of maximum feeding].

Therefore, in step st2, "L3-2" and "L2-1" are calculated from the number of turns and the count increase value per volume. Further, in step st3, the torque calculation formula for each stage is registered. In the torque calculation formula, "TnF" is the required winding torque when all the nth stages are wound, "TnL" is the required winding torque when all the nth stages are wound, and "CnF" is n. The count value at the time of entering the stage, "CnL", is represented by the following [Equation 1] as the count value at the end of the nth stage.

Then, in step st4, the count is integrated by the pulse input. Further, in step st5, it is determined whether or not "COUNT> L3-2", and if "NO", the process proceeds to step st6, and if "YES", the process proceeds to step st8. In step st6, the torque is calculated from the proportional straight line between the required torque in the third stage and the count value, and the process proceeds to step st7. In step st7, the required torque is output as an analog amount and the process ends.

Further, in step st8, it is determined whether or not "COUNT> L2-1", and if "NO", the process proceeds to step st9, and if "YES", the process proceeds to step st10. In step st9, the torque is calculated from the proportional straight line between the required torque in the second stage and the count value, and the process proceeds to step st7. Further, in step st10, the torque is calculated from the proportional straight line between the required torque in the first stage and the count value, and the process proceeds to step st7.

The torque control device according to the present invention has been described above based on the embodiment, but the present invention is not limited to the configuration described in the above-described embodiment, and is not deviated from the gist thereof. The configuration can be changed as appropriate.

1 Torque control device 2 Inverter 3 Crane girder 4 Position converter 4a Storage device 5 Cable drum 6 Trolley 7 Cable hanger 7a Crane bucket 8 Cable reel 9 Power supply cable 10 Wire cable 11 Crane 12 Pulse generator 13 Electric motor 14 Position sensor

The present invention has been proposed to solve the above problems, and the first invention (the invention according to claim 1) is suspended and supported by a wire cable and moved up and down by winding and unwinding the wire cable. An angle that detects the rotation angle of the cable reel, which is a torque control device that controls the torque of the cable reel that feeds out the cable in order to set the tension of the cable whose lower end is connected to the hanging tool to be operated to a predetermined value. A detection means, a drive means capable of varying the take-up torque of the cable reel, and a control means for acquiring a detection angle from the angle detection means and controlling the drive means to control the take-up torque of the cable reel. The control means is provided with an integrated rotation angle from the origin position of the cable reel when the final winding position of the cable to the cable reel is set to the origin position of the cable reel, and from the integrated rotation angle. more winding diameter of the cable in the calculated said cable reel, calculates the weight of the cable fed-out corresponding to the feed length of the cable corresponding to these, the integrated angle of rotation from the original position of the cable reel based on, it is characterized in that for controlling the take-up torque, the fed-out weight and winding torque corresponding to the winding diameter of the cable of the cable.

In the torque control device according to the first invention, the take-up torque corresponds to the weight of the unwound cable and the winding diameter of the cable based on the integrated rotation angle of the cable reel from the origin position. It controls the take-up torque .
In the second invention (the invention according to claim 2), the tension of a cable whose lower end is connected to a hanging tool which is suspended and supported by a wire cable and which is raised and lowered by winding and unwinding the wire cable is set as a predetermined value. Therefore, it is a torque control device that controls the torque of the cable reel for feeding the cable, and includes an angle detecting means for detecting the rotation angle of the cable reel, a driving means capable of varying the winding torque of the cable reel, and the above. A control means for acquiring a detection angle from an angle detecting means and controlling the driving means to control the winding torque of the cable reel, the control means stores a numerical table, and the numerical table is stored. Is a numerical value in which the winding torque of the cable reel corresponds to the integrated rotation angle from the origin position of the cable reel when the final winding position of the cable to the cable reel is set to the origin position of the cable reel. In the table, the winding torque in the numerical table is the unfolding length of the cable corresponding to the integrated rotation angle and the winding diameter of the cable in the cable reel calculated in advance from the integrated rotation angle. The weight of the unwound cable corresponding to the above is calculated in advance, and is calculated in advance based on the weight of the cable and the winding diameter of the cable. The control means is the cable reel using the numerical table. Based on the integrated rotation angle from the origin position of the above, the winding torque is controlled to a winding torque corresponding to the weight of the unwound cable and the winding diameter of the cable.
In the torque control device according to the second invention, using the numerical table, the take-up torque is calculated based on the integrated rotation angle of the cable reel from the origin position, the weight of the unwound cable and the cable. The winding torque is controlled according to the winding diameter of the cable.

Further, the third invention (the invention according to claim 3 ) includes the origin detecting means for detecting the ascending limit of the hanging tool in the first or second invention, and the controlling means is the origin detecting means. The climbing limit detected by the above-mentioned cable reel is set to the origin position of the cable reel.

In the torque control device according to the third invention, the origin position of the cable reel can be easily determined.

Further, in the fourth invention (the invention according to claim 4 ), in any one of the first, second or third inventions, the cables are stacked in the cable reel in the radial direction of the cable reel. It is characterized in that the winding diameter is changed according to the feeding length from the cable reel.

In the torque control device according to the fourth invention, even if the cables are stacked and wound in the radial direction of the cable reel and the winding diameter changes according to the feeding length, the torque control of the cable reel is performed. Can be done accurately.

A fifth invention (the invention according to claim 5 ) is the fourth invention, in which the cable is arranged in parallel in a predetermined number of rows in the axial direction of the cable reel in the cable reel. The rows are stacked and wound in the radial direction of the cable reel, and the change in the winding diameter of the cable according to the feeding length from the cable reel corresponds to the change in the number of stages of the stacking of the cable rows. It is characterized by a stepwise change.

In the torque control device according to the fifth invention, parallel cable rows are stacked and wound in the radial direction of the cable reel, and the winding diameter is stepped according to a change in the number of stages of the cable rows. Even if it changes, the torque control of the cable reel can be accurately performed.

Further, in the sixth invention (the invention according to claim 6 ), in any one of the first to fifth inventions, the angle detecting means is attached to the drive shaft of the drive means, and the control means is the control means. The torque control of the drive means is performed by vector control using an inverter, and the inverter is characterized in that the detection angle signal from the angle detection means is relayed to the control means.

In the torque control device according to the sixth invention, the angle detecting means is also used for detecting the rotation angle of the cable reel and calculating the feeding length of the cable, thereby simplifying the device configuration. Can be done.

Further, in the seventh invention (the invention according to claim 7 ), in any one of the first to sixth inventions, the crane suspension is a crane suspension that suspends and supports the crane bucket. The cable is characterized in that it is a power supply cable that supplies power to the crane bucket.

The torque control device according to the seventh invention can be applied to a crane in which a crane bucket is suspended and supported by a crane hanger.

According to the torque control device according to the first invention (the invention according to claim 1), for example, the torque control of the cable reel for feeding the power supply cable to the crane hanger is controlled by the weight of the cable delivered from the cable reel and the said. Since the winding diameter of the cable can be calculated accurately, it can be performed accurately.
According to the torque control device according to the second invention (the invention according to claim 2), for example, the torque control of the cable reel for feeding the power supply cable to the crane hanger is accurately performed by using a numerical table. Can be done.

Further , according to the torque control device according to the third invention (the invention according to claim 3 ), the origin position of the cable reel can be easily determined.

Further , according to the torque control device according to the fourth invention (the invention according to claim 4 ), the cables are stacked and wound in the radial direction of the cable reel, and the winding diameter changes according to the feeding length. Even so, the torque control of the cable reel can be accurately performed.

Further , according to the torque control device according to the fifth invention (the invention according to claim 5 ), the parallel cable rows are stacked and wound in the radial direction of the cable reel, and the cable rows are stacked. Even if the winding diameter changes stepwise according to the change in the number of stages, the torque control of the cable reel can be accurately performed.

Further , according to the torque control device according to the sixth invention (the invention according to claim 6 ), the angle detecting means is also used for detecting the rotation angle of the cable reel and calculating the feeding length of the cable. Therefore, the device configuration can be simplified.

Further , according to the torque control device according to the seventh invention (the invention according to claim 7 ), it can be applied to a crane in which a crane bucket is suspended and supported by a crane suspender.

In the torque control device according to the present invention, the cable is unwound in order to set the tension of the cable whose lower end is connected to the hanger which is suspended and supported by the wire cable and which is lifted and lowered by winding and unwinding the wire cable. It is a device that controls the torque of the cable reel.

Further, the feeding cable 9, the lower end is connected to the power supply input of the crane sling 7 supplies power required to operate the opening and closing of the crane bucket 7a to the power input unit. Further, the cable drum 5 for winding the wire cable 10 and the cable reel 8 for winding the power supply cable 9 are rotatably installed on the trolley 6 movably installed on the crane girder 3. There is.

Claims (6)

Torque control of the cable reel that unwinds the cable is performed in order to set the tension of the cable that is suspended and supported by the wire cable and whose lower end is connected to the hanger that is lifted and lowered by winding and unwinding the wire cable to a predetermined value. It is a torque control device
An angle detecting means for detecting the rotation angle of the cable reel and
A drive means that can change the winding torque of the cable reel,
A control means for acquiring a detection angle from the angle detection means and controlling the drive means to control the winding torque of the cable reel is provided.
The above control means
The final winding position of the cable to the cable reel is set as the origin position of the cable reel, and based on the winding diameter of the cable in the cable reel corresponding to the integrated rotation angle from the origin position of the cable reel.
Based on the integrated rotation angle of the cable reel and the feeding length of the cable corresponding to the winding diameter of the cable.
Based on the weight of the delivered cable corresponding to the feeding length of the cable
A torque control device characterized in that torque control of the cable reel is performed based on the weight of the delivered cable and the winding diameter of the cable. It is equipped with an origin detecting means for detecting the ascending limit of the hanging tool.
The torque control device according to claim 1, wherein the control means sets the rising limit detected by the origin detection means as the origin position of the cable reel. Claim 1 or 2 is characterized in that the cable is wound on the cable reel so as to be stacked in the radial direction of the cable reel, and the winding diameter changes according to the feeding length from the cable reel. Any of the described torque control devices. In the cable reel, the cables are paralleled in a predetermined number of rows in the axial direction of the cable reel, and the parallel cable rows are stacked and wound in the radial direction of the cable reel.
The torque according to claim 3, wherein the change in the winding diameter of the cable according to the feeding length from the cable reel is a stepwise change according to the change in the number of stages of the stacking of the cable rows. Control device. The angle detecting means is attached to the drive shaft of the drive means.
The control means controls the torque of the drive means by vector control using an inverter.
The torque control device according to any one of claims 1, 2, 3 or 4, wherein the inverter relays a detection angle signal from the angle detection means to the control means. The above-mentioned crane hanger is a crane hanger that suspends and supports the crane bucket.
The torque control device according to any one of claims 1, 2, 3, 4 or 5, wherein the cable is a power supply cable for supplying power to the crane bucket.

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