JP6702236B2 - Coil hanging method - Google Patents

Description

  The present invention, when unloading a coil to the ground by a crane, considers the interference between the ground coil placed on the ground and the crane, and automatically determines whether to unload the coil. Regarding the method.

  In a steel mill, a coil is hoisted by a crane, moved in the air, and then the coil is unloaded at a predetermined place on the ground to perform a coil hoisting operation. For example, when supplying a coil to a cold-rolled steel sheet production line, the coil conveyed to an entrance yard by a carriage such as a carriage or pay carriage is lifted by a crane and then unloaded onto a skid on the ground ( Hanging) is common.

  Conventionally, the hanging of a coil is performed by manned work in which a person operates a crane. Specifically, an operator on a crane monitors the condition of ground facilities such as a conveyor and a coil car, determines whether or not the coil can be loaded and unloaded on the ground, and carries out a coil handling operation.

  In recent years, it has been required to automate the operation of a crane in accordance with an increase in labor-saving needs of operators and a high-speed processing of a crane control device.

  The following Patent Documents 1 to 3 can be cited as documents disclosing a technique that contributes to automation of crane operation. Patent Document 1 discloses a coil recognition device that obtains a radius r of a coil based on signals from a scan sensor and a horizontal distance sensor attached to a sensor base arranged on the side of a coil carrier. In Patent Document 2, the crane stop position is corrected according to the amount of deviation from the reference position of the installation position of the coil pallet and the amount of deviation of the placement position of the coil on the coil pallet from the reference position, and the safety is automatically secured. There is disclosed a crane stop position control system capable of lifting and loading coils. In Patent Document 3, before starting the loading of the coil, an operator operates a manned crane to set the reference point by loading the coil, and by calculating the deviation of the trailer approach angle, the loading operation of the coil is performed accurately. A loading method is disclosed.

JP 2012-197165 A JP, 2015-140235, A JP, 2009-107736, A

  When the operation of the crane is automated, it is necessary to reliably prevent the crane from interfering with the coil existing on the ground when the crane is suspended on the ground.

  Specifically, description will be made with reference to FIG. 1, which is a schematic view of a coil transportation facility. In FIG. 1, there is a coil yard on the entrance side (left side in the drawing) of the coil car 4, and the coil is placed on the skid 3 placed on the ground. The coil placed on the skid 3 and the like is sent out by a coil car 4 to a payout device 5 represented by an uncoiler or the like. When the coil is placed on the coil car 4 and the skid 3 is vacant, the coil 2 in a state of being lifted by the crane 1 is unloaded on the skid 3. The coil 2 lifted from the ground by the crane 1 is referred to as a hoisting coil, and the hoisting coil is already placed on the ground before being unloaded on the ground (including the state mounted on the coil car 4 or the like). The coil 6 may be referred to as a ground coil.

  In the example of FIG. 1, the crane 1 hoists the coil by using two arms provided at both ends of the hoisting coil 2 in the axial direction. When the coil is unloaded on the ground, the left and right arms are opened to open the lifting coil 2. At this time, for example, if the coil car 4 is not sufficiently advanced toward the payout device 5, the open arm and the ground coil 6 may come into contact with each other when the lifting coil 2 is opened, which may lead to an operational trouble. There is.

  In particular, when the ground coil 6 is moved by the coil car 4 as shown in FIG. 1, the distance between the ground coil 6 and the lifting coil 2 changes depending on the degree of movement of the coil car 4. When unloading the coil by manned work, the operator can determine whether or not the unloading coil 2 can be unloaded according to the situation while observing the operation status of the coil car 4. On the other hand, when automating the operation of the crane, it is necessary to automatically determine whether the coil can be loaded or unloaded. However, when the position of the ground coil 6 suddenly changes, such as when the coil car 4 is manually operated, it is difficult to automatically determine whether the coil can be loaded or unloaded by the conventional technique.

  In particular, the above-mentioned Patent Documents 1 to 3 do not describe or suggest the technique of automatically determining whether or not the coil can be loaded and unloaded in consideration of the interference between the crane and the ground coil.

  The present invention has been completed in view of the above-mentioned problems, and when unloading a coil on the ground with a crane, the presence or absence of interference between the crane and the ground coil is checked to automatically determine whether or not the coil is unloaded. An object of the present invention is to provide a coil hanging method that can make a determination.

The means of the present invention are as follows.
[1] A coil hanging method of unloading a coil onto the ground by a crane, wherein the crane is already placed on the ground after hoisting the hoisting coil by an arm provided at at least one end in the axial direction of the coil The hoisting coil can be loaded and unloaded on the ground so that the ground coil and the hoisting coil are lined up in series in the axial direction. A coil hoisting method, wherein a distance between the hoisting coil and the hoisting coil when the hoisting coil is unloaded at a predetermined position is calculated, and the hoisting coil is hoisted when the distance exceeds a preset threshold value.
[2] The interval is calculated based on the width of the lifting coil, the position of the origin in the coil position recognition device, the position of the end surface of the ground coil on the side close to the lifting coil, and the planned mounting position of the ground coil [1 ] The coil hanging method described in [1].
[3] The coil suspension method according to [2], wherein the position of the end surface of the ground coil on the side closer to the lifting coil is recognized by the coil position recognition device.
[4] The coil hoisting method according to any one of [1] to [3], wherein the threshold is a size such that the crane arm and the ground coil do not contact each other when hoisting the hoisting coil.

  According to the present invention, it is possible to determine whether or not there is interference between the crane arm and the ground coil when the hoisting coil is unloaded, and automatically determine whether the hoisting coil can be unloaded by the crane.

FIG. 1 is a schematic diagram showing an outline of a problem in which a ground coil and an arm of a crane interfere with each other. FIG. 2 is a schematic diagram showing an outline of the coil hanging method according to the present invention.

  In the present invention, after the coil is hoisted by the crane and moved in the air, whether or not the hoisted coil can be unloaded is automatically determined in the coil transportation facility for unloading the coil to the ground.

  The details will be described with reference to FIG. FIG. 2 shows an example of equipment for transporting the coil to the cold-rolled steel sheet production line. In order to supply the coil to the manufacturing line equipped with the payout device 5, etc., the coil 1 is loaded onto the skid 3 on the ground by the crane 1, and then the coil car 4 loads the coil into the payout device 5.

  In FIG. 2, the crane 1 is in a state of hoisting the coil (hoisting coil 2). After moving the hoisting coil 2 in the air, the crane 1 unloads the hoisting coil 2 at a planned placement position on the ground (a position where the skid 3 is provided in the figure). At this time, the lifting coil 2 and the ground coil 6 already placed on the ground may be provided in series along the axial direction of the coil. In other words, the hoisting coil 2 and the ground coil 6 may be arranged such that the axial direction of the hoisting coil 2 stacked at the planned placement position and the axial direction of the ground coil 6 are aligned on a straight line. .. In the present invention, when the hoisting coil 2 and the ground coil 6 adjacent to the hoisting coil 2 are provided in series as described above, the ground coil 6 and the ground coil 6 are installed to determine whether or not the crane 1 and the ground coil 6 interfere. The distance between the hoisting coil 2 and the hoisting coil 2 when it is unloaded at the planned placement position is calculated.

  The crane 1 has two arms provided on at least one end side of the lifting coil 2 in the axial direction. In the example of FIG. 2, the left and right arms provided on both ends of the coil in the axial direction face the end surfaces of the lifting coil 2, respectively. The lower part of the arm is provided with a claw member that projects in the horizontal direction. The coil can be lifted by inserting the claw member into the hollow portion of the coil. Although an example of the crane 1 having two left and right arms will be described below, a C-shaped hook-shaped arm for inserting the claw member into the hollow portion of the coil from only one end side in the axial direction of the coil is provided. The present invention can be similarly applied to the case of using a crane.

  When the crane 1 lifts the lifting coil 2, the two arms of the crane 1 are closed. On the other hand, when the hoisting coil 2 is unloaded on the ground, the two arms are opened and the hoisting coil 2 is opened. When the arm changes from the closed state to the open state, the arm is displaced outward in the axial direction of the coil.

  When the planned placement position of the lifting coil 2 and the position of the ground coil 6 are close to each other, when the left and right arms are opened to unload the lifting coil 2, the arm and the ground coil 6 come into contact with each other. There is a risk of being killed. When the ground coil 6 and the arm of the crane 1 come into contact with each other, operational troubles are likely to occur. Therefore, when there is a high risk of the ground coil 6 and the arm coming into contact with each other, It is necessary to stop the unloading once.

  In the coil transportation equipment, the position of the skid 3 and the position of the ground coil 6 suddenly come close to each other when the lifting coil 2 is unloaded due to a condition change that was not originally planned, and the arm and the ground coil 6 interfere with each other. It can happen easily. Specifically, in a case where the coil car 4 holding the ground coil 6 is standing by without advancing toward the payout device 5 or a case where a wide coil is continuous, the arm and the ground coil 6 interfere with each other. Is more likely to occur. In addition, even if the coil is not automatically charged into the production line and the coil car is manually operated, or the distance between the skid 3 and the dispensing device 5 is short, the arm and the ground coil 6 may interfere with each other. Is more likely to occur. Even when the position of the skid 3 and the position of the ground coil 6 suddenly come close to each other, when carrying out the unloading of the coil by the manned work, the operator decides whether or not to unload the coil by checking the condition of the equipment each time. can do. On the other hand, when automating the operation of the crane, the presence or absence of interference between the arm and the ground coil 6 must be automatically determined to determine whether or not the coil can be unloaded.

  In the present invention, the distance between the ground coil 6 and the lifting coil 2 is calculated before unloading the hoisting coil 2, and whether or not the coil can be unloaded is determined based on the distance to determine whether or not the arm of the crane 1 and the hoisting coil 2 can be grounded. It is possible to reliably prevent contact with the coil 6. The distance between the hoisting coil 2 and the ground coil 6 means the coil axial direction between the hoisting coil 2 and the ground coil 6 when the hoisting coil 2 is placed at the expected placement position on the skid 3. The distance, more specifically, the distance between the end surfaces of the lifting coil 2 and the ground coil 6 that face each other.

  The intervals are the width (axial length) W0 of the hoisting coil 2, the position of the origin in the coil position recognition device 7, the end surface of the ground coil 6 on the side close to the hoisting coil 2 (the left end surface of the ground coil 6 in FIG. 2). Is calculated based on the position and the planned placement position of the ground coil.

  The origin of the coil position recognizing device 7 (details of which will be described later) is located in the axial direction between both end faces (the right end face and the left end face in FIG. 2) of the ground coil 6, in other words, the ground coil 6. It may be any position where the axial positions overlap. In FIG. 2, the starting point is the scanning start point at which the coil position recognition device 7 starts scanning. The position of the origin is a known parameter according to the installation position and setting of the coil position recognition device 7.

  As the expected placement position of the ground coil, an arbitrary axial position of the ground coil 2 placed on the skid 3 can be used. For example, the position of the central portion (skid center) of the skid 3 can be used as the planned placement position of the ground coil. Incidentally, it is usually assumed that the hoisting coils 2 are placed on the skid 3 with their central portions in the axial direction aligned.

  Based on the width W0 of the hoisting coil 2, the distance W3 in the coil axial direction from the origin to the left end surface of the ground coil 6, and the distance W4 in the coil axial direction from the skid center to the origin using FIG. A method of obtaining the distance W from the ground coil 6 will be described.

As shown in FIG. 2, the distance W between the lifting coil 2 and the ground coil 6 is W1 which is half the width of the lifting coil 2 and the distance W2 from the skid center to the left end surface of the ground coil 6. It is calculated by the following equation (1).
W=W2-W1 (1)

  The above W1 is obtained as a size (W0/2) that is half the width W0 of the lifting coil. The size of W0 can be a known value from the type of coil being conveyed.

Further, the above W2 can be calculated using the distance W3 from the origin to the left end surface of the ground coil and the distance W4 from the skid center to the origin as shown in the following equation (2).
W2=W4-W3 (2)

Using the above equations (1) and (2), the distance W between the lifting coil 2 and the ground coil 6 is obtained by the following equation (3).
W=W2-W1=W4-W3-W0/2 (3)

  Among the characters used in the right side of the above formula (3), W0 is a known value according to the type of coil as described above, and W4 is determined according to the preset position of the skid 3 and the position of the origin. Is the value to be set. On the other hand, W3 can be obtained by the coil position recognition device 7 provided on the ground. The unit of the characters used in the above equations (1) to (3) may be "m".

  The coil position recognition device 7 may be any device that can recognize the side surface of the ground coil 6 between the origin and the left end surface of the ground coil 6. The coil position recognition device 7 is provided on the ground so that the ground coil 6 can be recognized, and more specifically, it is preferably provided at substantially the same height as the ground coil 6. A scanning laser rangefinder can be used as a specific example of the coil position recognition device 7. The scanning laser range finder is capable of scanning along the axial direction of the ground coil 6, and irradiates the side surface of the ground coil 6 with light, ultrasonic waves, or the like, and receives the reflected wave, thereby We can recognize our existence. In FIG. 2, the scanning start point of the coil position recognition device 7 is the origin. Further, the scanning end point may be set to the left of the left end surface of the ground coil 6 (the side closer to the lifting coil 2) so that the position of the left end surface of the ground coil 6 can be recognized. As described above, by using the coil position recognition device 7, the distance W3 from the origin to the left end surface of the ground coil can be calculated.

  As described above, the interval W can be obtained by substituting the W3 calculated by the coil position recognition device 7 and the predetermined values W0 and W4 into the equation (3).

  The method for obtaining W is not limited to the method using the following equation (3). For example, the distance W between the coils can also be calculated by subtracting half (W0/2) of the width of the lifting coil 2 from the distance from the skid center position to the left end surface of the ground coil 6 (W2 in FIG. 2). You can

  Next, the calculated W is compared with a predetermined threshold value. When W is larger than the threshold value, it is determined that the crane 1 and the ground claim 6 are less likely to interfere with each other, and the hoisting coil 2 is unloaded.

  The above-mentioned threshold value is preferably set to a size such that the open arm of the crane 1 and the ground coil 6 do not come into contact with each other when the lifting coil 2 is opened on the ground. More specifically, when determining the threshold value, it is desirable to consider the opening/closing width of the arm, the size of the arm, the stopping accuracy of the crane, the load deflection amount of the coil in the crane, and the like.

  On the other hand, when W is equal to or less than the threshold value, it is determined that the crane 1 and the ground coil 6 are likely to interfere with each other, and the loading and unloading of the lifting coil 2 on the ground is temporarily stopped. In this case, it is desirable to output an alarm or the like to inform the operator that W is equal to or less than the threshold value. When W is equal to or less than the threshold value, after the position of the ground coil 6 is changed by the coil car 4 or the like, W is again obtained using the coil position recognition device 7 and the magnitude relationship with the threshold value is compared. Until W exceeds the threshold value, these operations are repeated to stop the lifting coil 2 from being unloaded. Further, when W is equal to or less than the threshold value, it is also effective to replace the coil loaded in the skid 3 with a coil having a smaller size.

  Although not shown, a controller can be used to automate the operation of the crane. The control device calculates W from the data obtained by the coil position recognition device 7 as described above, and compares the threshold value with W. Further, the control device gives an instruction to the crane 1 as to whether or not the hoisting coil 2 is to be unloaded based on the comparison result between the threshold value and W. As a result, the loading and unloading of the lifting coil 2 by the crane 1 is automatically controlled.

  In FIG. 2, the production line of the cold-rolled steel sheet in which the coil is sent from the coil yard equipped with the skid 3 to the payout device 5 by the coil car 4 has been described as an example. On the other hand, the equipment to which the present invention can be applied is not limited to this example, the ground coil already existing on the ground and the lifting coil hung by the crane, if the equipment is arranged along the axial direction of the coil, The present invention can be widely applied.

  Whether or not the coil can be unloaded can be determined before the crane 1 is instructed to carry the coil, that is, before the crane 1 hoists the coil. However, even when it is determined that the coils can be loaded and unloaded before the coil transfer instruction is issued, the period from when the transfer instruction is actually issued to the crane 1 until the crane 1 lifts the coil and moves to the predetermined position. The spacing between the lifting coil 2 (the planned mounting position thereof) and the ground coil 6 may change due to manual operation of the ground equipment. That is, even if there is no risk of interference between the crane 1 and the ground coil 6 before the transportation instruction, there is a possibility that interference may occur when the hoisting coil 2 is unloaded. Therefore, it is preferable to determine whether or not the coil 1 can be unloaded again before the hoisting coil 2 is unloaded at the stage where the crane 1 has moved right above the skid 3.

  According to the present invention, when the hoisting coil is unloaded, it is possible to judge whether or not the crane and the ground coil come into contact with each other, and it is possible to automatically determine whether or not the coil is unloaded, and the labor saving of the operator involved in the coil hoisting work can be achieved. It will be possible.

1 Crane 2 (Hoisting) Coil 3 Skid 4 Coil car 5 Discharge device 6 (Ground) Coil 7 Coil position recognition device W Distance between hoisting coil and ground coil W0 Width of hoisting coil W1 Half of width of hoisting coil W2 Ground from skid center Distance to the left end of the coil W3 Distance from the origin to the left end of the ground coil W4 Distance from the center of the skid to the origin

Claims (3)

A coil hanging method of loading and unloading coils on the ground by a crane,
In the crane, after the hoisting coil is hoisted by the arm provided on at least one end side in the axial direction of the coil, the hoisting coil is placed so that the ground coil and the hoisting coil already mounted on the ground are arranged in series in the axial direction. Can be loaded and unloaded on the ground,
Before unloading the hoisting coil onto the ground, calculate the distance between the hoisting coil when unloaded to the grounding coil and the planned placement position by the coil position recognition device provided on the ground,
When the interval exceeds a preset threshold value, the hoisting coil is unloaded .
The threshold value is based on the opening and closing width of the arm, the size of the arm, the stopping accuracy of the crane, and the load deflection amount of the lifting coil so that the crane arm and the ground coil do not contact each other when the lifting coil is unloaded. A coil hanging method characterized by being set. The interval is
The coil suspension according to claim 1, which is calculated based on the width of the hoisting coil, the position of the origin in the coil position recognition device, the position of the end face of the ground coil near the hoisting coil, and the planned mounting position of the ground coil. Method.   The coil hanging method according to claim 2, wherein the coil position recognition device recognizes the position of the end surface of the ground coil on the side closer to the lifting coil.