JP3220292U - Pile driver heat dissipation structure - Google Patents

Abstract

Provided is a heat dissipating structure for a pile driving machine which uses a pump device in an operation process to convey lubricating oil to a heat dissipating pipe to quickly dissipate heat. A heat dissipating structure of a pile driving machine includes a rotating base 1, a pivot base 2, a pile driving gear tank 3, and a heat radiating pipe 4. Pivoting holes 11 are formed on both corresponding sides of the rotary base 1. A pivot member 12 is located in each pivot hole 11. The pivot base 2 has pivot portions provided at corresponding positions of the pivot holes 11. When the pivot member 12 is inserted into the pivot hole 11 and pivoted to the pivot portion, the pivot base 2 rotates. The base 1 and the pivot base 2 are pivoted. The pivot base 2 has a pivot area. The pile driver gear tank 3 is formed in the pivot region, and the pivot base 2 and the pile driver gear tank 3 are pivoted. [Selection] Figure 1

Description

  The present invention relates to a heat dissipating structure of a pile driving machine, and more particularly, to a heat dissipating structure of a pile driving machine that uses a pump device in an operation process to quickly convey heat by conveying lubricating oil to a heat radiating pipe. It is.

  Conventionally, heavy machinery used in civil engineering has different types of styles depending on differences in construction work. A heavy machine that applies an impact and drives a pile into the formation is called a pile driver. The pile driver is composed of a weight, a kite and other attached equipment. The weight is attached between two parallel standing guide rods in front of the heel and is suspended from a hook. The kite has a structure in which a metal structure is stretched over, and a hoisting machine is attached to the rear part, the pile and weight are lifted by the hoisting machine, and a guide is provided in front of the kite to control the pile driving direction. A pile is accurately driven into the formation in the specified orientation. Since the weight is made of metal, it has a constant weight. After the hook is removed, the weight falls freely along the guide for pile driving. The steam hammer is composed of a hammer head and a hammer base. The hammer is divided into a drop hammer, a steam hammer, a diesel hammer, a hydraulic hammer, etc. according to the power source of the movement. The hydraulic pile driver uses hydraulic pressure as power, adjusts the hydraulic pressure according to the soil quality of the formation, and performs pile driving with an appropriate impact force. The hydraulic pile driver can accurately control the amount of pile driving and perform pile driving work according to the difference in the stratum. The hydraulic pile driver is low noise and can prevent vibration and noise generation, so it is particularly suitable for construction in cities with high population density. The hydraulic pile driver saves energy and emits carbon dioxide. It is a pile driver that is currently widely used in the construction industry due to the significant reduction in quantity.

  In the prior art, a synthetic oil having a lubrication function is mainly used for the liquid used in the pile driving machine, and the synthetic oil can adjust the heat resistance performance and the lubrication performance according to the use needs. Since it is difficult to discharge the heat energy generated in the construction process, the temperature of the synthetic oil gradually rises, the synthetic oil changes in quality, the lubricating function is lost, the equipment is worn, and the heat-resistant synthetic When using oil, the lubrication performance is high when operating at high temperatures, but the lubrication performance is low when operating at low temperatures, especially the degree of wear of the parts during startup, and the precision parts in the parts are May expand or deform. In particular, the bearing in the part is an important part in reducing the loss of kinetic energy when the kinetic energy of the part is conducted. The bearing structure is precise, and it is a big problem that its function is lost due to easy expansion and deformation in an overheated environment, and improvement has been demanded.

  Accordingly, a main problem of the present invention is to provide a heat dissipating structure for a pile driving machine that quickly dissipates heat in the operation process.

Therefore, as a result of intensive studies to solve the above-described problems of the present invention, the present inventor, as a result of conveying the lubricating oil to the heat radiating pipe using the pump device in the operation process of the pile driver, Focusing on being able to solve the problem, we came up with the present invention based on this knowledge.
Thus, the gist of the present invention is as described in the following (1) to (10).
(1) A heat dissipating structure of a pile driver comprising a rotating base, a pivot base, a pile driver gear tank and a heat radiating pipe,
Pivoting holes are formed on both sides corresponding to the rotation base, and pivoting members are located in the pivoting holes, respectively.
The pivot base has pivot portions provided at corresponding positions of the pivot holes, and when the pivot member is inserted into the pivot hole and pivoted to the pivot portion, The pivot base and the pivot base are pivoted, the pivot base having a pivot area;
The pile driver gear tank is formed in the pivot attachment region, the pivot base and the pile driver gear tank are pivotally attached, and the pile driver gear tank has an accommodation space and a vibration device. The vibration device is provided with at least one transmission shaft,
The pile driver gear tank has a drainage hole and an inflow hole, the inflow hole communicates with the accommodation space, and a pump device is fixed to one end of the accommodation space. An inflow port, an outflow port, a storage tank, a rotating shaft, a perforation, a drive member, and at least one flow guide member, wherein the inflow port communicates with the storage space and the storage tank; The rotary shaft communicates with the flow hole and the storage tank, the rotary shaft is inserted into the perforation and rotatably connected, and the lower end of the rotary shaft is provided in the storage tank and pivoted to the flow guide member. The driving member is provided at the upper end of the rotating shaft, and a corresponding transmission member is provided at one end of the transmission shaft. When the transmission shaft turns, the rotating shaft and each of the current guides are provided. The member is swung so that the liquid can pass from the inside of the accommodation space through the inlet. After being introduced into the containing recess Te, it is discharged from the outlet to the drainage hole,
The heat radiating pipe is made of a heat conducting material and has a heat radiating hole
The heat radiating hole is inserted into the heat radiating pipe, the heat radiating pipe is formed into a hollow tubular shape, the heat radiating hole has an inflow end and an outflow end, and the inflow end communicates with the exhaust hole. The outflow end communicates with the inflow hole, and the liquid discharged from the exhaust hole is introduced into the heat radiating hole through the inflow end, radiated by the heat radiating pipe and cooled, and then the outflow A heat dissipating structure for a pile driving machine, wherein the heat dissipating structure is introduced into the accommodation space from the end through the inflow hole.
(2) The vibration device has two gears,
The two gears mesh with each other;
The gears are pivotally attached to the transmission shafts,
One end of each gear is provided with a vibration member, and when each transmission shaft turns, each vibration member also turns to generate vibration. Pile driver heat dissipation structure.
(3) Each of the transmission shafts is pivotally attached to a plurality of positioning members,
Each of the positioning members is provided at a rear end of each of the gears and a front end of each of the vibration members, and clamps and fixes the gears and the vibration members at predetermined positions. The heat dissipating structure of the pile driver described in 1.
(4) A bearing is provided at each of the front end and the rear end of each transmission shaft,
Each said bearing is pivoted and fixed in the said accommodation space, The heat dissipation structure of the pile driving machine as described in said (2) characterized by the above-mentioned.
(5) A through hole is formed at one end of the pile driver gear tank,
The transmission shaft is inserted into the through hole, and the transmission shaft and the external power of the pile driver gear tank are interlocked to each other, whereby each of the transmission shafts is turned (1). The heat dissipating structure of the pile driver described in 1.
(6) The pivot base has a plurality of heat dissipating pieces,
Each of the heat radiating pieces is combined with the heat radiating pipe and is made of a heat conductive material, and heat energy is transmitted to the heat radiating pieces by the heat radiating pipe to obtain a high heat radiating effect. Heat dissipating structure of the pile driver.
(7) Thermal grease is applied between the heat radiating pipe and each of the heat radiating pieces,
The pile driver according to (6), wherein the thermal grease is made of any one of silicone, polyurethane, acrylic polymer, hot melt paste, and metal powder mixed in combination thereof. Heat dissipation structure.
(8) Since the pile driver gear tank and the pivot base are made of a metal material, the liquid in the accommodation space is radiated by the pile driver gear tank and the pivot base. The heat dissipating structure of the pile driving machine according to (1).
(9) An assembly surface is provided at the lower end of the pile driver gear tank,
The heat dissipating structure for a pile driving machine according to (1), wherein the assembly surface has a plurality of assembly holes.
(10) The assembly surface has a pile driving device,
The upper end of the pile driving device is pivotally attached to the assembly surface, and when a plurality of screwing members are inserted into the assembly holes, the upper end of the pile driving device is screwed to the upper end of the pile driving device. The heat dissipating structure of the pile driving machine according to (9).

  The present invention is configured as described above, and the liquid in the pile housing gear lateral housing space is continuously circulated to dissipate heat, and the heat energy can be effectively discharged, and the heat radiation can be performed quickly. Can do.

FIG. 1 is a perspective view showing a heat dissipation structure of a pile driving machine according to an embodiment of the present invention. FIG. 2 is an exploded perspective view showing a heat dissipation structure of a pile driving machine according to an embodiment of the present invention. FIG. 3 is a block diagram showing a conduction state of the heat dissipating structure of the pile driving machine according to the embodiment of the present invention. FIG. 4 is a bottom view showing a heat dissipation structure of a pile driving machine according to an embodiment of the present invention. FIG. 5 is an explanatory view showing a heat dissipation structure of a pile driving machine according to an embodiment of the present invention.

  Please refer to FIG. As shown in FIGS. 1-5, the heat dissipation structure of the pile driving machine which concerns on one Embodiment of this invention is comprised from the rotation base 1, the pivot attachment base 2, the pile driver gear tank 3, and the heat radiating pipe 4. Become.

  Pivoting holes 11 are formed on both sides of the rotary base 1 corresponding to each other. A pivot member 12 is located in each pivot hole 11 of the rotary base 1.

  The pivot base 2 has pivot portions 21 provided at corresponding positions of the pivot holes 11 of the rotary base 1. When the pivot attachment member 12 of the rotation base 1 is inserted into the pivot attachment hole 11 of the rotation base 1 and is pivotally attached to the pivot attachment portion 21 of the pivot attachment base 2, the rotation base 1 and the pivot attachment base 2 are connected. It is pivotally attached. The pivot base 2 has a pivot area 22. The pile driver gear tank 3 is formed in the pivot region 22 of the pivot base 2, and the pivot base 2 and the pile driver gear tank 3 are pivoted. The pile driver gear tank 3 includes a housing space 31 and a vibration device 32. The vibration device 32 of the pile driver gear tank 3 is provided with at least one transmission shaft 321. The pile driver gear tank 3 has a drain hole 33 and an inlet hole 34. The inflow hole 34 of the pile driver gear tank 3 communicates with the accommodation space 31 of the pile driver gear tank 3. A pump device 35 is fixed to one end of the accommodation space 31 of the pile driver gear tank 3. The pump device 35 of the pile driver gear tank 3 includes an inlet 351, an outlet 352, a storage tank 353, a rotating shaft 354, a perforation 355, a drive member 356, and at least one flow guide member 357. The inlet 351 of the pump device 35 of the pile driver gear tank 3 communicates with the storage space 31 of the pile driver gear tank 3 and the storage tank 353 of the pump device 35 of the pile driver gear tank 3. The outlet 352 of the pump device 35 of the pile driver gear tank 3 communicates with the drain hole 33 of the pile driver gear tank 3 and the storage tank 353 of the pump device 35 of the pile driver gear tank 3. The rotary shaft 354 of the pump device 35 of the pile driver gear tank 3 is inserted into the perforation 355 of the pump device 35 of the pile driver gear tank 3 and is rotatably connected. The lower end of the rotary shaft 354 of the pump device 35 of the pile driver gear tank 3 is provided in the storage tank 353 of the pump device 35 of the pile driver gear tank 3 and is guided to the pump device 35 of the pile driver gear tank 3. It is pivotally attached to the flow member 357. A drive member 356 of the pump device 35 of the pile driver gear tub 3 is provided at the upper end of the rotary shaft 354 of the pump device 35 of the pile driver gear tub 3, and the transmission of the vibration device 32 of the pile driver gear tub 3 is provided. A corresponding transmission member 3211 is provided at one end of the shaft 321, and when the transmission shaft 321 of the vibration device 32 of the pile driving gear 3 is turned, the rotary shaft 354 and the pile of the pump device 35 of the pile driving gear 3 The flow guide member 357 of the pump device 35 of the hammering gear tank 3 is swung, and the liquid is piled from the accommodation space 31 of the pile driver gear tank 3 through the inlet 351 of the pump device 35 of the pile driver gear tank 3. After being introduced into the storage tank 353 of the pump device 35 of the hammering gear tank 3, it is discharged from the outlet 352 of the pump device 35 of the pile driver gear tank 3 to the exhaust hole 33 of the pile driver gear tank 3. The heat radiating tube 4 is made of a heat conducting material. The heat radiating tube 4 has a heat radiating hole 41. The heat radiating tube 4 is inserted into the heat radiating hole 41 of the heat radiating tube 4, and the heat radiating tube 4 is formed into a hollow tubular shape. The heat radiating hole 41 of the heat radiating tube 4 has an inflow end 42 and an outflow end 43. The inflow end 42 of the heat radiating pipe 4 communicates with the exhaust hole 33 of the pile driving gear tank 3. The outflow end 43 of the heat radiating pipe 4 communicates with the inflow hole 34 of the pile driver gear tank 3, and the liquid discharged from the exhaust hole 33 of the pile driving machine gear tank 3 passes through the inflow end 42 of the heat radiating pipe 4. After being introduced into the heat radiating hole 41 of the heat radiating pipe 4 and radiating and cooling by the heat radiating pipe 4, the pile driver gear tank 3 of the pile driver gear tub 3 is passed from the outflow end 43 of the heat radiating pipe 4 through the inflow hole 34 of the pile driver gear tub 3. It is introduced into the accommodation space 31, the liquid in the accommodation space 31 of the pile driver gear tank 3 is circulated and continues to dissipate heat, and the heat energy can be effectively discharged.

  The vibration device 32 of the pile driver gear tank 3 described above has two gears 322. The two gears 322 are meshed with each other. Each gear 322 of the vibration device 32 of the pile driver gear tub 3 is pivotally attached to each transmission shaft 321 of the vibration device 32 of the pile driver gear tub 3 and each of the vibration devices 32 of the pile driver gear tub 3. When a vibration member 323 is provided at one end of the gear 322 and each transmission shaft 321 of the vibration device 32 of the pile driving gear tub 3 is turned, each vibration member 323 of the vibration device 32 of the pile driving gear tub 3 is also accompanied. To generate vibration.

  A plurality of positioning members 3212 are pivotally attached to the transmission shafts 321 of the vibration device 32 of the pile driver gear tank 3. Each positioning member 3212 of each transmission shaft 321 of the vibration device 32 includes a rear end of each gear 322 of the vibration device 32 of the pile driver gear tank 3 and a front end of each vibration member 323 of the vibration device 32 of the pile driver gear tank 3. The positioning members 3212 of the transmission shafts 321 of the vibration device 32 respectively set the gears 322 of the vibration device 32 of the pile driver gear tank 3 and the vibration members 323 of the vibration device 32 of the pile driver gear tank 3 to be predetermined. Hold it in place and fix it.

  Bearings 324 are respectively provided at the front end and the rear end of each transmission shaft 321 of the vibration device 32 of the pile driver gear tank 3. Each bearing 324 of the vibration device 32 of the pile driver gear tank 3 is pivotally fixed at a predetermined position in the accommodation space 31 of the pile driver gear tank 3.

  Lubricating oil after the heat radiating pipe 4 has radiated heat is introduced from the outflow end 43 of the heat radiating pipe 4 into the accommodation space 31 of the pile driving machine gear tank 3 through the inflow hole 34 of the pile driving machine gear tank 3. 324 is immersed in lubricating oil to maintain a constant operating temperature, and the operating environment of each bearing 324 is maintained within a predetermined temperature, so that each bearing 324 is prevented from expanding or deforming due to overheating. Thus, the mechanism 324 can operate normally, and the service life of the vibration device 32 can be extended.

  A through hole 36 is formed at one end of the pile driver gear tank 3 described above. The transmission shaft 321 of the vibration device 32 of the pile driver gear tank 3 is inserted into the through hole 36 of the pile driver gear tank 3, and the transmission shaft 321 of the vibration device 32 of the pile driver gear tank 3 and the pile driver. The transmission power 321 of the vibration device 32 of the pile driver gear tank 3 is swung in conjunction with the external power of the gear tank 3.

  Since the pile driver gear tank 3 and the pivot base 2 described above are made of a metal material, the liquid in the accommodation space 31 of the pile driver gear tank 3 is radiated by the pile driver gear tank 3 and the pivot base 2. .

  An assembly surface 37 is provided at the lower end of the pile driver gear tank 3 described above. The assembly surface 37 of the pile driver gear tank 3 has a plurality of assembly holes 371.

  The assembly surface 37 of the pile driving machine gear tank 3 has a pile driving device 5. The upper end of the pile driving device 5 is pivotally attached to the assembly surface 37 of the pile driver gear tank 3, and a plurality of screwing members 6 are inserted into the respective assembly holes 371 of the assembly surface 37 of the pile driver gear tank 3. Then, it is screwed to the upper end of the pile driving device 5.

  The pivot base 2 described above has a plurality of heat radiation pieces 23. Each heat radiating piece 23 of the pivot base 2 is combined with the heat radiating pipe 4. Each heat radiating piece 23 of the pivot base 2 may be made of a heat conducting material, and heat energy may be transmitted to each heat radiating piece 23 of the pivot base 2 by the heat radiating pipe 4 to obtain a high heat radiation effect.

  Here, thermal grease may be applied between the heat radiating tube 4 and each heat radiating piece 23 of the pivot base 2. The thermal grease is made of any one of silicone, polyurethane, acrylic polymer, hot melt paste, and metal powder mixed in combination thereof, and the heat radiating tube 4 and each heat radiating piece 23 of the pivot base 2 are connected to each other. The heat conduction effect of the contacted area may be enhanced.

  The heat dissipating structure of the pile driving machine according to the present embodiment includes at least a rotating base 1, a pivot base 2, a pile driving machine gear tank 3, and a heat radiating pipe 4.

  Pivoting holes 11 are formed on both sides of the rotating base 1 corresponding to each other. A pivot member 12 is provided in each pivot hole 11 of the rotary base 1.

  The pivot base 2 has pivot portions 21 provided at corresponding positions of the pivot holes 11 of the rotary base 1. The pivot attachment member 12 of the rotation base 1 is inserted in the pivot attachment hole 11 of the rotation base 1 and is pivotally attached to the pivot attachment portion 21 of the pivot attachment base 2 so that the rotation base 1 and the pivot attachment base 2 are pivoted. Worn. The pivot base 2 has a pivot area 22. The pile driver gear tank 3 is formed in the pivot region 22 of the pivot base 2, and the pivot base 2 and the pile driver gear tank 3 are pivoted. The pile driver gear tank 3 includes a housing space 31 and a vibration device 32. The vibration device 32 of the pile driver gear tank 3 is provided with a transmission shaft 321. The pile driver gear tank 3 has a drain hole 33 and an inlet hole 34. The inflow hole 34 of the pile driver gear tank 3 communicates with the accommodation space 31 of the pile driver gear tank 3. A pump device 35 is fixed to one end of the accommodation space 31 of the pile driver gear tank 3. The pump device 35 of the pile driver gear tank 3 includes an inlet 351, an outlet 352, a storage tank 353, a rotating shaft 354, a perforation 355, a drive member 356, and a flow guide member 357. The inlet 351 of the pump device 35 of the pile driver gear tank 3 communicates with the storage space 31 of the pile driver gear tank 3 and the storage tank 353 of the pump device 35 of the pile driver gear tank 3. The outlet 352 of the pump device 35 of the pile driver gear tank 3 communicates with the drain hole 33 of the pile driver gear tank 3 and the storage tank 353 of the pump device 35 of the pile driver gear tank 3. The rotary shaft 354 of the pump device 35 of the pile driver gear tank 3 is inserted into the perforation 355 of the pump device 35 of the pile driver gear tank 3 and is rotatably connected. The lower end of the rotary shaft 354 of the pump device 35 of the pile driver gear tank 3 is provided in the storage tank 353 of the pump device 35 of the pile driver gear tank 3 and is guided to the pump device 35 of the pile driver gear tank 3. It is pivotally attached to the flow member 357. The upper end of the rotary shaft 354 of the pump device 35 of the pile driver gear tank 3 is provided on the drive member 356 of the pump device 35 of the pile driver gear tank 3 and the transmission shaft of the vibration device 32 of the pile driver gear tank 3. At one end of 321, a corresponding transmission member 3211 is provided, and when the transmission shaft 321 of the vibration device 32 of the pile driver gear tub 3 is turned, the rotation shaft 354 of the pump device 35 of the pile driver gear tub 3 and The flow guide member 357 of the pump device 35 of the pile driver gear tank 3 is swung, and the liquid passes through the inlet 351 of the pump device 35 of the pile driver gear tank 3 from the accommodation space 31 of the pile driver gear tank 3. After being introduced into the storage tank 353 of the pump device 35 of the pile driver gear tank 3, it is discharged from the outlet 352 of the pump apparatus 35 of the pile driver gear tank 3 to the discharge hole 33 of the pile driver gear tank 3. . The heat radiating tube 4 is made of a heat conducting material. The heat radiating tube 4 has a heat radiating hole 41. The heat radiating tube 4 is inserted into the heat radiating hole 41 of the heat radiating tube 4, and the heat radiating tube 4 is formed into a hollow tubular shape. The heat radiating hole 41 of the heat radiating tube 4 has an inflow end 42 and an outflow end 43. The inflow end 42 of the heat radiating pipe 4 communicates with the exhaust hole 33 of the pile driving gear tank 3. The outflow end 43 of the heat radiating pipe 4 communicates with the inflow hole 34 of the pile driver gear tank 3, and the liquid discharged from the exhaust hole 33 of the pile driving machine gear tank 3 passes through the inflow end 42 of the heat radiating pipe 4. After being introduced into the heat radiating hole 41 of the heat radiating pipe 4 and being radiated and cooled by the heat radiating pipe 4, the pile driver gear tank 3 from the outflow end 43 of the heat radiating pipe 4 through the inflow hole 34 of the pile driver gear tank 3. The liquid in the storage space 31 of the pile driver gear tub 3 is circulated and continues to dissipate heat, thereby effectively discharging the heat energy. The heat dissipating structure of the pile driving machine according to the present invention can use the pump device 35 during operation to convey the lubricating oil to the heat dissipating pipe 4 and quickly dissipate heat.

DESCRIPTION OF SYMBOLS 1 Rotation base 2 Pivoting base 3 Pile driver gear tank 4 Radiating pipe 5 Pile driving device 6 Screwing member 11 Pivoting hole 12 Pivoting member 21 Pivoting part 22 Pivoting region 23 Radiation piece 31 Accommodating space 32 Vibration device 33 Exhaust flow hole 34 Inflow hole 35 Pump device 36 Through hole 37 Assembly surface 41 Radiation hole 42 Inflow end 43 Outflow end 321 Transmission shaft 322 Gear 323 Vibration member 324 Bearing 351 Inlet 352 Outlet 353 Storage tank 354 Rotating shaft 355 Drilling 356 Drive Member 357 Flow guide member 371 Assembly hole 3211 Transmission member 3212 Positioning member

Claims (10)

A heat dissipating structure of a pile driver comprising a rotating base, a pivot base, a pile driver gear tank and a heat radiating pipe,
Pivoting holes are formed on both sides corresponding to the rotation base, and pivoting members are located in the pivoting holes, respectively.
The pivot base has pivot portions provided at corresponding positions of the pivot holes, and when the pivot member is inserted into the pivot hole and pivoted to the pivot portion, The pivot base and the pivot base are pivoted, the pivot base having a pivot area;
The pile driver gear tank is formed in the pivot attachment region, the pivot base and the pile driver gear tank are pivotally attached, and the pile driver gear tank has an accommodation space and a vibration device. The vibration device is provided with at least one transmission shaft,
The pile driver gear tank has a drainage hole and an inflow hole, the inflow hole communicates with the accommodation space, and a pump device is fixed to one end of the accommodation space. An inflow port, an outflow port, a storage tank, a rotating shaft, a perforation, a drive member, and at least one flow guide member, wherein the inflow port communicates with the storage space and the storage tank; The rotary shaft communicates with the flow hole and the storage tank, the rotary shaft is inserted into the perforation and rotatably connected, and the lower end of the rotary shaft is provided in the storage tank and pivoted to the flow guide member. The driving member is provided at the upper end of the rotating shaft, and a corresponding transmission member is provided at one end of the transmission shaft. When the transmission shaft turns, the rotating shaft and each of the current guides are provided. The member is swung so that the liquid can pass from the inside of the accommodation space through the inlet. After being introduced into the containing recess Te, it is discharged from the outlet to the drainage hole,
The heat radiating pipe is made of a heat conducting material and has a heat radiating hole
The heat radiating hole is inserted into the heat radiating pipe, the heat radiating pipe is formed into a hollow tubular shape, the heat radiating hole has an inflow end and an outflow end, and the inflow end communicates with the exhaust hole. The outflow end communicates with the inflow hole, and the liquid discharged from the exhaust hole is introduced into the heat radiating hole through the inflow end, radiated by the heat radiating pipe and cooled, and then the outflow A heat dissipating structure for a pile driving machine, wherein the heat dissipating structure is introduced into the accommodation space from the end through the inflow hole. The vibration device has two gears,
The two gears mesh with each other;
The gears are pivotally attached to the transmission shafts,
The pile according to claim 1, wherein a vibration member is provided at one end of each of the gears, and when each of the transmission shafts turns, each of the vibration members also turns to generate vibration. The heat dissipating structure of the hammer. Each of the transmission shafts is pivotally attached to a plurality of positioning members,
3. Each positioning member is provided at a rear end of each gear and a front end of each vibration member, respectively, and clamps and fixes each of the gears and each vibration member at a predetermined position. The heat dissipating structure of the described pile driver. Bearings are respectively provided at the front end and the rear end of each transmission shaft,
The heat dissipating structure for a pile driving machine according to claim 2, wherein each of the bearings is pivotally fixed in the housing space. At one end of the pile driver gear tank, a through hole is formed,
2. The transmission shaft according to claim 1, wherein the transmission shaft is inserted into the through-hole, and the transmission shaft and the external power of the pile driver gear tank are interlocked to each other, so that each of the transmission shafts is turned. The heat dissipating structure of the described pile driver. The pivot base has a plurality of heat dissipating pieces,
2. The heat radiation piece according to claim 1, wherein each heat radiation piece is combined with the heat radiation pipe and is made of a heat conductive material, and heat energy is transmitted to each heat radiation piece by the heat radiation pipe to obtain a high heat radiation effect. Pile driver heat dissipation structure. Thermal grease is applied between the heat radiating pipe and each of the heat radiating pieces,
The pile driver according to claim 6, wherein the thermal grease is made of any one of silicone, polyurethane, acrylic polymer, hot melt paste, and metal powder mixed in combination thereof. Heat dissipation structure.   2. The pile driver gear tank and the pivot base are made of a metal material, so that the liquid in the accommodation space is radiated by the pile driver gear tank and the pivot base. The heat dissipating structure of the described pile driver. At the lower end of the pile driver gear tank, an assembly surface is provided,
The heat dissipating structure of a pile driving machine according to claim 1, wherein the assembly surface has a plurality of assembly holes. The assembly surface has a pile driving device,
The upper end of the pile driving device is pivotally attached to the assembly surface, and when a plurality of screwing members are inserted into the assembly holes, the upper end of the pile driving device is screwed to the upper end of the pile driving device. The heat dissipating structure for a pile driving machine according to claim 9.