CN220250451U - Energy-saving circulating water cooling device - Google Patents

Abstract

The utility model discloses an energy-saving circulating water cooling device which comprises a bottom plate, wherein a cooling box is arranged on the top surface of the bottom plate, and a partition plate is arranged inside the cooling box. According to the utility model, during operation, a worker firstly inputs quantitative ice cubes into the reflux cavity through the ice throwing port, so that during subsequent operation, cooling liquid in the flowing interior of the cooling plate enters the reflux cavity through the reflux pipe, the ice cubes are contacted with the liquid, the cooling liquid is rapidly cooled by the ice cubes, the sealing of the ice cubes is smaller than the density of water, the ice cubes float above the liquid level along with the continuous rising of the liquid in the reflux cavity, the cooling liquid entering the reflux cavity is directly contacted with the ice cubes, the cooling efficiency is improved, the second water pump is started after the temperature of the cooling liquid is lower than a normal value under the detection of the temperature sensor, and then the cooling liquid in the reflux cavity is pumped into the cooling cavity again under the action of the second water pump for reuse.

Description

Energy-saving circulating water cooling device

Technical Field

The utility model relates to the technical field of cooling equipment, in particular to an energy-saving circulating water cooling device.

Background

At present, a circulating water cooling device is provided for cooling production equipment. On the one hand, the water is used as cooling liquid and is recycled, on the other hand, the cooling device can be reduced, the cooling device enters the heat dissipation part of production equipment through the water suction pump, the heat of the part is taken out, hot water is pumped out through the water suction pump and is returned to the reservoir for cooling, the water is recycled, the cooling effect of the equipment can be achieved, and the waste of water resources can be reduced.

The prior art has the following problems:

the existing equipment adjusts the temperature of water in the cooling device by adding cold water, but when the cold water is added, the cold water needs to be mixed with the hot water in the device for a long time to achieve the effect of reducing the overall water temperature, so that the cooling efficiency of the device is reduced.

For this reason, we propose an energy-saving circulating water cooling device to solve the above-mentioned drawbacks.

Disclosure of Invention

The utility model aims to solve the defects in the prior art and provides an energy-saving circulating water cooling device.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: the utility model provides an energy-saving circulating water cooling device, includes the bottom plate, bottom plate top surface is provided with the cooling tank, the inside baffle that is provided with of cooling tank, the cooling tank is inside to be separated into cooling chamber and backward flow chamber through the baffle, cooling tank top surface mounting has the second water pump, second water pump output and input are provided with first drainage tube and second drainage tube respectively, first drainage tube and cooling chamber link up the connection, second drainage tube and backward flow chamber link up the connection, backward flow intracavity portion bottom is provided with temperature sensor.

Preferably, the cooling box top surface mounting has first water pump, first water pump output has the cooling plate through inlet tube through-connection, the runner has been seted up to the cooling plate inside, cooling plate surface below is through back flow and reflux cavity through-connection, first water pump input is through pipeline and cooling cavity through-connection.

Preferably, a transparent observation window is arranged on the surface of the cooling box.

Preferably, a grid mesh is arranged at the top of the partition plate, and the top end of the grid mesh is fixed with the top end inside the cooling box.

Preferably, the bottom plate bottom is provided with the drain pipe, and drain pipe surface mounting has the valve, water inlet and ice throwing mouth have been seted up respectively to cooling tank top surface.

Preferably, the bottom plate bottom is provided with the universal wheel, and the universal wheel is provided with a plurality of to a plurality of universal wheels equidistance are installed in bottom plate bottom four corners.

Preferably, a controller is arranged on the outer side surface of the cooling box.

Compared with the prior art, the utility model has the beneficial effects that;

(1) According to the energy-saving circulating water cooling device, through the arrangement of the partition plate, the ice throwing port, the second water pump, the first drainage tube and the second drainage tube, cooling liquid in the backflow cavity is conveniently and rapidly cooled, when the energy-saving circulating water cooling device is operated, workers firstly throw quantitative ice cubes into the backflow cavity through the ice throwing port, so that the cooling liquid in the flowing interior of the cooling plate enters the backflow cavity through the backflow tube in subsequent operation, the ice cubes are in contact with liquid, the cooling liquid is rapidly cooled, the sealing of the ice cubes is smaller than the density of water, the cooling liquid entering the backflow cavity is enabled to be directly contacted with the ice cubes along with the continuous rising of the liquid in the backflow cavity, cooling efficiency of the cooling liquid is improved, and then under the detection of the temperature sensor, the second water pump is started after the temperature of the cooling liquid is lower than a normal value, and then the cooling liquid in the backflow cavity is enabled to be pumped into the cooling cavity again under the action of the second water pump, and the cooling liquid is reused.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required to be used in the embodiments will be briefly described below.

FIG. 1 is a schematic diagram of an energy-saving circulating water cooling device according to the present utility model;

FIG. 2 is a schematic diagram of the internal structure of an energy-saving circulating water cooling device according to the present utility model;

fig. 3 is a schematic view of a runner of an energy-saving circulating water cooling device according to the present utility model.

Legend description:

1. a bottom plate; 2. a cooling box; 3. a transparent viewing window; 4. a drain pipe; 5. a universal wheel; 6. a controller; 7. an ice throwing port; 8. a return pipe; 9. a cooling plate; 10. a water inlet pipe; 11. a first water pump; 12. a water inlet; 13. a second water pump; 14. a cooling chamber; 15. a first drainage tube; 16. a partition plate; 17. a second drainage tube; 18. a temperature sensor; 19. a reflow chamber; 20. a flow channel.

Detailed Description

The objects, technical solutions and advantages of the present utility model will become more apparent by the following detailed description of the present utility model with reference to the accompanying drawings. It should be understood that the description is only illustrative and is not intended to limit the scope of the utility model. In addition, in the following description, descriptions of well-known structures and techniques are omitted so as not to unnecessarily obscure the present utility model.

Referring to fig. 1-3, an energy-saving circulating water cooling device comprises a bottom plate 1, a cooling box 2 is arranged on the top surface of the bottom plate 1, a partition plate 16 is arranged inside the cooling box 2, the cooling box 2 is divided into a cooling cavity 14 and a backflow cavity 19 through the partition plate 16, a second water pump 13 is arranged on the top surface of the cooling box 2, a first drainage tube 15 and a second drainage tube 17 are respectively arranged at the output end and the input end of the second water pump 13, the first drainage tube 15 is in through connection with the cooling cavity 14, the second drainage tube 17 is in through connection with the backflow cavity 19, and a temperature sensor 18 is arranged at the bottom end inside the backflow cavity 19.

In this embodiment: through setting up baffle 16, the ice throwing mouth 7, the cooperation of second water pump 13, first drainage tube 15 and second drainage tube 17 is used, be convenient for quick cooling to the inside coolant liquid of backward flow chamber 19, make during operation, the staff drops into quantitative ice-cube to backward flow chamber 19 inside earlier through ice throwing mouth 7, thereby during subsequent operation, make the inside coolant liquid of cooling plate 9 flow enter into backward flow chamber 19 inside through back flow pipe 8, thereby make ice-cube and liquid contact, make the ice-cube carry out quick cooling process to the coolant liquid, and the seal of ice-cube is less than the density of water, thereby along with the continuous rising of backward flow chamber 19 inside liquid, the ice-cube can float above the liquid level, thereby can make the inside coolant liquid of entering backward flow chamber 19 directly contact with the ice-cube, accelerate its cooling efficiency, under the detection of rethread temperature sensor 18, after the coolant liquid temperature is less than normal value, afterwards under the effect of second water pump 13, make the inside coolant liquid of backward flow chamber 19 draw in cooling chamber 14 again, reuse can.

Specifically, the first water pump 11 is installed to cooling tank 2 top surface mounting, first water pump 11 output has cooling plate 9 through inlet tube 10 through connection, runner 20 has been seted up to cooling plate 9 inside, cooling plate 9 surface below is through back flow 8 and reflux cavity 19 through connection, first water pump 11 input is through pipeline and cooling cavity 14 through connection, through setting up cooling plate 9, be convenient for cool off equipment for when the operation, the staff is through removing cooling tank 2, then makes cooling plate 9 and equipment surface contact, later starts first water pump 11, then under the cooperation of first water pump 11, makes the inside coolant liquid of cooling cavity 14 enter into cooling plate 9 through inlet tube 10 inside, thereby makes cooling plate 9 cooling start the heat dissipation effect to equipment.

Preferably, a transparent observation window 3 is installed on the surface of the cooling box 2.

In this embodiment: by providing the transparent observation window 3, the liquid amount inside the cooling tank 2 is convenient to observe.

Specifically, a grid mesh is arranged at the top of the partition plate 16, and the top end of the grid mesh is fixed with the top end inside the cooling box 2.

In this embodiment: by arranging the grid mesh, the blocking of ice cubes is facilitated.

Specifically, the bottom of bottom plate 1 is provided with drain pipe 4, and drain pipe 4 surface mounting has the valve, water inlet 12 and ice throwing mouth 7 have been seted up respectively to cooling tank 2 top surface.

In this embodiment: through setting up drain pipe 4, be convenient for to the unnecessary liquid discharge of backward flow chamber 19, through setting up water inlet 12, be convenient for pour into cooling water to cooling chamber 14 inside, through setting up ice throwing mouth 7, be convenient for throw into the ice-cube to backward flow chamber 19 inside, be convenient for cool down to the cooling water of inside backward flow.

Specifically, the bottom of the bottom plate 1 is provided with universal wheels 5, and the universal wheels 5 are provided with a plurality of universal wheels 5, and the universal wheels 5 are equidistantly arranged at four corners of the bottom plate 1.

In this embodiment: by providing the universal wheel 5, movement of the cooling box 2 is facilitated.

Preferably, a controller 6 is mounted on the outer side surface of the cooling tank 2.

In this embodiment: through setting up controller 6, be convenient for control the power consumption component inside the equipment, controller 6 control circuit can be realized through the simple programming of the person skilled in the art, belongs to the common sense of this field, only uses it, does not reform transform, so no more detailed description control mode and circuit connection.

Working principle: during operation, a worker moves the cooling box 2, then makes the cooling plate 9 contact with the surface of the equipment, then starts the first water pump 11, and then under the cooperation of the first water pump 11, makes the cooling liquid in the cooling cavity 14 enter the cooling plate 9 through the water inlet pipe 10, so that the cooling plate 9 cools down to start the heat dissipation effect on the equipment, and through the cooperation of the partition plate 16, the ice throwing port 7, the second water pump 13, the first drainage pipe 15 and the second drainage pipe 17, the rapid cooling liquid in the reflux cavity 19 is facilitated, so that during operation, the worker firstly throws quantitative ice cubes into the reflux cavity 19 through the ice throwing port 7, and during subsequent operation, the cooling liquid in the flowing part of the cooling plate 9 enters the reflux cavity 19 through the reflux pipe 8, so that ice cubes are contacted with liquid, the ice cubes are used for carrying out rapid cooling treatment on the cooling liquid, and the sealing of the ice cubes is smaller than the density of water, so that the ice cubes can float above the liquid level along with the continuous rising of the liquid in the reflux cavity 19, the cooling liquid entering the reflux cavity 19 can be directly contacted with the ice cubes, the cooling efficiency of the cooling liquid is improved, the second water pump 13 is started after the temperature of the cooling liquid is lower than a normal value under the detection of the temperature sensor 18, and then the cooling liquid in the reflux cavity 19 is pumped into the cooling cavity 14 again under the action of the second water pump 13 for reuse.

It is to be understood that the above-described embodiments of the present utility model are merely illustrative of or explanation of the principles of the present utility model and are in no way limiting of the utility model. Accordingly, any modification, equivalent replacement, improvement, etc. made without departing from the spirit and scope of the present utility model should be included in the scope of the present utility model. Furthermore, the appended claims are intended to cover all such changes and modifications that fall within the scope and boundary of the appended claims, or equivalents of such scope and boundary.

Claims (7)

1. The utility model provides an energy-saving circulating water cooling device, includes bottom plate (1), its characterized in that, bottom plate (1) top surface is provided with cooling tank (2), cooling tank (2) inside is provided with baffle (16), cooling tank (2) inside is separated into cooling chamber (14) and backward flow chamber (19) through baffle (16), cooling tank (2) top surface mounting has second water pump (13), second water pump (13) output and input are provided with first drainage tube (15) and second drainage tube (17) respectively, first drainage tube (15) and cooling chamber (14) through connection, second drainage tube (17) and backward flow chamber (19) through connection, backward flow chamber (19) inside bottom is provided with temperature sensor (18).

2. The energy-saving circulating water cooling device according to claim 1, wherein a first water pump (11) is installed on the top surface of the cooling box (2), the output end of the first water pump (11) is connected with a cooling plate (9) in a penetrating way through a water inlet pipe (10), a flow passage (20) is formed in the cooling plate (9), the lower surface of the cooling plate (9) is connected with a backflow cavity (19) in a penetrating way through a backflow pipe (8), and the input end of the first water pump (11) is connected with the cooling cavity (14) in a penetrating way through a pipeline.

3. An energy-efficient circulating water cooling apparatus according to claim 1, characterized in that the cooling box (2) is surface-mounted with a transparent viewing window (3).

4. An energy-saving circulating water cooling apparatus according to claim 1, wherein the top of the partition plate (16) is provided with a grid mesh, and the top end of the grid mesh is fixed with the top end inside the cooling tank (2).

5. The energy-saving circulating water cooling device according to claim 1, wherein a drain pipe (4) is arranged at the bottom end of the bottom plate (1), a valve is arranged on the surface of the drain pipe (4), and a water inlet (12) and an ice throwing port (7) are respectively formed in the top surface of the cooling box (2).

6. The energy-saving circulating water cooling device according to claim 1, wherein the bottom end of the bottom plate (1) is provided with universal wheels (5), the universal wheels (5) are provided in plurality, and the universal wheels (5) are equidistantly arranged at four corners of the bottom end of the bottom plate (1).

7. An energy-saving circulating water cooling apparatus according to claim 1, characterized in that the cooling tank (2) is provided with a controller (6) on the outer side surface.