CN116379805A

CN116379805A - Fog-dissipating water-saving cooling tower

Info

Publication number: CN116379805A
Application number: CN202310393600.8A
Authority: CN
Inventors: 王俊
Original assignee: Shandong Yatai Environmental Protection Technology Co ltd
Current assignee: Shandong Yatai Environmental Protection Technology Co ltd
Priority date: 2023-04-13
Filing date: 2023-04-13
Publication date: 2023-07-04
Anticipated expiration: 2043-04-13
Also published as: CN116379805B

Abstract

The invention discloses a fog-dissipating water-saving cooling tower, which comprises: the device comprises a spray pipe, a heat exchange chamber arranged below the spray pipe, a condensing chamber arranged above the spray pipe, a filler arranged in the heat exchange chamber, a water collecting tank arranged below the filler, and a plurality of air inlets arranged in the heat exchange chamber and the condensing chamber; the cooling tower further includes: a cooling box; a flow guiding assembly; a conversion assembly; the air flow after condensation is sent into the flow guiding component through the ventilation pipe, a part of water drops formed after condensation directly fall into the cooling box, other water drops rise to the top plate of the flow guiding component and flow to the cooling box in the guiding direction, meanwhile, the wet and hot air flow is guided in the same direction with the water drops, the water drops can be pushed to flow to the cooling box while the wet and hot air is output, the problem that the water drops are scattered in an impact mode due to the fact that the wet and hot air flow and the water drops flow in the dripping direction are mutually impacted is avoided, the water drops are contacted with the wet and hot air flow again, and therefore the condensation efficiency of the wet and hot air is reduced is solved, and the effect of fog dissipation and water saving is achieved.

Description

Fog-dissipating water-saving cooling tower

Technical Field

The invention particularly relates to the technical field of cooling towers, in particular to a fog-dissipating water-saving cooling tower.

Background

The cooling tower exchanges heat with air in the tower through circulating hot water, takes away the heat of the water through the air and discharges the heat into the atmosphere outside the tower, thereby cooling the circulating water. The circulating water and air of the conventional cooling tower mainly exchange heat at the filler, the circulating hot water evaporates and radiates heat to transfer the heat to the air, and the air absorbs the heat and moisture to become saturated hot air.

When the ambient temperature is lower in winter, the water in the hot air is condensed to generate a large amount of white fog, the white fog drifts to influence the visibility of the surrounding environment, and the white fog takes away a large amount of water to cause the waste of water resources.

The existing defogging water-saving cooling tower is usually provided with one or a combination structure of a water baffle and a cooling pipe for introducing cooling water before discharging hot and humid air, and pre-condensing the hot and humid air is disclosed in, for example, patent publication numbers CN111457757B and CN 115507669A; however, the technical scheme has the problem that the hot and humid air flow and the dripping direction of the condensed water are mutually collided in the practical application, so that condensed water drops are easily impacted and scattered, the re-contact degree of the condensed water drops and the hot and humid air flow is increased, the pre-condensation effect of the hot and humid air is reduced, and the hot and humid air cannot be reused after being directly discharged, so that waste is caused.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provide a defogging water-saving cooling tower so as to solve the technical problems that hot and humid air flows are mutually flushed with the dripping direction of condensed water and the utilization rate of the hot and humid air is low.

The aim of the invention can be achieved by the following technical scheme:

an defogging water conservation cooling tower, comprising:

the device comprises a spray pipe, a heat exchange chamber arranged below the spray pipe, a condensing chamber arranged above the spray pipe, a filler arranged in the heat exchange chamber, a water collecting tank arranged below the filler, and a plurality of air inlets arranged in the heat exchange chamber and the condensing chamber;

the cooling tower further includes:

the cooling box is fixed on the inner wall of the condensing chamber, and two ventilation pipes are arranged on the cooling box in a penetrating way, and the ventilation pipes are communicated with the condensing chamber and the heat exchange chamber;

the two diversion components are respectively connected with the two ventilation pipes, the two diversion components are communicated with the air duct arranged at the top of the cooling tower and are communicated with the cooling box, and when the hot and humid air enters the condensation chamber through the ventilation pipes, the diversion components guide the hot and humid air flow to have the same direction with water drops generated by condensation of the hot and humid air flow; and

the conversion assembly is arranged between the guide assemblies and the air cylinders in the condensing chamber, the two conversion assemblies are respectively connected with air outlets of the two guide assemblies, the conversion assembly is connected with an air inlet of the guide assemblies through a return pipe, and a first check valve is arranged on the return pipe.

As a further scheme of the invention: the flow guide assembly includes:

the air inlet of the inclined part is higher than the air outlet of the inclined part, the air inlet of the inclined part is connected with the air inlet in the condensation chamber and the ventilation pipe, and the air outlet of the inclined part is communicated with the cooling box; and

and the two ends of the vertical part are respectively connected with the air outlet of the inclined part and the air duct, and the conversion assembly is arranged on the vertical part.

As a further scheme of the invention: the flow guide assembly further comprises an auxiliary plate fixed on the cooling box, the auxiliary plate is located below the top plate of the inclined portion and is arranged in parallel with the inclined portion, and a through hole is formed in the position, connected with the auxiliary plate, of the cooling box.

As a further scheme of the invention: the conversion assembly includes:

the rotating shaft is rotatably arranged on the side wall of the vertical part; and

the fan blades are circumferentially arranged on the rotating shaft, and the rotating shaft interferes with air flow in the vertical part.

As a further scheme of the invention: the fan blade is provided with a water absorbing piece.

As a further scheme of the invention: the inside of the inclined part is provided with a circulating cooling pipe, and the cooling pipe is connected with a cooling water tank and a water pump.

As a further scheme of the invention: the cooling pipe is provided with a bending part, and the bending part is positioned in the cooling box.

As a further scheme of the invention: the bending part is communicated with the cooling box, and a second one-way valve is arranged at the communicating part.

The invention has the beneficial effects that:

(1) According to the invention, the condensed airflow is sent into the flow guiding assembly through the ventilation pipe, a part of water drops formed after condensation directly fall into the cooling box, other water drops rise to the top plate of the flow guiding assembly and flow to the cooling box along the guiding direction, meanwhile, the guiding direction of the damp and hot air flow is the same as the water drop flow, the water drops can be pushed to flow to the cooling box while the damp and hot air is output, the problem that the water drops are impacted and scattered due to the fact that the damp and hot air flow is impacted and scattered in the dripping direction of the condensed water is avoided, the water drops are contacted with the damp and hot air again, and the condensation efficiency of the damp and hot air is reduced is solved, and the fog dissipation and water saving effects are achieved;

(2) According to the invention, after the conversion component at the air outlet of the flow guiding component is contacted with the hot and humid air flow, part of the hot and humid air can be converted into common air, namely, air flow with the temperature lower than that of the hot and humid air is formed, and the air flow is conveyed to the air inlet of the flow guiding component through the return pipe, so that the subsequent condensation of the hot and humid air is promoted by utilizing the discharge of the hot and humid air flow, and the utilization rate of the hot and humid air is improved in the discharge process of the hot and humid air;

(3) According to the invention, the cooling water is circularly conveyed in the cooling pipe, so that the condensation temperature in the inclined part and the cooling box can be raised, the second one-way valve is arranged to enable the condensed water in the cooling box to only enter the bent part, and the cooling water in the cooling pipe cannot flow to the cooling box, thereby realizing the reutilization of the condensed water and further achieving the water saving effect.

Drawings

The invention is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of a partial enlarged structure at A of FIG. 1 in accordance with the present invention;

FIG. 3 is a schematic view of a partially enlarged structure at B of FIG. 1 in accordance with the present invention;

FIG. 4 is a schematic diagram of a conversion assembly according to the present invention;

fig. 5 is a schematic view of a partial enlarged structure at C of fig. 1 in the present invention.

In the figure: 1. a shower pipe; 2. a water collecting tank; 3. an air inlet; 4. a filler; 5. a cooling box; 6. a ventilation pipe; 7. a flow guiding assembly; 701. an inclined portion; 702. a vertical portion; 703. a sub-plate; 8. a conversion assembly; 801. a rotating shaft; 802. a fan blade; 803. a water absorbing member; 9. a return pipe; 10. a first one-way valve; 11. a cooling tube; 12. a second one-way valve; 13. a through hole; 14. a heat exchange chamber; 15. a condensing chamber.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-2, the present invention is a defogging water-saving cooling tower, comprising:

the device comprises a spray pipe 1, a heat exchange chamber 14 arranged below the spray pipe, a condensing chamber 15 arranged above the spray pipe 1, a filler 4 arranged in the heat exchange chamber 14, a water collecting tank 2 arranged below the filler 4 and a plurality of air inlets 3 arranged in the heat exchange chamber 14 and the condensing chamber 15;

the cooling tower further includes:

the cooling box 5 is fixed on the inner wall of the condensing chamber 15, and two ventilation pipes 6 are arranged on the cooling box in a penetrating way, and the ventilation pipes 6 are communicated with the condensing chamber 15 and the heat exchange chamber 14;

the flow guide assemblies 7 are arranged in the condensation chamber 15, the two flow guide assemblies 7 are respectively connected with the two ventilation pipes 6, the two flow guide assemblies 7 are communicated with the air cylinders arranged at the top of the cooling tower and are communicated with the cooling box 5, and when the hot and humid air enters the condensation chamber 15 through the ventilation pipes 6, the flow guide assemblies 7 guide the hot and humid air flow to have the same water dripping direction generated by condensation of the hot and humid air flow; and

the conversion assembly 8 is arranged between the guide assembly 7 and the air duct in the condensing chamber 15, two conversion assemblies 8 are respectively connected with air outlets of the two guide assemblies 7, the conversion assembly 8 is connected with an air inlet of the guide assembly 7 through the return pipe 9, and the return pipe 9 is provided with a first one-way valve 10.

In one case of the embodiment, the water inlet of the spray pipe 1 is connected with an industrial hot water tank, and a plurality of atomizing nozzles for spraying industrial hot water are arranged on the water inlet of the spray pipe 1, the filler 4, the air inlet 3 and the air duct are all in the prior art, and the spray pipe 1, the filler 4, the air inlet 3 and the air duct are not improved, so that the specific mechanical structure and the circuit structure of the spray pipe 1 and the specific circuit structure are not required to be disclosed, and the integrity of the spray pipe is not affected; it should be noted that, the first check valve 10 is configured such that the air flow can only enter the flow guiding assembly 7 from the return pipe 9, and the air flow in the flow guiding assembly 7 cannot enter the return pipe 9.

In practical application, industrial hot water is sprayed onto the filler 4 through the spray pipe 1, hot water in the filler 4 exchanges heat with air flowing upwards in the tower, and the cooled industrial hot water enters the water collecting tank 2 for recycling by other industrial devices needing cooling; the hot and humid air formed after the air absorbs heat and moisture flows upwards and enters the two diversion assemblies 7 through the two ventilation pipes 6, the hot and humid air is guided to move towards the wind cylinders in the diversion assemblies 7, in the process, the cold air introduced by the air inlet 3 in the condensation chamber 15 is contacted with the hot and humid air to condense the hot and humid air, part of water drops formed after condensation directly fall into the cooling box 5, the rest of water drops rise to the top plate of the diversion assemblies 7 and flow towards the cooling box 5 in the guiding direction, and meanwhile, the hot and humid air flow is guided in the same direction as the water drops, so that the hot and humid air is output and pushed to flow towards the cooling box 5 at the same time, and the problem that the water drops are impacted and scattered due to the collision of the hot and humid air flows in the dripping direction, so that the water drops are contacted with the hot and humid air flows again to reduce the condensation efficiency of the hot and humid air is avoided; the conversion component 8 at the air outlet of the flow guiding component 7 can convert part of the hot and humid air into common air after being contacted with the hot and humid air flow, namely, air flow with the temperature lower than that of the hot and humid air is formed, and the air flow is conveyed to the air inlet of the flow guiding component 7 through the return pipe 9, so that the subsequent condensation of the hot and humid air is promoted by utilizing the discharge of the hot and humid air flow, the utilization rate of the hot and humid air is improved in the discharge process of the hot and humid air, and the effect of fog dissipation and water saving is achieved.

As shown in fig. 1 to 3, as a preferred embodiment of the present invention, the flow guiding assembly 7 includes:

the air inlet of the inclined part 701 is higher than the air outlet of the inclined part, the air inlet of the inclined part 701 is connected with the air inlet 3 and the ventilation pipe 6 in the condensation chamber 15, and the air outlet of the inclined part 701 is communicated with the cooling box 5; and

the two ends of the vertical part 702 are respectively connected with the air outlet of the inclined part 701 and the air duct, and the conversion component 8 is arranged on the vertical part 702.

In practical application, the hot and humid air enters the air inlet of the inclined part 701 through the ventilation pipe 6 and contacts with the air input by the air inlet 3, water drops are generated by condensation, part of the water drops fall into the cooling box 5, the rest of the water drops rise to the top plate of the inclined part 701 and are condensed, the inclined part 701 is obliquely arranged, the air outlet is lower, and the water drops on the side wall of the inclined part 701 flow along the inclined direction, namely enter the cooling box 5 at the air outlet of the inclined part 701, and in the process, the hot and humid air flow and the water drops flow in the same direction, so that the water drops are not scattered due to the impact of flowing force, and the water drops can be pushed to flow into the cooling box 5, thereby improving the condensation efficiency of the hot and humid air; the condensed air flows along the vertical portion 702 to the wind tunnel and finally exits the cooling tower.

As shown in fig. 1-3, as a preferred embodiment of the present invention, the diversion assembly 7 further includes an auxiliary plate 703 fixed on the cooling box 5, and the auxiliary plate 703 is located below the top plate of the inclined portion 701 and is arranged parallel to the inclined portion 701, and a through hole 13 is provided on the cooling box 5 at a position connected to the auxiliary plate 703.

In practical application, the inclined auxiliary plate 703 is added to effectively guide water drops below the inclined portion 701 to flow into the cooling tank 5 through the through hole 13, so as to improve condensing efficiency of hot and humid air.

As shown in fig. 1 to 4, as a preferred embodiment of the present invention, the conversion assembly 8 includes:

a rotation shaft 801 rotatably installed on a sidewall of the vertical portion 702; and

the fan blades 802, a plurality of the fan blades 802 are circumferentially arranged on the rotating shaft 801, and the rotating shaft 801 interferes with the air flow in the vertical portion 702.

In one case of the present embodiment, the fan blades 802 have an inclined angle, and can generate wind when rotated; the fan blade 802 is provided with a water absorbing member 803.

In practical application, the condensed air flow can strike the fan blades 802 in the process of flowing to the wind barrel through the vertical part 702, and then the fan blades 802 drive the rotating shaft 801 to rotate, so that wind is generated, and the wind is conveyed to the air inlet of the flow guiding assembly 7 through the return pipe 9, and the condensation of the hot and humid air is promoted because the temperature of the wind is lower than that of the hot and humid air, so that the pre-condensation of the subsequent hot and humid air is promoted by utilizing the partial circulation of the discharged hot and humid air; the water absorbing member 803 is provided to effectively absorb moisture in the air to be discharged, and reduce smoke generated during discharge.

As shown in fig. 1 to 5, as a preferred embodiment of the present invention, a circulating cooling pipe 11 is provided in the inclined portion 701, and the cooling pipe 11 is connected to a cooling water tank and a water pump.

In one case of the present embodiment, the cooling pipe 11 is provided with a bent portion, and the bent portion is located in the cooling tank 5; the bending part is communicated with the cooling box 5, and a second one-way valve 12 is arranged at the communicating part.

In practical application, the cooling water is circulated in the cooling pipe 11, so that the condensation temperature in the inclined part 701 and the cooling tank 5 can be raised, the condensed water in the cooling tank 5 can only enter the bent part due to the arrangement of the second one-way valve 12, and the cooling water in the cooling pipe 11 cannot flow to the cooling tank 5, thereby realizing the reutilization of the condensed water and further achieving the water-saving effect.

The working principle of the invention is as follows: in the embodiment of the invention, the condensed air flow is sent into the diversion component 7 through the ventilation pipe 6 and is guided to move towards the wind barrel in the diversion component 7, in the process, cold air introduced by the air inlet 3 in the condensation chamber 15 is contacted with hot and humid air to condense the air, part of water drops formed after condensation directly fall into the cooling box 5, other water drops rise to the top plate of the diversion component 7 and flow towards the cooling box 5 in the guiding direction, and meanwhile, the hot and humid air flow is guided in the same direction as the water drops, so that the hot and humid air flow can be output and simultaneously pushed to flow towards the cooling box 5, and the problem that the water drops are impacted and scattered due to the collision of the hot and humid air flows in the dripping direction is avoided, so that the water drops are contacted with the hot and humid air flows again to reduce the condensing efficiency of the hot and humid air is avoided; the conversion component 8 at the air outlet of the flow guiding component 7 can convert part of the hot and humid air into common air after being contacted with the hot and humid air flow, namely, air flow with the temperature lower than that of the hot and humid air is formed, and the air flow is conveyed to the air inlet of the flow guiding component 7 through the return pipe 9, so that the subsequent condensation of the hot and humid air is promoted by utilizing the discharge of the hot and humid air flow, the utilization rate of the hot and humid air is improved in the discharge process of the hot and humid air, and the effect of fog dissipation and water saving is achieved.

The foregoing describes one embodiment of the present invention in detail, but the description is only a preferred embodiment of the present invention and should not be construed as limiting the scope of the invention. All equivalent changes and modifications within the scope of the present invention are intended to be covered by the present invention.

Claims

1. An defogging water conservation cooling tower, comprising:

the device comprises a spray pipe (1), a heat exchange chamber (14) arranged below the spray pipe, a condensing chamber (15) arranged above the spray pipe (1), a filler (4) arranged in the heat exchange chamber (14), a water collecting tank (2) arranged below the filler (4) and a plurality of air inlets (3) arranged in the heat exchange chamber (14) and the condensing chamber (15);

characterized in that the cooling tower further comprises:

the cooling box (5) is fixed on the inner wall of the condensing chamber (15), and two ventilation pipes (6) are arranged on the cooling box in a penetrating way, and the ventilation pipes (6) are communicated with the condensing chamber (15) and the heat exchange chamber (14);

the guide assemblies (7) are arranged in the condensing chamber (15), the two guide assemblies (7) are respectively connected with the two ventilation pipes (6), the two guide assemblies (7) are communicated with the air cylinders arranged at the top of the cooling tower and are communicated with the cooling box (5), and when the damp and hot air enters the condensing chamber (15) through the ventilation pipes (6), the guide assemblies (7) guide the damp and hot air flow to have the same water drip direction generated by condensation of the damp and hot air flow; and

the conversion assembly (8) is arranged between the guide assemblies (7) and the air cylinders in the condensing chamber (15), two conversion assemblies (8) are respectively connected with air outlets of the two guide assemblies (7), the conversion assembly (8) is connected with an air inlet of the guide assemblies (7) through a return pipe (9), and a first one-way valve (10) is arranged on the return pipe (9).

2. An anti-fog water-saving cooling tower according to claim 1, characterized in that the deflector assembly (7) comprises:

the air inlet of the inclined part (701) is higher than the air outlet of the inclined part, the air inlet of the inclined part is connected with the air inlet (3) in the condensing chamber (15) and the ventilation pipe (6), and the air outlet of the inclined part (701) is communicated with the cooling box (5); and

and the two ends of the vertical part (702) are respectively connected with the air outlet of the inclined part (701) and the air duct, and the conversion component (8) is arranged on the vertical part (702).

3. An anti-fog water-saving cooling tower according to claim 2, wherein the diversion assembly (7) further comprises an auxiliary plate (703) fixed on the cooling box (5), the auxiliary plate (703) is located below the top plate of the inclined part (701) and is arranged parallel to the inclined part (701), and a through hole (13) is arranged on the cooling box (5) at a position connected with the auxiliary plate (703).

4. An anti-fog water-saving cooling tower according to claim 2, characterized in that said conversion assembly (8) comprises:

a rotating shaft (801) rotatably mounted on a side wall of the vertical portion (702); and

the fan blades (802) are circumferentially arranged on the rotating shaft (801), and the rotating shaft (801) is interfered with the air flow in the vertical part (702).

5. An anti-fog water-saving cooling tower according to claim 4, wherein the fan blades (802) are provided with water absorbing members (803).

6. The defogging water-saving cooling tower according to claim 2, wherein a circulating cooling pipe (11) is arranged in the inclined portion (701), and the cooling pipe (11) is connected with a cooling water tank and a water pump.

7. An anti-fog water-saving cooling tower according to claim 6, characterized in that the cooling pipe (11) is provided with a bending part, and the bending part is located in the cooling tank (5).

8. An anti-fog water-saving cooling tower according to claim 7, characterized in that the bending part is communicated with the cooling tank (5), and a second one-way valve (12) is arranged at the communication position.