CN221170221U - Cooling equipment for oil pipeline of hydraulic winch - Google Patents
Cooling equipment for oil pipeline of hydraulic winch Download PDFInfo
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- CN221170221U CN221170221U CN202322813394.XU CN202322813394U CN221170221U CN 221170221 U CN221170221 U CN 221170221U CN 202322813394 U CN202322813394 U CN 202322813394U CN 221170221 U CN221170221 U CN 221170221U
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- 238000001816 cooling Methods 0.000 title claims abstract description 270
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims abstract description 169
- 239000007788 liquid Substances 0.000 claims description 40
- 230000017525 heat dissipation Effects 0.000 claims description 36
- 230000000149 penetrating effect Effects 0.000 claims description 12
- 238000002347 injection Methods 0.000 claims description 10
- 239000007924 injection Substances 0.000 claims description 10
- 230000005855 radiation Effects 0.000 claims description 9
- 238000000034 method Methods 0.000 claims description 2
- 239000000498 cooling water Substances 0.000 abstract description 32
- 239000003921 oil Substances 0.000 description 141
- RYGMFSIKBFXOCR-UHFFFAOYSA-N Copper Chemical compound [Cu] RYGMFSIKBFXOCR-UHFFFAOYSA-N 0.000 description 6
- 229910052802 copper Inorganic materials 0.000 description 6
- 239000010949 copper Substances 0.000 description 6
- 230000000694 effects Effects 0.000 description 5
- 238000010521 absorption reaction Methods 0.000 description 3
- 239000010720 hydraulic oil Substances 0.000 description 3
- 241000883990 Flabellum Species 0.000 description 2
- 230000005540 biological transmission Effects 0.000 description 2
- 238000002360 preparation method Methods 0.000 description 2
- 238000005086 pumping Methods 0.000 description 2
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000008878 coupling Effects 0.000 description 1
- 238000010168 coupling process Methods 0.000 description 1
- 238000005859 coupling reaction Methods 0.000 description 1
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Abstract
The utility model relates to the field of oil pipeline cooling equipment, in particular to hydraulic winch oil pipeline cooling equipment. Technical problems: when the oil body in the oil pipeline is conveyed for a long time, the oil pipeline is difficult to efficiently and rapidly dissipate heat, and the service life of the oil pipeline is influenced. The technical scheme is as follows: the cooling equipment for the oil pipeline of the hydraulic winch comprises a hydraulic table assembly. According to the utility model, cooling water is injected into the third cooling component by starting the circulating water cooling component, the cooling water also enters the second cooling component through the third cooling component, the cooling water flows back into the circulating water cooling component through the second cooling component, the cooling water enters the first cooling component through the second cooling component, and the first cooling component and the third cooling component both contain oil conveying pipelines, so that the circulating water cooling of the oil conveying pipelines can be realized, and the problems that the oil conveying pipelines are difficult to efficiently and rapidly dissipate heat and the service life of the oil conveying pipelines is influenced when the oil in the oil conveying pipelines is conveyed for a long time are solved.
Description
Technical Field
The utility model belongs to the field of oil pipeline cooling equipment, and particularly relates to oil pipeline cooling equipment of a hydraulic winch.
Background
The hydraulic winch oil pipeline cooling equipment refers to equipment for cooling an oil pipeline in a hydraulic transmission system, in the hydraulic transmission system, oil circulation can generate certain heat due to internal flow resistance, outflow leakage and other reasons, and the hydraulic winch always continuously uses hydraulic oil in the working process, so that the pipeline for conveying an oil body needs to be cooled timely to ensure normal operation of the system, and the cooling equipment of the oil pipeline is usually cooled by water, wind and oil, but when the oil body in the oil pipeline is conveyed for a long time, the oil pipeline is difficult to efficiently and quickly dissipate heat, and the service life of the oil pipeline is influenced.
Disclosure of utility model
In order to solve the problem that the oil pipeline is difficult to efficiently and rapidly dissipate heat and the service life of the oil pipeline is influenced when the oil body in the oil pipeline is conveyed for a long time.
The technical scheme of the utility model is as follows: the hydraulic winch oil pipeline cooling equipment comprises a hydraulic table component; the cooling system further comprises a first cooling assembly, a second cooling assembly, a circulating water cooling assembly, a third cooling assembly and a heat dissipation assembly; the upper end of the hydraulic table component is provided with a first cooling component and a heat dissipation component which are used for cooling the pipeline; the outer wall of the hydraulic table assembly is provided with a second cooling assembly, a circulating water cooling assembly and a third cooling assembly which are used for cooling pipelines.
Preferably, when in use, the circulating water cooling assembly is started to inject cooling water into the third cooling assembly, the cooling water is cooled through the cooling assembly to an oil outlet pipe of the hydraulic table assembly, the cooling water also enters the second cooling assembly through the third cooling assembly, the cooling water flows back into the circulating water cooling assembly through the second cooling assembly, the cooling water enters the first cooling assembly through the second cooling assembly, oil conveying pipelines are all contained in the first cooling assembly and the third cooling assembly, circulating water cooling of the oil conveying pipelines can be realized, and the problems that the oil conveying pipelines are difficult to efficiently and rapidly dissipate heat and the service life of the oil conveying pipelines is influenced when the oil body in the oil conveying pipelines is conveyed for a long time are solved.
Preferably, the hydraulic table assembly comprises an oil tank, a hydraulic pump, a first oil body filter, an electromagnetic reversing valve, a second oil body filter, a first oil outlet pipe, an electromagnetic valve and a second oil outlet pipe; the upper end of the oil tank is fixedly connected with a hydraulic pump; the pipe body on the liquid pumping port of the hydraulic pump penetrates through the upper end of the oil tank and extends to the inside of the oil tank; the upper end of the oil tank is fixedly connected with a first oil body filter, an electromagnetic reversing valve and a second oil body filter; the hydraulic pump is connected with the liquid inlet of the first oil body filter through a pipe body; the liquid outlet port of the hydraulic pump is connected with the liquid inlet port of the electromagnetic directional valve through a pipe body; the liquid outlet port of the electromagnetic reversing valve is connected with the liquid inlet port of the second oil body filter through a pipe body; a first oil outlet pipe is fixedly connected to the liquid outlet port of the second oil body filter; the left end of the oil tank is fixedly connected with an electromagnetic valve; a second oil outlet pipe is fixedly connected to the liquid outlet port of the electromagnetic valve; the other liquid outlet port on the electromagnetic directional valve is fixedly connected with the liquid inlet port of the electromagnetic valve through the pipe body, the hydraulic pump is started to enable the oil body to be discharged from the first oil outlet pipe through the electromagnetic directional valve and the second oil body filter, and the hydraulic pump is started to enable the oil body to be discharged through the electromagnetic directional valve and the electromagnetic valve.
Preferably, the first cooling assembly comprises a first cooling box, a connecting oil pipe, a third oil outlet pipe, a first U-shaped pipe and a second U-shaped pipe; a liquid outlet port of the first oil body filter is fixedly connected with a connecting oil pipe; the upper end of the oil tank is fixedly connected with a first cooling tank; a third oil outlet pipe is fixedly connected to the first cooling box; the third oil outlet pipe and the connecting oil pipe are communicated with each other in the first cooling box through a first U-shaped pipe; the first U-shaped pipe is fixedly connected with a second U-shaped pipe; the first U-shaped pipe and the second U-shaped pipe are U-shaped; the first U-shaped pipe and the second U-shaped pipe are communicated with each other, the hydraulic pump is started to enable the oil body to go out of the liquid through the first oil body filter, the hydraulic oil body is injected into the third oil outlet pipe through the connecting oil pipe and the first U-shaped pipe, the oil body also enters the second U-shaped pipe through the first U-shaped pipe, cooling water is injected into the first cooling box, the first U-shaped pipe and the second U-shaped pipe can be cooled by water, and therefore the cooling effect on the oil body can be improved.
Preferably, the second cooling assembly comprises a second cooling box, a motor, fan blades, a first water pipe and a second water pipe; the front end of the oil tank is fixedly connected with a second cooling tank; a water inlet port of the second cooling box is provided with a first water pipe; a second water pipe is arranged on the water outlet port of the second cooling box; the upper end of the second cooling box is fixedly connected with a third water pipe in a penetrating way; the other end of the third water pipe penetrates through the outer wall of the first cooling box and extends to the inside of the first cooling box; the front end of the second cooling box is fixedly connected with a motor; the output shaft of motor runs through the front end rigid coupling of second cooler bin has the flabellum, opens the motor and makes the flabellum rotate, can accelerate the flow of water, does benefit to the water and fully contacts with the second cooler bin, and the second cooler bin adopts the heat conduction copper preparation, can improve the absorption to the heat of water to improve the radiating effect of this equipment, the water that gets into in the second cooler bin still can pour into in the first cooler bin through the third water pipe, carries out the water-cooling to the pipeline in the first cooler bin.
Preferably, the circulating water cooling assembly comprises a third cooling box, a water pump, a fourth water pipe and a water injection pipe; the right end of the oil tank is fixedly connected with a third cooling tank; the right end of the third cooling box is fixedly connected with a water pump; the liquid pumping port of the water pump is connected to the inside of the third cooling box through a pipe body; a fourth water pipe is fixedly connected to the liquid outlet port of the water pump; the upper end of the third cooling box is fixedly connected with a water injection pipe in a penetrating way; the inner wall of the left end of the water injection pipe is fixedly connected with evenly distributed cooling fins, cooling water enters the second cooling box through the first water pipe, when the oil pipeline is required to be cooled by water circulation cooling, the water pump is started to pump the cooling water in the third cooling box into the fourth water pipe, the cooling water can flow into each cooling box along the fourth water pipe, water cooling is carried out on the oil pipeline in the cooling box, and the cooling fins can be used for accelerating cooling.
Preferably, the third cooling assembly comprises a fourth cooling box, a water inlet pipe, a water outlet pipe, a fifth cooling box and a fifth water pipe; the front end of the oil tank is fixedly connected with a fourth cooling tank; the upper end of the fourth cooling box is fixedly connected with a water inlet pipe and a water outlet pipe in a penetrating way; a fifth cooling box is fixedly connected to the outer wall of the first oil outlet pipe; the other end of the water inlet pipe penetrates through the outer wall of the fifth cooling box and extends to the inside of the fifth cooling box; the other end of the water outlet pipe penetrates through the outer wall of the fifth cooling box and extends to the inside of the fifth cooling box; the other end of the fourth water pipe penetrates through the outer wall of the fourth cooling box and extends to the inside of the fourth cooling box; the inner wall and the outer wall of the fourth cooling box are fixedly connected with a fifth water pipe in a penetrating manner, cooling water in the fourth water pipe flows into the fourth cooling box, and can be injected into the fifth cooling box through a water inlet pipe, so that the first oil outlet pipe wrapped by the fifth cooling box is cooled, the cooling water flows into the fourth cooling box through a water outlet pipe, and water in the fourth cooling box flows out through the fifth water pipe.
Preferably, the heat radiation component comprises a bracket, a heat radiation box, a heat radiation cylinder and a return pipe; the left end of the oil tank is fixedly connected with a plurality of brackets; the bracket is fixedly connected with a heat dissipation box; the other end of the fifth water pipe penetrates through the outer wall of the heat dissipation box and extends to the inside of the heat dissipation box; the lower end of the radiating box is fixedly connected with radiating cylinders which are uniformly distributed; the front end of the radiating cylinder is fixedly connected with a return pipe; the other end of the return pipe is mutually communicated with the other end of the first water pipe, water flowing out of the fifth water pipe enters the heat dissipation box, the heat dissipation box is made of heat conducting copper, heat transferred to the heat dissipation box can be transferred to the heat dissipation cylinders, and therefore the heat dissipation speed of the device can be improved, and the heat dissipation capacity of the device is improved.
The utility model has the beneficial effects that:
1. The circulating water cooling assembly is started to inject cooling water into the third cooling assembly, the cooling water cools an oil outlet pipe of the hydraulic table assembly through the heat dissipation assembly, the cooling water also enters the second cooling assembly through the third cooling assembly, the cooling water flows back into the circulating water cooling assembly through the second cooling assembly, the cooling water enters the first cooling assembly through the second cooling assembly, oil conveying pipelines are arranged in the first cooling assembly and the third cooling assembly, circulating water cooling of the oil conveying pipelines can be realized, and the problems that the oil conveying pipelines are difficult to efficiently and rapidly dissipate heat and the service life of the oil conveying pipelines is influenced when oil bodies in the oil conveying pipelines are conveyed for a long time are solved;
2. The hydraulic oil body is injected into the third oil outlet pipe through the connecting oil pipe and the first U-shaped pipe, the oil body also enters the second U-shaped pipe through the first U-shaped pipe, cooling water is injected into the first cooling box, the first U-shaped pipe and the second U-shaped pipe can be cooled by water, the cooling effect on the oil body can be improved, the cooling water enters the second cooling box through the first water pipe, the motor is started to enable the fan blades to rotate, the flow of the water body can be accelerated, the water body is in full contact with the second cooling box, the second cooling box is made of heat conducting copper, the absorption of the heat of the water body can be improved, the heat dissipation effect of the device is improved, the water body entering the second cooling box can also be injected into the first cooling box through the third water pipe, and the pipeline in the first cooling box is cooled by water;
3. The cooling water in the fourth water pipe flows into the fourth cooling box, can pour into in the fifth cooling box through the inlet tube, realize carrying out the water-cooling to the first play oil pipe of fifth cooling box parcel, the cooling water rethread outlet pipe flows into in the fourth cooling box, the water in the fourth cooling box flows out through the fifth water pipe, the water that flows out from the fifth water pipe gets into the heat dissipation box, the heat dissipation box adopts the heat conduction copper preparation, the heat that transmits to the heat dissipation box can be transmitted to a plurality of cooling cylinders on, can improve thermal emission rate, thereby the heat dissipation capacity of device has been improved.
Drawings
FIG. 1 shows a schematic perspective view of a cooling device for an oil pipeline of a hydraulic winch according to the present utility model;
FIG. 2 shows a schematic perspective view of a hydraulic table assembly and a heat dissipating assembly of the hydraulic winch oil line cooling apparatus of the present utility model;
FIG. 3 shows a schematic perspective view of a first cooling assembly of the hydraulic winch oil line cooling apparatus of the present utility model;
FIG. 4 shows a schematic perspective view of a second cooling assembly of the hydraulic winch oil line cooling apparatus of the present utility model;
FIG. 5 shows a schematic perspective sectional structure of a second cooling tank of the hydraulic winch oil pipeline cooling apparatus of the present utility model;
FIG. 6 shows a schematic perspective view of a third cooling tank of the cooling device for the oil pipeline of the hydraulic winch according to the present utility model;
Fig. 7 shows a schematic perspective view of a third cooling assembly of the cooling device for the oil pipeline of the hydraulic winch.
The marks in the drawings are: 1-hydraulic table assembly, 101-oil tank, 102-hydraulic pump, 103-first oil body filter, 104-electromagnetic directional valve, 105-second oil body filter, 106-first oil outlet pipe, 107-electromagnetic valve, 108-second oil outlet pipe, 2-first cooling assembly, 201-first cooling tank, 202-connecting oil pipe, 203-third oil outlet pipe, 204-first U-shaped pipe, 205-second U-shaped pipe, 3-second cooling assembly, 301-second cooling tank, 302-motor, 303-fan blade, 304-first water pipe, 305-second water pipe, 306-third water pipe, 4-circulating water cooling assembly, 401-third cooling tank, 402-water pump, 403-fourth water pipe, 404-water injection pipe, 405-heat sink, 5-third cooling assembly, 501-fourth cooling tank, 502-water inlet pipe, 503-water outlet pipe, 504-fifth cooling tank, 505-fifth water pipe, 6-heat dissipation assembly, 601-bracket, 602-heat dissipation box, 603-heat dissipation pipe, 604-heat dissipation pipe.
Detailed Description
The utility model is further described below with reference to the drawings and examples.
Referring to fig. 1, the present utility model provides an embodiment: the cooling equipment of the oil pipeline of the hydraulic winch comprises a hydraulic table assembly 1; the cooling system further comprises a first cooling component 2, a second cooling component 3, a circulating water cooling component 4, a third cooling component 5 and a heat dissipation component 6; the upper end of the hydraulic table component 1 is provided with a first cooling component 2 and a heat dissipation component 6 for cooling pipelines; the outer wall of the hydraulic table assembly 1 is provided with a second cooling assembly 3, a circulating water cooling assembly 4 and a third cooling assembly 5 for cooling the pipes.
Referring to fig. 2, in the present embodiment, the hydraulic table assembly 1 includes an oil tank 101, a hydraulic pump 102, a first oil body filter 103, a solenoid directional valve 104, a second oil body filter 105, a first oil outlet pipe 106, a solenoid valve 107, and a second oil outlet pipe 108; the upper end of the oil tank 101 is fixedly connected with a hydraulic pump 102; the pipe body on the liquid suction port of the hydraulic pump 102 penetrates through the upper end of the oil tank 101 and extends into the oil tank 101; the upper end of the oil tank 101 is fixedly connected with a first oil body filter 103, an electromagnetic directional valve 104 and a second oil body filter 105; the hydraulic pump 102 is connected to the liquid inlet of the first oil body filter 103 through a pipe body; the liquid outlet port of the hydraulic pump 102 is connected with the liquid inlet port of the electromagnetic directional valve 104 through a pipe body; the liquid outlet port of the electromagnetic directional valve 104 is connected with the liquid inlet port of the second oil filter 105 through a pipe body; a first oil outlet pipe 106 is fixedly connected to the liquid outlet port of the second oil body filter 105; the left end of the oil tank 101 is fixedly connected with a solenoid valve 107; a second oil outlet pipe 108 is fixedly connected to the liquid outlet port of the electromagnetic valve 107; the other liquid outlet port of the electromagnetic directional valve 104 is fixedly connected with the liquid inlet port of the electromagnetic valve 107 through a pipe body; the heat radiation assembly 6 comprises a bracket 601, a heat radiation box 602, a heat radiation cylinder 603 and a return pipe 604; a plurality of brackets 601 are fixedly connected to the left end of the oil tank 101; a heat dissipation box 602 is fixedly connected on the bracket 601; the other end of the fifth water pipe 505 extends to the inside of the heat dissipation case 602 through the outer wall of the heat dissipation case 602; a heat dissipation cylinder 603 which is uniformly distributed is fixedly connected to the lower end of the heat dissipation box 602; a return pipe 604 is fixedly connected to the front end of the radiating cylinder 603; the other end of the return pipe 604 is connected to the other end of the first water pipe 304.
Referring to fig. 3, in the present embodiment, the first cooling assembly 2 includes a first cooling tank 201, a connecting oil pipe 202, a third oil outlet pipe 203, a first U-shaped pipe 204 and a second U-shaped pipe 205; a liquid outlet port of the first oil body filter 103 is fixedly connected with a connecting oil pipe 202; the upper end of the oil tank 101 is fixedly connected with a first cooling tank 201; a third oil outlet pipe 203 is fixedly connected to the first cooling box 201; the third oil outlet pipe 203 and the connecting oil pipe 202 are mutually communicated and connected in the first cooling box 201 through a first U-shaped pipe 204; a second U-shaped pipe 205 is fixedly connected to the first U-shaped pipe 204; the first U-shaped pipe 204 and the second U-shaped pipe 205 are both U-shaped; the first U-shaped pipe 204 and the second U-shaped pipe 205 are mutually communicated.
Referring to fig. 4-6, in the present embodiment, the second cooling assembly 3 includes a second cooling tank 301, a motor 302, fan blades 303, a first water pipe 304 and a second water pipe 305; the front end of the oil tank 101 is fixedly connected with a second cooling tank 301; a first water pipe 304 is arranged on the water inlet port of the second cooling box 301; a second water pipe 305 is arranged on the water outlet port of the second cooling tank 301; a third water pipe 306 is fixedly connected at the upper end of the second cooling box 301 in a penetrating manner; the other end of the third water pipe 306 extends to the inside of the first cooling tank 201 through the outer wall of the first cooling tank 201; the front end of the second cooling box 301 is fixedly connected with a motor 302; the output shaft of the motor 302 penetrates through the front end of the second cooling box 301 and is fixedly connected with a fan blade 303; the circulating water cooling assembly 4 comprises a third cooling box 401, a water pump 402, a fourth water pipe 403 and a water injection pipe 404; a third cooling tank 401 is fixedly connected to the right end of the oil tank 101; a water pump 402 is fixedly connected to the right end of the third cooling box 401; the liquid suction port of the water pump 402 is connected to the inside of the third cooling box 401 through a pipe body; a fourth water pipe 403 is fixedly connected to the liquid outlet port of the water pump 402; the upper end of the third cooling box 401 is fixedly connected with a water injection pipe 404 in a penetrating manner; the inner wall of the left end of the water injection pipe 404 is fixedly connected with uniformly distributed cooling fins 405.
Referring to fig. 7, in the present embodiment, the third cooling module 5 includes a fourth cooling tank 501, a water inlet pipe 502, a water outlet pipe 503, a fifth cooling tank 504 and a fifth water pipe 505; a fourth cooling tank 501 is fixedly connected to the front end of the oil tank 101; a water inlet pipe 502 and a water outlet pipe 503 are fixedly connected at the upper end of the fourth cooling box 501 in a penetrating manner; a fifth cooling box 504 is fixedly connected to the outer wall of the first oil outlet pipe 106; the other end of the water inlet pipe 502 extends through the outer wall of the fifth cooling tank 504 to the inside of the fifth cooling tank 504; the other end of the water outlet pipe 503 extends to the inside of the fifth cooling tank 504 through the outer wall of the fifth cooling tank 504; the other end of the fourth water pipe 403 extends to the inside of the fourth cooling tank 501 through the outer wall of the fourth cooling tank 501; a fifth water pipe 505 is fixedly connected to the inner and outer walls of the fourth cooling tank 501.
When the oil pump works, the hydraulic pump 102 is started to enable the oil body to go out through the first oil body filter 103, the hydraulic pump 102 is started to enable the oil body to go out from the first oil outlet pipe 106 through the electromagnetic directional valve 104 and the second oil body filter 105, and the hydraulic pump 102 is started to enable the oil body to go out through the electromagnetic directional valve 104 and the electromagnetic valve 107;
When the oil conveying pipeline is required to be cooled by water circulation cooling, the water pump 402 is started to pump cooling water in the third cooling tank 401 into the fourth water pipe 403, the cooling water in the fourth water pipe 403 flows into the fourth cooling tank 501, and can be injected into the fifth cooling tank 504 through the water inlet pipe 502, so that the first oil outlet pipe 106 wrapped by the fifth cooling tank 504 is cooled, the cooling water flows into the fourth cooling tank 501 through the water outlet pipe 503, and water in the fourth cooling tank 501 flows out through the fifth water pipe 505;
the water flowing out of the fifth water pipe 505 enters the heat dissipation box 602, the heat dissipation box 602 is made of heat conducting copper, heat transferred to the heat dissipation box 602 can be transferred to the plurality of heat dissipation cylinders 603, and the water passing through the heat dissipation box 602 enters the second cooling box 301 through the return pipe 604 and the first water pipe 304;
The motor 302 is started to enable the fan blades 303 to rotate, so that the flow of water body can be accelerated, the water body is in full contact with the second cooling box 301, the second cooling box 301 is made of heat conducting copper, the absorption of heat of the water body can be improved, the heat dissipation effect of the device is improved, the water body entering the second cooling box 301 can be injected into the first cooling box 201 through the third water pipe 306, the pipeline in the first cooling box 201 is cooled by water, and the water body entering the second cooling box 301 flows back into the third cooling box 401 through the second water pipe 305 to complete the circulating flow of the water body.
Through the above-mentioned step, during the use, open circulating water cooling subassembly 4 and pour into cooling water in the third cooling subassembly 5, cooling water passes through cooling module 6 to the oil pipe water-cooling of hydraulic table subassembly 1, cooling water still gets into in the second cooling subassembly 3 through third cooling subassembly 5, cooling water flows back in circulating water cooling subassembly 4 through the second cooling subassembly 3, cooling water gets into in the first cooling subassembly 2 through the second cooling subassembly 3, all contain oil pipeline in first cooling subassembly 2 and the third cooling subassembly 5, can realize the circulating water cooling to oil pipeline, when having solved the oil body in oil pipeline and carry for a long time, oil pipeline is difficult to high-efficient quick heat dissipation, influence oil pipeline's life's problem.
The embodiments of the present utility model have been described in detail with reference to the drawings, but the present utility model is not limited to the above embodiments, and various changes can be made within the knowledge of those skilled in the art without departing from the spirit of the present utility model.
Claims (7)
1. The cooling equipment of the oil pipeline of the hydraulic winch comprises a hydraulic table assembly (1); the method is characterized in that: the cooling system further comprises a first cooling component (2), a second cooling component (3), a circulating water cooling component (4), a third cooling component (5) and a heat dissipation component (6); the upper end of the hydraulic table assembly (1) is provided with a first cooling assembly (2) and a heat dissipation assembly (6) which are used for cooling pipelines; the outer wall of the hydraulic table assembly (1) is provided with a second cooling assembly (3), a circulating water cooling assembly (4) and a third cooling assembly (5) which are used for cooling pipelines.
2. The hydraulic winch oil line cooling apparatus of claim 1, wherein: the hydraulic table assembly (1) comprises an oil tank (101), a hydraulic pump (102), a first oil body filter (103), an electromagnetic reversing valve (104), a second oil body filter (105), a first oil outlet pipe (106), an electromagnetic valve (107) and a second oil outlet pipe (108); the upper end of the oil tank (101) is fixedly connected with a hydraulic pump (102); the pipe body on the liquid suction port of the hydraulic pump (102) penetrates through the upper end of the oil tank (101) and extends into the oil tank (101); the upper end of the oil tank (101) is fixedly connected with a first oil body filter (103), an electromagnetic directional valve (104) and a second oil body filter (105); the hydraulic pump (102) is connected with a liquid inlet of the first oil body filter (103) through a pipe body; the liquid outlet port of the hydraulic pump (102) is connected with the liquid inlet port of the electromagnetic directional valve (104) through a pipe body; the liquid outlet port of the electromagnetic directional valve (104) is connected with the liquid inlet port of the second oil body filter (105) through a pipe body; a first oil outlet pipe (106) is fixedly connected to the liquid outlet port of the second oil body filter (105); the left end of the oil tank (101) is fixedly connected with an electromagnetic valve (107); a second oil outlet pipe (108) is fixedly connected to the liquid outlet port of the electromagnetic valve (107); the other liquid outlet port of the electromagnetic directional valve (104) is fixedly connected with the liquid inlet port of the electromagnetic valve (107) through a pipe body.
3. The hydraulic winch oil line cooling apparatus according to claim 2, wherein: the first cooling assembly (2) comprises a first cooling box (201), a connecting oil pipe (202), a third oil outlet pipe (203), a first U-shaped pipe (204) and a second U-shaped pipe (205); a liquid outlet port of the first oil body filter (103) is fixedly connected with a connecting oil pipe (202); the upper end of the oil tank (101) is fixedly connected with a first cooling tank (201); a third oil outlet pipe (203) is fixedly connected to the first cooling box (201); the third oil outlet pipe (203) and the connecting oil pipe (202) are communicated with each other in the first cooling box (201) through a first U-shaped pipe (204); a second U-shaped pipe (205) is fixedly connected to the first U-shaped pipe (204); the first U-shaped pipe (204) and the second U-shaped pipe (205) are U-shaped; the first U-shaped pipe (204) and the second U-shaped pipe (205) are communicated with each other.
4. A hydraulic winch oil line cooling apparatus according to claim 3, wherein: the second cooling assembly (3) comprises a second cooling box (301), a motor (302), fan blades (303), a first water pipe (304) and a second water pipe (305); the front end of the oil tank (101) is fixedly connected with a second cooling tank (301); a first water pipe (304) is arranged on the water inlet of the second cooling box (301); a second water pipe (305) is arranged on the water outlet port of the second cooling box (301); a third water pipe (306) is fixedly connected at the upper end of the second cooling box (301) in a penetrating way; the other end of the third water pipe (306) penetrates through the outer wall of the first cooling box (201) and extends to the inside of the first cooling box (201); the front end of the second cooling box (301) is fixedly connected with a motor (302); an output shaft of the motor (302) penetrates through the front end of the second cooling box (301) and is fixedly connected with a fan blade (303).
5. The hydraulic winch oil line cooling apparatus according to claim 2, wherein: the circulating water cooling assembly (4) comprises a third cooling box (401), a water pump (402), a fourth water pipe (403) and a water injection pipe (404); the right end of the oil tank (101) is fixedly connected with a third cooling tank (401); the right end of the third cooling box (401) is fixedly connected with a water pump (402); the liquid suction port of the water pump (402) is connected to the inside of the third cooling box (401) through a pipe body; a fourth water pipe (403) is fixedly connected to the liquid outlet of the water pump (402); the upper end of the third cooling box (401) is fixedly connected with a water injection pipe (404) in a penetrating way; the inner wall of the left end of the water injection pipe (404) is fixedly connected with uniformly distributed cooling fins (405).
6. The hydraulic winch oil line cooling apparatus according to claim 2, wherein: the third cooling assembly (5) comprises a fourth cooling box (501), a water inlet pipe (502), a water outlet pipe (503), a fifth cooling box (504) and a fifth water pipe (505); the front end of the oil tank (101) is fixedly connected with a fourth cooling tank (501); the upper end of the fourth cooling box (501) is fixedly connected with a water inlet pipe (502) and a water outlet pipe (503) in a penetrating way; a fifth cooling box (504) is fixedly connected to the outer wall of the first oil outlet pipe (106); the other end of the water inlet pipe (502) penetrates through the outer wall of the fifth cooling box (504) and extends to the inside of the fifth cooling box (504); the other end of the water outlet pipe (503) penetrates through the outer wall of the fifth cooling box (504) and extends to the inside of the fifth cooling box (504); the other end of the fourth water pipe (403) penetrates through the outer wall of the fourth cooling box (501) and extends into the fourth cooling box (501); a fifth water pipe (505) is fixedly connected on the inner wall and the outer wall of the fourth cooling box (501) in a penetrating way.
7. The hydraulic winch oil line cooling apparatus of claim 1, wherein: the heat radiation component (6) comprises a bracket (601), a heat radiation box (602), a heat radiation cylinder (603) and a return pipe (604); the left end of the oil tank (101) is fixedly connected with a plurality of brackets (601); a heat dissipation box (602) is fixedly connected on the bracket (601); the other end of the fifth water pipe (505) penetrates through the outer wall of the heat dissipation box (602) and extends to the inside of the heat dissipation box (602); the lower end of the radiating box (602) is fixedly connected with radiating cylinders (603) which are uniformly distributed; a return pipe (604) is fixedly connected at the front end of the radiating cylinder (603); the other end of the return pipe (604) is connected with the other end of the first water pipe (304) in a penetrating way.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202322813394.XU CN221170221U (en) | 2023-10-19 | 2023-10-19 | Cooling equipment for oil pipeline of hydraulic winch |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202322813394.XU CN221170221U (en) | 2023-10-19 | 2023-10-19 | Cooling equipment for oil pipeline of hydraulic winch |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN221170221U true CN221170221U (en) | 2024-06-18 |
Family
ID=91439305
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202322813394.XU Active CN221170221U (en) | 2023-10-19 | 2023-10-19 | Cooling equipment for oil pipeline of hydraulic winch |
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| CN (1) | CN221170221U (en) |
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2023
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