KR100904484B1 - Device for prevention overload of winch for floodgate - Google Patents

Abstract

A winch for operating a water gate to prevent overload is provided to prevent damage to the winch and prevent crack of a water gate and a concrete structure due to overload. A winch for operating a water gate to prevent overload comprises: an overload setting unit(100) having a structure for sensing overload applied on the winch in advance and being connected to a shaft of a motor; an overload intercepting unit(200) inducing slip between a pressure plate and a disc by separating a plurality of discs(202) and a pressure plate(204) in case the overload reaches on the overload set value of the overload setting unit and rotating the disc and the pressure plate in normal operation; and a power transmission unit being provided with torque from the disc of the overload intercepting unit and transferring torque to a driving gear for opening and closing the water gate and stopping transferring the torque to the torque to the driving gear in case the overload reaches on the overload set value of the overload setting unit.

Description

Device for prevention overload of winch for floodgate}

The present invention relates to a hydrostatic operation winch that blocks the overload, and more particularly, when the pre-set overload load is reached to prevent the damage of the water gate and concrete structure by blocking the rotation force toward the rack bar connected to the water gate It relates to a hydrostatic hoist which blocks an overload to protect it.

In general, water is kept at a certain level in waters, such as water repellents, or freshwater areas of amusement parks including lakes, and reservoirs storing water for agriculture or industrial purposes. In order to control floods in rivers and flooded areas, or to supply agricultural and industrial water needed in agricultural and industrial areas, such flood gates may be located in fresh water areas. Is being installed on.

For the installation, the water gate is first constructed in a position where the concrete structure having a waterway becomes a discharge path of the freshwater, and then the waterway of the concrete structure is mounted so that the descending water gate is opened and closed, and the concrete structure On the upper surface of the hydrologic operation hoist connected to the top of the hydrologic gate to raise and lower the hydrologic gate is installed.

Attached Figure 1 is a schematic diagram of a conventional hydrostatic operation winch.

Referring to Figure 1 briefly look at the lifting and lowering operation of the water gate by the winch, the drive gear provided in the gear box 14 in the winch (10) while driving the motor 16 of the winch (10) The water gate 18 connected to the rack bar 12 is lifted or lowered by 20. When the door 18 is opened or closed, the rack bar 12 is raised or lowered at the same time as the bottom of the rack bar 12. Hanging on the water gate 18 is also raised or lowered to be made to open and close the water gate.

By the way, the conventional hydrologic winch has the following problems.

First, during the closing operation of the gate, it is difficult to check whether the gate is completely lowered to the lower part of the waterway, and it is difficult to check whether it is closed. If obstacles such as various dirts are caught in the lower part of the gate, the winch is overloaded, causing damage to the gate and the rack bar. There was a problem.

Second, cracks occur in the concrete structure in which the hydro gate and the winch are installed due to the overload, and in particular, there are problems such as a breakage of the winch due to the crack of the concrete structure.

On the other hand, in view of the above problems, there has been a technology development to recognize whether the gate is completely closed or the obstacle is blocked by installing a primary limit switch and a secondary torque switch when opening and closing the gate by the operation of the winch. In this case, the first limit switch and the second torque switch may cause a detection failure and malfunction due to vibration or aging, and eventually, cracking of the concrete structure due to the overload of the winch may occur.

The present invention has been made in order to solve the above problems, and separately provided an overload blocking means for setting the overload load in three stages in the hoisting machine, and when the set overload load setting value is reached, the disc in the overload blocking means is spaced apart The purpose of this invention is to provide a hydro-operation hoist that prevents the overload to prevent cracking of the gate and concrete structure and damage of the hoist by preventing the rotational force of the motor from being transmitted to the rack bar connected to the gate. There is this.

The present invention for achieving the above object includes a rack bar connected to the water gate for opening and closing the waterway of the concrete structure, a gear box including a drive gear for raising and lowering the rack bar, and a motor for transmitting rotational force to the gear box In hydrologic winches to do,

Overload load setting means connected to the shaft of the motor; When the overload load setting means reaches the overload setting load value, a plurality of discs and pressure plates are spaced apart to induce slip between the discs and the pressure plates, and the overload blocking means for rotating the discs and the pressure plates in normal operation; When slipping between the disc and the pressure plate when the overload set load value is reached, the rotational force is not transmitted to the drive gear in the gearbox, and in normal operation, the rotational force is received from the disc of the overload blocking means. It provides a hydrostatic action winker to block the overload, characterized in that it comprises a; power transmission means for transmitting a rotational force for opening and closing the gate of the drive gear.

The overload load setting means according to the present invention, the rear end is connected to the shaft of the motor, the front end shaft and the spline is formed; A first cap having a bearing inner hole in which a rear end of the shaft is inserted; A second cap having a bearing inner hole coupled to the first cap and a bolt, into which a rear end of the shaft is inserted, and having a first inclined mating surface formed at a front end thereof; A lever interlocking body having a second inclined mating surface which is meshable with the first inclined mating surface of the second cap, formed at a rear end surface thereof, and an outer end surface of which is integrally formed with a coupling end coupled with a three-stage adjustment lever; A thrust bearing inserted close to the rear end of the shaft and disposed in close contact with a front end of the lever linkage; And a disk-shaped pressing plate which is inserted in close contact with the front end of the thrust bearing while being inserted into a rear end section of the spline section of the shaft.

The overload blocking means according to the present invention comprises: a through hole into which the shaft is inserted through, and a first spring fixing plate formed through the radially arranged four pocket support holes around the through hole; A shaft fixing drum integrally formed at equal intervals by four vertically bent rotary feet which are fitted with the fitting hole to be fitted to the front end of the spline of the shaft, the outer circumferential part being assembled in close contact between the pocket support holes; A second spring fixing plate having four stud bolts integrally formed at a rear surface thereof so as to be inserted into a pocket supporting hole of the first spring fixing plate; A plurality of ring-type pressure plates disposed between the first and second spring fixing plates to receive rotational power from the shaft fixing drum; A plurality of ring type disks disposed between the pressure plates to transmit rotational force to the power transmission means; A spring support pocket inserted and seated at a rear side of each pocket support hole of the first spring fixing plate; A compression spring inserted into the stud bolt of the second spring fixing plate protruding through the spring pocket; And a cap bolt fastened to an end of the stud bolt in which the compression spring is inserted.

In particular, the inner circumferential surface of each ring-type pressure plate to receive the rotational force from the shaft fixing drum is characterized in that the fitting grooves for fitting the respective vertical bending rotary feet of the shaft fixing drum are formed at equal intervals.

In addition, the power transmission piece is characterized in that protruding at equal intervals on the outer circumferential surface of the plurality of ring-type disk to transmit the rotational force to the power transmission means.

The power transmission means according to the present invention, the rear is provided with a circular hollow space in which each disk and the pressure plate is embedded, the inner circumferential surface of the circular hollow space is a power transmission groove of the groove-shaped groove into which the power transmission pieces of each disk is inserted A clutch drum bearing a front end of the shaft at a central position of the circular hollow space; A power transmission rotating plate bolted to the front of the clutch drum; And a chain gear formed integrally with the front surface of the power transmission rotating plate and connected by a transmission gear and a chain interlocked with the drive gear in the gear box.

The present invention provides the following effects through the problem solving means described above.

According to the present invention, the three-stage overload load setting means in the hydrostatic operation winch, and if the overload is greater than the set value, the overload blocking means for inducing the slip between the power transmission disk and the pressure plate to block the overloading of the winch; In the case of an overload, the power transmission means for releasing the rotational force to the rack bar connected to the water gate to the internal blockage of the rotational force when overloaded, thereby preventing the crack of the water gate and concrete structures, and there is an effect that can prevent the damage to the winch.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, a brief description of the accompanying drawings, Figure 2 is a perspective view showing the appearance of the winch according to the present invention, Figure 3 is an overload load setting means and overload interruption means and power transmission means provided in the winch according to the present invention 4 and 5 are perspective views of the assembled state of the overload load setting means and overload interruption means and power transmission means provided in the winch according to the present invention.

In addition, Figure 6 is a perspective view showing a state in which the power transmission means separated in the state of assembling the configuration of the overload load setting means and the overload interruption means and the power transmission means provided in the hoist according to the present invention, Figure 7 is the present invention Some cross-sectional perspective view for explaining the internal structure in the state of assembling the configuration of the overload load setting means and the overload blocking means provided in the winch according to.

As described above, the winch for lifting and lowering the water gate is a rack box connected to the water gate for opening and closing the waterway of the concrete structure, a gear box including a drive gear for lifting and lowering the rack bar, and a rotational force in the gear box. An apparatus including a motor for transmitting the apparatus, the apparatus for lifting or lowering the rack bar during the opening or closing operation of the gate, and at the same time, for the opening and closing of the water gate connected to the bottom of the rack bar.

The winch of the present invention is to prevent the damage of the hydrologic and concrete structures and the damage of the winch according to the overload load, the configuration is the overload load setting means 100, the overload blocking means 200, The power transmission means 300 is largely divided.

Here, the configuration of the overload load setting means 100 of the present invention will be described.

The overload load setting means 100, as shown in Figure 3, is a structure that can be set in advance the overload load value applied to the winch, the shaft 108 is first connected to the shaft of the motor 16.

That is, the rear end of the shaft 108 is connected to the shaft of the motor 16, the spline 106 is formed at the front end of the shaft 108.

The first cap 112 and the second cap 118 coupled to each other by bolts are inserted into the rear end of the shaft 108, and the shaft 108 is located at a central position of the first cap 112. Bearing inner hole 110 is formed to insert the rear end of the), and the bearing inner hole 114 is also formed in the central position of the second cap 118.

In particular, three first inclined mating surfaces 116 inclined along the arc direction are formed on the front end surface of the second cap 118.

In addition, a lever interlocking body 124 is inserted into the shaft 108 next to the second cap 118, and the rear end surface of the lever interlocking body 124 is a first inclined plane of the second cap 118. Three second inclined mating surfaces 120 that can engage with the 116 is formed along the arc direction, and the outer end of the lever interlock 124 is coupled to the coupling stage 122 coupled to the three-stage adjustment lever 400. It is formed integrally.

In addition, a thrust bearing 126 is inserted into the shaft 108 next to the lever interlock 124, and the rear surface of the thrust bearing 126 is in close contact with the front end surface of the lever interlock 124 so as to be frictional friction. In addition, the front surface of the thrust bearing 126 is in close contact with the rear end surface of the disk-shaped pressing plate 128 is inserted into and fastened to the shaft 108 in a linear movement next.

At this time, the spline inner diameter hole 130 is formed in the center of the disk-shaped pressing plate 128 for insertion coupling with the front end section of the spline 106 of the shaft 108.

Here, the configuration of the overload blocking means 200 of the present invention will be described.

As shown in FIG. 3, when the overload breaking means 200 according to the present invention reaches the overload setting load value set by the overload load setting means 100, the plurality of disks 202 and the pressure plate 204 are reached. Spaced apart) to induce a slip between the disk 202 and the pressure plate 204, and serves to rotate the disk 202 and the pressure plate 204 in normal operation.

First, the first spring fixing plate 210 is inserted after the pressing plate 128 which is linearly coupled to the spline 106 of the shaft 108, and the shaft is located at the center of the first spring fixing plate 210. A through hole 206 through which the 108 is penetrated is formed, and four pocket support holes 208 are formed through the radial position around the through hole 206.

At this time, the shaft fixing drum 216 is coupled to the spline 106 of the shaft 108 next to the first spring fixing plate 210, the shaft 108 in the center of the shaft fixing drum 216 4 is a vertically bent rotary foot that is fitted through the fitting hole 212 is fitted to the front end of the spline 106, the outer circumferential portion is tightly assembled by a bolt on each side of the pocket support hole 208 214 are formed at equal intervals and are integrally formed.

As shown in FIG. 7, the shaft fixing drum 216 having the vertical bending rotary foot 214 is rotated when the shaft 108 connected to the shaft of the motor 106 rotates. Rotation of the spline 106 together with the pressure plate 128 is rotated.

At this time, the spring support pocket 222 is seated in each pocket support hole 208 of the first spring fixing plate 210, and a plurality of disks 202 in the first spring fixing plate 210. And a second spring fixing plate 220 with the pressure plate 204 therebetween.

That is, four stud bolts 218 integrally formed on the rear surface of the second spring fixing plate 220 are disposed in the spring support pocket 222 seated in the pocket support hole 208 of the first spring fixing plate 210. After insertion and protruding, the protruding stud bolts 218 are fitted to the compression springs 224, and then the cap bolts 226 are fastened to the ends of the stud bolts 218.

Accordingly, when the cap bolt 226 is pressed in a state in which the first spring fixing plate 210 is integrally assembled by the shaft fixing drum 216 and the bolt, the compression spring 224 is caused by the cap bolt 226. ) Is compressed and the stud bolt 218 is pushed down, and the second spring fixing plate 220 in which the stud bolt 218 is integrally pushed off.

In particular, a plurality of ring-type pressure plates 204 that receive rotational power from the shaft fixing drum 216 are mounted between the first and second spring fixing plates 210 and 220, and the shaft fixing drum 216 is provided. Into the inner circumferential surface of each ring-type pressure plate 204 to receive a rotational force from the fitting groove 228 is fitted at equal intervals to be fitted with the vertical bending rotary foot 214 of the shaft fixing drum 216.

In addition, a plurality of ring-type disks 202 for transmitting rotational power to the power transmission means 300 to be described later are arranged between each of the pressure plate 204, the plurality of power transmission means to transmit the rotational force 300 The power transmission pieces 230 protrude at equal intervals on the outer circumferential surface of the two ring type disks 202.

Here, the configuration of the power transmission means 300 of the present invention will be described.

The power transmission means 300, as shown in Figure 3, receives the rotational force from the disk 202 of the overload blocking means 200 in the normal operation of the winch to the water gate drive gear in the gear box 14 It serves to transmit the rotational force for opening and closing.

On the contrary, when the overload load setting means 100 reaches a preset overload load during operation of the winch, the slip between the disk 202 and the pressure plate 204 of the overload blocking means 200 is induced, and the power transmission means 300 does not transmit the rotational force to the drive gear in the gearbox (14).

In the power transmission means 300 having such a role, the disk 202 and the pressure plate 204 of the overload blocking means 200 are embedded in the clutch drum 306.

That is, each of the disk 202 and the pressure plate 204 is embedded in the circular hollow space 302 formed on the rear of the clutch drum 306, the circular hollow space 302 as shown in FIG. The inner circumferential surface of the power transmission groove 304 is formed in the groove shape is inserted into the power transmission piece 230 of each disk 202, and also in the central position of the circular hollow space 302 of the shaft 108 The shear end is combined with the bearing.

In addition, the front plate of the clutch drum 306 is integrally assembled with a bolt-shaped power transmission rotating plate 308 by a bolt, the front surface of the power transmission rotating plate 308 is equipped with a chain gear 310, the chain The gear 310 is connected by a drive gear and a chain in the gearbox 14.

Hereinafter, the operation of the hydrological winch of the present invention made of the configuration as described above are as follows.

8 is a cross-sectional view illustrating a one-stage operation operating state of the hydrostatic operation winch of the present invention, FIG. 9 is a cross-sectional view illustrating a two-stage operation operation state of the hydrological action winch of the present invention, and FIG. It is sectional drawing explaining the three stage operation | movement operation state of the hydrological action winch machine of this invention.

First, the three-stage adjustment lever 400 to set the overload load set value, when operating the three-stage adjustment lever 400 in one stage, the lever linkage 124 connected to the three-stage adjustment lever 400 is When the angular rotation is performed, and the second and third stage operations are performed, the lever linkage rotates further sequentially.

Thus, in the case of the first stage operation, the lowest surface of the second inclined plane surface 120 section of the lever linkage 124 and the first slope of the first slope surface 116 section of the second cap 118. The lower surfaces are brought into close contact with each other.

Next, in the case of two-stage operation, the middle height surface of the second inclined plane surface 120 section of the lever interlocking body 124 and the first slope of the first slope value plane 116 section of the second cap 118 The surfaces of the intermediate height are in close contact with each other, the lever interlock 124 is moved from the second cap 118 toward the pressure plate 128, and eventually the front surface of the lever interlock 124 is The pressure plate 128 is pushed.

Next, in the case of the three-stage operation, the highest surface of the second inclined plane surface 120 of the lever interlocking body 124 and the first slope of the first inclined plane 116 of the second cap 118 The high surfaces are in close contact with each other, but the lever interlock 124 is moved farthest from the second cap 118 toward the pressure plate 128, and eventually the front surface of the lever interlock 124 is The pressure plate 128 is pushed to the maximum.

Subsequently, as the pressure plate 128 is pushed, the front surface of the pressure plate 128 pushes the cap bolt 226.

That is, to push the back of the cap bolt 226 fastened to each stud bolt 218 of the second spring fixing plate 220 protruding through the spring support pocket 222 of the first spring fixing plate 210 do.

Subsequently, the cap bolt 226 pushes the stud bolt 218 and the second spring fixing plate 220 while compressing the compression spring 224, and eventually the cap bolt 226 and the stud bolt 218 and the The two spring fixing plate 220 is pushed at the same time, but is pushed further by a long distance when the two-stage and three-stage operation as described above.

In more detail, the cap plate 226, the stud bolt 218, and the second spring fixing plate 220 are not pushed because the pressing plate 128 does not apply pressure to the cap bolt 226 during the first stage operation. In the second and third stages, the cap plate 226, the stud bolt 218, and the second spring fixing plate 220 are pushed out as the pressing plate 128 is pushed out of the second cap 118. do.

Accordingly, the frictional force and the separation between the plurality of disks 202 and the pressure plate 204 arranged between the first spring fixing plate 210 and the second spring fixing plate 220 at every first, second, and third stage operations as described above. The distance is finely adjusted.

For example, the adhesion force between the disk 202 and the pressure plate 204 in the first stage operation is based on the overload load setting value of about 1 ton, and the overload load setting value of about 2 tons in the second stage operation. In operation, however, the overload load setting value is about 3 tons, and the overload load setting value may be set differently according to the specification of each component and the capacity of the winch.

After setting the overload load as described above, when the motor 106 of the winch is operated, the shaft 108 connected to the axis of the motor 106 rotates according to the driving of the motor 106, and the shaft 108 A shaft fixing drum 216 having a pressure plate 128 and a vertically bent rotary foot 214 is coupled to the spline 106 of the rotation.

In addition, since the four vertical bending rotary feet 214 of the shaft fixing drum 216 is inserted into the fitting groove 228 formed on the inner circumferential surface of each of the pressure plate 204, the shaft fixing drum 216 As it rotates, the pressure plate 204 also rotates together.

At the same time, the disk 202 in close contact with the pressure plate 204 also rotates.

In this case, since the power transmission piece 230 formed on the outer circumferential surface of the disk 202 is inserted into the power transmission groove 304 formed on the inner circumferential surface of the circular hollow space 302 of the clutch drum 306, the disk ( As the 202 rotates, the clutch drum 306 also rotates.

Subsequently, as the clutch drum 306 rotates, the power transmission rotating plate 308 integrally formed on the front surface of the clutch drum 306 and the chain gear 310 integrally mounted on the front surface of the power transmission rotating plate 308. ) Will rotate.

Accordingly, the rotational force of the chain gear 310 is transmitted to the power transmission gear in the gearbox 14 connected by the chain, and the drive gear in the gearbox 14 interlocked with the power transmission gear rotates. Since the lifting or lowering operation of the rack bar 12 engaged with the driving gear is made, the rack bar 12 is raised or lowered together with the water gate 18 coupled to the bottom of the rack bar 12 based on the lifting or lowering operation. Thus the opening and closing operation of the gate is made.

During the normal lock-in operation of the floodgate, if an obstacle such as dirt is caught in the lower part of the floodgate, an overload load is applied to the winch, and the overload load is set as the critical load (for example, 1 in the first stage operation). 2 tons in the two-stage operation and 3 tons in the three-stage operation), the slip between the disk 202 and the pressure plate 204 is generated.

Thus, when the overload load of the hoisting device set as described above is applied to the hoist during normal hydrological lock operation, it is coupled to the shaft 108 according to the driving of the motor 106 and the spline 106 of the shaft 108. An axial fixing drum 216 having a pressing plate 128 and four vertically bending rotary feet 214, a first spring fixing plate 210 coupled to the axial fixing drum 216 by bolts, Only the second spring fixing plate 220 coupled to the first spring fixing plate 210 by the stud bolt 218 and the cap bolt 226 is rotated.

At the same time, the plurality of disks 202 and the pressure plates 204 arranged between the first and second spring fixing plates 210 and 220 do not overcome the overload load set above the critical load, but slip together. Since the first and second spring fixing plates 210 and 220 are also slipped, the pressure plate 204 and the disk 202 lose rotational transmission force and thus do not transmit rotational force to the clutch drum 306 of the power transmission means 300. I can't.

Therefore, the power transmission rotating plate 308 and the chain gear 310 of the power transmission means 300 is not rotated so that the rotational force is not transmitted to the drive gear in the gearbox 14, the rack bar to raise and lower the water gate eventually As the lifting or lowering operation of (12) is stopped and the overload load is prevented from being transferred to the winch, it is possible to prevent cracks in the gate and the concrete structure.

1 is a schematic diagram illustrating problems in construction and operation of a conventional winch machine;

Figure 2 is a perspective view showing the appearance of the winch according to the present invention.

Figure 3 is an exploded perspective view showing the overload load setting means and overload blocking means and power transmission means provided in the winch according to the present invention in sequence.

Figure 4 and Figure 5 is a perspective view of the assembled state of the configuration of the overload load setting means and the overload blocking means and power transmission means provided in the winch according to the present invention.

Figure 6 is a perspective view showing a state in which the power transmission means separated in the state of assembling the configuration of the overload load setting means and the overload blocking means and power transmission means provided in the winch according to the present invention.

Figure 7 is a partial cross-sectional perspective view for explaining the internal structure in the state of assembling the configuration of the overload load setting means and the overload blocking means provided in the winch according to the present invention.

8 is a cross-sectional view illustrating a one-stage operation operation state of the hydrological operation winch of the present invention.

9 is a cross-sectional view for explaining a two-stage operation operation state of the hydrostatic operation winch of the present invention.

10 is a cross-sectional view illustrating a three-stage operation operation state of the hydrological operation winch of the present invention.

<Description of the symbols for the main parts of the drawings>

10: winch 12: rack bar

14 gearbox 16 motor

18: sluice 20: drive gear

100: overload load setting means 106: spline

108: shaft 110: bearing inner hole

112: first cap 114: bearing inner hole

116: first inclined plane 118: second cap

120: second sloped surface 122: coupling end

124: lever linkage 126: thrust bearing

128: pressure plate 130: spline inner diameter hole

200: overload blocking means 202: disk

204: pressure plate 206: through hole

208: pocket support hole 210: first spring fixing plate

212: engagement hole 214: vertical bending type rotary foot

216: shaft fixing drum 218: stud bolt

220: second spring fixing plate 222: spring support pocket

224: compression spring 226: cap bolt

228: fitting groove 230: power transmission

300: power transmission means 302: circular empty space

304: power transmission groove 306: clutch drum

308: power transmission rotating plate 310: chain gear

400: 3-step lever

Claims (6)

In the hydrologic operation hoist including a rack bar connected to a water gate for opening and closing a waterway of a concrete structure, a gear box including a drive gear for lifting and lowering the rack bar, and a motor for transmitting rotational force to the gear box, An overload load setting means (100) connected to the shaft of the motor (16); When the overload setting load value of the overload setting means 100 is reached, the disk 202 and the pressure plate 204 are spaced apart to induce a slip between the disk 202 and the pressure plate 204, and operates normally. Overload interruption means (200) for rotating the disk (202) and the pressure plate (204); When the slip between the disk 202 and the pressure plate 204 is reached when the overload setting load value is reached, the rotational force is not transmitted to the drive gear in the gearbox 14, and the overload blocking means 200 Hydropower operation to block the overload, characterized in that it comprises a; power transmission means for receiving the rotational force from the disk 202 of the drive) to transmit the rotational force for opening and closing the gate of the drive gear in the gearbox 14; windlass. The method according to claim 1, The overload load setting means (100), the rear end is connected to the shaft of the motor (16), the front end of the shaft 108 is formed with a spline (106); A first cap 112 having a bearing inner hole 110 into which a rear end of the shaft 108 is inserted; The second cap is coupled to the first cap 112 and the bolt, the bearing inner hole 114 is inserted into the rear end of the shaft 108, the second cap formed on the front surface of the first inclined mating surface 116 118; A second inclined mating surface 120 that can engage with the first inclined mating surface 116 of the second cap 118 is formed on the rear end surface, and the coupling end 122 coupled to the three-stage adjustment lever 400 on the outer circumferential surface. Lever linkage body 124 is formed integrally with; A thrust bearing 126 inserted into a rear end of the shaft 108 and closely attached to a front end of the lever interlock 124; Hydrostatic protection block for overload, characterized in that consisting of; disk plate pressing plate 128 is inserted into the rear end of the spline 106 section of the shaft 108 is placed in close contact with the front end of the thrust bearing 126 Action hoist. The method according to claim 1 or 2, The overload blocking means 200 includes a through hole 206 through which the shaft 108 is inserted, and four pocket support holes 208 radially arranged around the through hole 206 and formed therethrough. A spring fixing plate 210; The fitting hole 212 is formed through the fitting of the front end of the spline 106 of the shaft 108, the outer peripheral portion of the four vertical bent-type rotary foot that is assembled in close contact between the pocket support hole 208 ( 214 and the shaft fixing drum 216 integrally formed at equal intervals; A second spring fixing plate 220 having four stud bolts 218 integrally formed at a rear surface thereof so as to be inserted into the pocket support hole 208 of the first spring fixing plate 210; A plurality of ring-type pressure plates 204 disposed between the first and second spring fixing plates 210 and 220 to receive rotational force from the shaft fixing drum 216; A plurality of ring type disks 202 disposed between the pressure plates 204 to transmit rotational force to the power transmission means 300; A spring support pocket 222 inserted and seated at a rear side of each pocket support hole 208 of the first spring fixing plate 210; A compression spring 224 inserted into the stud bolt 218 of the second spring fixing plate 220 protruding through the spring support pocket 222; The hydrostatic action winker to block the overload, characterized in that consisting of ;; the cap spring 226 is fastened to the end of the stud bolt 218 in which the compression spring 224 is inserted. The method according to claim 3, The inner circumferential surface of the ring-type pressure plate 204 is fitted with a fitting groove 228 into which the vertically curved rotary foot 214 of the shaft fixing drum 216 is fitted to receive the rotational force from the shaft fixing drum 216. Hydrostatic action hoist to cut off the overload, characterized in that formed at intervals. The method according to claim 3, Hydrostatic action winch blocking the overload, characterized in that the power transmission piece 230 protrudes at equal intervals on the outer circumferential surface of the plurality of ring-type disk 202 to transmit the rotational force to the power transmission means (300). The method according to claim 1 or 2, The power transmission means 300 is provided with a circular hollow space 302 in which the disc 202 and the pressure plate 204 are embedded in the rear surface, the inner peripheral surface of the circular hollow space 302 of the disc 202 A power transmission groove 304 in the form of a recess in which the power transmission piece 230 is inserted is formed, and a clutch drum 306 in which a front end of the shaft 108 is coupled to a bearing at a central position of the circular hollow space 302. and; A power transmission rotating plate 308 bolted to the front of the clutch drum 306; A chain gear 310 formed integrally with the front surface of the power transmission rotating plate 308 and connected by a transmission gear and a chain interlocked with a drive gear in the gearbox 14; Munjeong Hoist.

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