CN111981864A - Water-saving and power-saving type fog-dissipation cooling tower - Google Patents

Water-saving and power-saving type fog-dissipation cooling tower Download PDF

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Publication number
CN111981864A
CN111981864A CN202010860410.9A CN202010860410A CN111981864A CN 111981864 A CN111981864 A CN 111981864A CN 202010860410 A CN202010860410 A CN 202010860410A CN 111981864 A CN111981864 A CN 111981864A
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China
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water
dry
air
cold air
cooling tower
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Chinese (zh)
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包可羊
来周传
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Hangzhou Fuding Energy Saving Technology Service Co ltd
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Hangzhou Fuding Energy Saving Technology Service Co ltd
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Priority to CN202010860410.9A priority Critical patent/CN111981864A/en
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28CHEAT-EXCHANGE APPARATUS, NOT PROVIDED FOR IN ANOTHER SUBCLASS, IN WHICH THE HEAT-EXCHANGE MEDIA COME INTO DIRECT CONTACT WITHOUT CHEMICAL INTERACTION
    • F28C1/00Direct-contact trickle coolers, e.g. cooling towers
    • F28C1/14Direct-contact trickle coolers, e.g. cooling towers comprising also a non-direct contact heat exchange
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F25/00Component parts of trickle coolers
    • F28F25/02Component parts of trickle coolers for distributing, circulating, and accumulating liquid
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F25/00Component parts of trickle coolers
    • F28F25/02Component parts of trickle coolers for distributing, circulating, and accumulating liquid
    • F28F25/04Distributing or accumulator troughs
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F25/00Component parts of trickle coolers
    • F28F25/02Component parts of trickle coolers for distributing, circulating, and accumulating liquid
    • F28F25/06Spray nozzles or spray pipes
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F25/00Component parts of trickle coolers
    • F28F25/10Component parts of trickle coolers for feeding gas or vapour
    • F28F25/12Ducts; Guide vanes, e.g. for carrying currents to distinct zones
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F9/00Casings; Header boxes; Auxiliary supports for elements; Auxiliary members within casings

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Thermal Sciences (AREA)
  • Heat-Exchange Devices With Radiators And Conduit Assemblies (AREA)

Abstract

The invention relates to a water-saving and electricity-saving type fog-dissipation cooling tower, which comprises a cooling tower body and a water collecting tank arranged at the bottom of the cooling tower body, wherein the upper end of the cooling tower body is provided with a water turbine, and a water inlet pipe of the water turbine is introduced with cooling water from the water collecting tank; the water outlet pipe of the hydraulic turbine falls downwards, and the atomizing inlet tube is gushed into after the cooling water drops perpendicularly, through the atomizer atomizing blowout that the atomizing inlet tube set, the atomizer upper end sets up receives the hydrophone, receive the hydrophone upper end and set up condensation heat transfer device, the air chamber is reserved to condensation heat transfer device upper end, the air chamber upper end sets up the fan blade at cooling tower body opening part, condensation heat transfer device introduces dry cold air and this internal atomizing spun damp and hot air wall formula heat transfer of cooling tower, lets in behind dry cold air and the damp and hot air heat transfer behind the air chamber and fuses, forms unsaturated air outside the discharge tower after. The invention provides a cooling tower which can effectively reduce the power consumption and the water consumption and eliminate the plume.

Description

Water-saving and power-saving type fog-dissipation cooling tower
Technical Field
The invention relates to the technical field of circulating water cooling, in particular to a water-saving and electricity-saving type fog-dissipation cooling tower.
Background
The main effect of industrial circulating water is to produce the heat transfer cooling of equipment, and the circulating water need provide kinetic energy by the water pump in the circulation process, need pass through the cooling tower cooling after giving the production facility heat transfer, and general industrial circulating water system mostly adopts mechanical draft cooling tower, even with motor drive fan and circulating water convection heat transfer to reach the effect of cooling. A large amount of electric energy and water resources are consumed in the operation process of the system.
According to incomplete statistics, the electric quantity consumed by pump devices and cooling tower devices in the circulating water system accounts for more than 25% of the total electric energy production. The average design efficiency of the water pump in China is 75 percent, which is 5 percent lower than the international advanced level, and the operation efficiency is about 20 percent lower; the total circulating water quantity of the mechanical ventilation type cooling tower in China exceeds 22 hundred million tons, only the power consumption of a fan motor is nearly 8000 hundred million degrees every year, and the cooling tower has serious phenomena of back pressure, water floating and the like due to unreasonable design and operation. At present, the total water consumption in the whole country is about 6000 billion cubic meters, wherein the industrial water accounts for more than 20%, and the circulating water moisturizing accounts for 70-80% of the industrial water consumption, most industrial enterprises realize water conservation through improving the concentration multiple of the circulating water and reducing the sewage, the production cost is reduced, but after the concentration multiple is improved, along with the continuous evaporation of the circulating water, the salt concentration in the water is increased to cause precipitation, thereby forming scale, simultaneously, dirt can be formed in the circulating water operation process, the problems of microorganism slime, equipment corrosion and the like are solved, the heat transfer efficiency of the circulating water is reduced, and the service life of the equipment is also influenced. However, the sewage reduced by increasing the concentration factor is only a small part of the water supplement amount of the system, and evaporation and wind blowing loss are the large part of the water supplement amount.
Therefore, the operation of the existing industrial circulating water system is that on one hand, pumps and cooling tower devices have high power consumption, on the other hand, moisture evaporation and moisture blowing loss of the cooling tower exist, and meanwhile, the cooling tower fog phenomenon also exists, so that not only energy is consumed, but also the environment is influenced. The water saving, fog dispersal and electricity saving of the cooling tower are the problems to be solved urgently at present by modifying the cooling tower.
Disclosure of Invention
In order to solve the technical problems, the invention provides the cooling tower which can effectively reduce the power consumption and the water consumption and eliminate the plume.
In order to achieve the purpose, the water-saving and power-saving type fog-dissipating cooling tower comprises a cooling tower body and a water collecting tank arranged at the bottom of the cooling tower body, wherein an atomizing device is arranged in the cooling tower body, a condensation heat exchange device is arranged at the upper end of the atomizing device, an air chamber is reserved at the upper end of the condensation heat exchange device, the upper end of the air chamber is communicated with an outlet of the cooling tower, dry and cold air is introduced into the cooling tower body to be subjected to wall-type heat exchange with damp and hot air atomized and sprayed out, the dry and cold air and the damp and hot air are subjected to heat exchange and then introduced into the air chamber to be mixed and melted, and unsaturated air is formed;
the condensation heat exchange device comprises a condensation heat exchange shell and a condensation heat exchange cavity, the condensation heat exchange cavity comprises a hot humid air channel and a cold dry air channel, and the hot humid air channel and the cold dry air channel exchange heat through the dividing wall of the condensation heat exchange shell; the wet and hot air channel obliquely discharges wet and hot air after heat exchange, the dry and cold air channel obliquely discharges dry and cold air after heat exchange, the wet and hot air obliquely discharged from the wet and hot air channel and the dry and cold air obliquely discharged from the dry and cold air channel are intersected in a reserved air chamber, a water vapor condensation part in the wet and hot air is recycled into a water tank, and the wet and hot air after moisture content is reduced and the dry and cold air are mixed in the air chamber and are sent out of the cooling tower body through fan blades.
Further, the wet hot air channel is provided with a plurality of layers, and the dry cold air channel is provided with a plurality of layers; use the dry and cold air passageway as the wall between each damp and hot air passageway, form damp and hot air passageway and dry and cold air passageway adjacent setting and realize the heat transfer of multilayer next door in order to improve heat exchange efficiency, and the damp and hot air that each layer damp and hot air passageway and each layer dry and cold air passageway lead to forms a plurality of junctions with dry and cold air, improves damp and hot air liquefaction degree.
Furthermore, the section of the dry and cold air channel in the longitudinal direction is in the shape of an oblique rhombus, dry and cold air flows upwards from the dry and cold air channel in the shape of the oblique rhombus, when the dry and cold air flows in the dry and cold air channel, the dry and cold air channel is easy to collide with the wall to promote heat exchange with the hot and humid air channel on the other side of the wall surface, and the dry and cold air is led out from the air outlet at the upper end of the dry and cold air channel in the shape of the oblique rhombus, so that the dry and cold air is blown out obliquely.
Furthermore, an air inlet of the dry and cold air channel is communicated with the outer wall of the cooling tower body to be led in, a dry and cold air inlet air door perpendicular to the dry and cold air channel is arranged at the air inlet of the dry and cold air channel, a plurality of dry and cold air inlet shunting partition plates are arranged between the dry and cold air inlet air door and an inlet of the dry and cold air channel, and dry and cold air flowing in from the dry and cold air inlet air door is uniformly shunted by the dry and cold air inlet shunting partition plates;
or the dry and cold air inlet air door is an electric air door.
Further, the section of damp and hot air passageway on the vertical direction is oblique rhombus, damp and hot air passageway's air intake is for being the bevel connection of an angle with the horizontal direction, and atomizing spun damp and hot air circulates from being the hot and humid air passageway of oblique rhombus, and when damp and hot air circulated in damp and hot air passageway, because of damp and hot air passageway's shape, easily hit the wall and promote the dry cold air passageway heat transfer with the wall opposite side, and damp and hot air is for being the bevel connection of an angle with the horizontal direction from the air outlet of the hot and humid air passageway of rhombus, has realized simultaneously that damp and hot air blows off to one side, with dry cold air forms alternately.
Furthermore, the condensation heat exchange shell is in a flat rhombus shape, and the air flow direction of the hot and humid air channel is crossed with that of the dry and cold air channel;
two or more condensation heat exchange shells are arranged in the horizontal direction, and each condensation heat exchange shell is arranged in parallel;
and the wet and hot air channels and the dry and cold air channels of the condensation heat exchange shells are respectively obliquely blown out to be intersected to form a plurality of heat-exchanged dry and cold air and wet and hot air intersections.
Furthermore, the upper end of the cooling tower body is provided with a water turbine, and a water inlet pipe of the water turbine is introduced with cooling water from a water collecting tank; the water turbine comprises a water turbine, and is characterized in that a water outlet pipe of the water turbine falls downwards, cooling water flows into an atomization water inlet pipe after falling vertically, atomization spray heads arranged on the atomization water inlet pipe atomize and spray out, a water collector is arranged at the upper end of each atomization spray head, and a condensation heat exchange device is arranged at the upper end of each water collector.
Furthermore, a heat exchange device is arranged on a water inlet pipe of the water turbine;
or the water outlet pipe of the heat exchange device is connected with an atomization water inlet pipe, the atomization water inlet pipe is connected with the water outlet pipe of the heat exchange device, and introduced water is directly atomized and sprayed out by utilizing the surplus pressure head of the water outlet pipe of the heat exchange device.
Furthermore, the heat exchange device is connected with a water turbine, the water turbine is provided with a vertical water outlet pipe, and vertically falling water generates residual pressure through the geometric height difference of the water outlet pipe, enters the spraying device and is sprayed out through the atomizing nozzle through the atomizing water inlet pipe; the spraying device comprises an atomization water inlet pipe and atomization nozzles distributed on the atomization water inlet pipe;
the cooling tower water supply pipe is connected with the atomization water inlet pipe through a bypass valve, and surplus pressure heads of the water system are directly utilized to be atomized and sprayed out through the atomization spray head.
Furthermore, the cooling tower is provided with an auxiliary motor for assisting in driving the fan blades of the cooling tower to rotate, and the water turbine and the auxiliary motor drive the fan blades to rotate through the double-input speed reducer, so that the surplus energy of the system is fully utilized, and meanwhile, the cooling effect of the cooling tower is guaranteed.
Compared with the prior art, the invention has the beneficial effects that:
1. the height of the water inlet pipe of the cooling tower is reduced, and the available return water pressure head of the system is increased.
2. Circulating hot water is atomized into fine water droplets by utilizing the surplus pressure energy of circulating water return water, so that the heat exchange area of the circulating water is increased; meanwhile, due to the fact that the filler is removed, ventilation resistance is reduced, air quantity is increased, air-water ratio is improved, and the mode of upward spraying is adopted, so that the heat exchange time of atomized water drops and air can be prolonged, and the heat exchange effect of circulating water is improved.
3. If the surplus energy is large and surplus is left after the circulating hot water is atomized, the fan driven by the original motor can be changed into a water turbine or a water-electricity hybrid driving fan to utilize the surplus energy, so that the energy-saving effect is realized.
4. The condensation heat exchange device with the flat diamond design can occupy the air chamber as less as possible, and is more suitable for the transformation of the existing cooling tower. And the modular design is convenient for installation.
5. The atomized circulating hot water exchanges heat with air to form nearly saturated hot and humid air, and the nearly saturated hot and humid air exchanges heat with additionally introduced dry and cold air outside the tower in a condensation heat exchange device in a dividing wall manner, so that the temperature and the moisture content of the hot and humid air in the tower are reduced, and water vapor in the hot and humid air is condensed and flows back to a cooling tower for utilization; meanwhile, the wet hot air with the reduced moisture content and the dry cold air are mixed in the air chamber and discharged out of the tower, unsaturated air is formed when the wet hot air and the dry cold air are mixed with the cold air outside the tower again, and plume cannot be formed, so that the effect of fog dissipation is achieved. The tower top fan provides kinetic energy for the damp hot air and the dry cold air.
Drawings
FIG. 1 is a schematic diagram of a cooling tower of the present invention;
FIG. 2 is a side view of a cooling tower of the present invention;
FIG. 3 is a schematic structural diagram of a condensation heat exchange module of the present invention;
FIG. 4 is a side view of a condensing heat exchange module of the present invention;
FIG. 5 is a schematic structural diagram of a dry cold air channel and a wet hot air channel of the condensing heat exchange module of the invention;
in the drawings, a water collecting tank 1; a circulating water pump 2; a heat exchange device 3; a cooling tower body 4; a water turbine 41; a condensing heat exchange device 42; a condensing heat exchange shell 421; the hot and humid air path 422; a dry and cool air passage 423; a dry and cool air inlet splitter plate 425; a dry and cool air inlet damper 426; a spraying device 43; an atomization water inlet pipe 431; an atomizer head 432; a water outlet pipe 414; a bypass valve 433; a dry and cool air inlet damper 45; fan blades 46; a dual input reducer 47; an auxiliary motor 48; a water collector 8; an air chamber 9.
Detailed Description
The invention is further illustrated with reference to the following figures and examples.
Example 1
As shown in fig. 1-5, the water-saving and power-saving defogging cooling tower of the invention comprises a cooling tower body 4 and a water collecting tank 1 arranged at the bottom of the cooling tower body 4, wherein the upper end of the cooling tower body 4 is provided with a water turbine 41, and a water inlet pipe of the water turbine 41 is introduced with cooling water from the water collecting tank 1; the outlet pipe of hydraulic turbine 41 falls downwards, and the atomizing inlet tube 431 is gushed into after the cooling water falls from perpendicular, through the atomizer 432 atomizing blowout that the atomizing inlet tube 431 set, atomizer 432 upper end sets up receives hydrophone 8, receive hydrophone 8 upper end and set up condensation heat transfer device 42, air chamber 9 is reserved to condensation heat transfer device 42 upper end, air chamber 9 upper end sets up fan blade 46 at cooling tower body 4 opening part, condensation heat transfer device introduces dry cold air and this internal atomizing spun damp and hot air wall type heat transfer of cooling tower, and dry cold air and damp and hot air heat transfer back let in the air chamber after fuse, form unsaturated air outside the discharge tower.
The condensation heat exchange device 42 comprises a condensation heat exchange shell 421 and a condensation heat exchange cavity, the condensation heat exchange cavity comprises a hot and humid air channel 422 and a cold and dry air channel 423, and the hot and humid air channel 422 and the cold and dry air channel exchange heat through the walls of the condensation heat exchange shell 421; the damp and hot air channel 422 obliquely discharges damp and hot air after heat exchange, the dry and cold air channel 423 obliquely discharges dry and cold air after heat exchange, the damp and hot air obliquely discharged from the damp and hot air channel 422 and the dry and cold air obliquely discharged from the dry and cold air channel 423 are intersected in the reserved air chamber 9, water vapor in the damp and hot air is condensed and flows back to the cooling tower, air blowing loss in the damp and hot air can be collected through a water collector, condensed water can flow down through the dry and cold air channel 423 and the damp and hot air channel 422, and the damp and hot air with reduced moisture content and the dry and cold air are mixed in the air chamber and are sent out of the cooling tower body through a fan blade.
According to the water-saving and power-saving type fog-dissipation cooling tower, the condensation heat exchange device 42 is arranged in the air chamber 9 above the water collector 8, and a certain amount of dry and cold air outside the tower and wet and hot air atomized and sprayed from the inside of the tower are introduced to perform wall-dividing type heat exchange in the condensation heat exchange device, so that the temperature and the moisture content of the wet and hot air in the tower are reduced, water vapor in the wet and hot air is condensed and flows back to the cooling tower for utilization, and the purpose of saving water is achieved; in addition, after the condensation heat exchange device exchanges heat, the wet hot air and the dry cold air are obliquely led out from the wet hot air channel 422 and the dry cold air channel 423, dry cold and wet heat in the air chamber are mixed to form unsaturated air, part of water vapor in the wet hot air flows into the water tank after being condensed, the wet hot air flows out of the tower through the fan blades 46 after being subjected to heat exchange and liquefaction, and no fog can be formed, so that the effects of water saving and fog dissipation are achieved. The hot and humid air ventilation channel 422 is discharged in an inclined direction, and an air outlet of hot and humid air is fed into the air chamber 9 in an inclined angle direction in a vertical direction; the dry and cold air ventilation channel 423 is fed into the air chamber in the direction of an inclined angle, the ventilation direction of the dry and cold air ventilation channel 423 is crossed with the ventilation direction of the wet and hot air ventilation channel 422, so that dry and cold air and wet and hot air are formed to be converged in the air chamber after the heat exchange of the partition walls, and flow into the water pool after being liquefied, and the water-saving and fog-eliminating functions of the cooling tower are realized.
The wet hot air channel 422 is provided with a plurality of layers, and the dry cold air channel 423 is provided with a plurality of layers; use dry cold air passageway 423 as the interval layer between each damp and hot air passageway 422, form damp and hot air passageway 422 and dry cold air passageway 423 adjacent setting and realize the heat transfer of multilayer next door in order to improve heat exchange efficiency, and the damp and hot air that each layer damp and hot air passageway 422 and each layer dry cold air passageway 423 lead to forms a plurality of junctions with dry cold air, increased the intersection of dry cold air and damp and hot air, realize fully intersecting in the circulation direction after dry cold air and damp and hot air intersect, the vapor condensation rate in the damp and hot air, reduce the cooling water loss that the feather fog caused.
The condensation heat exchange shell is in a flat rhombus shape, and the air flow direction of the hot and humid air channel is crossed with that of the dry and cold air channel; two or more condensation heat exchange shells are arranged in the horizontal direction, and each condensation heat exchange shell is arranged in parallel; and the wet and hot air channels and the dry and cold air channels of the condensation heat exchange shells are respectively obliquely blown out to be intersected to form a plurality of heat-exchanged dry and cold air and wet and hot air intersections.
The condensation heat exchange shell 421 is formed by installing two or more modules, is convenient to install, is more suitable for the transformation of the existing cooling tower, and each condensation heat exchange shell 421 is in a flat rhombus shape, the air flow direction of the wet hot air channel 422 and the air flow direction of the dry cold air channel 423 are crossed.
The two condensation heat exchange shells 421 in the invention share the same dry and cold year air inlet air door 426 and also share the dry and cold air inlet diversion partition 425, thus reducing the occupation in the cooling tower body, simplifying the structure for use and improving the circulation rate of damp and hot air.
The air flow direction of the hot and humid air channel 422 is inclined with the air flow direction of the dry and cold air channel 423, and the direction of the hot and humid air is inclined with the direction of the dry and cold air, so that the intersection area of the hot and humid air and the dry and cold air is increased, the moisture content of the hot and humid air can be further reduced, the probability of secondary or tertiary intersection in the flow direction after the hot and humid air and the dry and cold air are intersected can be increased, the liquefaction degree of the hot and humid air is further realized, and the loss of cooling water caused by plume is reduced.
The section of the dry and cold air channel 423 in the longitudinal direction is in the shape of an oblique rhombus, dry and cold air upwards circulates from the dry and cold air channel 423 in the shape of the oblique rhombus, when the dry and cold air circulates in the dry and cold air channel 423, the dry and cold air easily collides with the wall to promote heat exchange with the wet and hot air channel on the other side of the wall surface, and the dry and cold air is exhausted from the air outlet at the upper end of the dry and cold air channel in the shape of the oblique rhombus, so that the dry and cold air is obliquely blown out. An air inlet of the dry and cold air channel 423 is communicated with the outer wall of the cooling tower body to be introduced, a dry and cold air inlet air door 426 perpendicular to the dry and cold air channel is arranged at the air inlet of the dry and cold air channel 423, a plurality of dry and cold air inlet flow dividing partition plates 425 are arranged between the dry and cold air inlet air door 426 and the inlet of the dry and cold air channel 423, and dry and cold air flowing in from the dry and cold air inlet air door 426 is uniformly divided by the dry and cold air inlet flow dividing partition plates 425;
and the dry and cold air inlet air door is an electric air door.
The cross-section of hot and humid air passageway 422 on longitudinal direction is oblique rhombus, hot and humid air passageway 422's air intake is for being the bevel connection of angle with the horizontal direction, and atomizing spun hot and humid air is from being the hot and humid air passageway 422 circulation of rhombus, and when hot and humid air circulated in hot and humid air passageway 422, because of hot and humid air passageway 422's shape, increased the heat transfer area of dry cold air and hot and humid air, hot and humid air is from the air outlet of the hot and humid air passageway 422 of rhombus for being the bevel connection of angle with the horizontal direction, has realized simultaneously that hot and humid air blows off to one side, with the cold and humid air forms alternately.
The hot and humid air channel 422 is provided with a hot and humid air guide plate 425 in the air inlet direction, and the hot and humid air inlet guide plate 425 guides the hot and humid air introduced into the hot and humid air channel 422.
The wet hot air channel 422 is provided with a plurality of layers, and the dry cold air channel 423 is provided with a plurality of layers; the dry and cold air channels 423 are used as spacing layers between the wet and hot air channels 422 to form a plurality of layers of wet and hot air channels 422 and dry and cold air channels 423 which are adjacent to each other, so that the heat exchange efficiency is enhanced.
The hot and humid air path 422 has an airflow direction crossing the airflow direction of the cold and dry air path 423.
The water inlet pipe of the water turbine 41 is connected with each heat exchange device; the water outlet pipe of the heat exchange device 3 is connected with an atomization water inlet pipe 431, the atomization water inlet pipe is connected with the water outlet pipe of the heat exchange device, and introduced water is directly sprayed out through atomization by utilizing a surplus pressure head of the water outlet pipe of the heat exchange device.
The heat exchange device 3 is communicated with a spraying device 43, the spraying device 43 comprises an atomizing water inlet pipe 431 and atomizing nozzles 432 distributed on the atomizing water inlet pipe 431, the water turbine 41 is provided with a vertical water outlet pipe 414, the vertically falling water generates residual pressure through the geometric height difference of the water outlet pipe 414, and the residual pressure is introduced into the atomizing water inlet pipe 431 and is sprayed out through the atomizing nozzles;
the cooling tower water supply pipe is connected with the atomization water inlet pipe 431 through a bypass valve 433, and surplus pressure heads of the water system are directly utilized to be atomized and sprayed out through the atomization spray head 432.
The cooling tower 4 is provided with an auxiliary motor 48 for assisting in driving the fan blades 46 of the cooling tower 4 to rotate, and the water turbine 41 and the auxiliary motor 48 drive the fan blades 46 to rotate through a double-input speed reducer 47, so that the surplus energy of the system is fully utilized, and meanwhile, the cooling effect of the cooling tower 4 is ensured.
According to the water-saving and electricity-saving type fog-dissipation cooling tower, water in a water pool is driven by the water pump to go to the heat exchange device for heat exchange, if surplus energy is still left after circulating water is atomized, the cooling tower 4 can be a 'water turbine drive' or 'water and electricity hybrid drive' fan blade type cooling tower, so that the energy consumption of the cooling tower is reduced; the cooling tower 4 is provided with a condensation heat exchange device 42 in an air chamber, the condensation heat exchange device 42 comprises a condensation heat exchange shell 421 and a condensation heat exchange cavity, the condensation heat exchange cavity comprises a wet hot air ventilation channel 422 and a dry cold air ventilation channel 423, and air in the two ventilation channels exchanges heat in the condensation heat exchange shell 421; the main dry and cold air channel 423 introduces dry and cold air outside the tower to perform wall-type heat exchange with damp and hot air in the cooling tower to generate unsaturated air for separating from the tower;
the cooling tower electricity-saving technology provided by the invention utilizes the redundant backwater surplus energy of the system, changes the original motor-driven fan into 'water turbine drive' or 'water and electricity motor hybrid drive', solves the problems of system energy consumption waste and insufficient surplus energy utilization, and reduces the power consumption driven by the fan blades. The cooling tower 4 is provided with an auxiliary motor 48 for assisting in driving the fan blades 46 of the cooling tower 4 to rotate, and the water turbine 41 and the auxiliary motor 48 drive the fan blades 46 to rotate through a double-input speed reducer 47, so that the surplus energy of the system is fully utilized, and meanwhile, the cooling effect of the cooling tower 4 is ensured.
The condensation heat exchange device is arranged in the air chamber above the water collector of the cooling tower, and a certain amount of dry and cold air outside the tower and wet and hot air inside the tower are introduced to carry out wall-type heat exchange in the condensation heat exchange device, so that the temperature and the moisture content of the wet and hot air inside the tower are reduced, water vapor in the wet and hot air is condensed and flows back to the cooling tower to be utilized, and the purpose of saving water is achieved; meanwhile, the upper end of the condensation heat exchange device is communicated with the damp and hot air and the dry and cold air at intervals, the dry and cold air and the damp and hot mixed air in the air chamber are mixed to form unsaturated air, and no fog is formed when the mixed air flows out of the tower, so that the fog dissipation effect is achieved. The moist and hot air and the dry and cold air in the invention are sucked upwards through the fan blades 46, and the dry and cold air and the moist and hot air are driven to enter the air chamber 9 after heat exchange from the condensation heat exchange shell.
The 4 exports of hydraulic turbine still are equipped with atomizer 43, atomizer 43 includes atomizing inlet tube 431 and the atomizer 432 of distribution on atomizing inlet tube 431, and hydraulic turbine 41 sets up upright outlet pipe 414, and the water that vertically falls produces the excess pressure through outlet pipe 414 geometric altitude difference, lets in atomizing inlet tube 431 through the atomizer blowout.
The cooling tower water supply pipe is connected with the atomization water inlet pipe 431 through a bypass valve 433, and surplus pressure heads of the water system are directly utilized to be atomized and sprayed out through the atomization spray head 432.
In the mechanism, the spraying device 43 utilizes the redundant potential energy of water to realize low-pressure atomization spraying, realizes the atomization cooling without filler in the tower and reduces the ventilation resistance of the cooling tower.
According to the structure, circulating hot water is atomized in a low-pressure atomizing spray head by utilizing a geometrical height difference between a surplus pressure head or an atomizing spray head of a system and an original water inlet pipe, the atomized hot water forms nearly saturated damp and hot air after exchanging heat with air, and then a certain amount of ambient air outside a tower and the damp and hot air inside the tower are introduced to perform wall-type heat exchange in a condensation heat exchange device arranged in a cooling tower, so that the temperature and the moisture content of the damp and hot air inside the tower are reduced, and water vapor in the damp and hot air is condensed and flows back to the cooling tower for utilization; meanwhile, when the air in the tower with the reduced moisture content is discharged out of the tower, unsaturated air is formed when the air is mixed with cold air outside the tower, and plume cannot be formed. Because the cooling tower adopts non-filler atomization cooling, the ventilation resistance of the cooling tower is reduced, and the cooling effect is improved by increasing the air-water ratio, the heat exchange time and the heat exchange area.
The cooling tower body 4 is provided with a dry and cold air inlet damper 45 matched with the dry and cold air channel 423 to control the flow of introduced dry and cold air.
The dry and cold air inlet air door 45 is electrically controlled, the opening degree of the air door is automatically adjusted by the difference between the inlet water temperature and the return water temperature of the cooling tower, and when the difference is larger than a set value, the air door is automatically opened to improve the effects of water saving and fog dissipation; when the temperature difference is smaller than a set value, the air door is automatically closed, and the cooling effect of the circulating water is improved. The dry and cold air inlet damper 45 can also be manually controlled according to actual conditions on site.
The upper end of the condensation heat exchange shell 421 is reserved with a space for meeting dry and cold air, the condensation heat exchange shell 421 is in a flat rhombus shape, the occupied air chamber is reduced in height, a sufficient meeting space is reserved for cold and hot air, unsaturated gas is convenient to form, and fog is not easy to form. The design increases the space of the air chamber to the maximum extent, and is convenient for reforming the existing cooling tower
The invention is further demonstrated below with reference to specific examples.
In the example, 3 circulating water pumps (2 for 1 device) with rated flow of 10000m3/h, lift of 50m and motor power of 1800kW are designed, 4 square counter-flow mechanical ventilation cooling towers with rated water treatment capacity of 5000m3/h are matched, the water inlet height is 10.5 m, the design temperature difference is 43-33 ℃, and the motor power matched with a fan of the cooling tower is 200 kW. The system sends circulating water from the water pool to each heat exchange device through the circulating water pump 2 for heat exchange, and hot water after heat exchange is cooled through the mechanical ventilation cooling tower and returns to the water pool.
In the operation process of the system, the actual operation flow is found to be larger than the designed rated flow of the water pump and the cooling tower, so that the heat exchange effect of the terminal equipment is improved in a manner of increasing the flow; and the system also improves the water supply pressure by adjusting the upper tower valve, so that the water inlet pressure of each heat exchanger reaches the designed working pressure, and a large amount of energy consumption is wasted. Meanwhile, the cooling tower has a fog phenomenon, which wastes water resources and affects the environment, causes corrosion of peripheral production equipment and affects the service life of the equipment. The actual operating conditions of the water system are as follows:
actual operation condition of system before system optimization and transformation
Figure BDA0002647874580000121
Aiming at the problems of the circulating water system, the system is optimized and modified, and finally the optimal operation effect is achieved. The method comprises the following specific steps:
1. the filling material is removed, so that the ventilation resistance can be reduced by about 50 percent; the water distribution pipe and the spray head which are originally arranged above the filler and below the water collector are moved to the lower end of the filler which is originally arranged, so that the water feeding height is reduced, and the circulating water atomization pressure head is increased by about 3 meters. Meanwhile, an original disc type spray head installed in a downward spraying mode is changed into an upward spraying type atomization spray head, and circulating water is atomized by means of the geometrical height difference of a backwater surplus pressure head and a water distribution pipe of the system after the downward movement.
2. Because the return water pressure of the system is 0.25Mpa (1Mpa approximately equals to 102 meters of water column), the installation height of the atomizing spray head is 7.5 meters, and the surplus pressure head of the return water available for the system is approximately equals to 25.5-7.5 approximately equals to 18 meters. The pressure head required by the atomizing nozzle is about 5-8 meters, the surplus pressure head still has surplus after the atomizing nozzle is used, and the fan blade driven by the motor is changed into 'water turbine driving' or 'water and electricity hybrid driving' to realize the full utilization of energy.
3. The upper part of the water collector of the cooling tower is provided with the condensation heat exchange device, so that the occupied space of the air chamber can be reduced as much as possible due to the flat rhombic design, and sufficient space is reserved for mixing the moist hot air and the dry cold air; the condensing heat exchange device adopts a modular design, and is simple and convenient to install.
4. The lower part of the condensation heat exchange device is provided with a dry cold air ventilation duct which is separated by a shunt partition plate, so that dry cold air can uniformly enter each condensation heat exchange device to exchange heat with damp and hot air. The electric air door is arranged on the dry and cold air inlet, the opening of the air door is automatically adjusted according to the water inlet temperature and the water outlet temperature of the cooling tower, and the optimal operation of water saving and fog dissipation is realized on the premise of ensuring the cooling effect of circulating water.
5. After the improvement, the air quantity of the fan is increased due to the reduction of the ventilation resistance, so that the air-water ratio of the circulating water is improved; meanwhile, after the non-filler atomization is adopted, the heat exchange area of the circulating water is increased; and the heat exchange time of the atomized water drops and the air is prolonged by adopting an upward spraying mode, the cooling effect of the cooling water is integrally improved, and the temperature difference is increased from 6.5 ℃ to about 8 ℃, so that the production efficiency is improved.
After the technology of the invention is adopted for transformation, the actual operation working conditions of the circulating water system of the chemical enterprise are as follows:
operation condition of system after system optimization and reconstruction
Figure BDA0002647874580000131
Figure BDA0002647874580000141
Through optimizing and transforming, under the prerequisite that water pump operating power, flow and supply return water pressure are all unchangeable, the electric quantity can be practiced thrift every hour to the cooling tower fan: (155-16) × 4 pieces 556kW, power saving rate: (155-16) ÷ 155 ═ 89.7%, can save 487 ten thousand degrees of electricity used annually; the water saving rate of the system is 307-charge 266 ═ 41 tons/hour, the water saving rate is (307-charge 266) ÷ 307 ═ 13.3%, and the annual water saving rate is 35.9 ten thousand tons. And because the heat exchange temperature difference of the cooling tower is improved, the production efficiency of enterprises is improved, and the yield is increased.
Finally, it should be noted that the above-mentioned list is only the specific embodiment of the present invention. Obviously, the present invention is not limited to the above embodiments, and many modifications are possible. All modifications which can be derived or suggested by a person skilled in the art from the disclosure of the present invention are to be considered within the scope of the invention.

Claims (10)

1. The utility model provides a water conservation and power saving type fog dispersal cooling tower, includes the cooling tower body, sets up in the catch basin of cooling tower body bottom, its characterized in that: an atomization device is arranged in the cooling tower body, a condensation heat exchange device is arranged at the upper end of the atomization device, an air chamber is reserved at the upper end of the condensation heat exchange device, the upper end of the air chamber is communicated with an outlet of the cooling tower, dry and cold air and humid and hot air atomized and sprayed in the cooling tower body are introduced into the condensation heat exchange device to perform wall-type heat exchange, the dry and cold air and the humid and hot air are introduced into the air chamber to be mixed and melted after heat exchange, and unsaturated air is formed after being discharged out of the tower;
the condensation heat exchange device comprises a condensation heat exchange shell and a condensation heat exchange cavity, the condensation heat exchange cavity comprises a hot humid air channel and a cold dry air channel, and the hot humid air channel and the cold dry air channel exchange heat through the dividing wall of the condensation heat exchange shell; the wet and hot air channel obliquely discharges wet and hot air after heat exchange, the dry and cold air channel obliquely discharges dry and cold air after heat exchange, the wet and hot air obliquely discharged from the wet and hot air channel and the dry and cold air obliquely discharged from the dry and cold air channel are intersected in a reserved air chamber, a water vapor condensation part in the wet and hot air is recycled, and the wet and hot air with reduced moisture content and the dry and cold air are mixed in the air chamber and are sent out of the cooling tower body through the fan blades.
2. The water and electricity saving type defogging cooling tower according to claim 1, wherein: the wet hot air channel is provided with a plurality of layers, and the dry cold air channel is provided with a plurality of layers; use the dry and cold air passageway as the wall between each damp and hot air passageway, form damp and hot air passageway and dry and cold air passageway adjacent setting and realize the heat transfer of multilayer next door in order to improve heat exchange efficiency, and the damp and hot air that each layer damp and hot air passageway and each layer dry and cold air passageway lead to forms a plurality of junctions with dry and cold air, improves damp and hot air liquefaction degree.
3. A water and electricity saving type defogging and cooling tower according to claim 1 or 2, wherein: the section of the dry and cold air channel in the longitudinal direction is in the shape of an oblique rhombus, dry and cold air flows upwards from the dry and cold air channel in the shape of the oblique rhombus, when the dry and cold air flows in the dry and cold air channel, the dry and cold air easily collides with the wall to promote heat exchange with the wet and hot air channel on the other side of the wall, and the dry and cold air flows out from the air outlet at the upper end of the dry and cold air channel in the shape of the oblique rhombus, so that the dry and cold air is obliquely blown out.
4. A water and electricity saving type defogging and cooling tower as recited in claim 3, wherein: an air inlet of the dry and cold air channel is communicated with the outer wall of the cooling tower body to be introduced, a dry and cold air inlet air door perpendicular to the dry and cold air channel is arranged at the air inlet of the dry and cold air channel, a plurality of dry and cold air inlet shunting partition plates are arranged between the dry and cold air inlet air door and an inlet of the dry and cold air channel, and dry and cold air entering from the dry and cold air inlet air door is uniformly shunted by the dry and cold air inlet shunting partition plates;
or the dry and cold air inlet air door is an electric air door.
5. A water and electricity saving type defogging and cooling tower as claimed in any one of claims 1, 2 and 4, wherein: the cross-section of damp and hot air passageway on the vertical direction is oblique rhombus, damp and hot air passageway's air intake is for being the bevel connection of angle with the horizontal direction, and atomizing spun damp and hot air is from being oblique rhombus damp and hot air passageway circulation, and when damp and hot air circulated in damp and hot air passageway, because of damp and hot air passageway's shape, easily hit the wall and promote the dry cold air passageway heat transfer with the wall opposite side, and damp and hot air has realized simultaneously that damp and hot air blows off to one side for being the bevel connection of angle with the horizontal direction from rhombus damp and hot air passageway's air outlet, with dry cold air forms alternately.
6. The water and electricity saving type defogging and cooling tower according to claim 5, wherein: the condensation heat exchange shell is in a flat rhombus shape, and the air flow direction of the hot and humid air channel is crossed with that of the dry and cold air channel; two or more condensation heat exchange shells are arranged in the horizontal direction, and each condensation heat exchange shell is arranged in parallel; and the wet and hot air channels and the dry and cold air channels of the condensation heat exchange shells are respectively obliquely blown out to be intersected to form a plurality of heat-exchanged dry and cold air and wet and hot air intersections.
7. A water and electricity saving type defogging and cooling tower as claimed in any one of claims 1, 2, 4 and 6 wherein: the upper end of the cooling tower body is provided with a water turbine, and a water inlet pipe of the water turbine is filled with cooling water from a water collecting tank; the water turbine comprises a water turbine, and is characterized in that a water outlet pipe of the water turbine falls downwards, cooling water flows into an atomization water inlet pipe after falling vertically, atomization spray heads arranged on the atomization water inlet pipe atomize and spray out, a water collector is arranged at the upper end of each atomization spray head, and a condensation heat exchange device is arranged at the upper end of each water collector.
8. A water-saving and electricity-saving defogging cooling tower as claimed in any one of claim 7, wherein:
the water outlet pipe of the heat exchange device is connected with an atomization water inlet pipe, the atomization water inlet pipe is connected with the water outlet pipe of the heat exchange device, and introduced water is directly sprayed out through atomization by utilizing a surplus pressure head of the water outlet pipe of the heat exchange device.
9. The water and electricity saving type defogging and cooling tower according to claim 8, wherein: the heat exchange device is connected with a water turbine, the water turbine is provided with a vertical water outlet pipe, and vertically falling water generates residual pressure through the geometric height difference of the water outlet pipe, enters the spraying device and is sprayed out through the atomizing nozzle through the atomizing water inlet pipe; the spraying device comprises an atomization water inlet pipe and atomization nozzles distributed on the atomization water inlet pipe;
the cooling tower water supply pipe is connected with the atomization water inlet pipe through a bypass valve, and surplus pressure heads of the water system are directly utilized to be atomized and sprayed out through the atomization spray head.
10. A water and electricity saving type defogging and cooling tower as claimed in claims 1 to 4, 6, 8 and 9 wherein: the cooling tower is provided with an auxiliary motor to assist in driving the fan blades of the cooling tower to rotate, and the water turbine and the auxiliary motor drive the fan blades to rotate through the double-input speed reducer, so that the surplus energy of the system is fully utilized, and the cooling effect of the cooling tower is ensured.
CN202010860410.9A 2020-08-25 2020-08-25 Water-saving and power-saving type fog-dissipation cooling tower Pending CN111981864A (en)

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CN202010860410.9A CN111981864A (en) 2020-08-25 2020-08-25 Water-saving and power-saving type fog-dissipation cooling tower

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Application Number Priority Date Filing Date Title
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