CN213179521U - Cooling tower with condensation wing plates arranged in three-dimensional staggered manner - Google Patents

Abstract

The utility model provides a cooling tower with three-dimensional staggered condensation wing plates, which comprises a tower body, an air exhaust device, a heat exchange device and a water distribution device, wherein the tower body comprises a cooling part, an air exhaust part and a water pool, the air exhaust device comprises an air exhaust fan, the cooling part is provided with a water inlet hole, an air inlet hole and a louver hole, the water distribution device comprises a water inlet pipe arranged on the water inlet hole and a water distribution plate arranged on the inner wall of the air exhaust part, the heat exchange device comprises a louver arranged in the louver hole, an installation boss arranged above the louver and a fog dissipation water-saving component arranged on the installation boss, the fog dissipation water-saving component comprises an upper layer pipe and a lower layer pipe which are arranged at intervals, the upper layer pipe is communicated with the louver, the upper layer pipe is arranged on the installation boss, the upper layer pipe is arranged above the lower layer pipe, the environment air of cooling liquid carries out secondary heat exchange with the environment air, the cooling liquid is cooled, and the purposes of reducing water mist and saving water can be achieved.

Description

Cooling tower with condensation wing plates arranged in three-dimensional staggered manner

Technical Field

The utility model relates to a cooling tower technical field especially relates to a three-dimensional staggered arrangement's of condensation pterygoid lamina cooling tower.

Background

When using the condensing tower to cool down liquid, the liquid that needs the cooling is when with the ambient air heat transfer, and the part becomes steam and follows ambient air and continuously rises, forms supersaturated gas promptly and continuously rises, and when above-mentioned outside the condensing tower, forms white fog after the supersaturated gas cooling, and simultaneously, white fog can invade equipment such as cooling blower, causes corrosion damage to equipment, simultaneously, can lead to liquid loss, resources are wasted during the water smoke is discharged.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is: when the liquid is cooled, a large amount of water mist is generated, and the liquid is wasted.

The utility model provides a technical scheme that its technical problem adopted is: a cooling tower with condensation wing plates arranged in a three-dimensional staggered manner comprises a tower body, an exhaust device arranged in the tower body, a heat exchange device arranged below the exhaust device and a water distribution device arranged in the tower body, wherein the tower body comprises a cooling part, an exhaust part arranged at the upper end of the cooling part and a water pool arranged at the lower end of the cooling part, the exhaust device comprises an exhaust fan arranged in the exhaust part, the cooling part is provided with a water inlet hole, an air inlet hole and louver holes, the water distribution device comprises a water inlet pipe arranged on the water inlet hole and a water distribution plate arranged on the inner wall of the exhaust part, the heat exchange device comprises a louver arranged in the louver holes, an installation boss arranged above the louver and a fog-eliminating water-saving assembly arranged on the installation boss, and the fog-eliminating water-saving assembly comprises an upper pipe and a lower pipe which are arranged at intervals, the upper layer pipe is communicated with the shutter, the upper layer pipe is installed on the installation boss, and the upper layer pipe is installed above the lower layer pipe.

Further, the upper-layer pipe is a tubular mechanism with two through ends, the lower-layer pipe is of a solid tubular structure, and a gap is reserved between the upper-layer pipes.

Furthermore, the water distribution plate is arranged below the water inlet hole, the water distribution device further comprises a condensation filler arranged on the inner wall of the air exhaust part, and the condensation filler is arranged below the water distribution plate.

Furthermore, the exhaust device also comprises a vortex street air mixer arranged above the water distribution plate, and the vortex street air mixer can mix heat in ambient air for distribution.

Furthermore, the exhaust device also comprises a driving motor arranged at the top end of the cooling part, and the driving motor can control the rotation of the exhaust fan.

Furthermore, the exhaust device also comprises a support rod arranged in the pool, and the exhaust fan is fixedly arranged at the end part of the support rod far away from the pool.

Furthermore, the inlet opening sets up the below of fresh air inlet, the tripe hole sets up the top of fresh air inlet.

Furthermore, heat transfer device is still including setting up the installation boss of tripe hole top, the upper tube is installed on the installation boss, the installation boss orientation the axle center setting of tower body.

The beneficial effects of the utility model are that, set up fog dispersal water conservation subassembly in the cooling portion in the tower body, upper strata pipe and lower floor's pipe interval among the fog dispersal water conservation subassembly set up, and upper strata pipe and lower floor's pipe layering from top to bottom, upper strata pipe extracts other ambient air from the shutter, when oversaturated air passes through upper strata pipe, take place heat exchange between ambient air and the oversaturated air, after the oversaturated air cools down, wherein water smoke content reduces, a large amount of water smoke condenses into the water droplet and adheres to on lower floor's pipe, thereby reduce water smoke content in the high temperature air, reach the purpose of fog dispersal water conservation.

Drawings

The present invention will be further explained with reference to the drawings and examples.

FIG. 1 is a schematic view of the internal structure of the cooling tower of the present invention;

FIG. 2 is a perspective view of the defogging and water saving assembly of FIG. 1;

FIG. 3 is a top view of the fog dispersal water conservation assembly shown in FIG. 2;

in the figure:

cooling tower 100 tower body 10 exhaust device 20

Cooling part 110 of water distribution device 40 of heat exchange device 30

Air inlet hole 111 of air exhaust part 120 pool 130

Inlet opening 112 drive motor 210 exhaust fan 220

Condensation packing 420 of water inlet pipe 410 of support rod 230

Louver holes 113 of water distribution plate 430 vortex street air mixer 210

Mounting boss 320 of shutter 310 fog dispersal water saving assembly 330

Upper tube 331 and lower tube 332

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present invention, and should not be construed as limiting the present invention. On the contrary, the embodiments of the invention include all changes, modifications and equivalents coming within the spirit and terms of the claims appended hereto.

As shown in fig. 1 to 3, the present invention provides a cooling tower 100 with three-dimensional staggered condensation wing plates, wherein the cooling tower 100 comprises a tower body 10, an exhaust device 20 installed in the tower body 10, a heat exchange device 30 disposed below the exhaust device 20, and a water distribution device 40 disposed in the tower body 10.

The tower body 10 includes a cooling portion 110 and an air exhaust portion 120 installed at the top of the cooling portion 110, a water tank 130 is disposed at the bottom of the cooling portion 110, the air exhaust portion 120 and the water tank 130 are integrally formed, the cross section of the air exhaust portion 120 is smaller than that of the cooling portion 110, and an air inlet hole 111 and an air inlet hole 112 are formed in the side wall of the cooling portion 110. The water inlet 112 is arranged above the air inlet 111, liquid to be cooled enters the cooling part 110 from the water inlet 112, is sprayed and recovered into the water tank 130, ambient air at normal temperature enters from the air inlet 111 and is discharged from the air exhaust part 120, heat exchange occurs between the ambient air and the liquid to be cooled when the ambient air flows in the cooling part 110, and the temperature of the liquid is gradually reduced to be close to the temperature of the ambient air in the process that the liquid drops into the water tank 130.

The exhaust device 20 includes a driving motor 210 provided at the top of the cooling part 110, an exhaust fan 220 provided in the exhaust part 120, and a support rod 230 fixed in the sump 130. The supporting rod 230 is arranged to observe the water tank 130 and the cooling portion 110, the exhaust fan 220 is installed on the supporting rod 230 at an end portion far away from the water tank 130, and the driving motor 210 can drive the exhaust fan 220 to operate, and it can be understood that after the driving motor 210 is started, the exhaust fan 220 exhausts supersaturated air in the tower body 10, where the supersaturated air refers to air with excessive humidity and heavy mist. The inside of the tower body 10 is in a relatively negative pressure state, and the ambient air enters the tower body 10 through the air inlet holes 112, thereby ensuring the real-time supply amount of the ambient air in the tower body 10.

The water distribution device 40 includes a water inlet pipe 410 installed on the water inlet hole 112, a condensation packing 420 installed on an inner wall of the exhaust part 120, and a water distribution plate 430 disposed between the condensation packing 410 and the water inlet pipe 410. The water inlet pipe 410 is communicated with the water pump, liquid needing to be cooled is discharged into the cooling part 110 through the water inlet pipe 310 under the suction action of the water pump, the liquid flows onto the water distribution plate 430, the liquid can be uniformly dispersed onto the surface of the condensing filler 410 under the action of the water distribution plate 430, the contact time of the liquid and ambient air is prolonged through the interception of the condensing filler 410, and the cooling efficiency of the liquid is improved.

Preferably, the exhaust device 20 further includes a vortex street air mixer 210 disposed above the water distribution plate 430, and after the ambient air passes through the water distribution plate 430, the ambient air can be absorbed by the vortex street air mixer 210, and the ambient air is fully stirred and mixed by using the karman vortex street principle, so that uniform cooling and heating distribution in the ambient air is achieved.

The side wall of the cooling part 110 is also opened with a louver hole 113, and the heat exchanging device 30 comprises a louver 310 installed in the louver hole 113, an installation boss 320 installed above the louver 310, and a fog dispersal water saving assembly 330 installed on the installation boss 320.

The louver 310 is covered on the opening of the louver hole 113, the mounting boss 320 is arranged above the louver hole 113, the mounting boss 320 is arranged towards the inside of the cooling part 110, the mounting boss 320 is arranged between the louver hole 113 and the water distribution plate 430, and the mounting boss 320 is covered above the vortex street air mixer 210.

The fog dispersal water saving assembly 330 comprises an upper layer pipe 331 and a lower layer pipe 332, wherein the upper layer pipe 331 and the lower layer pipe 332 are both of open hollow tubular structures, the upper layer pipe 331 is fixedly installed on the installation boss 320, the lower layer pipe 331 is fixedly connected with the upper layer pipe 332, the upper layer pipe 331 and the lower layer pipe 332 are multiple, the upper layer pipe 331 and the lower layer pipe 332 are arranged at intervals, the upper layer pipe 331 is arranged above the lower layer pipe 332, the upper layer pipe 331 and the lower layer pipe 332 are communicated with the louver 310, and both the upper layer pipe 331 and the lower layer pipe 332 can be communicated to the interior of the cooling part 110. Gaps are left between the adjacent upper-layer tubes 331 and between the adjacent lower-layer tubes 332, and air in the cooling unit 110 can flow from between the upper-layer tubes 331 and the lower-layer tubes 332 to the exhaust unit 120.

It is understood that the ambient air is reintroduced into the cooling part 110 through the louvers 310, heat exchange occurs between the high temperature air of the cooling liquid in the cooling part 110 and the ambient air in the upper pipe 331, the temperature of the high temperature air decreases, moisture in the high temperature air is more condensed, the weight of moisture in the high temperature air increases, and most of the moisture is condensed on the lower pipe 332 until being collected and dropped into the sump 130.

The cooling tower 100 is used by injecting a liquid to be cooled into the cooling portion 110 of the tower 10 through the water inlet pipe 410, the liquid is shunted by the water distribution plate 430 and drops onto the condensation filler 420, the liquid drops along the inner wall of the condensation filler 420 and gathers in the water tank 130, the ambient air enters the cooling portion 110 of the tower 10 through the air inlet holes 111 and the louver holes 113 under the suction action of the exhaust fan 220, the air entering from the air inlet holes 111 exchanges heat with the liquid in the condensation filler 420 to become high-temperature gas, the high-temperature gas carries part of the atomized liquid to form high-temperature water mist due to the contact between the high-temperature gas and the liquid, the gas carrying the high-temperature water mist carries out heat exchange with the ambient gas in the upper-layer pipe 331 before entering the exhaust portion 120 and passing through the gap between the upper-layer pipe 331, the temperature of the high-temperature gas is reduced, and more moisture in the gas is condensed, the liquid is collected along the lower pipe 332 and flows into the water tank 130, and the remaining gas is discharged out of the tower body 10 by the exhaust fan 220.

In the above-mentioned use process, the upper layer pipe 331 and the lower layer pipe 332 are arranged in a staggered manner, a sufficiently large gap is formed, high-temperature and fog-rich gas can rapidly pass through the upper layer pipe 331, and when passing through the gap, the gas is cooled for the second time, liquid in the gas is cooled and condensed in the lower layer pipe 332, and the gas drops into the water tank 130 along the side wall of the lower layer pipe 332, so that condensation and recovery of fog in the high-temperature gas are realized, and meanwhile, generation of fog in the gas is reduced.

In light of the foregoing, it will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (8)

1. A cooling tower with three-dimensional staggered condensation wing plates is characterized in that: the tower comprises a tower body, an exhaust device arranged in the tower body, a heat exchange device arranged below the exhaust device and a water distribution device arranged in the tower body, wherein the tower body comprises a cooling part, an exhaust part arranged at the upper end of the cooling part and a water pool arranged at the lower end of the cooling part, the exhaust device comprises an exhaust fan arranged in the exhaust part, the cooling part is provided with a water inlet hole, an air inlet hole and a louver hole, the water distribution device comprises a water inlet pipe arranged on the water inlet hole and a water distribution plate arranged on the inner wall of the exhaust part, the heat exchange device comprises a louver arranged in the louver hole, an installation boss arranged above the louver and a fog-eliminating water-saving assembly arranged on the installation boss, the fog-eliminating water-saving assembly comprises an upper layer pipe and a lower layer pipe which are arranged at intervals, and the upper layer pipe is communicated with the louver, and the upper layer pipe is arranged on the mounting boss, and the upper layer pipe is arranged above the lower layer pipe.

2. The cooling tower with three-dimensional staggered condensation wings as claimed in claim 1, wherein: the upper-layer pipe is a tubular mechanism with two penetrating ends, the lower-layer pipe is of a solid tubular structure, and a gap is reserved between the upper-layer pipes.

3. The cooling tower with three-dimensional staggered condensation wings as claimed in claim 1, wherein: the water distribution plate is arranged below the water inlet hole, the water distribution device further comprises a condensation filler arranged on the inner wall of the air exhaust part, and the condensation filler is arranged below the water distribution plate.

4. The cooling tower with three-dimensional staggered condensation wings as claimed in claim 1, wherein: the exhaust device also comprises a vortex street air mixer arranged above the water distribution plate, and the vortex street air mixer can mix heat in ambient air for distribution.

5. The cooling tower with three-dimensional staggered condensation wings as claimed in claim 1, wherein: the exhaust device also comprises a driving motor arranged at the top end of the cooling part, and the driving motor can control the exhaust fan to rotate.

6. The cooling tower with three-dimensional staggered condensation wings as claimed in claim 1, wherein: the air exhaust device further comprises a support rod arranged in the pool, and the air exhaust fan is fixedly arranged at the end part, far away from the pool, of the support rod.

7. The cooling tower with three-dimensional staggered condensation wings as claimed in claim 1, wherein: the water inlet hole is arranged below the air inlet hole, and the louver holes are arranged above the air inlet hole.

8. The cooling tower with three-dimensional staggered condensation wings as claimed in claim 1, wherein: the heat exchange device further comprises an installation boss arranged above the louver hole, the upper-layer pipe is installed on the installation boss, and the installation boss faces towards the axis of the tower body.

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