CN101922772A

CN101922772A - Multistage countercurrent flow heat exchange-evaporation-refrigeration device

Info

Publication number: CN101922772A
Application number: CN2009101133669A
Authority: CN
Inventors: 于向阳
Original assignee: Individual
Current assignee: Individual
Priority date: 2009-06-16
Filing date: 2009-06-16
Publication date: 2010-12-22
Anticipated expiration: 2029-06-16
Also published as: CN101922772B

Abstract

The invention discloses a multistage countercurrent flow heat exchange-evaporation-refrigeration device, comprising direct devaporizers, an air outlet, an air inlet, a water tank, heat exchanging chambers and fan drifts, wherein the direct devaporizer the upper part of which is provided with a spray system is arranged in the heat exchanging chamber; the air outlet is arranged on the upper part of the spray system; the air inlet is arranged on the lower part of the direct devaporizer; the water tank is mounted at the bottom of the heat exchanging chamber; the heat exchanging chambers mutually separated are evenly distributed in a machine case; the fan drift is arranged between the adjacent heat exchanging chambers; the upper port of the fan drift is communicated with the air outlet of the last stage heat exchanging chamber; the lower port of the fan drift is communicated with the air inlet of the next stage heat exchanging chamber; the air outlet of the final stage heat exchanging chamber leads outdoor, the water discharging pipe of a water pump of the water tank of the next stage heat exchanging chamber is connected with the spraying system of the last stage heat exchanging chamber; and the cool water in the water tank of the final stage heat exchanging chamber is output through the water pump. The invention not only can reduce the irreversible loss of the heat and moisture exchange of the cool water in the process of heat and moisture exchange of inlet air and improve heat exchanger efficiency, but also can achieve single cool water supply, or single cool air supply, or simultaneous cool water and cool air supply according to different conditions and demands.

Description

Multistage countercurrent flow heat exchange-evaporation-refrigeration device

Technical field

The present invention relates to field of renewable energy technology, belonging to the dry air that contains with the open-air seasoning air can be the evaporation-refrigeration device of the driving force of refrigeration, particularly multistage countercurrent flow heat exchange-evaporation-refrigeration device.

Background technology

China is vast in territory, and climate difference is obvious, and the Northwest belongs to typical xeothermic meteorological condition, and precipitation is generally less, and sunshine is abundant, belongs to the arid and semi-arid lands.With respect to hot and humid area, inland, because water in air steam absolute quantity is few, relative humidity is low, and is dry, the easy more evaporation of aqueous water, and the water evaporation absorbs heat, has produced the freezing by change of state effect.Air is dry more, and then its available energy is just big more in the dry air, and the refrigerating capacity of generation is big more, and this energy that is used for freezing just is referred to as the dry air energy, and the technology of utilizing dry air can be used for cooling then is referred to as the Evaporative Cooling Air Conditioning technology.

Air-conditioning system is carried out the branch time-like according to the used medium difference of the indoor hot humidity load of burden, can be summed up as all-air system, air one water system and all water system three major types.Wherein all water system is used less owing to can not play the effect of ventilation.Common is all-air system and air one water system.

All-air system is meant by air processing machine and produces cold wind, for carrying cold medium, is transported to air-conditioned room with air, is born the air-conditioning system of the whole hot humidity loads in room by cold wind.Because the specific heat capacity of air is less, need more air output just can reach and eliminate waste heat, surplus wet purpose, therefore require to have the air channel of big section or higher wind speed.The characteristics of this system are that initial cost is little, and it is reliable to introduce new wind, help improving indoor air quality; But the required space of the air distributing system of air-line system is bigger, generally requires dwelling house that higher floor height is arranged, and should consider also that simultaneously airduct passes through the problem of body of wall and the cooperation of building is had relatively high expectations.

Air one water system is meant that the hot humidity load of air-conditioned room bears this air-conditioning system jointly by empty G﹠W and produce idle call cold water by handpiece Water Chilling Units, be transported to each indoor end equipment by pipe-line system, such as fan coil, cold emission coil pipe etc., eliminate the surplus wet amount of room residual heat by heat exchange.Meanwhile, produce cold wind, be transported to air-conditioned room, for the resh air requirement of needed by human body by air processing machine.Therefore this system single room adjusting function is better, because the cold water specific heat capacity is bigger, the shared space of cold water distributing system is very little, and it is less that handpiece Water Chilling Units takies space, relative better with the cooperation of building.

Make a general survey of existing patent and prior art, early stage technology is in the majority with the sweat cooling air processing machine, constitutes evaporative cooling all-air conditioning system.Air processing machine is by sweat cooling, and the cold wind of acquisition is sent into air-conditioned room, bears the sweat cooling air-conditioning system of the hot humidity load in room.Low-temperature receiver comes from the sweat cooling air processing machine, and year cold medium of output is single cold wind.

Partial monopoly relates to and utilizes dry air to freeze, and can utilize the fresh air refrigerating of open-air seasoning, produces cold water, and cold water temperature can level off to the dew-point temperature of new wind in theory, output to carry a cold medium be single cold water.

Partial monopoly relates to a kind of indirect evaporation refrigerating method and device that produces cold water and cold wind simultaneously, and the caloic exchange process of air and water is cross-current (crossing current), and can only produce cold water and cold wind simultaneously, can not realize the function of independent supply cold wind or cold water.

In addition, cold water and air intake take place to have bigger heat temperature exchange irreversible loss in the wet process that exchanges of heat, have reduced heat exchanger efficiency.

Summary of the invention

The object of the present invention is to provide a kind of multistage countercurrent flow heat exchange-evaporation-refrigeration device, not only can reduce the wet exchange of the heat irreversible loss in the wet exchange process of cold water and air intake generation heat, improve heat exchanger efficiency, but also can realize the function of independent cooling water or independent supply cold wind or while cooling water and cold wind according to different conditions and requirement.

The object of the present invention is to provide a kind of multistage countercurrent flow heat exchange-evaporation-refrigeration device, be included in the direct evaporative cooler that top has spray equipment is installed in the Heat Room, top at spray equipment is being provided with air outlet, bottom at direct evaporative cooler is being provided with air inlet, in the bottom of Heat Room the water tank water pump is being set, uniform in cabinet mutual separated Heat Room is being set, between adjacent Heat Room, wind channel is being set, the air outlet with the upper level Heat Room suitable for reading of wind channel is communicated with, the end opening of wind channel is communicated with the air inlet of next stage Heat Room, and the exhaust blower air outlet of final stage Heat Room passes to outside the Heat Room.

Because the present invention's uniform Heat Room that is being provided with in cabinet, between adjacent Heat Room, wind channel is being set, the air outlet with the upper level Heat Room suitable for reading of wind channel is communicated with, the end opening of wind channel is communicated with the air inlet of next stage Heat Room, it is variant that cooling water in each water tank and corresponding Heat Room carry out the hot temperature that wets after exchanging like this, and the water temperature of secondary heat-exchanging water tank is higher than the higher level.Therefore along on the air bottom horizontal flow sheet direction, the water temperature of separate water tank is arranged in order from high to low.Owing to realized that the water temperature of shower water distributes by gradient, when carrying out the caloic exchange, given full play to the potentiality of the wet exchange of heat with air intake, to arrive irreversible loss minimum, make that remaining big as far as possible heat exchange in Heat Room drives gesture, improved heat exchanger efficiency, improved refrigeration.In addition, can also and require according to different conditions on basis of the present invention, can widen function of use, realize the function of independent cooling water or independent supply cold wind or while cooling water and cold wind.

Description of drawings

The invention will be further described below in conjunction with accompanying drawing.

Fig. 1 is an agent structure schematic diagram of the present invention;

Fig. 2 is the structural representation of direct evaporative cooler profile parallelogram of the present invention;

Fig. 3 is the structural representation of user's cooling water;

Fig. 4 provides the structural representation of cold water to the user for the precooling of air intake surface cooler;

Fig. 5 is the structural representation of user side surface cooler in parallel;

Fig. 6 is subscriber multiple, series connection surface cooler type structural representation;

Fig. 7 is for providing the structural representation of bise series connection surface cooler type to the user;

Fig. 8 is for providing the structural representation of cold water and bise to the user;

Fig. 9 is for providing the structural representation of cold water and clammy wind to the user;

Figure 10 is for providing the structural representation of bise series connection surface cooler to the user;

Figure 11 is for providing the structural representation of clammy wind and cold water surface cooler in parallel to the user;

Figure 12 is for providing cold water and bise, the structural representation of surface cooler in parallel to the user;

Figure 13 is for providing cold water and clammy wind to the user, and, the structural representation of series connection surface cooler;

Figure 14 is for providing cold water and bise to the user, and, the structural representation of series connection surface cooler.

The specific embodiment

A kind of multistage countercurrent flow heat exchange-evaporation-refrigeration device, as shown in Figure 1, be included in the direct evaporative cooler 1 that top has spray equipment 2 is installed in the Heat Room, top at spray equipment 2 is being provided with air outlet, bottom at direct evaporative cooler 1 is being provided with air inlet, in the bottom of Heat Room water tank 4 and water pump are being set, uniform in cabinet mutual separated Heat Room is being set, wind channel 3 is being set between adjacent Heat Room, the air outlet with the upper level Heat Room suitable for reading of wind channel 3 is communicated with, the end opening of wind channel 3 is communicated with the air inlet of next stage Heat Room, and the air outlet of final stage Heat Room passes to outside the Heat Room.

As shown in Figure 2, the profile parallelogram of upright direct evaporative cooler 1, wherein the windward side and the horizontal angle of direct evaporative cooler bottom are acute angle.Because the windward side and the horizontal angle of direct evaporative cooler bottom are acute angle, have enlarged the area of windward side, the air loss that air is flowed is less, has improved heat transfer medium and has driven gesture, and then improved heat exchange efficiency.

As shown in Figure 3, back one-level Heat Room water tank 4 pumping lines are connecting the spray equipment 2 of upper level Heat Room, and the outlet pipe of chopped-off head Heat Room water tank 4 water pumps is connecting user 5, and user 5 outlet pipe is connecting the spray equipment 2 of final stage Heat Room.From the cold water of chopped-off head Heat Room water tank 4 water pumps output lowest temperature, send into user 5 and realize refrigeration.User 5 is air-conditioned room end or fan coil or floor radiant cooling coil pipe or new blower fan group surface cooler.

As shown in Figure 4, air inlet duct 7 with import is being set in the front portion of cabinet, the outlet of air inlet duct 7 is connecting the air inlet of first order Heat Room, surface cooler 6 is installed in the import of air inlet duct 7, user 5 outlet pipe is connecting the water inlet of surface cooler 6, and the delivery port of surface cooler 6 is connecting the spray equipment 2 of final stage Heat Room by pipeline.It is but clammy that 6 pairs of air intakes of surface cooler carry out etc., reduce the dry-bulb temperature and the wet-bulb temperature of air intake, below from first order Heat Room enters first order Heat Room subsequently, adverse current caloic exchange for the first time takes place at the inner top-down water droplet that forms of filler, moisture film in the shower water uniform with spray equipment 2, the cold water that produces falls into first order Heat Room water tank 4, be delivered to user 5 by water pump, produce equally the cold water of different temperatures to the n level Heat Room in the second level, according to different allocation proportions, connect higher level's spray equipment 2 respectively and be transported to user 5.

As shown in Figure 5, the water tank 4 of water pump is connecting user 5 and surface cooler 6 respectively by three-way pipe, and the pipeline that the outlet pipe of user 5 outlet pipe and surface cooler 6 compiles by three-way connection is being connected the spray equipment 2 of final stage Heat Room.This unit is a cooling-water machine, user side surface cooler in parallel.

As shown in Figure 6, the two-stage surface cooler 6 of water route series connection is installed in the import of air inlet duct 7, the outlet pipe of water tank 4 water pumps of chopped-off head Heat Room is connecting the water inlet of user 5 and second level surface cooler 6 respectively by three-way pipe, user 5 outlet pipe is connected with the series connection water pipe of two-stage surface cooler 6, and the outlet pipe of first order surface cooler 6 is connecting the spray equipment 2 of final stage Heat Room.The cold water of chopped-off head Heat Room water tank 4 is drawn by water pump, part water feeds user 5, another part feeds second level surface cooler 6, user 5 and surface cooler 6 are in parallel, two parts water is after the series connection water pipe behind the first order surface cooler 6 converges, enter second level surface cooler 6 again, behind the released cold quantity, insert the spray equipment 2 of final stage Heat Room by pipeline.

As shown in Figure 7, the wind channel 8 of air-introduced machine is equipped with in the outlet that is provided with on cabinet, the outlet of air inlet duct 7 is connecting the import of the air inlet and the wind channel 8 of chopped-off head Heat Room simultaneously, the outlet pipe of chopped-off head Heat Room water pump is connecting the water inlet of surface cooler 6, and the delivery port of surface cooler 6 is connecting the spray equipment 2 of final stage Heat Room by pipeline.This unit is the cold wind cooling-water machine, when cold water is provided, also provides bise, and a part of in addition cold wind enters unit as working media.

As Fig. 8, shown in Figure 9, the outlet pipe of chopped-off head Heat Room water pump is connecting user 5, and user 5 outlet pipe is connecting the water inlet of surface cooler 6, and the outlet pipe of surface cooler 6 is connecting the spray equipment 2 of final stage Heat Room.Fig. 8 is for providing cold water and cold dry-air blast, series connection surface cooler type to the user.Fig. 9 is for providing cold water and clammy wind, series connection surface cooler type to the user.

As shown in figure 10, the outlet of air inlet duct 7 is connecting the import of the air inlet and the wind channel 8 of first order Heat Room simultaneously, the two-stage surface cooler 6 of water route series connection is installed in the import of air inlet duct 7, the outlet pipe of chopped-off head Heat Room water tank 4 water pumps is connecting the water inlet of second level surface cooler 6, and the outlet pipe of first order surface cooler 6 is connecting the spray equipment 2 of final stage Heat Room.For user 5 provides bise, the type of series connection surface cooler 6.

As shown in figure 11, wherein the lower openings of the wind channel 3 of one-level Heat Room is connecting the import of wind channel 8, water tank 4 water pumps are connecting user 5 and surface cooler 6 respectively by three-way pipe, and the pipeline that the outlet pipe of user 5 outlet pipe and surface cooler 6 compiles by three-way connection is being connected the spray equipment 2 of final stage Heat Room.For user 5 provides cold water and clammy wind simultaneously, the type of series connection surface cooler 6.

As shown in figure 12, the outlet of air inlet duct 7 is connecting the import of the air inlet and the wind channel 8 of chopped-off head Heat Room simultaneously, water tank 4 water pumps are connecting user 5 and surface cooler 6 respectively by three-way pipe, and the pipeline that the outlet pipe of user 5 outlet pipe and surface cooler 6 compiles by three-way connection is being connected the spray equipment 2 of final stage Heat Room.For user 5 provides cold water and bise simultaneously, the type of series connection surface cooler 6.

As shown in figure 13, wherein wind channel 3 openings of one-level Heat Room are connecting the import of wind channel 8, two-stage surface cooler 6 is installed in the import of air inlet duct 7, the water pump of water tank 4 is connecting user 5 and second level surface cooler 6 by three-way pipe, two-stage surface cooler 6 is connected by water pipe, user 5 outlet pipe is connected with the series connection water pipe of two-stage surface cooler 6, and the outlet pipe of first order surface cooler 6 is connecting the spray equipment 2 of final stage Heat Room.For user 5 provides cold water and clammy wind, the type of series, parallel surface cooler 6 simultaneously.

As shown in figure 14, the outlet of air inlet duct 7 is connecting the import of the air inlet and the wind channel 8 of chopped-off head Heat Room simultaneously, two-stage surface cooler 6 is installed in the import of air inlet duct 7, the water pump of chopped-off head water tank 4 is connecting user 5 and second level surface cooler 6 by three-way pipe, two-stage surface cooler 6 is by the water pipe series connection, and user 5 outlet pipe is connected with the series connection water pipe of two-stage surface cooler 6.For user 5 provides cold water and bise simultaneously, the type of series, parallel surface cooler 6.

As Fig. 1, Fig. 2, Fig. 3, Fig. 4, Fig. 5, Fig. 6, Fig. 7, Fig. 8, Fig. 9, Figure 10, Figure 11, Figure 12, Figure 13, shown in Figure 14, on the cabinet wall on wind channel 3 tops wherein, first order Heat Room rear portion, air inlet 9 is being set, in machine, mend outdoor new wind.

Claims

1. multistage countercurrent flow heat exchange-evaporation-refrigeration device, be included in the direct evaporative cooler (1) that top is installed in the Heat Room has spray equipment (2), top at spray equipment (2) is being provided with air outlet, bottom at direct evaporative cooler (1) is being provided with air inlet, water tank (4) and water pump are being set in the bottom of Heat Room, it is characterized in that: uniform in cabinet mutual separated Heat Room is being set, wind channel (3) is being set between adjacent Heat Room, suitable for reading and the superposed air outlet of upper level Heat Room of wind channel (3) is communicated with, the end opening of wind channel (3) is communicated with the air inlet of next stage Heat Room, and the exhaust blower air outlet of final stage Heat Room passes to outside the casing.

2. multistage countercurrent flow heat exchange-evaporation-refrigeration device according to claim 1 is characterized in that: the profile parallelogram of upright direct evaporative cooler (1), wherein the windward side and the horizontal angle of direct evaporative cooler (1) bottom are acute angle.

3. multistage countercurrent flow heat exchange-evaporation-refrigeration device according to claim 1, it is characterized in that: the pumping line of back one-level Heat Room water tank (4) is connecting the spray equipment (2) of upper level Heat Room, the outlet pipe of chopped-off head Heat Room water tank (4) water pump is connecting user (5), and user's (5) outlet pipe is connecting the spray equipment (2) of final stage Heat Room.

4. multistage countercurrent flow heat exchange-evaporation-refrigeration device according to claim 3, it is characterized in that: the air inlet duct (7) with import is being set in the front portion of cabinet, the outlet of air inlet duct (7) is connecting the air inlet of chopped-off head Heat Room, and surface cooler (6) is installed in the import of air inlet duct (7).

5. multistage countercurrent flow heat exchange-evaporation-refrigeration device according to claim 4 is characterized in that: user's (5) outlet pipe is connecting surface cooler (6), and the outlet pipe of surface cooler (6) is connecting the spray equipment (2) of final stage Heat Room.

6. multistage countercurrent flow heat exchange-evaporation-refrigeration device according to claim 4, it is characterized in that: water tank (4) water pump is connecting user (5) and surface cooler (6) respectively by three-way pipe, and the pipeline that the outlet pipe of user's (5) outlet pipe and surface cooler (6) compiles by three-way connection is being connected the spray equipment (2) of final stage Heat Room.

7. multistage countercurrent flow heat exchange-evaporation-refrigeration device according to claim 4, it is characterized in that: the two-stage surface cooler (6) that the water route series connection is installed in the import of air inlet duct (7), the outlet pipe of the water tank of chopped-off head Heat Room (4) water pump is connecting the water inlet of user (5) and second level surface cooler (6) respectively by three-way pipe, user's (5) outlet pipe is connected with the series connection water pipe of two-stage surface cooler (6), and the outlet pipe of first order surface cooler (6) is connecting the spray equipment (2) of final stage Heat Room.

8. multistage countercurrent flow heat exchange-evaporation-refrigeration device according to claim 4, it is characterized in that: outlet is being set on cabinet the wind channel (8) of air-introduced machine is being housed, the air inlet that the outlet of air inlet duct (7) is connecting the chopped-off head Heat Room simultaneously and the import of wind channel (8) or wherein the wind channel of one-level Heat Room (3) opening be connected the import of wind channel (8).

9. multistage countercurrent flow heat exchange-evaporation-refrigeration device according to claim 8 is characterized in that: the outlet pipe of chopped-off head Heat Room water tank (4) water pump is connecting surface cooler (6), and the outlet pipe of surface cooler (6) is connecting the spray equipment (2) of final stage Heat Room.

10. multistage countercurrent flow heat exchange-evaporation-refrigeration device according to claim 8, it is characterized in that: the outlet pipe of chopped-off head Heat Room water tank (4) water pump is connecting user (5), user's (5) outlet pipe is connecting the water inlet of surface cooler (6), and the outlet pipe of surface cooler (6) is connecting the spray equipment (2) of final stage Heat Room.

11. multistage countercurrent flow heat exchange-evaporation-refrigeration device according to claim 8, it is characterized in that: the two-stage surface cooler (6) that the water route series connection is installed in the import of air inlet duct (7), the outlet pipe of chopped-off head Heat Room water tank (4) water pump is connecting the water inlet of second level surface cooler (6), and the outlet pipe of first order surface cooler (6) is connecting the spray equipment (2) of final stage Heat Room.

12. multistage countercurrent flow heat exchange-evaporation-refrigeration device according to claim 8, it is characterized in that: chopped-off head Heat Room water tank (4) water pump is connecting user (5) and surface cooler (6) respectively by three-way pipe, and the pipeline that the outlet pipe of user's (5) outlet pipe and surface cooler (6) compiles by three-way connection is being connected the spray equipment (2) of final stage Heat Room.

13. multistage countercurrent flow heat exchange-evaporation-refrigeration device according to claim 8, it is characterized in that: two-stage surface cooler (6) is installed in the import of air inlet duct (7), the water pump of water tank (4) is connecting user (5) and second level surface cooler (6) by three-way pipe, two-stage surface cooler (6) is connected by water pipe, user's (5) outlet pipe is connected with the series connection water pipe of two-stage surface cooler (6), and the outlet pipe of first order surface cooler (6) is connecting the spray equipment (2) of final stage Heat Room.

14., it is characterized in that: on the cabinet wall on wind channel (3) top wherein, first order Heat Room rear portion, air inlet (9) is being set according to claim 1 or 2 or 3 or 4 or 5 or 6 or 7 or 8 or 9 or 10 or 11 or 12 or 13 described multistage countercurrent flow heat exchange-evaporation-refrigeration devices.