JP2014118237A - Remote unslinging device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a remote unslinging device that can install a heavy construction in an installation target spot without being affected by the presence or absence of an obstacle existing between a worker and a heavy construction.SOLUTION: A remote unslinging device includes: a frame 16 suspended by a crane; slinging/unslinging means 17 having engagement pieces 24a, 24b, 24c including a moveable pin 23 alternatively switched in either one of a slinging position attached to the frame 16 and a slinging wire rope for suspending a heavy construction hooked therein, and an unslinging position for taking off the hooking of the slinging wire rope, and an engagement hole 25 for inserting and engaging the movable pin 23; and a hydraulic cylinder 18 having a cylinder tube 27, and a rod 28 reciprocating from the cylinder tube 27 and performing the position switching operation of the moveable pin 23.

Description

  The present invention relates to a remote ball removing device.For example, when a heavy structure is installed in the sea under severe sea conditions, the wire rope can be safely removed from the heavy structure by remote control even if no person is submerged in the sea. The present invention relates to a remote ball removing device that can be removed.

  Conventionally, work to install breakwater works or artificial reefs is performed by suspending a suspension frame from a crane wire rope, and hanging a wire rope for hanging a heavy structure on a shackle provided on the suspension frame. A heavy rope is lifted to the required height with a wire rope, a suspension frame, and a wire rope for slinging, carried to the installation target point, and then submerged on the seabed. Thereafter, a heavy structure sinking technique is widely used in which a ball rope is removed by human power by a diver. The series of underwater operations performed by the divers is a dangerous operation near the suspended load, and improvement in safety is required by unmanned operation.

  Therefore, as a countermeasure above, attach a so-called auto release hook to the wire rope of the crane of the hoist ship, suspend a heavy structure, and remove the load of the wire rope by grounding this heavy structure. A method of automatically releasing and laying heavy structures has been proposed.

  In this method, when the load is removed from the hook, the lock is automatically released regardless of the operator's intention, so if the load is removed for some reason before the heavy structure has settled, the sling wire rope will come off. There is a problem that the heavy structure falls. In particular, in offshore construction where heavy structures are sunk in the sea in places with severe sea conditions, the ship greatly shakes up and down during stormy weather, etc., and the heavy structures suspended due to that effect also shake up and down together. There is a risk that the load of the heavy structure is released from the hook before the heavy structure reaches the bottom, the sling wire rope comes off from the hook, and the heavy structure falls.

  In addition, a suspension frame is attached to the tip of the wire rope of the crane of the hoist ship, and a plurality of shackles are provided on the suspension frame, and a release hook is provided at the tip, and an ultrasonic wave whose base end is suspended from one of the shackles. An automatic ball comprising an actuated disconnect device, a sling wire rope whose one end is suspended on another shackle and whose other end is connected to a release hook of the ultrasonically actuated disconnect device, and a transponder transmitter A removal device has also been proposed (see, for example, Patent Document 1).

  When the automatic ball removing device of Patent Document 1 confirms that the heavy structure has settled at the installation target point, it sends an ultrasonic signal from the transponder transmitter to the ultrasonically operated disconnecting device, and the ultrasonically operated disconnecting device is Actuate to release the release hook. Further, the release hook is released to release the connection of the other end portion of the laying wire rope hung on the heavy structure and release it from the suspension frame, and the heavy structure is set on the seabed.

Japanese Unexamined Patent Publication No. 2010-229656.

  In the ultrasonically actuated detaching device according to the invention described in Patent Document 1, the signal exchange between the transponder transmitter and the ultrasonically actuated detaching device is performed wirelessly using an ultrasonic signal. In this case, if there are obstacles between them, radio waves are difficult to reach and the situations that can be used are limited. For example, when a hoist ship is installed inside the breakwater and a heavy structure is installed on the offshore side of the breakwater, it may be necessary to devise.

  In addition, in the ultrasonic operation type separation device that the operator throws into the sea, an electric control circuit and power source for transmitting and receiving wireless control signals and a power source for operating the separation device are arranged. However, in order to cope with operation at a large depth, the apparatus is likely to be large-scale, and since a more advanced waterproof structure is required, the cost of the entire apparatus is increased.

  Therefore, the solution is to provide a remote ball removal device that can install a heavy structure at a target installation point without being affected by the presence or depth of obstacles existing between the worker and the heavy structure. The technical problem which should arise arises, and this invention aims at solving this subject.

  The present invention has been proposed in order to achieve the above object, and the invention according to claim 1 is a remote ball removing device used when a heavy structure is suspended by a crane, and is suspended by the crane. Selected from either a frame position, a sling position at which a sling wire rope that is attached to the frame and suspends the heavy structure is hung, and a slack position at which the sling of the sling wire rope is unfastened. A beveling / removing means having a movable pin that can be switched in a single manner and an engagement piece having an engagement hole for inserting and engaging the movable pin, and a cylinder tube and a position change of the movable pin by moving forward and backward from the cylinder tube A remote deballing device is provided comprising a hydraulic cylinder having a rod for operation.

  According to this configuration, the wire hanging rope is hung on the movable pin that is switched to the sling position, the heavy structure is suspended by the sling wire rope and moved to the installation target point, and the installation target point is reached. Then, the hydraulic oil is sent to the hydraulic cylinder through the hydraulic hose, and the hydraulic cylinder is remotely operated to switch the movable pin to the ball removal position. When the wire rope for the sling is removed from the movable pin, the latch of the wire rope for slack is released. The heavy structure can be installed at the installation target point. Accordingly, it is possible to unmanned underwater work, which has been performed conventionally, and to perform the deballing work by operating the hydraulic cylinder at the operator's will. Moreover, since the operation principle is hydraulic, operation control and power supply can be performed at the same time, so there is no need for high waterproof performance as in the case of a structure using an electric circuit or the like. Therefore, it is possible to realize a remote ball removing device having a simple structure that can reduce costs. Further, by adjusting the length of the hydraulic hose, it is possible to easily cope with a large depth.

  According to a second aspect of the present invention, in the configuration according to the second aspect, the hydraulic cylinder is provided on an upper surface side of the frame, and the slinging / ball removing means is provided on a lower surface side of the frame, and the hydraulic cylinder The rod and the movable pin of the slinging / unballing means are connected to each other so as to be slidably coupled to each other.

  According to this configuration, the size of the frame in the horizontal direction (horizontal direction) can be reduced by providing a hydraulic cylinder on the upper side of the frame and a slinging / removing means on the lower side of the frame, respectively. Enables compactness.

  According to a third aspect of the present invention, in the configuration according to the first or second aspect, the frame includes at least one shackle attachment portion for attaching a shackle to which one end of the sling wire rope is latched. A ball removing device is provided.

  According to this configuration, one end of the sling wire rope is hooked on the shackle, and the other end is detachably hung on the movable pin, and the heavy structure is suspended by the sling wire rope. When the installation target point is reached, the hydraulic cylinder is remotely controlled, the movable pin is switched to the ball removal position, and the latch on the other end side is removed. When the frame is lifted by the crane, the heavy structure remains at the installation target point, and the frame and sling wire rope are also lifted and collected. In addition, when multiple shackle attachments are provided and shackles are individually attached to the shackle attachments, it is used to fix one end of the multiple staking wire ropes to the shackle and suspend several heavy structures. Can also be done.

  According to a fourth aspect of the present invention, in the configuration according to any one of the first to third aspects, the slinging / unballing means includes a plurality of the engaging pieces spaced apart from each other and the bottom surface of the frame. Further, each of the movable pins is provided so as to hang down, and the movable pin can provide a remote ball removing device that can be stopped at each installation position of the plurality of engagement pieces.

  According to this configuration, when hanging several heavy structures using a plurality of sling wire ropes, when the movable pin is stopped in order for each position where a plurality of engagement pieces are installed, Do not uncouple multiple slinging wire ropes at once. For example, obtain a cue from a diver or the like, and check the state of the heavy structure and release the connection at each position of the engagement piece. be able to.

  According to a fifth aspect of the present invention, in the configuration according to any one of the first to fourth aspects, the hydraulic cylinder switches the position of the rod under the control of the hydraulic unit, and the hydraulic unit There is provided a remote ball removing device having detection means for detecting that the rod of a cylinder has slid to the stroke end on the retracting side.

  According to this configuration, when it is detected from the detection signal by the detection means that the rod has reached the stroke end on the retracting side, it can be confirmed from this signal that the movable pin has been slid to the ball removal position. When the frame is lifted with a crane after confirmation, the heavy structure remains at the installation target point, and the sling wire rope and the frame can be lifted together and collected.

  According to the first aspect of the present invention, even when the heavy structure is installed in the sea, when the heavy structure is moved to the installation target point, the hydraulic cylinder is operated by remote control even if the person does not dive in the sea. It is possible to safely and reliably remove the wire rope latching by the movable pin. As described above, since the wire rope can be safely and reliably extracted and removed from the heavy structure by remote control, unmanned underwater work can be performed. In addition, since the operator can operate the hydraulic cylinder to perform the ball removal operation, the safety of the work is further improved. In addition, hydraulic cylinders are installed as actuators in the parts that are thrown into the sea, and since there are no actuators that are driven by electricity and require high waterproof performance, safety can be improved and the structure Can be simplified and can be provided at low cost.

  Since the invention according to claim 2 can reduce the size of the frame in the lateral direction (horizontal direction), in addition to the effect of the invention of claim 1, an effect that a compact device can be realized can be expected.

According to the invention of claim 3, when the hook on the other end side of the wire rope for slinging by the movable pin is released and then the frame is lifted by a crane, the heavy structure is left at the installation target point, and the wire rope for slinging is simultaneously performed. Since it can be lifted and collected, in addition to the effect of the invention of claim 1 or claim 2, further improvement in workability can be expected. Furthermore, in the case where a plurality of shackle attachment portions are provided, it is possible to expect an effect that several heavy weight structures can be easily suspended using a plurality of sling wire ropes.

  In the invention according to claim 4, when a plurality of heavy wire ropes are used to suspend several heavy structures, the state of the heavy structure is checked while checking the state of the heavy structure. Since the connection can be removed stepwise, in addition to the effect of the invention of any one of claims 1 to 3, an effect that the work can be performed more safely can be expected.

  According to the fifth aspect of the present invention, when it is confirmed that the rod has reached the stroke end on the evacuation side, the frame can be lifted with a crane and the sling wire rope can be simultaneously recovered. In addition to the effect of any one of the inventions, the effect of further improving workability can be expected.

1 is a schematic configuration diagram of a heavy structure laying system to which a remote ball removing device according to an embodiment of the present invention is applied. FIG. 2 is a perspective view of the remote ball removing device shown in FIG. 1, where (a) is a view from the upper surface side, and (b) is a view from the lower surface side. FIG. 2 is a plan view of a single remote ball removing device shown in FIG. 1. The side view which looked at the remote ball removal apparatus simple substance shown by FIG. 1 from the arrow A direction of FIG. FIG. 2 is a bottom view of the remote ball removing device shown in FIG. 1. The side view which looked at the remote ball removal apparatus simple substance shown by FIG. 1 from the arrow B direction of FIG. It is an operation explanatory view of the same remote ball removing device used in the one-point suspension mode, (a) is a bottom view, (b) is an operation explanatory view when connecting a wire rope for sling, (c) is a wire rope for sling Explanatory drawing of operation at the time of release. It is operation | movement explanatory drawing of the remote bead removal apparatus same as the above used in another one-point hanging mode, (a) is a bottom view, (b) is operation | movement explanatory drawing at the time of the wire rope connection for slinging, (c) is for slinging Operation | movement explanatory drawing at the time of wire rope release. It is an operation explanatory view of the same remote ball removing device used in the two-point suspension mode, (a) is a bottom view, (b) is an operation explanatory view when connecting a wire rope for slinging, (c) is a wire rope for slinging Explanatory drawing of operation at the time of release. It is operation explanatory drawing of the same remote ball removing device used in the three-point hanging mode, (a) is a bottom view, (b) is an operation explanatory diagram when connecting a wire rope for slinging, (c) is a wire rope for slinging Explanatory drawing of operation at the time of release. It is operation explanatory drawing of the same remote ball removing device used in the four-point hanging mode, (a) is a bottom view, (b) is an operation explanatory diagram when connecting a wire rope for slinging, (c) is a wire rope for slinging Explanatory drawing of operation at the time of release. The perspective view which shows one modification of a remote ball removal apparatus same as the above. The side view of the remote ball removal apparatus shown in FIG.

  An object of the present invention is to provide a remote ball removing device capable of installing a heavy structure at an installation target point without being affected by the presence or absence of an obstacle existing between an operator and the heavy structure. In order to achieve the above, a remote ball removing device used when a heavy structure is suspended by a crane, the frame suspended by the crane, and a sling attached to the frame and hanging the heavy structure A movable pin that can be selectively switched to either a slinging position where the wire rope is latched or a ball unloading position where the slinging wire rope is unlatched, and an engagement hole for inserting and engaging the movable pin. A slinging / removing means having an engaging piece, a cylinder tube, and a forward / backward movement from the cylinder tube to switch the position of the movable pin. A hydraulic cylinder having a rod, was realized by providing the.

  Hereinafter, an example of a remote ball removing apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a schematic configuration diagram of a heavy structure laying system to which a remote ball removing device according to an embodiment of the present invention is applied. This heavy structure laying system is attached to a wire rope (not shown) of a crane operated by an operator, and a remote ball removing device 11 that suspends the heavy structure 100 and a hydraulic pressure of the remote ball removing device 11. And a hydraulic control device 12 as a hydraulic unit for controlling the operation of the cylinder 18. The remote ball removing device 11 and the hydraulic control device 12 are connected by a flexible hydraulic hose 13. Then, the slinging / unballing operation of the remote ball removing device 11 is performed by operating a predetermined switch provided on the control panel 14a or the remote control switch 14b of the hydraulic control device 12 by the operator's will. By controlling the hydraulic oil (hydraulic pressure) supplied to the remote ball removing device 11 from the remote control device 11, it can be remotely operated at the operator's will.

  In this heavy structure laying system, for example, as shown in FIG. 1, two wire ropes 15 and 15 for hanging are turned to portions where the heavy structure 100 can be suspended, respectively. The ball portion 15a on one end side of the wire ropes 15 and 15 for hanging the ball is hooked to the remote ball removing device 11 via the shackle 102, and the ball portion 15a on the other end side is movable pin 23 described later. When the slinging device 11 is lifted and moved together with the slinging wire ropes 15 and 15 and the heavy structure 100 by a crane, the heavy structure 100 can be carried to the installation target point.

  When the heavy structure 100 is carried to the installation target point, the ball portion 15a on one side of the slinging wire ropes 15, 15 is removed from the movable pin 23 of the remote ball removing device 11, and then the remote ball removing device using a crane. When 11 is lifted, the heavy structure 100 is left at the installation target point, and the slinging wire ropes 15 and 15 are also lifted together with the remote ball removing device 11 and can be collected.

  Next, the detailed structure of the remote ball removing device 11 will be further described with reference to FIGS. In the figure, a remote ball removing device 11 includes a frame 16, a ball hanging / ball removing means 17, a hydraulic cylinder 18 as an actuator, and the like.

  As shown in FIGS. 2 (a), 3 and 5, the frame 16 has a band annular body portion 16a formed as a hollow annular body and a large surface covering the upper surface of the annular body portion 16a. An upper plate portion 16b in a plan view disc shape provided fixed to the annular body 16a and a disc in a plan view view provided fixed to the annular body 16a so as to largely block the lower surface of the annular body portion 16a. And is formed as a generally low profile disc body as a whole. In the upper plate portion 16b and the lower plate portion 16c, four fan-shaped openings 19 are provided radially at positions corresponding to each other.

  Further, four shackle mounting pieces 20 having mounting holes 20a are provided on the outer peripheral side of the upper surface of the upper plate portion 16b so as to protrude from each other between the adjacent openings 19 and the openings 19. Yes.

  On the other hand, on the outer peripheral side of the lower surface of the lower plate portion 16c, four shackle mounting pieces 21 each having mounting holes 21a provided between the adjacent openings 19 and the openings 19, respectively, Two shackle mounting pieces 22 having the same mounting holes 22a provided in parallel with the two shackle mounting pieces 21 in the shackle mounting pieces 21 are provided so as to protrude downward. These shackle mounting pieces 20, 21, 22 are respectively fixed to the upper plate portion 16b and the lower plate portion 16c by welding or the like, and the shackles 102 (FIGS. 1, 9, 10) are mounted in the mounting holes 20a, 21a, 22a. , Shown in FIG. 11) can be attached. Further, on the outer peripheral side of the lower surface of the lower plate portion 16c, four legs 31 having a pipe shape on the lower surface are suspended. The lengths of the four legs 31 are larger than the amount of sling / ball removal means 17 (described later) protruding downward from the lower surface of the lower plate portion 16c, and the remote ball removal device 11 is placed on the ground. The sling / ball removal means 17 is prevented from touching the ground.

  The sling / ball removal means 17 is composed of a movable pin 23 and three engagement pieces 24a, 24b, 24c and the like for holding the movable pin 23 slidably. Is suspended.

  As shown in FIGS. 2 (b) and 5, the three engagement pieces 24a, 24b, and 24c are arranged with an engagement piece 24b at the approximate center on the lower surface side of the lower plate portion 16c, and the engagement pieces 24b are engaged in the front and rear sides thereof. The combined pieces 24a and 24c are arranged in a line with the engaging pieces 24b facing each other and with a predetermined gap between the engaging pieces 24a, 24b and 24c. Each of the engagement pieces 24a, 24b, and 24c has an engagement hole 25 that also serves as a guide hole in which the movable pin 23 is slidably engaged.

  The movable pins 23 are commonly engaged with the engagement holes 25 of the engagement pieces 24a, 24b, and 24c, and are held so as to move in parallel with the lower surface of the lower plate portion 16c. Further, one end (lower end) of the connecting member 26 is fixed to one end side (engagement piece 24a side) of the movable pin 23 so as to be integrally movable. Note that the other end of the connecting piece 26 penetrates the openings 19 of the lower plate portion 16c and the upper plate portion 16b and protrudes from the upper surface side of the upper plate portion 16b.

  The hydraulic cylinder 18 includes a cylinder tube 27 and a rod 28 that moves forward and backward from the cylinder tube 27 to switch the position of the movable pin 23. These are formed on the upper surface of the upper plate portion 16b. It is disposed in a state lying parallel to the movable pin 23, that is, at a position corresponding to the movable pin 23 up and down. As shown in FIGS. 1 and 2A, the cylinder tube 27 is fixed to the upper surface of the upper plate portion 16b via a bracket 30. On the other hand, the rod 28 that advances and retreats from the cylinder tube 27 corresponds to the other end (upper end) of the connecting member 26 attached to the movable pin 23, and the tip is connected to the other end of the connecting member 26 and the pivot 29. Are linked through. By this link connection, the slide operation of the rod 28 of the hydraulic cylinder 18 is transmitted to the movable pin 23 so that the position of the movable pin 23 can be switched.

  As shown in FIGS. 1 and 2A, a hydraulic hose 13 connected to the hydraulic control device 12 is connected to the side surface of the cylinder tube 27. The cylinder tube 27 is configured such that the rod 28 can be advanced and retracted by hydraulic oil (hydraulic pressure) sent from the hydraulic control device 12 through the hydraulic hose 13. By controlling this, the so-called rod 28, which is stopped at an intermediate position within the entire stroke range, can be stopped stepwise for each intermediate position.

  Further, when the rod 28 advances and retreats, the movable pin 23 also moves along the lower surface of the lower plate portion 16c by the link connection of the connecting member 26 and the rod 28, that is, the engagement holes 25 of the engagement pieces 24a, 24b, 24c. Move in order.

  The movement of the movable pin 23 is related to the stepwise movement of the rod 28, and the movement of the rod 28 is such that the tip of the movable pin 23 enters the engagement hole 25 of the engagement piece 24a. The retracted position (hereinafter, this position is referred to as “all ball removal end”), the movable pin 23 passes through the movable pin engagement hole 25 of the engagement piece 24a, and the tip portion thereof is the engagement piece 24b. A position in which the movable pin 23 is inserted into and engaged in the engagement hole 25 (hereinafter, this position is referred to as a “first sling end”), and the movable pin 23 is engaged with the movable pin engagement hole 25 and the engagement piece of the engagement piece 24a. A position where the distal end of the movable pin engaging hole 25 of 24b is inserted and engaged in the engaging hole 25 of the engaging piece 24c (hereinafter, this position is referred to as a “second staking end”). , You can stop each.

  In the following description, (1) when the tip of the movable pin 23 is disposed at the “all ball removal end”, the movable pin 23 is said to be in the “all ball removal position”, and (2) the movable pin When the tip end portion of the movable pin 23 is disposed at the “first sling end”, the movable pin 23 is said to be in the “first sling end position”, and (3) the tip portion of the movable pin 23 is at the “second sling end”. When arranged, the movable pin 23 is said to be in the “second sling position”.

  Further, the stop of the rod 28 in the hydraulic cylinder 18 is caused by the detection signal from the detection means provided in the hydraulic control device 12, that is, the sliding movement of the rod 28 in the hydraulic cylinder 18 is "all ball removal end", This is accurately performed based on, for example, a signal from a stroke monitoring sensor that is output when the “one slinging end” and the “second slinging end” are reached.

  In addition, on the control panel 14 of the hydraulic control device 12, a display for confirming that the rod 28 has arrived at the positions of the “all ball removal end”, the “first slinging end”, and the “second slinging end”. A lamp may be provided, and at the same time, a voice generating means for notifying the position by voice may be provided.

  7 to 11 are operation explanatory views of the remote ball removing device 11 according to the present invention. In this remote ball removal device 11, the heavy structure 100 can be suspended by various methods and carried to the installation target point, and the remote ball removal device 11 can be collected leaving the weight structure portion 100. Several methods will be described below. The remote ball removing device 11 is attached to a shackle attachment piece 20a provided on the upper surface of the upper plate portion 16b of the frame 16, and a shackle is connected to a wire rope (not shown) and suspended by a crane. It can be carried to the installation target point.

  FIG. 7 shows that a middle portion of one slinging wire rope 15 is passed through a hollow portion where the heavy structure 100 can be suspended, and ball portions 15 a provided on both ends of the slinging wire rope 15. Each of 15a is slung on the movable pin 23 of the remote ball removing device 11. The remote ball removing device 11 is suspended by a crane together with the slinging wire rope 15 and the heavy structure 100, and is carried to the installation target point in a state where the heavy structure 100 is suspended at one point.

  In this case, prior to setting the sling wire rope 15 to the weight structure portion 100, the operator operates a predetermined switch provided on the control panel (or a remote control switch, the same shall apply hereinafter) to operate the hydraulic pressure. A hydraulic operation for sending hydraulic oil from the control device 12 to the hydraulic cylinder 18, that is, a remote operation is performed, and the position of the movable pin 23 is switched to a state where the tip of the movable pin 23 is retracted to the “ball removal end”. When the tip portion of the movable pin 23 is retracted to the “ball removal end”, the ball portions 15a and 15a of the wire rope 15 for staking are engaged with the engagement piece 24b and between the engagement piece 24a and the engagement piece 24b, respectively. Then, the operator operates a predetermined switch on the control panel again so that the tip of the movable pin 23 is disposed at the “second sling end”. As a result, as shown in FIGS. 7A and 7B, both ball portions 15 a and 15 a of the wire rope 15 for slinging are slung on the movable pin 23.

  In this state, when the wire rope of the crane is wound up and the remote ball removing device 11 is lifted by the crane, the heavy structure 100 is also lifted together with the sling wire ropes 15 and 15, and the heavy structure 100 thus lifted is installed at the installation target point. Can carry up to.

  When the heavy structure 100 is moved to the installation target point, the operator operates a predetermined switch on the control panel to perform a hydraulic operation for sending hydraulic oil from the hydraulic control device 12 to the hydraulic cylinder 18. The rod 28 is slid to switch the position of the movable pin 23 to a state where the tip end portion of the movable pin 23 is disposed at the “first slinging end”. As a result, the ball portion 15a that is slung on the movable pin 23 at the “first sling position” is kept hung on the movable pin 23, but the ball portion 15a that is slacked at the “second sling position”. Is removed from the movable pin 23.

  Next, when the remote ball removing device 11 is lifted again by a crane, as shown in FIG. 7C, one end of the wire rope 15 for slinging where the ball portion 15a is slung on the movable pin 23 at the “first slinging position”. The side is still connected to the movable pin 23, and the ball portion 15a on the other end side is disengaged from the movable pin 23. Therefore, the remote ball removing device remains with the heavy structure 100 at the installation target point. 11 and the wire rope 15 for sling are lifted together and collected.

  FIG. 8 shows that one end (lower end) side of one slinging wire rope 15 is attached to the heavy structure 100 through a ring portion of a ring-shaped suspension member 101 provided on the heavy structure 100. The ball portion 15 a provided on the other end (upper end) side of the staking wire rope 15 is shook on the movable pin 23 of the remote ball removing device 11. Then, the remote ball removal device 11 is lifted and moved together with the slinging wire rope 15 and the heavy structure 100 by a crane, and is carried to the installation target point in a state where the heavy structure 100 is suspended at one point.

  In this case, prior to setting the slinging wire rope 15 to the weight structure unit 100, the operator operates a predetermined switch on the control panel to send hydraulic oil from the hydraulic control device 12 to the hydraulic cylinder 18, and the hydraulic cylinder Eighteen rods 28 are slid to switch the position of the movable pin 23 to a state in which the tip portion of the movable pin 23 is retracted to the “first sling end”.

  When the distal end portion of the movable pin 23 is retracted to the “first sling end”, in this state, the ball portion 15a of the sling wire rope 15 is disposed between the engagement piece 24b and the engagement piece 24c, and then The operator operates a predetermined switch on the control panel so that the tip portion of the movable pin 23 is disposed at the “second sling end”. As a result, as shown in FIGS. 8A and 8B, the ball portion 15 a of the wire rope 15 for slinging is slung on the movable pin 23.

  In this state, when the wire rope of the crane is wound up and the remote ball removing device 11 is lifted by the crane, the heavy structure 100 is also lifted together with the wire rope 15 for slinging, and the lifted heavy structure 100 is moved to the installation target point. Can carry.

  When the heavy structure 100 is moved to the installation target point, the operator operates a predetermined switch on the control panel to send hydraulic oil from the hydraulic control device 12 to the hydraulic cylinder 18 and move the rod 28 of the hydraulic cylinder 18. By sliding, the position of the movable pin 23 is switched to a state where the tip end portion of the movable pin 23 is disposed at the “first sling end”. Thereby, as shown in FIG. 8C, the ball portion 15 a on the upper end side of the wire rope 15 for slinging is removed from the movable pin 23.

  Next, when the remote ball removing device 11 is lifted again by the crane, the remote ball removing device 11 is lifted and collected while leaving the sling wire rope 15 and the heavy structure 100 at the installation target point.

  FIG. 9 shows that the middle portions of the two slinging wire ropes 15 and 15 are respectively passed through the ring portions of different places where the heavy structure 100 can be suspended, and both end sides of the slinging wire ropes 15 and 15. One of the ball portions 15 a provided on the shackle mounting piece 21 is fixed to the shackle 102 attached to the shackle mounting piece 21, and the other is hung on the movable pin 23 of the remote ball removing device 11. The remote ball removing device 11 is lifted and moved together with the slinging wire ropes 15 and 15 and the heavy structure 100 by a crane, and is carried to the installation target point in a state where the heavy structure 100 is suspended at two points. is there.

  Prior to setting the slinging wire ropes 15, 15 to the weight structure unit 100, an operator operates a predetermined switch on the control panel to send hydraulic oil from the hydraulic control device 12 to the hydraulic cylinder 18, The rod 28 of the cylinder 18 is slid to switch the position of the movable pin 23 to a state in which the tip end portion of the movable pin 23 is retracted to the “ball removal end”.

  When the distal end portion of the movable pin 23 is retracted to the “ball removal end”, the ball portions 15a and 15a on one side of the wire ropes 15 and 15 for slinging are respectively engaged between the engagement pieces 24a and the engagement pieces 24b, and engaged. An operator operates a predetermined switch on the control panel so that the movable pin 23 is disposed at the “second sling end” after being disposed between the piece 24b and the engagement piece 24c. As a result, as shown in FIGS. 9A and 9B, one of the ball portions 15a of the sling wire ropes 15 and 15 is mounted on the shackle mounting piece 21, and the other is slung on the movable pin 23. The

  In this state, when the wire rope of the crane is wound up and the remote ball removing device 11 is lifted by the crane, the heavy structure 100 is also lifted together with the sling wire ropes 15 and 15, and the heavy structure 100 thus lifted is installed at the installation target point. Can carry up to.

  When the heavy structure 100 is moved to the installation target point, the operator operates a predetermined switch on the control panel to send hydraulic oil from the hydraulic control device 12 to the hydraulic cylinder 18 and slide the rod 28 of the hydraulic cylinder 18. The operation is switched to a state where the tip portion of the movable pin 23 is disposed at the “ball removal end”. As a result, the ball portions 15 a and 15 a that are hung on the movable pin 23 at the “first sling position” and “second slack position” are removed from the movable pin 23.

  Next, when the remote ball removing device 11 is lifted again by the crane, the ball portion 15a on one end side of the wire ropes 15 and 15 for slinging is attached to the shackle 102 attached to the shackle mounting piece 21 as shown in FIG. Since the ball portion 15a on the other end side is detached from the movable pin 23, the remote ball removing device 11 and the slinging wire rope 15, while leaving the heavy structure 100 at the installation target point, remain fixed. 15 are lifted together and collected.

  FIG. 10 shows that the intermediate portions of the three slinging wire ropes 15, 15, 15 are respectively passed through the ring portions at different locations where the heavy structure 100 can be suspended, and the slinging wire ropes 15, 15, 15 One of the ball portions 15 a provided at both end sides of 15 is fixed to the shackle 102 attached to the shackle attaching pieces 21, 22, and the other is put on the movable pin 23 of the remote ball removing device 11. The remote ball removing device 11 is lifted and moved together with the slinging wire ropes 15, 15, 15 and the heavy structure 100 by a crane, and is carried to the installation target point in a state where the heavy structure 100 is suspended at three points. Is. In addition, the position of the shackle attachment pieces 21 and 22 to be used is selected in consideration of the balance of the heavy structure 100, and the shackle attachment pieces 21 and 22 at positions where the remote ball removing device 11 is as horizontal as possible.

  Further, prior to setting the slinging wire ropes 15, 15, 15 to the weight structure unit 100, the operator operates a predetermined switch on the control panel to send hydraulic oil from the hydraulic control device 12 to the hydraulic cylinder 18, The rod 28 of the hydraulic cylinder 18 is slid to switch the position of the movable pin 23 to a position where the tip of the movable pin 23 is retracted to the “ball removal end”.

  When the distal end portion of the movable pin 23 is retracted to the “ball removal end”, the ball portions 15a, 15a, 15a on one side of the wire ropes 15, 15, 15 for the sling are respectively connected to the engagement piece 24a and the engagement piece 24b. Between the engagement piece 24b and the engagement piece 24c, and then the operator presses a predetermined switch on the control panel so that the distal end portion of the movable pin 23 is located at the “second sling end”. Manipulate. As a result, as shown in FIGS. 10A and 10B, one of the ball portions 15a of the sling wire ropes 15, 15, 15 is attached to the shackle attachment pieces 21, 22, and the other is the movable pin 23. Each is slapped.

  In this state, when the wire rope of the crane is wound up and the remote ball removing device 11 is lifted by the crane, the heavy structure 100 is also lifted together with the sling wire ropes 15, 15, and 15. Can be carried to the target point.

  When the heavy structure 100 is moved to the installation target point, the operator operates a predetermined switch on the control panel to send hydraulic oil from the hydraulic control device 12 to the hydraulic cylinder 18 and slide the rod 28 of the hydraulic cylinder 18. Thus, the tip of the movable pin 23 is switched to a state where it is disposed at the “ball removal end”. As a result, the ball portions 15 a that are respectively slung on the movable pin 23 at the “first sling position” and the “second slack position” are removed from the movable pin 23.

  Next, when the remote ball removing device 11 is lifted again by the crane, the ball portion 15a on one end side of the wire ropes 15, 15, 15 for slinging is attached to the shackle mounting pieces 21, 22 as shown in FIG. 10 (c). Since the ball portion 15a on the other end side is detached from the movable pin 23, the remote ball removing device 11 and the sling are left while the heavy structure 100 remains at the installation target point. The wire ropes 15, 15, 15 are lifted together and collected.

  FIG. 11 shows a ring-shaped suspension member 103 provided at each of four corners of the upper surface of the weight structure 200 having a quadrangular shape in the middle portion of the four slinging wire ropes 15, 15, 15, 15. And one of the ball portions 15a provided at both ends of each of the wire ropes 15, 15, 15, 15 for each sling is fixed to the shackle 102 attached to the shackle mounting piece 21, and the other The movable pin 23 of the remote ball removing device 11 is slung. Then, the remote ball removing device 11 is lifted and moved together with the slinging wire ropes 15, 15, 15, 15 and the heavy structure 200 by a crane so as to carry the heavy structure 200 to the installation target point in a state where the heavy structure 200 is suspended at four points. It is a thing.

  Prior to setting the sling wire ropes 15, 15, 15, 15 to the weight structure unit 200, an operator operates a predetermined switch on the control panel to supply hydraulic oil from the hydraulic control device 12 to the hydraulic cylinder 18. Then, the rod 28 of the hydraulic cylinder 18 is slid to switch the position of the movable pin 23 to a state where the tip of the movable pin 23 is retracted to the “ball removal end”.

When the tip of the movable pin 23 is retracted to the “ball removal end”, the ball portions 15 a, 15 a, 15 a, 15 a on one side of the wire ropes 15, 15, 15, 15 for staking are respectively engaged with the engagement pieces 24 a. It is arranged between the joining pieces 24b and between the engaging pieces 24b and the engaging pieces 24c, and thereafter, the operator sets the predetermined position of the control panel so that the tip end portion of the movable pin 23 is placed at the “second sling end”. Operate the switch. Thus, as shown in FIGS. 11A and 11B, one of the ball portions 15 a of the wire ropes 15, 15, 15 for hanging is attached to the shackle attachment piece 21, and the other is attached to the movable pin 23. Be slapped.

  In this state, when the wire rope of the crane is wound up and the remote ball removing device 11 is lifted by the crane, the heavy structure 200 is also lifted together with the slinging wire ropes 15, 15, 15, 15. Can be carried to the target location.

  When the heavy structure 200 is moved to the installation target point, the operator operates a predetermined switch on the control panel to send hydraulic oil from the hydraulic control device 12 to the hydraulic cylinder 18, and the rod 28 of the hydraulic cylinder 18 is moved. By sliding, the tip of the movable pin 23 is switched to the state where it is arranged at the “ball removal end”. As a result, the ball portion 15 a that is hung on the movable pin 23 at the “first sling position” and “second slack position” is removed from the movable pin 23.

  Next, when the remote ball removing device 11 is lifted again by a crane, the ball portion 15a on one end side of the wire ropes 15, 15, 15, 15 for hanging is attached to the shackle attachment piece 21 as shown in FIG. Since the ball portion 15a on the other end side is detached from the movable pin 23, the remote ball removing device 11 and the sling are left while the heavy structure 200 remains at the installation target point. The wire ropes 15, 15, 15, 15 are lifted together and collected.

  As described above, according to the remote ball removing device 11 according to the present embodiment, the slinging wire is attached to the movable pin 23 that is switched to the “first slinging position” or the “second slinging position” that is the latching position. In a state where the rope 15 is hooked, the heavy structure 100, 200 is hung with the wire rope 15 for hanging and moved to the installation target point, and when the installation target point is reached, the hydraulic hose 13 is transferred from the hydraulic control device 12 to the hydraulic cylinder 18. When the movable pin 23 is moved to the “first slinging end” or “thickening end” which is the position where the ball is removed, and the wire rope 15 for slinging is removed from the movable pin 23 The heavy structure 100, 200 suspended by the slinging wire rope 15 is released from the connection of the slinging wire rope 15. It can be installed the heavy construction 100, 200 to the installation target point. Therefore, even in the case of installation in the sea, the operator can confirm that the heavy structure 100, 200 has bottomed, for example, with a load meter of a crane, and then perform a ball removal operation so that the underwater work can be performed. Unmanned work is possible. In addition, since the hydraulic circuit is used without using electricity, the structure can be simplified without requiring high waterproof performance even when a heavy structure is thrown into the sea.

  In the above-described embodiment, the configuration in which the engagement pieces 24a, 24b, and 24c are provided to provide the “first stake position” and the “second stake position” is disclosed, but the number of the engagement pieces is two or more. If there are, it is not necessarily three, but may be four or more.

  12 and 13 show a modified example of the remote ball removing device shown in FIGS. 1 to 11, FIG. 12 is a perspective view of the remote ball removing device, and FIG. 13 is a side view of the remote ball removing device. It is. In this modification, a protective cover 32 is provided on the upper surface of the upper plate portion 16b of the frame 16 so as to cover the hydraulic cylinder 18 provided on the upper surface, and other configurations are shown in FIGS. 11 are the same as those shown in FIG.

  The protective cover 32 includes three pipe members 32a that are bent in the same direction in the same direction and are arranged in parallel in the horizontal direction and are connected to bracket pieces 32b and 32b. Integrated. The pipe members 32a, 32a, 32a cover the upper side of the hydraulic cylinder 18, and the bracket pieces 32b, 32b are detachably fixed to the upper surface of the upper plate portion 16b with screws (not shown).

  As described above, in the structure in which the upper side of the hydraulic cylinder 18 is covered with the protective cover 32, it is possible to prevent the hydraulic cylinder 18 from being damaged when an object collides from the outside toward the hydraulic cylinder 18.

  It should be noted that the present invention can be variously modified without departing from the spirit of the present invention, and the present invention naturally extends to the modified ones.

  Although this invention demonstrated the case where it uses for the work which installs a breakwater construction or an artificial reef, etc., it is applicable also when performing the construction on land other than this.

11 Remote ball removal device 12 Hydraulic control device (hydraulic unit)
13 Hydraulic hose 14a Control panel 14b Remote control switch 15 Wire rope 15a for slinging Ball portion 16 Frame 16a Annular body portion 16b Upper plate portion 16c Lower plate portion 17 Catching / ball removing means 18 Hydraulic cylinder 19 Opening 20 Shackle mounting piece 20a Mounting Hole 21 Shackle attachment piece 21a Attachment hole 22 Shackle attachment piece 22a Attachment hole 23 Movable pins 24a-24c Engagement piece 25 Engagement hole 26 Connecting member 27 Cylinder tube 28 Rod 29 Axis 30 Bracket 31 Leg 32 Protective cover 32a Pipe material 32b Bracket Piece 100 Heavy structure 200 Heavy structure 101 Suspension member 102 Shackle 103 Suspension member

Claims (5)

A remote ball removal device used when a heavy structure is suspended by a crane,
A frame suspended by the crane;
Switch selectively to either a sling position where a sling wire rope that is attached to the frame and suspends the heavy structure is hung, and a ball slack position where the sling is removed. A slinging / unballing means having a movable pin and an engagement piece having an engagement hole for inserting and engaging the movable pin;
A hydraulic cylinder having a cylinder tube and a rod that moves forward and backward from the cylinder tube to perform a position switching operation of the movable pin;
A remote ball removing device characterized by comprising: The hydraulic cylinder is provided on the upper surface side of the frame,
The slinging / removing means is provided on the lower surface side of the frame,
2. The remote ball removing device according to claim 1, wherein the rod of the hydraulic cylinder and the movable pin of the slinging / ball removing means are slidably coupled to each other.   3. The remote ball removing device according to claim 1, wherein the frame includes at least one shackle attachment portion to which a shackle to which one end of the sling wire rope is hooked is attached. The slinging / unballing means are respectively provided below the lower surface of the frame in a state where the plurality of engaging pieces are separated from each other,
4. The remote ball removing device according to claim 1, wherein the movable pin can be stopped at each installation position of the plurality of engaging pieces. 5.   The hydraulic cylinder switches the position of the rod under the control of a hydraulic unit, and the hydraulic unit has detection means for detecting that the rod of the hydraulic cylinder has slid to the retracting stroke end. The remote ball removing device according to any one of claims 1 to 4, wherein:

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