CN222542789U - Hydraulic station energy-saving control system - Google Patents

Abstract

The utility model discloses a hydraulic station energy-saving control system, which specifically relates to the technical field of hydraulic station control, including a bottom plate, a hydraulic station body is arranged on the top of the bottom plate, a water cooling component for cooling and dissipating heat is arranged outside the hydraulic station body; a functional component for enhancing heat dissipation performance is arranged outside the water cooling component; the functional component includes a movable shaft, and the movable shaft is arranged on the top of the bottom plate. The utility model drives the movable shaft and the linkage shaft driven by the meshing of the main bevel gear and the slave bevel gear to rotate by a motor, and the movable shaft drives a plurality of spoiler blades to rotate to accelerate the flow of liquid in the water tank, thereby improving the contact efficiency and heat dissipation efficiency of the liquid and the air, and the linkage shaft drives the fan to rotate to accelerate the air flow efficiency outside the hydraulic station body, improve the heat dissipation effect of the hydraulic station body, thereby realizing air cooling and improving the water cooling efficiency, so as to effectively ensure the practicality of the utility model.

Description

Energy-saving control system of hydraulic station

Technical Field

The utility model relates to the technical field of hydraulic station control, in particular to an energy-saving control system of a hydraulic station.

Background

The hydraulic station is a hydraulic device composed of a hydraulic pump, a motor, an oil tank, a directional valve, a throttle valve, an overflow valve and the like, and is supplied with oil according to the flow direction, pressure and flow rate required by the driving device, and the hydraulic station is connected with an oil pipe for the driving device, so that the hydraulic system can realize various specified actions.

As shown in the application document with the prior art publication number CN220396186U, this technical scheme can guide the inside heat that produces of hydraulic pressure station main part to the inside of heat energy exchange chamber through heat-conducting plate and heat-conducting rod, make the inside water of heat energy exchange chamber carry out the inner loop through water circulation structure simultaneously, thereby can guide the inside heat of heat energy exchange chamber to the outside of hydraulic pressure station main part, accomplish the heat dissipation to the hydraulic pressure station main part, and promote the radiating efficiency of hydraulic pressure station main part, utilize the heat that the heat energy exchange chamber led out to carry out the difference in temperature through the semiconductor thermoelectric generation piece and take place, accomplish the charge to the battery, make this hydraulic pressure station energy-saving control system possess energy-conserving effect.

But the water in the water tank of the technical scheme is absorbed, and then the water tank cannot be cooled down rapidly, so that the cooling effect of the subsequent water on the hydraulic station body can be influenced, and the heat dissipation performance of the technical scheme can be influenced.

Disclosure of utility model

In order to overcome the defects in the prior art, the utility model provides the energy-saving control system of the hydraulic station, which drives the movable shaft and the linkage shaft which are driven by the main bevel gear and the slave bevel gear to rotate through the motor, and the movable shaft drives the plurality of turbulence blades to rotate so as to accelerate the flow of liquid in the water tank, thereby improving the contact efficiency and the heat dissipation efficiency of the liquid and air, and the linkage shaft drives the fan to rotate so as to accelerate the flow efficiency of the air outside the hydraulic station body, thereby improving the heat dissipation effect on the hydraulic station body, and realizing air cooling heat dissipation and water cooling heat dissipation efficiency, thereby effectively ensuring the practicability of the utility model, and solving the problems in the prior art.

The hydraulic station energy-saving control system comprises a bottom plate, wherein a hydraulic station body is arranged at the top of the bottom plate, and a cooling and heat dissipation water cooling assembly is arranged outside the hydraulic station body;

The outside of the water cooling component is provided with a functional component for enhancing heat dissipation performance;

The functional assembly comprises a movable shaft, the movable shaft is arranged at the top of the bottom plate, a plurality of turbulence blades distributed at intervals are arranged at the outer part of the bottom end of the movable shaft, a main bevel gear is sleeved at the outer part of the top end of the movable shaft, a linkage shaft is arranged at one side of the top end of the main bevel gear, a slave bevel gear is sleeved at the outer part of one end of the linkage shaft, which is close to the main bevel gear, the slave bevel gear is meshed with the main bevel gear, and a fan is arranged at one end of the linkage shaft, which is far away from the slave bevel gear.

In a preferred embodiment, the water cooling assembly comprises a water tank, the water tank is arranged at the top of one end of a bottom plate, far away from the hydraulic station body, an output pipe is fixedly communicated with the rear side of the water tank, an injection pump is arranged outside the output pipe, an input pipe is arranged on one side of the water tank, far away from the output pipe, and is provided with a suction pump, a heat exchange cavity is arranged inside the hydraulic station body, two outer heat conducting plates are arranged inside the heat exchange cavity, the two outer heat conducting plates are symmetrically distributed about the central axis of the heat exchange cavity, inner heat conducting plates are arranged on the side, close to the two outer heat conducting plates, of the two outer heat conducting plates, the inner heat conducting plates are arranged inside the hydraulic station body, the outer heat conducting plates penetrate through the hydraulic station body and are fixed with the inner heat conducting plates, one end, far away from the water tank, of the output pipe and one end, far away from the water tank, of the input pipe are all penetrated through the hydraulic station body and are communicated with the heat exchange cavity, and the movable shaft, the turbulence blades, the main bevel gears and the fan are all arranged inside the water tank.

In a preferred embodiment, a semiconductor thermoelectric generation sheet is arranged on one side, away from the hydraulic station body, of the water tank, and a storage battery is arranged outside the semiconductor thermoelectric generation sheet.

In a preferred embodiment, the movable shaft is externally sleeved with a movable ring, the inner wall of the movable ring is movably connected with the outside of the movable shaft through a bearing, movable brackets are arranged on the front side and the rear side of the movable ring, and one end, far away from the movable ring, of the movable bracket is fixed with the top of the water tank.

In a preferred embodiment, the linkage shaft is sleeved with a linkage ring, the inner wall of the linkage ring is movably connected with the outer part of the linkage shaft through a bearing, linkage supports are arranged on the front side and the rear side of the linkage ring, and one end of the linkage support, which is far away from the linkage ring, is fixed with the top of the water tank.

In a preferred embodiment, the top of the main bevel gear is provided with a fixed support, the top of the fixed support is provided with a motor, an output shaft of the motor penetrates through the fixed support and is fixed with the top of the movable shaft, the front end and the rear end of the fixed support are both fixed with the top of the water tank, the inner parts of the two ends of the front end of the fixed support are both provided with embedded holes in a penetrating mode, and the movable support is arranged in the embedded holes.

The utility model has the technical effects and advantages that:

The motor drives the movable shaft and the linkage shaft which are meshed and driven by the main bevel gear and the slave bevel gear to rotate, the movable shaft drives the plurality of turbulence blades to rotate so as to accelerate the flow of liquid in the water tank, so that the contact efficiency and the heat dissipation efficiency of the liquid and air are improved, the linkage shaft drives the fan to rotate so as to accelerate the air flow efficiency outside the hydraulic station body, and the heat dissipation effect on the hydraulic station body is improved, thereby realizing air cooling heat dissipation and improving the water cooling heat dissipation efficiency, and further effectively ensuring the practicability of the utility model.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a rear view of the floor of the present utility model;

FIG. 3 is a side view of the water tank of the present utility model;

FIG. 4 is a cross-sectional view of a heat exchange chamber of the present utility model;

Fig. 5 is an exploded view of the fixing bracket of the present utility model.

The device comprises a base plate, a hydraulic station body, a movable shaft, a turbulence blade, a main bevel gear, a 6, a linkage shaft, a 7, a secondary bevel gear, a 8, a fan, a 9, a water tank, a 10, an output pipe, a 11, an injection pump, a 12, an input pipe, a 13, a suction pump, a 14, a heat exchange cavity, a 15, an outer heat conducting plate, a 16, an inner heat conducting plate, a 17, a semiconductor thermoelectric generation sheet, a 18, a storage battery, a 19, a movable ring, a 20, a movable support, a 21, a linkage ring, a 22, a linkage support, a 23, a fixed support, a 24, a motor, a 25 and a jogged hole.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to the accompanying drawings 1-5 of the specification, the utility model provides an energy-saving control system of a hydraulic station, which comprises a bottom plate 1, wherein the top of the bottom plate 1 is provided with a hydraulic station body 2, and the outside of the hydraulic station body 2 is provided with a cooling and heat dissipation water cooling assembly;

As shown in figures 1, 2 and 4, the water cooling assembly comprises a water tank 9, the water tank 9 is arranged at the top of one end of a bottom plate 1 far away from a hydraulic station body 2, an output pipe 10 is fixedly communicated with the rear side of the water tank 9, an injection pump 11 is arranged outside the output pipe 10, an input pipe 12 is arranged at one side of the water tank 9 far away from the output pipe 10, a suction pump 13 is arranged outside the input pipe 12, a heat exchange cavity 14 is arranged inside the hydraulic station body 2, two outer heat conducting plates 15 are symmetrically distributed on the central axis of the heat exchange cavity 14, inner heat conducting plates 16 are arranged at the sides, close to each other, of the two outer heat conducting plates 15, of the two outer heat conducting plates 16 are arranged inside the hydraulic station body 2, the outer heat conducting plates 15 penetrate through the hydraulic station body 2 and are fixed with the inner heat conducting plates 16, one end, far away from the water tank 9, of the output pipe 10 and one end, far away from the water tank 9, of the input pipe 12 are all penetrated through the hydraulic station body 2 and are communicated with the heat exchange cavity 14, the movable shaft 3, a vortex blade 4, a bevel gear 5, a bevel gear 7 and a fan 8 are arranged inside the heat exchange cavity 9 are symmetrically distributed on the central axis of the heat exchange cavity 14, the two outer heat conducting plates 15 are arranged on the side of the heat conducting plates 15, heat exchange plates are repeatedly arranged on the side of the water tank 9 and are arranged on the side of the water tank body, the water is conveyed into the water through the heat exchange cavity 14, the heat conducting plates is conveyed into the inner heat conducting plate body 14 through the heat conducting plate 12, and is repeatedly, and is conveyed into the heat exchange cavity through the heat exchange cavity 9, and is conveyed into the heat exchange cavity through the heat exchange cavity is 16, and is inside by the heat exchange pipe is 16, and is conveyed through the heat exchange pipe is 16, and is inside, and is cooled by the heat, and is 9, and is subjected to be and is cooled.

As shown in fig. 1-3, a semiconductor thermoelectric generation sheet 17 is installed on a side, far away from the hydraulic station body 2, of the water tank 9, a storage battery 18 is arranged outside the semiconductor thermoelectric generation sheet 17, thermoelectric generation is performed by utilizing the difference between the water temperature and the air temperature of the water tank 9 through the semiconductor thermoelectric generation sheet 17, and then the storage battery 18 is charged, so that the semiconductor thermoelectric generation sheet can serve as a standby power supply.

In order to improve the heat radiation performance, a functional component for enhancing the heat radiation performance is arranged outside the water cooling component;

As shown in fig. 1, 2, 3 and 5, the functional module includes loose axle 3, loose axle 3 establishes at bottom plate 1 top, loose axle 3 bottom externally mounted has a plurality of interval distribution's vortex leaf 4, loose axle 3 top outside cover is equipped with main bevel gear 5, main bevel gear 5 top one side is equipped with universal driving shaft 6, the outside cover of one end that universal driving shaft 6 is close to main bevel gear 5 is equipped with from bevel gear 7, from bevel gear 7 and main bevel gear 5 mesh, fan 8 is installed to the one end that universal driving shaft 6 kept away from bevel gear 7, the outside cover of loose axle 3 is equipped with loose collar 19, the loose collar 19 inner wall is through bearing and the outside swing joint of loose axle 3, the movable support 20 is all installed to both sides around the loose collar 19, the one end that loose collar 19 was kept away from to the movable support 20 is in the same place with water tank 9 top, through the swing joint of ring 19 and loose collar 19 for the movable support 20 can support fixedly to the loose axle 3 with the cooperation, the stability when guaranteeing that loose axle 3 moves, from bevel gear 7 meshes with main bevel gear 5, the outside cover 21 is equipped with the fixed moving collar 21 and the movable support 21, the movable support 21 is kept away from both sides with the outside through the fixed swivel collar 21 and the movable support 21, and the movable support 21 is connected with the movable support 21 and the outside is connected with the movable collar 6 through the movable collar 21, and the movable support 21 and the movable support is guaranteed to move together with the outside and the movable collar 21.

As shown in fig. 1, 2, 3 and 5, a fixed bracket 23 is arranged at the top of the main bevel gear 5, a motor 24 is arranged at the top of the fixed bracket 23, an output shaft of the motor 24 penetrates through the fixed bracket 23 and is fixed with the top of the movable shaft 3, the front end and the rear end of the fixed bracket 23 are both fixed with the top of the water tank 9, embedded holes 25 are formed in the inner parts of the two ends of the front end of the fixed bracket 23 in a penetrating manner, the movable bracket 20 is arranged in the embedded holes 25, and the motor 24 can drive the movable shaft 3 and the linkage shaft 6 which are in meshed transmission by the main bevel gear 5 and the slave bevel gear 7 to rotate through the connection of the output shaft of the motor 24 and the movable shaft 3.

The movable shaft 3 is driven to rotate by the motor 24 to drive the plurality of turbulence blades 4 and the main bevel gear 5, the rotation of the plurality of turbulence blades 4 can accelerate the liquid flow in the water tank 9, so that the cooling efficiency of the liquid can be accelerated, the main bevel gear 5 drives the fan 8 on the linkage shaft 6 to rotate by the meshed slave bevel gear 7, so that the air flow efficiency outside the hydraulic station body 2 can be accelerated by the operation of the fan 8, the heat dissipation effect on the hydraulic station body 2 is improved, the air cooling heat dissipation and the water cooling heat dissipation efficiency can be improved, and the practicability of the utility model can be effectively ensured.

Finally, the foregoing description of the preferred embodiment of the utility model is provided for the purpose of illustration only, and is not intended to limit the utility model to the particular form disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the utility model.

Claims (6)

1. The hydraulic station energy-saving control system comprises a bottom plate (1) and is characterized in that a hydraulic station body (2) is arranged at the top of the bottom plate (1), and a cooling and heat dissipation water cooling component is arranged outside the hydraulic station body (2);

The outside of the water cooling component is provided with a functional component for enhancing heat dissipation performance;

The functional assembly comprises a movable shaft (3), the movable shaft (3) is arranged at the top of a bottom plate (1), a plurality of turbulence blades (4) are arranged at the outer part of the bottom end of the movable shaft (3) at intervals, a main bevel gear (5) is sleeved outside the top end of the movable shaft (3), a linkage shaft (6) is arranged on one side of the top end of the main bevel gear (5), a slave bevel gear (7) is sleeved outside one end of the linkage shaft (6) close to the main bevel gear (5), the slave bevel gear (7) is meshed with the main bevel gear (5), and a fan (8) is arranged at one end of the linkage shaft (6) away from the slave bevel gear (7).

2. The hydraulic station energy-saving control system according to claim 1, wherein the water cooling assembly comprises a water tank (9), the water tank (9) is arranged at the top of one end of the bottom plate (1) far away from the hydraulic station body (2), an output pipe (10) is fixedly communicated with the rear side of the water tank (9), an injection pump (11) is arranged outside the output pipe (10), an input pipe (12) is arranged at one side of the water tank (9) far away from the output pipe (10), and a suction pump (13) is arranged outside the input pipe (12);

The hydraulic station is characterized in that a heat exchange cavity (14) is formed in the hydraulic station body (2), two outer heat conducting plates (15) are mounted in the heat exchange cavity (14), the two outer heat conducting plates (15) are symmetrically distributed around the central axis of the heat exchange cavity (14), inner heat conducting plates (16) are arranged on one sides, close to the two outer heat conducting plates (15), of the two outer heat conducting plates, the inner heat conducting plates (16) are mounted in the hydraulic station body (2), the outer heat conducting plates (15) penetrate through the hydraulic station body (2) and are fixed with the inner heat conducting plates (16), and one end, far away from a water tank (9), of an output pipe (10) and one end, far away from the water tank (9), of an input pipe (12) penetrate through the hydraulic station body (2) and are communicated with the heat exchange cavity (14);

the movable shaft (3), the turbulence blades (4), the main bevel gear (5), the auxiliary bevel gear (7) and the fan (8) are all arranged in the water tank (9).

3. The hydraulic station energy-saving control system according to claim 2, wherein a semiconductor thermoelectric generation sheet (17) is arranged on one side of the water tank (9) far away from the hydraulic station body (2), and a storage battery (18) is arranged outside the semiconductor thermoelectric generation sheet (17).

4. The hydraulic station energy-saving control system according to claim 1, wherein the movable shaft (3) is externally sleeved with a movable ring (19), the inner wall of the movable ring (19) is movably connected with the outside of the movable shaft (3) through a bearing, movable brackets (20) are arranged on the front side and the rear side of the movable ring (19), and one end, far away from the movable ring (19), of the movable bracket (20) is fixed with the top of the water tank (9).

5. The hydraulic station energy-saving control system according to claim 1, wherein a linkage ring (21) is sleeved outside the linkage shaft (6), the inner wall of the linkage ring (21) is movably connected with the outside of the linkage shaft (6) through a bearing, linkage supports (22) are arranged on the front side and the rear side of the linkage ring (21), and one end, far away from the linkage ring (21), of the linkage supports (22) is fixed with the top of the water tank (9).

6. The hydraulic station energy-saving control system according to claim 4, wherein a fixed bracket (23) is arranged at the top of the main bevel gear (5), a motor (24) is arranged at the top of the fixed bracket (23), and an output shaft of the motor (24) penetrates through the fixed bracket (23) and is fixed with the top of the movable shaft (3);

Both ends are all together fixed with water tank (9) top around fixed bolster (23), inside gomphosis hole (25) of having all running through in fixed bolster (23) front end both ends, movable support (20) are established inside gomphosis hole (25).