CN215572278U

CN215572278U - Fog dispersal device and cooling tower

Info

Publication number: CN215572278U
Application number: CN202121389615.XU
Authority: CN
Inventors: 李金鹏; 陈良才; 林振兴; 李进; 刘岩; 孙刚; 刘敏; 杜娟
Original assignee: Shandong Beno Cooling Equipment Co ltd
Current assignee: Shandong Beno Cooling Equipment Co ltd
Priority date: 2021-06-22
Filing date: 2021-06-22
Publication date: 2022-01-18
Anticipated expiration: 2031-06-22

Abstract

The utility model relates to the technical field of cooling towers, in particular to a fog dissipation device. This fog dispersal device includes: the first flow path and the second flow path are stacked and are used for carrying out heat exchange on the first airflow and the second airflow flowing from bottom to top; the inflow side of the first flow path is formed at one side of the width direction of the fog dispersal device, and the outflow side of the first flow path is formed at the top of the fog dispersal device; the inflow side of the second flow path is formed at the bottom of the fog dispersal device, and the outflow side of the second flow path is formed at the top of the fog dispersal device; and a flow guide structure which is used for guiding the first airflow to the range of the full width of the fog dispersal device is formed in the first flow path, and the flow guide structure comprises a plurality of first flow guide convex edge parts. The fog dispersal device can play the roles of water saving and fog dispersal. The cooling tower comprises the fog dispersal device.

Description

Fog dispersal device and cooling tower

Technical Field

The utility model relates to a cooling tower, in particular to a cooling tower with water-saving and fog-dispersing requirements.

Background

In a cooling tower of the prior art, an air mixing section, a water collecting mist capturing section, a spraying section, a heat exchanging section, an air inflow port, and a water collecting section are provided in the cooling tower body in this order from top to bottom. The upper part of the body is provided with an exhaust part which comprises an air duct and an induced draft fan arranged in the air duct. And spraying water from the spraying part to the heat exchange part, wherein the heat exchange part is formed by laminating a plurality of filler sheets, the sprayed water flows from top to bottom, and on the other hand, air is sucked into the cooling tower from an air inlet at the lower part of the cooling tower, flows from bottom to top and transfers heat and mass with the sprayed hot water, so that the temperature of the hot water is reduced.

And the air after the heat exchange with the water is discharged from the wind barrel of the cooling tower. The discharged air is saturated humid air, and after the air is mixed with cold air outside the tower, the temperature is reduced, the saturated moisture content is reduced, and then supersaturated water vapor can be condensed into mist. Particularly in winter in high latitude areas, the exhaust of the cooling tower can form dense fog, further rain and snow fall, the environment is adversely affected, and more seriously, the equipment and the ground are frozen to form freeze injury.

Chinese patent CN106225507B discloses a condensation type fog dispersal water saving fixtures, including the main tower, the main tower bilateral symmetry of institute is equipped with two sets of auxiliary towers, the auxiliary tower is located the upper portion of main tower both sides, and every group auxiliary tower is hugged closely the side wall of main tower by a plurality of axial fan and tube bundle body and arranges side by side and forms, the auxiliary tower arrange for double multiseriate or arrange for single row two, the inclined end of auxiliary tower and the main tower lateral wall through connection that the slope set up are passed through to the auxiliary tower bottom. The utility model has the advantages of solving the problems of incomplete demisting, water saving, large additional resistance, seriously weakened capacity of the original open cooling tower and the like of the existing demisting device of the open cooling tower. However, the above technical solutions have the following problems:

on one hand, the auxiliary towers are arranged on two sides of the main tower, and the fans are additionally arranged, so that when the auxiliary towers are required to be defogged, more fan energy is consumed for pushing air to pass through the tube bundle body, the operation cost of the cooling tower is obviously increased, the main tower fans inevitably have influence on the hot and humid air suction of the auxiliary tower fans, and the energy consumption of the auxiliary tower fans is further increased; on the other hand, external dry cold air enters the main tower after absorbing heat through the transverse channel and flows out upwards to form a dry warm air group, hot and humid air enters the module from the lower part of the module, the wet warm air flows out continuously and converges into a wet warm air group after releasing heat, reducing temperature and condensing water, and in order to ensure the fog dissipation effect, the dry warm air and the wet warm air need to be uniformly mixed to reduce the moisture content and become an unsaturated state. The amount of the dry warm air group and the wet warm air group is large, and if the dry warm air group and the wet warm air group are mixed uniformly, the dry warm air group and the wet warm air group need to flow upwards for a long distance, namely, a high mixing space needs to be provided above the module. Therefore, the cooling tower is significantly increased in height and cost. However, the height of the old tower cannot be increased.

SUMMERY OF THE UTILITY MODEL

The present invention has been made in view of the above problems, and provides a mist eliminator which performs a function of saving water and eliminating mist by exchanging heat between air subjected to heat exchange with water and outside cold air which flows into a cooling tower and does not exchange heat with the air in the mist eliminator, and a cooling tower.

In order to achieve the above technical object, an embodiment of the present invention provides a fog dispersal device, including: the first flow path and the second flow path are stacked and are used for carrying out heat exchange on the first airflow and the second airflow flowing from bottom to top; the inflow side of the first flow path is formed at one side of the width direction of the fog dispersal device, and the outflow side of the first flow path is formed at the top of the fog dispersal device; the inflow side of the second flow path is formed at the bottom of the fog dispersal device, and the outflow side of the second flow path is formed at the top of the fog dispersal device; and a flow guide structure which is used for guiding the first airflow to the range of the approximate full width of the fog dispersal device is formed in the first flow path, and the flow guide structure comprises a plurality of first flow guide convex edge parts.

Further, the fog dispersal device comprises a first fog dispersal sheet and a second fog dispersal sheet which limit the first flow path and the second flow path, wherein the first fog dispersal sheet and the second fog dispersal sheet are alternately stacked.

Furthermore, a plurality of downstream cavities are formed among the first flow guide convex edge parts, and the downstream cavities approximately occupy half of the fog dispersal device.

Furthermore, an inlet for the first airflow to flow into is formed on the inflow side of the downstream cavity, and the distance between a plurality of inlets gradually increases from one side edge to the other side edge in the width direction of the mist eliminator.

Furthermore, the outflow side of the downstream cavity is provided with a guide outlet for the first airflow to flow out, and the width of the guide outlets is gradually increased from one side edge of the width direction of the fog dispersal device to the other side edge.

Further, the first guide rib portion is formed substantially in an arc shape with a notch side facing the first flow path outflow side.

Further, the first flow guiding rib is formed by forming a first flow guiding rib protruding to one side of the stacking direction on the surface of the first fog dispersal sheet; and a second flow guide convex edge corresponding to the first flow guide convex edge is formed on the surface of the second fog dispersal sheet, and the ridge top of the first flow guide convex edge is hermetically connected with the ridge top of the second flow guide convex edge.

Furthermore, the flow guide structure further comprises a second flow guide convex edge part formed in the first flow passage, and a flow passage for air flow to pass through is formed between the second flow guide convex edge part and the first flow guide convex edge part close to the inflow side of the first flow passage.

Furthermore, a plurality of flow dividing convex edge parts are arranged in the first flow path and above the second flow guiding convex edge part; the diversion rib part is formed by forming a first diversion rib on the surface of the first fog dispersal sheet; and a second shunting ridge is formed on the surface of the second antifogging sheet, and the ridge top of the first shunting ridge is connected with the ridge top of the second shunting ridge in a sealing manner.

Another aspect of the present invention provides a cooling tower comprising the fog dispersal device as defined in any of the above claims.

One or more technical solutions provided in the embodiments of the present invention have at least the following technical effects or advantages:

the flow guide structure is arranged in the first flow path, so that the first airflow flowing in through the first flow inlet can be guided to the range of the approximate full width of the fog dispersal device, the heat exchange efficiency is increased, and the fog dispersal effect is improved.

Drawings

FIG. 1 is a sectional elevation view of a cooling tower in an embodiment of the present invention;

FIG. 2 is a partial perspective view of an embodiment of the mist eliminator;

FIG. 3 is a flow diagram of the gas flow in the first flow path in an embodiment of the present invention;

FIG. 4 is a front perspective view of a first anti-fogging patch in an embodiment of the present invention;

fig. 5 is a rear perspective view of a second anti-fogging sheet in an embodiment of the present invention.

Description of the reference numerals

1000-cooling tower; 1010 a body; 1020 an exhaust part; 1021 an air duct; 1022 of the induced draft fan; 1100 an air mixing part; 1200 a spray part; 1300 a heat exchanging section; 1400 an air flow inlet; 1500 water collecting part; 1600 fog dispersal parts; 1211 a spray head; 1700 cold air inlet;

1601. 1602 a fog dispersal device; A. a' a first fog dispersal sheet; B. b' a second fog dispersal sheet; a1, a2, A3, B1, B2, B3 offset;

1610 a first inlet; 1620 a second inlet port; 1630 a first outlet port; 1640 a second outflow port; 1651A, 1651B ribs; 1652A first flow-guiding ridge; 1652B second flow-guiding ridge; 1653A third flow-directing ridge; 1653B a fourth flow-directing ridge; 1654A a flow splitting section; 1654B a flow splitting section; 1660 a downstream chamber; 1670 introducing port; 1680 leading out the opening; 1690 flow channel.

Detailed Description

Other objects and advantages of the present invention will become apparent by the following explanation of preferred embodiments of the present invention.

Fig. 1 shows a schematic structure of each part in a cooling tower 1000 according to the present embodiment.

Fig. 1 is a schematic configuration diagram of a cooling tower 1000 according to a first embodiment of the present invention. As shown in fig. 1, an air mixing unit 1100, a mist eliminating unit 1600, a shower unit 1200, a heat exchanging unit 1300, an air inlet 1400, and a water collecting unit 1500 are provided in a main body 1010 of a cooling tower 1000 from top to bottom. An exhaust part 1020 is provided at an upper portion of the body 1010, and the exhaust part 1020 includes an air duct 1021 and an induced draft fan 1022 provided in the air duct 1021. An air inlet through which external cold air flows is formed at a lower portion of the body 1010, and the external cold air sequentially passes through the heat exchanging part 1300 and the shower part 1200.

According to the cooling tower 1000, the plurality of sets of nozzles 1211 disposed above the shower portion 1200 shower hot water downward, and the hot water drops in the internal space of the shower portion 1200 and enters the heat exchange portion 1300. In the heat exchanger 1300, hot water is heat-exchanged with cold air flowing in from the bottom of the heat exchanger 1300, flows out from the bottom of the heat exchanger 1300, passes through the air inlet 1400, falls to the water collector 1500, and is collected from the bottom of the main body 1010 of the cooling tower 1000. The heat exchange portion 1300 may employ conventional packing sheets. A louver may be disposed at the air inlet 1400, and the amount of dry cold air flowing from the air inlet 1400 is adjusted by adjusting the size of the louver, so as to adjust the amount of hot and humid air entering the fog

dispersal devices

1601, 1602, and adjust the fog dispersal effect. For example, when the ambient temperature is low, the air inlet of the louver can be adjusted to be small, so that the amount of dry and cold air flowing into the cold air inlet 1700 is relatively large, and the fog dissipation effect is enhanced.

Thus, dry and cold air outside the tower can enter the defogging unit 1600 through the side surface of the cooling tower 1000, and flow through the first flow paths of the

defogging devices

1601 and 1602 to the air mixing unit 1100; the dry cool air flowing in from the air inlet 1400 flows through the heat exchange unit 1300 for spraying hot water to contact with the hot water and exchange heat to form hot and humid air, and the hot and humid air also flows upward to the second flow channels of the fog

dispersal devices

1601, 1602 to the air mixing unit 1100 to be mixed with the dry cool air, and after mixing, the hot and humid air is changed from a saturated state to an unsaturated state, and is discharged out of the cooling tower 1000 without fog, thereby realizing fog dispersal. In the present embodiment, the existing structure of the cooling tower 1000 is utilized, and compared with the prior art, no new fan is added, thereby further reducing the energy consumption of the cooling tower 1000.

In the

defogging devices

1601 and 1602, when the hot and humid air in the second flow path contacts the cold surface of the first flow path, condensed water droplets are formed on the surface of the second flow path. These water droplets are the result of condensation of the hot humid gas, which results in a reduction of water vapour in the hot humid gas. The condensed water drops back to the water collecting part 1500, and water saving is achieved. The fog dispersal portion 1600 may include two fog

dispersal devices

1601, 1602, two fog

dispersal devices

1601, 1602 are arranged in the horizontal direction relatively, and the air intake of dry and cool wind sets up dorsad. The density of the dry warm air and the wet warm air in the

fog dissipation devices

1601 and 1602 is smaller than that of the ambient air, so that the dry warm air and the wet warm air can be subjected to buoyancy, and the upward movement of the dry warm air and the upward movement of the wet warm air are promoted. The outflow direction of the dry warm air and the wet warm air is consistent with the buoyancy direction, so that the buoyancy effect can be fully exerted, the suction force required by the induced draft fan 1022 can be relatively reduced, and the reduction of the operation energy consumption is facilitated.

Next, the mist eliminator 1601 of the present embodiment will be described by taking the mist eliminator 1601 (either one of the mist eliminators 1601, 1602) as an example.

Fig. 2 shows that the fog dispersal device 1601 is formed by stacking a plurality of fog dispersal sheets, and the length of the fog dispersal device 1601 can be changed by increasing or decreasing the number of stacked fog dispersal sheets.

The defogging device 1601 includes a first inlet 1610, a second inlet 1620, a first outlet 1630, and a second outlet 1640. Wherein, the first inlet 1610 is communicated with an air inlet on the side wall of the cooling tower 1000; the second inlet 1620 is in communication with the space in the column. The first and

second outlet ports

1630 and 1640 are both in communication with the air mixing section 1100. The first inlet 1610 introduces a first airflow flowing from one side in the width direction of the defogging device 1601 into the first flow path, and the first outlet 1630 discharges the first airflow flowing out of the first flow path above the defogging device 1601; the second inlet 1620 introduces the second airflow flowing in from the bottom of the defogging device 1601 into the second flow path, and the second outlet 1650 discharges the second airflow flowing out from the second flow path to the upper side of the defogging device 1601.

In the present embodiment, the first outlet 1630 and the second outlet 1640 are alternately arranged, and the first and

second outlets

1630 and 1640 are thinner in the stacking direction of the defogging sheets, so that the first airflow flowing out through the first outlet 1630 and the second airflow flowing out through the second outlet 1640 can be quickly and uniformly mixed, and the defogging effect is enhanced. In the present embodiment, the first channel and the second channel are stacked and occupy substantially the entire width of the mist eliminator 1601. The dry and cold air enters the fog dispersal device 1601 to absorb heat and raise temperature to become dry and warm air. The damp and hot air enters the fog dispersal device 1601 to release heat and cool to become damp and warm air. The flow directions of the wet heating air and the dry warm air outlet are consistent; the cross section of the outlet of each channel is wide and thin, so that the outlet of the dry warm air is in a wide and thin air curtain, and the outlet of the wet warm air is in a wide and thin air curtain. According to the jet flow theory, the air curtain and the air curtain with the same flow direction and the same width are easy to mix, the required mixing distance is short, the required mixing space is short, the tower height can be reduced, and the cost is saved. The tower crane can adapt to the reconstruction of the old tower without increasing the height, thereby reducing the difficulty of the reconstruction of the old tower.

In the present embodiment, a cool air inlet 1700 is provided on the right side of the defogging device 1601, and the cool air inlet 1700 communicates with the first flow path in the defogging device 1601. The cold air inflow port 1700 penetrates one side wall of the cooling tower 1000 to communicate with the outside air. Therefore, the dry cool air outside the tower can enter the first flow path of the defogging device 1601 through the cool-air inlet 1700 (as indicated by the dashed arrow in fig. 1).

The air flowing in from the air inlet 1400 passes through the heat exchanger 1300 and the shower unit 1200 in this order from bottom to top to become hot humid air, and the hot humid air continues to flow upward and enters the second flow path in the defogging device 1601 (as indicated by solid arrows in fig. 1).

Fig. 4 is a front perspective view of the first defogging sheet a. As shown in fig. 4, when viewed from the front of the first antifogging sheet a, the left edge in the width direction of the first antifogging sheet a is offset from the plane of the base material to the inside of the paper plane to form an offset portion a1, the bottom edge is offset from the plane of the base material to the inside of the paper plane to form an offset portion a2, and the right edge in the width direction of the first antifogging sheet a is offset from the plane of the base material to the outside of the paper plane to form an offset portion A3. Further, a rib 1651A protruding in the paper surface outer direction is formed on the first antifogging sheet a at a position near the left side edge, and the rib 1651A may extend in the height direction of the first antifogging sheet a. The rib 1651A is a continuous long bar shape, but is not limited thereto.

Fig. 5 is a rear perspective view of the second defogging sheet B. As shown in fig. 5, when viewed from the back surface of the second antifogging sheet B, the right side edge in the width direction of the second antifogging sheet B is offset in the direction toward the inside of the paper surface from the plane of the base material to form a offset portion B1; the bottom edge is deviated from the plane of the base material to the inner side of the paper plane to form a deviation part B2; the left side edge of the second antifogging sheet B in the width direction is offset towards the outer side of the paper surface from the plane of the base material to form an offset part B3. Further, a rib 1651B protruding in the paper surface outer direction is formed on the second antifogging sheet B at a position close to the right side edge, and the rib 1651B may extend in the longitudinal direction along the height of the second antifogging sheet B. The rib 1651B is a continuous long bar shape, but is not limited thereto.

Thereby, a first flow path is formed between the first fog dispersal sheet A and the second fog dispersal sheet B; a second flow path is formed between the second fog dispersal sheet B and the first fog dispersal sheet A'; a first flow path … … is formed between the first defogging sheet a 'and the second defogging sheet B'. Thereby, the first channel and the second channel are alternately stacked.

Taking the first flow path formed between the first fog dispersal sheet A and the second fog dispersal sheet B as an example, the deflection part A1 of the first fog dispersal sheet A and the deflection part B1 of the second fog dispersal sheet B are connected in a sealing way to form a sealed continuous part; the deflection part A2 of the first fog dispersal sheet A and the deflection part B2 of the second fog dispersal sheet B are connected in a sealing way to form a sealed continuous part.

Further, taking the second flow path formed between the second defogging sheets B and the first defogging sheets a 'as an example, the ribs 1651A of the first defogging sheets a' and the ribs 1561B of the second defogging sheets B are hermetically connected. Preferably, the rib tops of the ribs 1651A of the first antifogging sheet a' and the rib tops of the ribs 1651B of the second antifogging sheet B may be bonded. The bent portion B3 of the second defogging sheet B and the bent portion A3 of the first defogging sheet a 'are hermetically connected, thereby forming a second flow path between the second defogging sheet B and the first defogging sheet a'.

In order to uniformly distribute the airflow in the first flow path, a flow guide structure for guiding the first airflow to the substantially full width range of the fog dispersal device 1601 is formed in the first flow path; the flow guide structure comprises a plurality of first flow guide convex edge parts.

As shown in fig. 3, a plurality of downstream chambers 1660 are formed between the plurality of first flow guiding convex edges, and the plurality of downstream chambers 1660 occupy approximately half of the fog dispersal device 1601. A plurality of first water conservancy diversion convex edge portions are arranged in proper order, and a plurality of downstream chamber 1660 that form roughly use the diagonal of fog dispersal device 1601 to separate the first flow path for two parts as the boundary, guide the top of fog dispersal device 1601 with first air current evenly distributed, increased heat exchange efficiency, improved fog dispersal efficiency.

Next, a description will be given of an example of the first flow guide ridge portion in the first flow path formed by stacking the first atomizing plate a and the second atomizing plate B.

As shown in fig. 4 and 5, a plurality of first guide ridges 1652A protruding toward one side in the stacking direction are formed on the surface of the first antifogging sheet a, and a plurality of second guide ridges 1652B protruding away from one side in the stacking direction and corresponding to the first guide ridges 1652A one-to-one are formed on the surface of the second antifogging sheet B; the guide rib is formed such that the top of the first guide rib 1652A is hermetically connected to the top of the corresponding second guide rib 1652B. When viewed from the front of the first antifogging sheet a, the first flow guiding protruding edge 1652A protrudes to the inner side of the paper; the top end of the first flow guiding protruding edge 1652A extends towards the top of the first fog dispersal sheet a, and the bottom end extends towards the right side of the first fog dispersal sheet a; the second flow guiding protruding edge 1652B protrudes inward of the paper when viewed from the back of the second antifogging sheet B; the top end of the second guiding protrusion 1652B extends to the top of the second fog dispersal sheet B and extends to the left of the second fog dispersal sheet B. The top of the first flow projection 1652A and the corresponding top of the second flow projection 1652B may be sealed together by adhesive or the like to form a plurality of downstream chambers 1660.

When the airflow enters the downstream cavity 1660, due to the characteristic of "shortcut" of airflow, the outflow rate is larger closer to the right side of the fog dispersal device 1601, so that the airflow resistance entering the downstream cavity 1660 is uneven, and the heat exchange efficiency of the airflow is relatively affected.

As shown in fig. 3, in the mist eliminator 1601 of the present embodiment, an inlet 1670 for the first airflow to flow in is formed on the inflow side of the downstream chamber 1660, and the pitch of the plurality of inlets 1670 gradually increases from one side edge to the other side edge in the width direction of the mist eliminator 1601. The distance between the introducing ports 1670 close to the right side of the fog dispersal device 1601 is smaller, and the flow resistance is larger; the distance between the inlets 1670 near the left side of the fog dispersal device 1601 is larger, and the flow resistance is smaller, so that the airflow flowing in through the inlets 1670 enters the downstream chambers 1660 and flows out uniformly. The outflow side of the downstream chamber 1660 is formed with a plurality of outlet ports 1680 for the outflow of the first airflow, and the width of the plurality of outlet ports 1680 gradually increases from one side edge to the other side edge of the fog dispersal device 1601 in the width direction. The leading-out port 1680 near the right side of the fog dispersal device 1601 has a smaller width and a larger flow resistance; the width of the outlet 1680 close to the left side of the fog dispersal device 1601 is larger, the flow resistance is smaller, and the guide openings 1670 are matched, so that the first airflow flowing in through the guide openings 1640 and flowing out through the outlet 1680 is more uniform in the forward flow cavity 1660, and the heat exchange efficiency of the fog dispersal device 1601 is further improved.

As shown in fig. 3, the first guide rib is formed in an arc shape with the concave side facing the outflow side of the first flow path, so that the first air flow is guided and the collision resistance is reduced.

As shown in fig. 3, the flow guiding structure further includes a second flow guiding convex edge portion formed in the first flow passage, and a flow passage 1690 for an air flow to pass through is formed between the second flow guiding convex edge portion and the first flow guiding convex edge portion close to the inflow side of the first flow passage. As shown in fig. 4 and 5, a third flow guiding ridge 1653A protruding inward of the paper is formed on the surface of the first antifogging sheet a near the right side when viewed from the front; a fourth flow guide protruding edge 1653B protruding toward the inner side of the paper surface is formed on the surface of the area of the second antifogging sheet B near the left side when viewed from the back of the second antifogging sheet B, and the ridge top of the third flow guide protruding edge 1653A and the ridge top of the fourth flow guide protruding edge 1653B are connected in a sealing manner to form a second flow guide protruding edge portion. As shown in fig. 3, the third flow guiding protrusion is formed at the upper right corner of the first flow path, one end of the third flow guiding protrusion extends to the first inlet 1630, and a flow channel 1690 is formed between the other end and the rightmost first flow guiding protrusion. Therefore, the second flow guide convex edge part can block the first airflow from directly short-circuiting and ascending through the first outflow opening 1630, and part of the airflow is guided to the upper right corner of the first flow path through the flow channel 1690, so that the airflow is delayed to flow out, and the heat exchange efficiency at the corner of the fog dispersal device 1601 is enhanced. Preferably, the second guide rib is formed in an arc shape with a concave side facing the first outflow port 1630, so as to facilitate the air flow.

As shown in fig. 3 to 5, a plurality of flow dividing convex edge portions are provided between the second flow guiding convex edge portion and the rightmost first flow guiding convex edge portion, and the plurality of flow dividing convex edge portions are formed such that a plurality of flow dividing sections 1654A protruding toward one side in the stacking direction are formed on the surface of the first defogging sheet a, a plurality of flow dividing sections 1654B protruding away from one side in the stacking direction are formed on the surface of the second defogging sheet B, and the tip end of the flow dividing section 1654A of the first defogging sheet a and the tip end of the flow dividing section 1654B of the second defogging sheet B are hermetically connected. Preferably, the protruded side surface of the flow dividing section 1654A and the protruded side surface of the flow dividing section 1654B are bonded to form a plurality of flow dividing convex edge portions, so that the air flow entering through the flow channel 1690 is guided to be uniformly distributed at the corners of the fog dispersal device 1601, and the heat exchange efficiency is further improved.

The mist eliminator of this invention has been described in detail with reference to preferred embodiments thereof, however, it will be apparent to those skilled in the art that many changes, modifications and variations can be made therein without departing from the spirit of the utility model. The utility model includes the specific embodiments described above and any equivalents thereof.

Claims

1. A fog dispersal device, comprising:

the first flow path and the second flow path are stacked and are used for carrying out heat exchange on the first airflow and the second airflow flowing from bottom to top; the inflow side of the first flow path is formed at one side of the width direction of the fog dispersal device, and the outflow side of the first flow path is formed at the top of the fog dispersal device; the inflow side of the second flow path is formed at the bottom of the fog dispersal device, and the outflow side of the second flow path is formed at the top of the fog dispersal device; and

a flow guide structure which is used for guiding the first airflow to the range of the approximate full width of the fog dispersal device is formed in the first flow path, and the flow guide structure comprises a plurality of first flow guide convex edge parts.

2. Mist dissipating apparatus according to claim 1,

the fog dispersal device comprises a first fog dispersal sheet and a second fog dispersal sheet which limit the first flow path and the second flow path, wherein the first fog dispersal sheet and the second fog dispersal sheet are alternately stacked.

3. Mist dissipating apparatus according to claim 1,

a plurality of downstream cavities are formed among the first flow guide convex edge parts, and the plurality of downstream cavities approximately occupy half of the fog dispersal device.

4. Mist dissipating apparatus according to claim 3,

an inlet for the first airflow to flow in is formed on the inflow side of the downstream cavity, and the distance between the inlets gradually increases from one side edge to the other side edge in the width direction of the fog dispersal device.

5. Mist dissipating apparatus according to claim 3,

and the outflow side of the downstream cavity is provided with a guide outlet for the first airflow to flow out, and the width of the guide outlets is gradually increased from one side edge of the width direction of the fog dispersal device to the other side edge.

6. Mist dissipating apparatus according to claim 1,

the first guide rib portion is formed in an arc shape having a concave side facing the first flow path outflow side.

7. Mist dissipating apparatus according to claim 2,

the first flow guiding convex edge part is formed by forming a first flow guiding convex edge protruding towards one side of the stacking direction on the surface of the first fog dispersing sheet; and a second flow guide convex edge corresponding to the first flow guide convex edge is formed on the surface of the second fog dispersal sheet, and the ridge top of the first flow guide convex edge is hermetically connected with the ridge top of the second flow guide convex edge.

8. Mist dissipating apparatus according to claim 2,

the flow guide structure further comprises a second flow guide convex edge part formed in the first flow channel, and a flow channel for air flow to pass through is formed between the second flow guide convex edge part and the first flow guide convex edge part close to the inflow side of the first flow channel.

9. Mist dissipating apparatus according to claim 8,

a plurality of flow dividing convex edge parts are arranged in the first flow path and above the second flow guiding convex edge parts;

the diversion rib part is formed by forming a first diversion rib on the surface of the first fog dispersal sheet; and a second shunting ridge is formed on the surface of the second antifogging sheet, and the ridge top of the first shunting ridge is connected with the ridge top of the second shunting ridge in a sealing manner.

10. A cooling tower comprising the mist elimination device of any one of claims 1-9.