CN105972703B - Rain-type haze removal tower and haze removal tower heat pump adopting same - Google Patents

Abstract

The invention relates to the technical field of haze treatment, in particular to a rain-type haze removing tower and a haze removing tower heat pump adopting the same. The rain-type haze removal tower comprises a tower body, wherein an air outlet and an air inlet are formed in the tower body, and a rain fan is arranged at the air outlet; the upper part in the tower body is provided with a rain spray assembly, the lower part is filled with rain liquid, and the rain spray assembly is communicated with the rain liquid through a circulating pipeline; the rain spray assembly is composed of at least one group of downward spray nozzles or a plurality of groups of nozzles with adjustable angles. Simultaneously, still provide and adopt above-mentioned formula of drenching with rain to remove haze tower heat pump. The haze removing tower provided by the invention has the functions of a cooling tower, can remove haze, and has the advantages of short haze removing period and low use cost.

Description

Rain-type haze removal tower and haze removal tower heat pump adopting same

Technical Field

The invention relates to the technical field of haze treatment, in particular to a rain-type haze removing tower and a haze removing tower heat pump adopting the same.

Background

At present, the concept of haze treatment extends to the British haze treatment route, the energy structure is modified by one step, fuel gas is changed from fire coal, industrial enterprises with high pollution are dismantled, the high-tech pollution-free industrial project is adopted, and the British improvement is long-lived. However, the fossil energy in china is mainly coal, the petroleum and natural gas is very deficient, and if all the coal is changed into gas, how many petroleum and natural gas resources are imported in china? From a strategic perspective: once China is not tested, people need to look at the face of the house, otherwise, the energy is completely blocked by people. From another perspective: although the energy improvement in china is probably ten and a half years faster than that in the uk, the improvement is still carried out for about 30 years, and even 30 years, it is not known how many people who live yellow springs due to a large amount of inhaled air pollutants pay for the medical expenses of respiratory diseases caused by haze inhalation in China and common people; not to mention how many high-tech pollution-free projects can replace the existing industrial products in the China industry, once a large amount of the existing pollution enterprises are dismantled or limited to produce, the GDP force of China slips down, and the economic status of China in the world is reduced.

Pm-2.5 atmospheric pollutant content is observed, severe haze is usually generated in the winter heating period, and the heating supply by coal and natural gas is an excellent cause of severe haze. Therefore, the haze treatment concept of the invention is as follows: the air renewable energy is used for replacing coal and natural gas for heating while long energy structural modification and industrial transformation are relied on, zero emission heating and heat supply are thoroughly realized from the source, and permanent cure and haze removal are realized; the technology and the product for eliminating the atmospheric pollutants are researched and developed cheaply and quickly, the Pm-2.5 reaches the standard or is close to a slight numerical value immediately, and people can breathe clean air as soon as possible to achieve the effect of treating the symptoms and removing the haze.

That is to say that the haze mode of current removal has with high costs, the problem of cycle length.

To the above problem, a rain-type haze removal tower capable of solving the problem that the existing haze removal mode is high in cost and long in period and a haze removal heat pump system adopting the same are provided.

Disclosure of Invention

The invention aims to provide a rain type haze removing tower which can solve the problems of high cost and long period of the existing haze removing mode.

The invention also aims to provide a haze removal tower heat pump system which adopts the rain type haze removal tower.

In order to achieve the purpose, the invention adopts the following technical scheme:

a rain-type haze removal tower comprises a tower body, wherein an air outlet and an air inlet are formed in the tower body, and a rain fan is arranged at the air outlet;

the upper part in the tower body is provided with a rain spray assembly, the lower part is filled with rain liquid, and the rain spray assembly is communicated with the rain liquid through a circulating pipeline;

the rain spray assembly is at least composed of a group of downward spray nozzles, or comprises a plurality of groups of nozzles which spray at a plurality of angles or nozzles with adjustable spray angles.

As a preferable scheme of the rain-type haze removal tower, a fan silencer is arranged at the top of the tower body, the rain fan is arranged in the fan silencer, and the air outlet is arranged at the upper end of the side wall of the fan silencer;

the top end of the fan silencer is provided with a silencing hood;

the rain spray assembly is arranged at the lower part of the rain fan, and a gas-water separation device is arranged between the rain spray assembly and the rain fan;

and a rain purification synergistic filler is arranged between the rain spraying component and the air inlet.

As a preferred scheme of the rain-type haze removal tower, the upper part of the fan silencer is a silencing static pressure chamber, wherein a silencing air pipe is arranged on the silencing static pressure chamber, and a silencing rainproof elbow is arranged at the free end of the silencing air pipe;

one end of the silencing rainproof elbow is communicated with the silencing air pipe, and the air outlet is obliquely and downwards arranged at the other end of the silencing rainproof elbow.

As a preferred scheme of the rain-type haze removal tower, an upper liquid storage tank and a lower liquid storage tank are arranged at the lower part of the tower body, the upper liquid storage tank is used as a rain liquid circulating tank for summer clear water, and the lower liquid storage tank is used for recovering winter anti-freezing liquid rain liquid in summer;

the upper liquid storage tank and the lower liquid storage tank are arranged in parallel, the upper liquid storage tank and the lower liquid storage tank are respectively connected with the deluge spraying component through pipelines, and the upper liquid storage tank and/or the lower liquid storage tank are/is used for providing deluge liquid for the deluge spraying component (4).

As a preferred scheme of the rain-type haze removal tower, an upper liquid storage tank and a lower liquid storage tank are arranged at the lower part of the tower body, the upper liquid storage tank is used as a rain liquid circulating tank for summer clear water, and the lower liquid storage tank is used for recovering winter anti-freezing liquid rain liquid in summer;

and the upper liquid storage tank and the lower liquid storage tank are arranged in parallel, the upper liquid storage tank and the lower liquid storage tank are respectively connected with the deluge spraying assembly through pipelines, and the upper liquid storage tank and/or the lower liquid storage tank are/is used for providing deluge liquid for the deluge spraying assembly.

As a preferred scheme of the rain type haze removal tower, the tower body comprises a horizontal tower body and a vertical air pipe which is arranged at one end of the horizontal tower body and communicated with the horizontal tower body;

the air outlet is arranged on the side wall of the upper end of the vertical air pipe, and the air inlet is arranged on the side wall of the horizontal tower body;

the rain spray assembly is arranged on the upper portion of the horizontal tower body, the rain liquid is arranged on the lower portion of the horizontal tower body, and the rain spray assembly and the rain liquid are communicated through a circulating pipeline.

As a preferred scheme of the rain type haze removal tower, the tower body comprises a horizontal tower body and a horizontal air pipe which is arranged at one end of the horizontal tower body and communicated with the horizontal tower body;

the air outlet is arranged at the end part of the horizontal air pipe, and the air inlet is arranged on the side wall of the horizontal tower body;

the rain spray assembly is arranged at the upper part of the horizontal tower body, the rain liquid is arranged at the lower part of the horizontal tower body, and the rain spray assembly and the rain liquid are communicated through a circulating pipeline;

one end of the horizontal tower body, which is close to the horizontal air pipe, is provided with a deluge purification synergistic filler, and the upper end of the deluge purification synergistic filler is provided with a deluge liquid device.

As a preferred scheme of the rain-type haze removal tower, rain purification synergistic fillers are arranged at two ends of the horizontal tower body, and a rain liquid distribution device is arranged at the upper end of the rain purification synergistic fillers;

the top of the vertical air pipe is provided with a fan silencer, the deluge fan is arranged in the fan silencer, and the air outlet is arranged at the upper end of the side wall of the fan silencer;

the top end of the fan silencer is provided with a silencing hood, and an air-water separation device is arranged at the air inlet end of the fan silencer;

and a rain purification synergistic filler is arranged between the rain spraying component and the air inlet.

As a preferred scheme of the rain type haze removal tower, the tower body comprises a horizontal tower body and a vertical air pipe which is arranged at the upper part of the horizontal tower body and communicated with the horizontal tower body;

the air inlet is formed in the side wall of the horizontal tower body;

the vertical air pipe is provided with an air outlet, and a rain fan is arranged below the air outlet;

both ends of the horizontal tower body are provided with the deluge purification synergistic filler, and the upper end of the deluge purification synergistic filler is provided with a deluge liquid device;

the rain spray assembly is arranged at the upper part of the horizontal tower body, the rain liquid is arranged at the lower part of the horizontal tower body, and the rain spray assembly and the rain liquid are communicated through a circulating pipeline;

as a preferred scheme of the rain type haze removal tower, the tower body comprises a horizontal tower body and a vertical air pipe which is arranged at the upper part of the horizontal tower body and communicated with the horizontal tower body;

the air inlet is formed in the side wall of the horizontal tower body;

a fan silencer is arranged at the upper part of the vertical air pipe, and a silencing static pressure chamber is arranged at the upper part of the fan silencer, wherein a silencing air pipe is arranged on the silencing static pressure chamber, and a silencing rainproof elbow is arranged at the free end of the silencing air pipe;

one end of the silencing rainproof elbow is communicated with the silencing air pipe, and the air outlet is obliquely and downwards arranged at the other end of the silencing rainproof elbow;

the rain spray assembly is arranged at the upper part of the horizontal tower body, the rain liquid is arranged at the lower part of the horizontal tower body, and the rain spray assembly and the rain liquid are communicated through a circulating pipeline;

both ends of the horizontal tower body are provided with the deluge purification synergistic filler, and the upper end of the deluge purification synergistic filler is provided with a deluge liquid device;

the lower part of the horizontal tower body is provided with an upper liquid storage tank and a lower liquid storage tank, the upper liquid storage tank is used as a rain liquid circulating tank for summer clear water, and the lower liquid storage tank is used for recovering anti-freezing rain liquid in summer;

and the upper liquid storage tank and the lower liquid storage tank are arranged in parallel and are connected with the deluge spraying component through pipelines.

A heat pump system comprises the rain-type haze removal tower and a heat pump exchanging energy with the rain-type haze removal tower.

As a preferable scheme of the haze removal tower heat pump system, the heat pump is a water source heat pump, the water source heat pump is formed by connecting a refrigeration compressor, a condenser, an expansion valve, an evaporator, an air conditioner output circulating pump and a fan coil sequentially through pipelines, one end of the air conditioner output circulating pump is connected with one end of the water side of the condenser, the other end of the water side of the condenser is connected with one end of the fan coil, the other end of the fan coil is connected with the other end of the air conditioner output circulating pump,

both ends of the water side of the evaporator are communicated with the tower body, and one end of the water side of the evaporator is provided with a deluge circulating pump.

As a preferable scheme of the haze tower heat pump system, the heat pump is a cold and hot air type heat pump air conditioner, and the cold and hot air type heat pump air conditioner comprises a refrigeration compressor, a cold and hot air type air conditioner tail end, an expansion valve and an evaporator which are connected;

the tail end of the cold and hot air type air conditioner is formed by assembling an indoor cold and hot air heat exchanger and an indoor air conditioner fan, one end of the indoor cold and hot air heat exchanger is connected with an exhaust end of a refrigeration compressor, the other end of the indoor cold and hot air heat exchanger is connected with an expansion valve, and the tail end of the cold and hot air type air conditioner at least comprises a one-stage or multi-stage cold and hot air type air conditioning system;

both ends of the water side of the evaporator are communicated with the tower body, and one end of the water side of the evaporator is provided with a deluge circulating pump.

As a preferred scheme of the haze removal tower heat pump system, the heat pump is a water source heat pump, and the water source heat pump comprises a refrigeration compressor, a condenser, an expansion valve, an evaporator, a domestic hot water heat storage circulating pump, a domestic hot water heat storage and heat preservation water tank, a tap water interface and a domestic hot water output interface which are connected;

one end of the domestic hot water heat storage and insulation water tank is connected with one end of the water side of the condenser, the other end of the water side of the condenser is connected with one end of a domestic hot water heat storage and circulation pump, the other end of the domestic hot water heat storage and insulation water tank is connected with the domestic hot water heat storage and insulation water tank, one end of the domestic hot water heat storage and insulation water tank is connected with a tap water system through a tap water interface, and the other end of the domestic hot water heat storage and insulation water tank is connected with a domestic hot water supply system through a;

both ends of the water side of the evaporator are communicated with the tower body, and one end of the water side of the evaporator is provided with a deluge circulating pump. As a preferable scheme of the haze removal tower heat pump system, the water source heat pump further comprises a first cooling and heating conversion valve, a second cooling and heating conversion valve, a third cooling and heating conversion valve and a fourth cooling and heating conversion valve which are connected, one end of the first refrigerating and heating conversion valve is connected with one end of the second refrigerating and heating conversion valve and then connected with the exhaust end of the refrigerating compressor, the other end of the first refrigerating and heating conversion valve is connected with one end of the fourth refrigerating and heating conversion valve and then connected with one end of the refrigerant side of the condenser, the other end of the refrigerant side of the condenser is connected with one end of the expansion valve, the other end of the expansion valve is connected with one end of the refrigerant side of the evaporator, the other end of the refrigerant side of the evaporator is connected with one ends of the second refrigerating and heating conversion valve and the third refrigerating and heating conversion valve, and the other end of the third refrigerating and heating conversion valve is connected with the other end of the fourth refrigerating and heating conversion valve and.

As a preferred scheme of the haze tower heat pump system, the haze tower heat pump system further comprises an antifreeze solution storage and proportioning tank, wherein the antifreeze solution storage and proportioning tank comprises an inlet end and an outlet end, and the inlet end and the outlet end of the antifreeze solution storage and proportioning tank are communicated with the tower body.

As a preferred scheme of the haze tower heat pump system, the haze tower heat pump system further comprises a cooling tower, and the cooling tower is composed of cooling tower heat exchange fillers, spraying liquid, a water receiving disc, a spraying liquid distribution device and a cooling tower fan.

The one end of the water side of evaporimeter is connected with sprays the liquid distribution device, and the other end and the water collector and the tower body of evaporimeter water side are linked together, and communicate through the pipeline between water collector and the tower body.

As a preferable scheme of the haze tower removing heat pump system, the haze tower removing heat pump system further comprises an antifreeze solution storage and proportioning tank, wherein one end of the antifreeze solution storage and proportioning tank is communicated with the spraying and liquid distributing device and one end of the water side of the evaporator through a pipeline, and the other end of the antifreeze solution storage and proportioning tank is communicated with the water receiving disc;

the system also comprises an automatic antifreeze solution concentration monitoring device, and two ends of the automatic antifreeze solution concentration monitoring device are respectively communicated with two ends of the evaporator.

As a preferred scheme of the haze removal tower heat pump system, the water source heat pump further comprises an energy storage circulating pump, an energy storage heat preservation water tank and an air conditioner output isolation heat exchanger;

one end of the energy storage heat preservation water tank is connected with one end of the water side of the condenser, the other end of the water side of the condenser is connected with one end of the primary side of the air conditioner output isolation heat exchanger through an energy storage circulating pump, and the other end of the primary side of the air conditioner output isolation heat exchanger is connected with the other end of the energy storage heat preservation water tank;

one end of the secondary side of the air-conditioning output isolation heat exchanger is connected with one end of an air-conditioning output circulating pump, the other end of the air-conditioning output circulating pump is connected with one end of a fan coil, and the other end of the fan coil is connected with the other end of the secondary side of the air-conditioning output isolation heat exchanger.

As a preferable scheme of the haze tower heat pump system, the haze tower heat pump system further comprises an antifreeze solution drying heating coil arranged in the antifreeze solution storage and proportioning tank, and two ends of the antifreeze solution drying heating coil are respectively communicated with two ends of a water side of the condenser.

As a preferable scheme of the haze removal tower heat pump system, the haze removal tower heat pump system further comprises a purification heat exchanger, a purification heating primary pump and a purification heating secondary pump;

one end of the purification heating primary pump is connected with one end of the condenser and one end of the fan coil, the other end of the purification heating primary pump is connected with one end of the primary side of the purification heat exchanger, and the other end of the primary side of the purification heat exchanger is connected with one end of the air conditioner output circulating pump and one end of the fan coil;

one end of the secondary side of the purification heat exchanger is connected with one end of a purification heating secondary pump, the other end of the purification heating secondary pump is connected with an antifreeze solution storage and proportioning tank, and the other end of the secondary side of the purification heat exchanger is also connected with the antifreeze solution storage and proportioning tank.

As a preferable scheme of the haze removal tower heat pump system, the haze removal tower heat pump system further comprises an antifreeze solution drying and purifying device, a purifying heat exchanger, a purifying and heating primary pump and a purifying and heating secondary pump;

one end of the primary side of the purification heat exchanger is connected with one end of the condenser and one end of the fan coil, the other end of the purification heating primary pump is connected with one end of the primary side of the purification heat exchanger, and the other end of the primary side of the purification heat exchanger is connected with one end of the air conditioner output circulating pump and one end of the fan coil; one end of the secondary side of the purification heat exchanger is connected with the antifreeze solution drying and purifying device, and the other end of the secondary side of the purification heat exchanger is connected with the antifreeze solution drying and purifying device through a purification heating secondary pump;

one end of the antifreeze solution drying and purifying device is communicated with the antifreeze solution storage and proportioning tank, and the other end of the antifreeze solution drying and purifying device is communicated with the water pan and used for purifying antifreeze solution in the antifreeze solution drying and purifying device and then injecting the purified antifreeze solution into the water pan.

As a preferable scheme of the haze tower removing heat pump system, the haze tower removing heat pump system further comprises a second-stage heat pump which is connected with the water source heat pump in series, wherein the second-stage heat pump comprises a second-stage refrigeration compressor, a second-stage condenser, a second-stage expansion valve and a second-stage evaporator;

the system is characterized in that one end of the water side of the second-stage evaporator is connected with one end of the water side of the condenser and then connected with one end of a fan coil, one end of the water side of the second-stage condenser and a purification heating primary pump, the other end of the second-stage condenser is connected with one end of a second single-double conversion valve, the other end of the second single-double conversion valve is connected with one end of a first single-double conversion valve and one end of an air conditioner output circulating pump, the other end of the air conditioner output circulating pump is connected with one end of the fan coil and the primary side of the purification heat exchanger, the other end of the first single-double conversion valve is connected with the other end of the water side of the condenser and one end of a coupling heat exchange circulating pump, and the other end of the coupling heat.

As a preferable scheme of the haze removal tower heat pump system, the water source heat pump further comprises a first cooling and heating conversion valve, a second cooling and heating conversion valve, a third cooling and heating conversion valve and a fourth cooling and heating conversion valve which are connected, one end of the first refrigerating and heating conversion valve is connected with one end of the second refrigerating and heating conversion valve and then connected with the exhaust end of the refrigerating compressor, the other end of the first refrigerating and heating conversion valve is connected with one end of the fourth refrigerating and heating conversion valve and then connected with one end of the refrigerant side of the condenser, the other end of the refrigerant side of the condenser is connected with one end of the expansion valve, the other end of the expansion valve is connected with one end of the refrigerant side of the evaporator, the other end of the refrigerant side of the evaporator is connected with one ends of the second refrigerating and heating conversion valve and the third refrigerating and heating conversion valve, and the other end of the third refrigerating and heating conversion valve is connected with the other end of the fourth refrigerating and heating conversion valve and.

As an optimal scheme of the haze removal tower heat pump system, the haze removal tower heat pump system further comprises a domestic hot water heat storage circulating pump, a domestic hot water heat storage and heat preservation water tank, a tap water interface and a domestic hot water output interface.

As a preferable scheme of the haze removal tower heat pump system, the haze removal tower heat pump system further comprises an energy storage heat preservation water tank and an air conditioner output isolation heat exchanger, wherein one end of a water side of the second-stage evaporator is connected with one end of a water side of the condenser and then connected with one end of the energy storage heat preservation water tank, one end of a water side of the second-stage condenser and the purification heating primary pump, the other end of the second-stage condenser is connected with one end of a second single-double-stage conversion valve, the other end of the second single-double-stage conversion valve is communicated with one end of the first single-double-stage conversion valve and one end of the energy storage circulating pump, the other end of the energy storage circulating pump is connected with one end of a primary side of the air conditioner output isolation heat exchanger and a primary side of the; the other end of the first single-stage and double-stage conversion valve is connected with one end of the coupling heat exchange circulating pump and one end of the condenser water side;

one end of the secondary side of the air conditioner output isolation heat exchanger is communicated with one end of the fan coil, the other end of the secondary side of the air conditioner output isolation heat exchanger is connected with one end of an air conditioner output circulating pump, and the other end of the air conditioner output circulating pump is communicated with the other end of the fan coil.

As above-mentioned remove haze tower heat pump system's an preferred scheme, still include the coupling circulation jar, coupling circulation jar one end connect the one end of condenser water side, the other end of condenser water side is connected with the one end of coupling heat transfer circulating pump, the one end of second level evaporimeter water side is connected to the other end of coupling heat transfer circulating pump, the other end of second level evaporimeter water side is connected with the coupling circulation jar through the pipeline, the coupling circulation jar still one end is connected with the one end of first single double-stage change-over valve, the other end of first single double-stage change-over valve is connected with the one end of second single double-stage change-over valve and the one end of air conditioner output circulating pump, the coupling circulation jar still one end is passed through the one end of pipeline and second level condenser, the one end of the first pump.

As a preferable scheme of the haze removal tower heat pump system, a heat source required by the antifreeze solution drying heating coil or the purifying heat exchanger is replaced by an electric heating source, residual waste heat, solar energy or a boiler heat source.

The invention has the beneficial effects that: the haze removing tower provided by the invention has the functions of a cooling tower, can remove haze, and has the advantages of short haze removing period and low use cost.

Drawings

FIG. 1 is a schematic view of a basic embodiment of a deluge-type vertical haze removal tower according to the present invention;

FIG. 2 is an implementation schematic diagram of a multifunctional device for noise elimination, gas-water separation and the like of a fan configured on the rain-type vertical haze removal tower;

FIG. 3 is a schematic diagram of an embodiment of a four-outlet silencing plenum device configured on the deluge-type vertical haze removal tower according to the present invention;

FIG. 4 is a schematic diagram illustrating an implementation of a liquid storage function configured in the rain-type vertical haze removal tower according to the present invention;

FIG. 5 is an implementation schematic diagram of a four-air-outlet device with a liquid storage function and configured on the rain-type vertical haze removal tower according to the invention;

FIG. 6 is a schematic view of a basic implementation of the deluge horizontal haze removal tower of the present invention;

FIG. 7 is a schematic view of the horizontal installation and implementation of the rain horizontal haze removal tower fan;

FIG. 8 is a schematic view of the rain-shower horizontal haze removal tower according to the present invention, wherein the rain-shower horizontal haze removal tower is implemented by a plurality of purification synergistic filler efficient purification devices;

FIG. 9 is an implementation schematic diagram of the deluge horizontal haze removal tower of the present invention, which is implemented by a plurality of groups of purification synergistic fillers, and is configured with vertical air pipes and a liquid storage device;

FIG. 10 is a schematic view of an implementation of the deluge horizontal haze removal tower with four air outlets and a plurality of groups of purification synergistic fillers;

FIG. 11 is an implementation schematic diagram of a haze-removing tower heat pump haze-addressing system formed by the rain-type haze-removing tower water source heat pump air conditioner;

FIG. 12 is an implementation schematic diagram of a haze treatment and temporary treatment system of the rain type haze removal tower cold and hot air type heat pump air conditioner;

FIG. 13 is a schematic diagram of an embodiment of the shower-type haze tower domestic hot water removal unit;

FIG. 14 is a schematic view of an embodiment of a water source heat pump air conditioner with cooling and heating conversion of the deluge-type haze removal tower completed at the refrigerant side according to the present invention;

FIG. 15 is a schematic view of an embodiment of an antifreeze solution storage and proportioning tank configured for the rain type haze removal tower water source heat pump air conditioner;

FIG. 16 is an implementation schematic diagram of an antifreeze solution storage proportioning tank air conditioner configured by the rain type haze removal tower cold and hot air type heat pump;

FIG. 17 is an implementation schematic diagram of an antifreeze solution storage and proportioning tank configured for the deluge-type haze-removing tower domestic hot water unit;

FIG. 18 is a schematic view of an antifreeze solution storage and proportioning tank configured for the rain-type haze removal tower water source heat pump air conditioner and implementation of refrigeration and heating conversion on a refrigerant side;

FIG. 19 is a schematic view of the implementation of addressing both the symptoms and root causes of the haze of the rain type haze removal tower and cooling tower combined water chilling unit air conditioner haze;

FIG. 20 is a haze treatment addressing implementation schematic diagram combining a rain-type haze removal tower and a cooling tower combined type cold and hot air type air conditioner;

FIG. 21 is a schematic view of an embodiment of a shower-type haze removal tower and cooling tower combined domestic hot water unit according to the present invention;

FIG. 22 is a schematic view of the deluge-type haze removal tower and cooling tower combined air conditioner with refrigeration and heating conversion implemented on the refrigerant side;

FIG. 23 is an implementation schematic diagram of the air conditioner combining the rain-type haze removing tower and the cooling tower and provided with an antifreeze solution storage tank and an antifreeze solution concentration detection control device according to the present invention;

FIG. 24 is an implementation schematic diagram of an antifreeze solution storage and proportioning tank air conditioner configured by the combination of the rain-type haze removal tower and the cooling tower and the cold and hot air type heat pump according to the present invention;

FIG. 25 is a schematic view of the rain-type haze removal tower and cooling tower water source heat pump air conditioner combined type antifreeze solution storage proportioning tank and implementation of the cooling and heating conversion device on the refrigerant side;

FIG. 26 is a schematic diagram of the implementation of the deluge haze removal tower and cooling tower water source heat pump combined domestic hot water unit;

FIG. 27 is an implementation schematic diagram of the energy storage type air conditioner with the combination of the rain type haze removal tower and the cooling tower water source heat pump and the configuration of an antifreeze solution storage and proportioning tank;

FIG. 28 is an implementation schematic diagram of a rain-type haze removal tower and cooling tower combined water source heat pump air conditioner provided with an antifreeze solution storage proportioning tank and a heating and drying device according to the present invention;

FIG. 29 is an implementation schematic diagram of the rain-type haze removal tower and cooling tower combined water source heat pump combined air conditioner and the antifreeze solution storage and proportioning tank provided with a purification heat exchanger;

FIG. 30 is a schematic diagram of an implementation of the independent purification device configured by the rain-type haze removal tower and the cooling tower combined with the water source heat pump air conditioner;

FIG. 31 is a schematic diagram of a two-stage water source heat pump air conditioner configured by combining a deluge-type haze removal tower and a cooling tower according to the present invention;

FIG. 32 is a schematic view of a two-stage water source heat pump air conditioner configured by combining the deluge-type haze removal tower and the cooling tower according to the present invention, with refrigeration and heating conversion implemented on the refrigerant side;

FIG. 33 is a schematic diagram of an embodiment of a dual-stage water source heat pump domestic hot water unit configured by combining the deluge-type haze removal tower and the cooling tower according to the present invention;

FIG. 34 is a schematic diagram of an embodiment of a two-stage water source heat pump energy storage air conditioner configured by combining a deluge-type haze removal tower and a cooling tower according to the present invention;

FIG. 35 is a schematic view of an embodiment of a dual-stage water source heat pump configuration coupling circulation tank device configured by combining the deluge-type haze removal tower and the cooling tower according to the present invention.

In the drawings:

1 vertical haze removal tower, 2 deluge liquid, 3 deluge pump, 4 deluge spraying components, 5 air inlets, 6 deluge fans, 7 air outlets, 8 fans, 9 noise elimination hoods, 10 gas-water separation devices, 11 dust screens, 12 noise elimination static pressure chambers, 13 noise elimination air pipes, 14 noise elimination rainproof elbows, 15 cooling towers, 16 cooling tower heat exchange fillers, 17 spray liquid, 18 water trays, 19 spray liquid distribution devices, 20 cooling tower fans, 21 cooling tower spray pumps, 22 spray liquid outlet valves, 23 spray liquid return valves, 24 deluge liquid spray valves, 25 deluge liquid circulating pumps, 26 water source heat pumps, 27 refrigeration compressors, 28 condensers, 29 expansion valves, 30 evaporators, 31 cooling tower air outlet pipes, 32 cooling tower air outlet opening and closing air valves, 33 haze removal tower air pipe opening and closing air valves, 34 haze removal tower air pipes, 35 air conditioner output circulating pump, 36 fan coil, 37 indoor cold and hot air heat exchanger, 38 indoor air conditioner fan, 39 domestic hot water heat storage circulating pump, 40 domestic hot water heat storage and heat preservation water tank, 41 tap water interface, 42 domestic hot water output interface, 43 diluted antifreeze liquid pouring valve, 44 antifreeze liquid concentration control valve, 45 antifreeze liquid concentration control valve, 46 antifreeze liquid storage proportioning tank, 47 antifreeze liquid stirring valve, 48 antifreeze liquid concentration proportioning pump, 49 antifreeze liquid concentration proportioning valve, 50 tap water injection valve, 51 tap water interface, 52 antifreeze liquid concentration automatic monitoring device, 53 antifreeze liquid drying and purifying device, 54 blow-down valve, 55 diluted antifreeze liquid injection valve, 56 purified antifreeze liquid output pump, 57 purified antifreeze liquid output valve, 58 purified heat exchanger, 59 purified heating primary pump, 60 purified secondary heating pump, 61 a third single-double-stage conversion valve, 62 a coupling heat exchange circulating pump, 63 a sewage draining interface, 64 a fourth single-double-stage conversion valve, 65 a first single-double-stage conversion valve, 66 a second-stage heat pump, 67 a second-stage refrigeration compressor, 68 a second-stage condenser, 69 a second-stage expansion valve, 70 a second-stage evaporator, 71 a second single-double-stage conversion valve, 72 an energy storage circulating pump, 73 an energy storage and heat preservation water tank, 74 an air conditioner output isolation heat exchanger, 75 a domestic hot water output pump, 76 a domestic hot water output interface, 77 a tap water injection valve, 78 a tap water interface, 79 an equipment room, 80 a haze removal tower on-off air valve, 81 a cold-hot air conditioner tail end, 82 a diluted antifreeze solution, 83 a purified antifreeze solution, 84 a cooling tower rain and snow prevention air outlet elbow, 85 a sewage draining valve, 86 a sewage draining interface, 87 an, 89 tap water injection valve, 90 tap water interface, 91 antifreeze liquid raw material adding door, 92 antifreeze liquid treatment valve, 93 antifreeze liquid discharging interface, 94 deluge liquid spraying pump, 95 cold and hot air type heat pump air conditioner, 96 antifreeze liquid drying heating coil water supply valve, 97 antifreeze liquid drying heating coil water return valve, 98 refrigeration and heating change-over valve, 99 refrigeration and heating change-over valve, 100 refrigeration and heating change-over valve, 101 refrigeration and heating change-over valve, 102 tap water injection valve, 103 upper deluge liquid supply valve, 104 lower deluge liquid supply valve, 105 lower sewage discharge valve, 106 upper liquid storage tank, 107 lower liquid storage tank, 108 recovered deluge liquid, 109 cooling tower water injection valve, 110 tap water interface, 111 horizontal haze removing tower, 112 deluge liquid distribution device, 113 vertical and 114 coupling circulation tank.

Detailed Description

The technical scheme of the invention is further explained by the specific implementation mode in combination with the attached drawings.

FIG. 1 is a schematic diagram of a basic implementation of the rain-type vertical haze removal tower of the present invention. In the figure, the device comprises a vertical haze removal tower 1, a deluge liquid 2, a deluge pump 3, a deluge spraying assembly 4, an air inlet 5, a deluge fan 6 and an air outlet 7. This rain formula removes haze tower and removes haze system can independently install on the street both sides in urban area, removes the elimination volume of haze tower pollutant and the purification grade of needs according to every rain formula and installs this that removes the haze tower of appropriate quantity, eliminates the low empty haze atmospheric pollutants in urban area, provides clear air for the city. The rain-type haze removal tower can be powered by electric energy of a power company, and solar energy and a wind driven generator can be installed on the tower body to supply power jointly. The number of deluge spray assemblies 4 is increased appropriately to achieve the required level of decontamination, depending on the amount of PM-2.5 removed. The rain spray component 4 can be horizontally arranged, also can be vertically arranged and installed, and can also be arranged in a top-down spiral spray pipe type rain spray structure, in order to improve the effect of spraying and washing atmospheric haze by rain, the rain spray component 4 should be installed and combined and spray multi-angle and multi-azimuth raindrops. The spray pipes of each group of deluge spray assemblies 4 are not easy to overlong so as to avoid influencing the deluge spray effect.

When removing the haze operation in spring, summer, autumn season, rain liquid 2 notes be the running water, and rain pump 3 moves when needing to remove the haze, will rain liquid 2 and inhale the pressure boost by rain pump 3 and arrange to drench and spray subassembly 4 to drenching, drench and spray subassembly 4 and spray intensive raindrop to removing haze tower 1 perpendicularly, level and multi-angle perpendicularly by drenching, simulate the rainstorm effect of nature. Simultaneously rain fan 6 operation, remove perpendicularly and form the negative pressure in the haze tower 1, the atmosphere that contains the severe haze gets into from air intake 5 and removes haze tower 1 perpendicularly, powerful air inlet and rain spray the rainstorm raindrop reverse friction that subassembly 4 sprayed wash, utilize and remove haze tower 1 perpendicularly and possess certain vertical height, increase rain shower washing time and way, the atmosphere of severe haze is through the washing back that the storm is suddenly rainy, the haze is washed and is got into among the rain liquid 2, fresh air is discharged to the atmosphere from air outlet 7, realize the purpose that the atmosphere purifies. If the negative ion generating device is arranged in the vertical haze removing tower 1, the natural fresh air feeling of raining weather can be obtained. When the haze removing operation is carried out in winter, the anti-freezing solution should be injected into the rain liquid 2 so as to prevent the tap water rain liquid 2 from freezing, and the anti-freezing solution should be selected from environment-friendly anti-freezing solutions which do not harm human bodies.

When the haze removing operation is carried out at the temperature of less than or equal to 0 ℃ in winter, in order to prevent the rain liquid 2 from freezing, the rain liquid 2 is filled with an anti-freezing liquid, and the rain washing process is the same as the haze removing operation in spring, summer and autumn. The atmosphere of severe haze is washed like storm, haze is washed away and enters the anti-freezing solution 2, and fresh air is discharged to the atmosphere from the air outlet 7, so that the purpose of atmosphere purification is achieved.

The rain-type haze removal tower has the advantages of low manufacturing cost, low operation and maintenance cost, small occupied area and convenience in installation, and a haze removal tower purification network can be formed in a city, so that a city science and technology landscape line can be formed. As long as a certain amount of vertical haze removal towers 1 are arranged, the amount of the atmospheric pollutants Pm-2.5 is larger than the pollutant emission amount of people, haze can be eliminated instantly, and people can enjoy clean and fresh air quickly without waiting for long time for industrial modification and energy structure adjustment. Each vertical haze removal tower 1 can purify air of about 2000000 cubic meters at least in about 24 hours, and it can be imagined how many cars can purify tail gas discharged into the atmosphere by one vertical haze removal tower 1.

FIG. 2 is an implementation schematic diagram of a multifunctional device for noise elimination, gas-water separation and the like of a fan configured on the rain-type vertical haze removal tower. The device comprises a vertical haze removal tower 1, deluge liquid 2, a deluge pump 3, a deluge spraying assembly 4, an air inlet 5, a deluge fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, an equipment room 79, a drain valve 85, a drain interface 86, deluge purification synergistic filler 88, a tap water injection valve 89, a tap water interface 90, an antifreeze liquid raw material adding door 91, an antifreeze liquid treatment valve 92 and an antifreeze liquid discharging interface 93. In fig. 2, a drain valve 85, a drain port 86, a deluge purification synergistic filler 88, a tap water filling valve 89, a tap water port 90, an antifreeze raw material addition gate 91, an antifreeze treatment valve 92, and an antifreeze discharge port 93 are added to fig. 1. The working principle of the attached drawing 2 is basically the same as that of the attached drawing 1, and only some functional configurations are added, so that the performance of the rain-type haze removal tower is improved.

The horizontal level of the dry sound of the haze removal tower 1 is reduced due to the arrangement of the fan silencer 8 and the silencing hood 9 in the attached drawing 2, so that the vertical haze removal tower 1 can run under the mute state.

Fig. 2 is because disposed rain and purified increase filler 88, and the atmospheric haze is by 6 forces through rain and purify increase filler 88 after, is obstructed, the separation, makes the raindrop purify increase filler 88 in the rain, with inspiratory severe haze atmosphere fully cut, bump , damping and increase reverse friction process, and during the pollutant in the messenger atmosphere fully falls into rain liquid 2, improves the rain washing effect. After being washed by rain, the fresh air is discharged to the atmosphere by the rain blower 6.

As the air-water separation device 10 is arranged in the attached figure 2, before fresh air containing certain moisture enters the deluge fan 6, the air-water separation device 10 separates and recovers water drops, and the dry and fresh air is discharged into the atmosphere.

Due to the fact that the equipment room 79 is arranged in the attached drawing 2, equipment such as the deluge pump 3, valves and power distribution can be installed in the equipment room 79, and the equipment installed in the open air of the vertical haze removal tower 1 is prevented from being corroded by rain and snow. Tap water is connected with a tap water supply system through a tap water injection valve 89 and a tap water connector 90, and tap water deluge liquid 2 is automatically injected into the vertical haze removal tower 1 after a water level device is configured. After the raining liquid 2 has too much dirt, the raining liquid 2 can be connected with a municipal sewer through a blowdown valve 85 and a blowdown interface 86, and then the raining liquid 2 can be manually discharged to the sewer, or a relevant dirt detection device is configured, so that the dirt raining liquid 2 can be automatically and periodically discharged.

When the antifreeze is used in winter purification operation, because the price of the antifreeze is more expensive than that of tap water, when the antifreeze 2 is used for washing haze, contaminants in the haze enter the antifreeze, and the antifreeze is polluted to a certain degree and is connected with the mobile drying and filtering device or sent to a treatment plant through the antifreeze treatment valve 92 and the antifreeze discharge interface 93, and the antifreeze is treated and then continuously reused. After the concentration of the antifreeze solution runs for a certain time, the concentration of the antifreeze solution can be diluted, and when the concentration of the antifreeze solution is diluted to a certain degree, the raw material of the antifreeze solution is added to the rain-type vertical haze removal tower 1 through the antifreeze solution raw material adding door 91, so that the concentration of the antifreeze solution returns to a required value.

FIG. 3 is an implementation schematic diagram of a four-air-outlet device of a silencing static pressure chamber configured on the rain-type vertical haze removal tower. The device comprises a vertical haze removal tower 1, deluge liquid 2, a deluge pump 3, a deluge spraying assembly 4, an air inlet 5, a deluge fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dustproof net 11, a silencing static pressure chamber 12, a silencing air pipe 13, a silencing rainproof elbow 14, an equipment chamber 79, a blowdown valve 85, a blowdown port 86, deluge purification synergistic filler 88, a tap water injection valve 89, a tap water port 90, an antifreeze liquid raw material adding door 91, an antifreeze liquid treatment valve 92 and an antifreeze liquid discharging port 93. The working principle of the attached drawing 3 is basically the same as that of the attached drawing 1 and the attached drawing 2, and the attached drawing 3 is added with a silencing static pressure chamber 12, a silencing air pipe 13 and a silencing rainproof elbow 14 on the basis of the attached drawing 2, so that the silencing effect is further enhanced, and an ultra-silent purification environment is created. Otherwise, the same as fig. 1 and 2, and the description thereof will not be repeated.

FIG. 4 is a schematic diagram of the liquid storage function of the rain-type vertical haze removal tower. The device comprises a vertical haze removal tower 1, a deluge liquid 2, a deluge pump 3, a deluge spraying component 4, an air inlet 5, a deluge fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, an air-water separation device 10, a dust screen 11, an equipment room 79, a drain valve 85, a drain interface 86, a deluge purification synergistic filler 88, a tap water filling valve 89, a tap water interface 90, an antifreeze liquid raw material adding door 91, an antifreeze liquid processing valve 92, an antifreeze liquid discharging interface 93, a tap water lower pouring valve 102, a deluge upper liquid supply valve 103, a deluge lower liquid supply valve 104, a lower drain valve 105, an upper liquid storage tank 106, a lower liquid storage tank 107 and a recovered deluge liquid 108. In fig. 4, an upper liquid storage tank 106 and a lower liquid storage tank 107 are added on the basis of fig. 2, and the function of the lower liquid storage tank 107 is to discharge the recovered anti-freezing solution 108 into the lower liquid storage tank 107 for storage when the haze removing tower is switched from winter to spring, summer and autumn for haze removing operation, and the anti-freezing solution can be reused in winter in the next year. When the haze removing operation is performed in spring, summer and autumn, the upper liquid storage tank 106 is filled with tap water deluge liquid 2 to be used as deluge liquid. When the shower spray assembly is operated, the under-shower liquid supply valve 104 is closed, the over-shower liquid supply valve 103 is opened, and the tap water shower liquid 2 is supplied to the shower spray assembly 4 through the shower pump 3. Running water and rain liquid 2 are discharged in winter haze removal operation, the upper liquid storage tank 106 and the lower liquid storage tank 107 are filled with the anti-freezing liquid and rain liquid 2, and the upper liquid supply valve 103 and the lower liquid supply valve 104 are opened for operation respectively or simultaneously. When the upper storage tank 106 and the lower storage tank 107 need tap water, the tap water is respectively injected into the upper storage tank 106 and the lower storage tank 107 through the tap water injection valve 89 and the tap water injection valve 102 through the tap water interface 90.

The rest of fig. 4 is the same as fig. 2, the working principle is the same, and the description is not repeated here.

FIG. 5 is an implementation schematic diagram of the rain-type vertical haze removal tower provided with the four air outlet devices with the liquid storage function. The device comprises a vertical haze removal tower 1, a deluge liquid 2, a deluge pump 3, a deluge spraying component 4, an air inlet 5, a deluge fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, an air-water separation device 10, a dustproof net 11, a silencing static pressure chamber 12, a silencing air pipe 13, a silencing rainproof elbow 14, an equipment chamber 79, a blow-down valve 85, a blow-down connector 86, deluge purification synergistic filler 88, a tap water injection valve 89, a tap water connector 90, an antifreeze liquid raw material adding door 91, an antifreeze liquid treatment valve 92, an antifreeze liquid discharging connector 93, a tap water lower pouring valve 102, a deluge upper liquid supply valve 103, a deluge lower liquid supply valve 104, a lower sewage discharge valve 105, an upper liquid storage tank 106, a lower liquid storage tank 107 and a recovered deluge liquid. FIG. 5 is a view similar to FIG. 4 and FIG. 3, but with the addition of an upper tank 106 and a lower tank 107, the operation and operation of which are identical to those of FIG. 3 and are not repeated herein.

FIG. 6 is a schematic view of a basic implementation of the deluge horizontal haze removal tower of the present invention. In the figure, by horizontal haze tower 111 that removes, drench liquid 2, deluge pump 3, drench and spray subassembly 4, air intake 5, deluge fan 6, air outlet 7 and perpendicular tuber pipe 113 are connected and are constituted, the difference of figure 6 and figure 1 lies in horizontal haze tower 111 horizontal assembly that removes, utilize the atmosphere to spray 2 of drench liquid that subassembly 4 sprayed through drenching perpendicularly and by the washing, will have certain horizontal distance at least according to the purification grade, drench liquid 2 that spray subassembly 4 sprayed for deluge and the severe haze atmosphere that air intake 5 inhaled provide sufficient horizontal washing time. The deluge fan 6 is installed below the air outlet 7 in the vertical air duct 113, and the difference from fig. 1 is that the installation height of the deluge fan 6 does not need a certain vertical height, and the height thereof can be determined as required. The rain spray component 4 is installed to be composed of rain spray heads which are horizontally opposite from top to bottom, are formed by the inner wall from left to right and are formed by four directions from bottom to top, and sprays rain liquid 2 in four directions to the haze removal tower to wash haze pollutants. Other working processes are the same as those in fig. 1, and are not described again here. Horizontal haze tower 111 that removes constitute the haze atmosphere purifier that removes of independent operation by the one-level at least, dispose on the roof of building, utilize the height on building roof, remove the haze of haze tower 1 cooperation elimination high altitude and low latitude perpendicularly with figure 1. If haze tower 1 is removed perpendicularly in fig. 1 and a proper amount of horizontal haze tower 111 that removes in fig. 6 is installed in a matched manner, urban atmosphere haze can be eliminated immediately.

FIG. 7 is a schematic view of the horizontal installation and implementation of the rain horizontal haze removal tower fan. In the figure, the device comprises a horizontal haze removal tower 111, a deluge liquid 2, a deluge pump 3, a deluge spraying component 4, an air inlet 5, a deluge fan 6, an air outlet 7, a deluge purification synergistic filler 88 and a deluge liquid device 112. The difference between fig. 7 and fig. 6 is that the deluge fan 6 is horizontally installed and is provided with deluge purification synergistic filler 88, which has the function of increasing the purification efficiency on the one hand, and on the other hand, because the deluge fan 6 is horizontally installed, the deluge liquid 2 is easily discharged, and because of the deluge purification synergistic filler 88, the raindrops sprayed by the deluge spraying component 4 can be blocked, so that the deluge liquid is not blown to the outside of the haze tower by the deluge fan 6. Other working processes are the same as those in fig. 6, and are not repeated.

FIG. 8 is a schematic view of the rain-shower horizontal haze removal tower according to the present invention, which is implemented by a plurality of purification synergistic filler efficient purification devices. The device comprises a horizontal haze removal tower 111, deluge liquid 2, a deluge pump 3, a deluge spraying assembly 4, an air inlet 5, a deluge fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, an air-water separation device 10, a dust screen 11, a blow-down valve 85, a blow-down interface 86, deluge purification synergistic packing 88, a tap water filling valve 89, a tap water interface 90, an antifreeze liquid raw material adding door 91, an antifreeze liquid treatment valve 92, an antifreeze liquid discharging interface 93, a deluge liquid device 112 and a vertical air pipe 113. Fig. 8 is different from fig. 6 in that fig. 8 is additionally provided with functional devices such as a fan muffler 8, a noise elimination hood 9, a gas-water separation device 10, a dust screen 11, a blow-off valve 85, a blow-off connector 86, a deluge purification synergistic filler 88, a tap water injection valve 89, a tap water connector 90, an antifreeze raw material adding door 91, an antifreeze treatment valve 92, an antifreeze discharging connector 93, a vertical air pipe 113 and a deluge liquid device 112, so that the haze elimination and atmosphere purification functions are improved, and the working process is already described in fig. 2 and will not be repeated.

FIG. 9 is an implementation schematic diagram of the deluge horizontal haze removal tower of the present invention, which is implemented by a plurality of groups of purification synergistic fillers, and is configured with vertical air pipes and a liquid storage device. The device comprises a horizontal haze removal tower 111, deluge liquid 2, a deluge pump 3, a deluge spraying assembly 4, an air inlet 5, a deluge fan 6, an air outlet 7, a blow-down valve 85, a blow-down interface 86, deluge purification synergistic packing 88, a tap water filling valve 89, a tap water interface 90, an antifreeze treatment valve 92, an antifreeze discharge interface 93, a deluge liquid distribution device 112 and a vertical air pipe 113. Fig. 9 is different from fig. 8 in that the vertical air duct 113 in fig. 8 is disposed at the upper portion of the horizontal haze removal tower 111, the air inlets 5 are disposed at two ends of the horizontal haze removal tower 111 to improve the haze removal and atmosphere purification functions, and the working process is already described in fig. 2 and will not be described again.

FIG. 10 is a schematic view of the rain-shower horizontal haze removal tower according to the present invention, wherein the haze removal tower is implemented by a plurality of groups of purification synergistic filler four-air-out devices. The device comprises a horizontal haze removal tower 111, deluge liquid 2, a deluge pump 3, a deluge spraying assembly 4, an air inlet 5, a deluge fan 6, an air outlet 7, a fan silencer 8, an air-water separation device 10, a dustproof net 11, a silencing static pressure chamber 12, a silencing air pipe 13, a silencing rainproof elbow 14, an equipment chamber 79, a blow-off valve 85, a blow-off connector 86, deluge purification synergistic filler 88, a tap water injection valve 89, a tap water connector 90, an antifreeze liquid raw material adding door 91, an antifreeze liquid treatment valve 92, an antifreeze liquid discharging connector 93, a deluge liquid distribution device 112 and a vertical air pipe 113. FIG. 10 is a combination of the parts shown in FIG. 9 and FIG. 3, which creates an ultra-silent horizontal haze removal system. The working process is described in fig. 9 and 3 and is not repeated.

FIG. 11 is an implementation schematic diagram of a haze-removing tower heat pump haze-addressing system formed by the rain-type haze-removing tower water source heat pump air conditioner. In the figure, the haze-removing tower heat pump is composed of a vertical haze-removing tower 1, a deluge liquid 2, a deluge pump 3, a deluge spraying assembly 4, an air inlet 5, a deluge fan 6, an air outlet 7, a deluge liquid circulating pump 25, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, an air conditioner output circulating pump 35 and a machine coil pipe 36. FIG. 11 removes haze tower 1 perpendicularly with FIG. 1 and combines together with water source heat pump 26, constitutes and removes haze tower heat pump air conditioning system, realizes eliminating the pollutant that other people discharged to the atmosphere again free when the heating operation of zero release in winter realizes, administers to the haze and reaches the effect of addressing both the symptoms and root causes. The heat pump air-conditioning system of the haze removal tower is installed and used in a large number, haze can be cured in a short time, and blue sky white cloud dreams can be rapidly realized.

When heating and heat supply are carried out in winter, the anti-freezing rain liquid 2 and the atmospheric haze washing process are also the process of the interaction heat exchange between the rain liquid 2 and air, the air heat is converted into the heat of the rain liquid 2, the rain liquid 2 represents the air temperature, the rain liquid 2 is sent to the water side of the water source heat pump 26 evaporator 30 for circulation through the rain liquid circulating pump 25, the rain liquid 2 is evaporated and absorbs the heat by the refrigerant circulating at the refrigerant side of the evaporator 30, and after the heat of the rain liquid 2, namely the air, is absorbed, the superheated refrigerant gas is compressed by the refrigerant compressor 27 and the resulting high-temperature and high-pressure discharge gas is condensed to release heat on the refrigerant side by the condenser 28, the heating water circulated by the air conditioner output circulating pump 35 is heated and sent to the fan coil 36 to blow hot air to the air-conditioning room for heating, the heating water condensed and heated by the refrigerant side of the condenser 28 is continuously circulated, and zero emission heating operation is realized through the fan coil 36. The refrigerant after heat release is condensed by the refrigerant side of the condenser 28, throttled by the expansion valve 29 and repeatedly flows into the refrigerant side of the evaporator 30, the heat in the raining liquid 2 circulated by the raining liquid circulating pump 25 is continuously evaporated and absorbed, the supercooled raining liquid 2 flows back to the vertical haze removal tower 1 and is circulated to the raining spraying component 4 again by the raining pump 3, raindrops are sprayed to reversely wash and rub atmospheric haze, the raining liquid 2 which exchanges heat with the atmospheric air and is supercooled is heated by the atmospheric air again, and after the heat is exchanged to the atmospheric temperature, the heat is continuously and repeatedly used as heat source water of the water source heat pump, so that an air heat source is continuously provided for the water source heat pump, and the normal operation of the water source heat pump air. The crowd-view deluge liquid 2 sends air heat to the water source heat pump, after the water source heat pump extracts heat to realize zero-emission heating, the supercooled deluge liquid 2 is sent back to the vertical haze removal tower 1 to be used as the deluge liquid 2 for washing atmospheric haze again, pollutants discharged to the atmosphere from other industries, power plants and motor vehicles are washed free of charge, the process of ideal zero-emission heating and heat supply and simultaneously obligatory elimination of pollutants discharged to the atmosphere from other people is completed, and both principal and secondary aspects of treatment and treatment of haze are achieved.

During the operation of summer refrigeration, the antifreeze who heats the operation in winter is changed for the running water, exchange the position with condenser 28 and 30 water sides of evaporimeter by eight conventional valves, make condenser 28 water side be connected to drench liquid circulating pump 25 one end and remove the one end of haze tower 1 perpendicularly, with the heat of condensation heat transfer to perpendicularly remove among the drench liquid 2 of haze tower 1 this moment, through the process of washing atmosphere haze, with the heat of condensation by drench liquid 2 give off to the atmosphere in, accomplish the exothermic cooling process of condensation. Meanwhile, the water side of the evaporator 30 is connected to one end of an air conditioner output circulating pump 35 and one end of a fan coil 36, at this time, refrigerant throttled by an expansion valve 29 on the refrigerant side of the evaporator 30 evaporates and absorbs refrigerant water circulated by the air conditioner output circulating pump 35, the refrigerant water is refrigerated into chilled water by evaporating and absorbing heat on the refrigerant side of the evaporator 30, the chilled water is circulated and input into the fan coil 36, the chilled water flows back to the air conditioner output circulating pump 35 through the fan coil 36, the air conditioner is refrigerated and operated by blowing cold air to an air conditioning room through the fan coil 36, and atmospheric pollutants are eliminated in a free obligation.

Fig. 12 is an implementation schematic diagram of a haze treatment and temporary treatment system of the rain type haze removal tower cold and hot air type heat pump air conditioner. In the figure, a haze-removing tower heat pump is composed of a vertical haze-removing tower 1, a deluge liquid 2, a deluge pump 3, a deluge spraying assembly 4, an air inlet 5, a deluge fan 6, an air outlet 7, a deluge liquid circulating pump 25, a refrigeration compressor 27, an expansion valve 29, an evaporator 30, an indoor cold and hot air heat exchanger 37, an indoor air conditioner fan 38, a cold and hot air type air conditioner terminal 81 and a cold and hot air type heat pump air conditioner 95. Fig. 12 shows a combination of the vertical shower tower 1 of fig. 1 and a cold-hot air type heat pump air conditioner 95 to form a shower tower cold-hot air type heat pump air conditioning system. Fig. 12 is different from fig. 11 only in the form of the air conditioning terminal, and the cold and hot air type air conditioning terminal 81 in fig. 12 blows cold and hot air to the air-conditioned room through the refrigerant for air conditioning operation, and the condensation heat directly releases heat to the space through the indoor cold and hot air heat exchanger 37 during heating operation and is circularly blown to the air-conditioned room by the indoor air conditioning fan 38. In fig. 11, after the condenser 28 outputs cold and hot water to the fan coil 36, the fan coil 36 blows cold and hot air to the air-conditioned room. During the operation of summer refrigeration, compressor 27 inhales, exhausts and commutates through conventional four-way reversing valve, and evaporimeter 30 becomes the condenser and uses, removes haze tower 1 with the condensation heat input perpendicularly and drenches among liquid 2, through the process of washing atmosphere haze, with the condensation heat by drenching liquid 2 distribute to the atmosphere among, accomplish the exothermic cooling process of condensation. The rest is the same as that of FIG. 11, and the description will not be repeated.

Fig. 13 is a schematic diagram of the implementation of the rain tower and the water source heat pump domestic hot water unit of the rain tower type haze rapid and low-cost radical treatment system. In the figure, a deluge tower 1, deluge liquid 2, a deluge pump 3, a deluge spraying component 4, an air inlet 5, a deluge fan 6, an air outlet 7, a deluge liquid circulating pump 25, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a domestic hot water heat storage circulating pump 39, a domestic hot water heat storage heat preservation water tank 40, a tap water interface 41 and a domestic hot water output interface 42. Fig. 13 is the same as fig. 11, except that a domestic hot water heat storage circulating pump 39 replaces the air conditioner output circulating pump 35 in fig. 11, a domestic hot water heat storage and heat preservation water tank 40 replaces the fan coil 36 in fig. 11, the domestic hot water heat storage circulating pump 39 stores hot water in the domestic hot water heat storage and heat preservation water tank 40, domestic hot water is supplied to the domestic hot water system through a domestic hot water output interface 42, and tap water is filled from a tap water interface 41. The utility model provides a rain tower haze is quick low-priced radical treatment formula zero release boiler device.

If a refrigerating and heating conversion valve is arranged on the water source heat pump 26 in the figure 13, the figure 12 can also form an energy storage air conditioning system application. When the domestic hot water heat storage and heat preservation water tank 40 operates as an energy storage air conditioner, the domestic hot water heat storage and heat preservation water tank is used as an air conditioner energy storage water tank to store cold water and hot water required by the air conditioner. The domestic hot water output interface 42 and the tap water interface 41 are used as cold and hot water output interfaces of the air conditioner and are connected with a fan coil air conditioner terminal system, and cold and hot water stored in the domestic hot water heat storage and heat preservation water tank 40 is output to the air conditioner terminal system to form an energy storage air conditioner operation system.

Fig. 14 is a schematic view of an implementation of the water source heat pump air conditioner in which the rain-type haze removal tower completes cooling and heating conversion at the refrigerant side. In the figure, the haze-removing tower heat pump is composed of a vertical haze-removing tower 1, a deluge liquid 2, a deluge pump 3, a deluge spraying component 4, an air inlet 5, a deluge fan 6, an air outlet 7, a deluge liquid circulating pump 25, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, an air conditioner output circulating pump 35, a fan coil 36, a refrigeration and heating conversion valve 98, a refrigeration and heating conversion valve 99, a refrigeration and heating conversion valve 100 and a refrigeration and heating conversion valve 101. Fig. 14 is substantially the same as fig. 11 except that the cooling/heating switching of fig. 14 is performed on the refrigerant side by the cooling/heating switching valve 98, the cooling/heating switching valve 99, the cooling/heating switching valve 100, and the cooling/heating switching valve 101.

During heating operation in winter, the cooling and heating conversion valve 98 is opened, the cooling and heating conversion valve 99 is closed, the exhaust gas of the refrigeration compressor 27 enters the refrigerant side of the condenser 28 through the cooling and heating conversion valve 98, the refrigerant after condensation and heat release throttles the expansion valve 29 and then enters the refrigerant side of the evaporator 30, after the heat of the deluge liquid 2 is evaporated and absorbed, the superheated refrigerant gas is input to the suction end of the refrigeration compressor 27 through the cooling and heating conversion valve 100, and the refrigeration compression cycle operation is repeated after compression.

When in refrigerating operation in summer, the refrigerating and heating conversion valve 98 is closed, the refrigerating and heating conversion valve 99 is opened, the exhaust gas of the refrigerating compressor 27 enters the refrigerant side of the evaporator 30 from the refrigerating and heating conversion valve 99 to release condensation heat, the condensed refrigerant is throttled by the expansion valve 29 and then is input to the refrigerant side of the condenser 28, after the heat in the air-conditioning refrigerant water flowing through the water side of the condenser 28 is evaporated and absorbed, the overheated refrigerant is input to the air suction end of the refrigerating compressor 27 through the refrigerating and heating conversion valve 101, and the refrigerating and compressing cycle operation is repeated after the compression. The rest is identical to that of fig. 10, and the description is not repeated.

FIG. 15 is a schematic view of an embodiment of an antifreeze solution storage and proportioning tank configured for the rain type haze removal tower water source heat pump air conditioner. In the figure, the haze removal tower heat pump system is composed of a vertical haze removal tower 1, a deluge liquid 2, a deluge pump 3, a deluge spraying component 4, an air inlet 5, a deluge fan 6, an air outlet 7, a spraying liquid return valve 23, a deluge liquid spraying valve 24, a deluge liquid circulating pump 25, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, an air conditioner output circulating pump 35, a fan coil 36, a diluted antifreeze liquid pouring valve 43, an antifreeze liquid storage proportioning tank 46, an antifreeze liquid concentration proportioning pump 48, an antifreeze liquid concentration proportioning valve 49 and a diluted antifreeze liquid 82. Fig. 15 is a view that an antifreeze solution storage and proportioning tank 46 is added on the basis of fig. 11, in winter, when the antifreeze solution of the system is diluted and the liquid level is increased and the vertical haze removal tower 1 cannot be accommodated, the diluted antifreeze solution pouring valve 43 is opened, the spray returning valve 23 is closed, the raining solution 2 circulated by the raining solution circulating pump 25 is poured into the antifreeze solution storage and proportioning tank 46 from the diluted antifreeze solution pouring valve 43, and after a proper amount of the raining solution is poured, the diluted antifreeze solution pouring valve 43 is closed, the spray returning valve 23 is opened, and the system resumes normal operation. The antifreeze solution raw materials are added into the antifreeze solution storage proportioning tank 46, the antifreeze solution concentration proportioning pump 48 and the antifreeze solution concentration proportioning valve 47 are opened, the diluted antifreeze solution pouring valve 43 is closed, the antifreeze solution raw materials are dissolved in the diluted antifreeze solution 82 by the antifreeze solution concentration proportioning pump 48, and the concentration of the diluted antifreeze solution 82 is increased. If the system is lack of antifreeze, the antifreeze in the antifreeze storage tank 46 can be supplemented to the system. The high-concentration antifreeze solution is supplemented by an antifreeze solution concentration proportioning pump 48 and an antifreeze solution concentration proportioning valve 49, and the high-concentration antifreeze solution is injected into the deluge 2 system, so that the concentration of the deluge 2 of the system is changed. The other working processes are the same as those in FIG. 11 and are not repeated.

FIG. 16 is an implementation schematic diagram of an antifreeze solution storage proportioning tank air conditioner configured by the rain type haze removal tower cold and hot air type heat pump. In the figure, a haze removal tower heat pump is composed of a vertical haze removal tower 1, a deluge liquid 2, a deluge pump 3, a deluge spraying component 4, an air inlet 5, a deluge fan 6, an air outlet 7, a spraying liquid return valve 23, a deluge liquid spraying valve 24, a deluge liquid circulating pump 25, a refrigeration compressor 27, an expansion valve 29, an evaporator 30, an indoor cold and hot air heat exchanger 37, an indoor air conditioner fan 38, a diluted antifreeze liquid pouring valve 43, an antifreeze liquid storage and proportioning tank 46, an antifreeze liquid concentration proportioning pump 48, an antifreeze liquid concentration proportioning valve 49, a diluted antifreeze liquid 82, a cold and hot air type air conditioner terminal 81, and a cold and hot air type heat pump air conditioner 95. FIG. 15 is substantially the same as FIG. 11, except that a diluted antifreeze solution pouring valve 43, an antifreeze solution reservoir tank 46, an antifreeze solution concentration proportioning pump 48, an antifreeze solution concentration proportioning valve 49, and an antifreeze solution processing apparatus for diluted antifreeze solution 82 are provided, and the operation of FIG. 16 is the same as that of FIGS. 11 and 15, and will not be described again.

FIG. 17 is an implementation schematic diagram of an antifreeze solution storage and proportioning tank configured for the deluge-type haze-tower-removing domestic hot water unit. The system comprises a vertical haze removal tower 1, a deluge liquid 2, a deluge pump 3, a deluge spraying component 4, an air inlet 5, a deluge fan 6, an air outlet 7, a spray liquid return valve 23, a deluge liquid spray valve 24, a deluge liquid circulating pump 25, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a domestic hot water heat storage circulating pump 39, a domestic hot water heat storage heat preservation water tank 40, a tap water interface 41, a domestic hot water output interface 42, a diluted antifreeze liquid pouring valve 43, an antifreeze liquid storage tank 46, an antifreeze concentration proportioning pump 48, an antifreeze concentration proportioning valve 49 and a diluted antifreeze liquid 82. FIG. 16 is the same as FIG. 12, except that FIG. 16 additionally includes a diluted antifreeze pouring valve 43, an antifreeze reservoir tank 46, an antifreeze concentration proportioning pump 48, an antifreeze concentration proportioning valve 49, and a diluted antifreeze 82.

Fig. 17 shows that if a cooling/heating conversion device is provided in the water source heat pump 26, an energy storage air conditioning system can be further constructed, and the working principle thereof is the same as that in fig. 13, and the description thereof is not repeated. The rest of the operation of fig. 17 is the same as that of fig. 13 and 15, and the description will not be repeated.

Fig. 18 is a schematic diagram of an antifreeze solution storage and proportioning tank configured for the rain-type haze removal tower water source heat pump air conditioner and implementing refrigeration and heating conversion on a refrigerant side. In the figure, the haze removal tower heat pump is composed of a vertical haze removal tower 1, a deluge liquid 2, a deluge pump 3, a deluge spraying component 4, an air inlet 5, a deluge fan 6, an air outlet 7, a deluge liquid circulating pump 25, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, an air conditioner output circulating pump 35, a fan coil 36, a diluted antifreeze liquid pouring valve 43, an antifreeze liquid storage and proportioning tank 46, an antifreeze liquid concentration proportioning pump 48, an antifreeze liquid concentration proportioning valve 49, a diluted antifreeze liquid 82, a refrigeration and heating switching valve 98, a refrigeration and heating switching valve 99, a refrigeration and heating switching valve 100 and a refrigeration and heating switching valve 101. FIG. 17 is the same as FIG. 13, except that FIG. 17 is provided with a diluted antifreeze pouring valve 43, an antifreeze reservoir tank 46, an antifreeze concentration proportioning pump 48, an antifreeze concentration proportioning valve 49, and a diluted antifreeze 82. The operation of fig. 18 is the same as that of the systems of fig. 14 and 15 and will not be described again.

FIG. 19 is a haze treatment addressing implementation schematic diagram of the combination of the rain type haze removal tower and the cooling tower type water chilling unit air conditioner. In the figure, the haze removing tower comprises a vertical haze removing tower 1, a rain liquid 2, a rain pump 3, a rain spraying component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spraying liquid 17, a water receiving disc 18, a spraying liquid distribution device 19, a cooling tower fan 20, a cooling tower spraying pump 21, a spraying liquid outlet valve 22, a spraying liquid return valve 23, a rain liquid spraying valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a cooling tower snow air outlet elbow 84, a rain tower opening and closing air valve 33, a rain tower air pipe 34, an air conditioner output circulating pump 35, a fan coil 36, a blow-down valve 54, a blow-down interface 63, an equipment room 79, a rain tower opening and closing air, The haze treatment system comprises a blow-down valve 85, a blow-down interface 86, a deluge purification synergistic filler 88, a tap water injection valve 89, a tap water interface 90, an antifreeze raw material adding door 91, an antifreeze treatment valve 92, an antifreeze discharging interface 93, a deluge spray pump 94, a cooling tower water injection valve 109 and a tap water interface 110. The difference between fig. 19 and fig. 11 is that a cooling tower 15 is disposed between the vertical haze removal tower 1 and the water source heat pump 26, a cooling tower air outlet pipe 31 and a rain tower air pipe 34 are disposed on the cooling tower blower 20, a cooling tower air outlet opening/closing air valve 32 and a rain tower air pipe opening/closing air valve 33 are disposed at the three-way air pipes of the cooling tower air outlet pipe 31 and the rain tower air pipe 34, and a cooling tower rain/snow prevention air outlet elbow 84 is disposed at the cooling tower air outlet pipe 31 above the cooling tower air outlet opening/closing air valve 32.

During heating operation in winter, the cooling tower 15 is used for extracting air heat for the water source heat pump 26 and converting the air heat into antifreeze heat to provide heat source water for the water source heat pump 26. When the air conditioner runs, the spraying liquid outlet valve 22 is opened, the cooling tower spraying pump 21 runs, the anti-freezing spraying liquid 17 is input to the water side of the evaporator 30 and flows into the spraying liquid distribution device 19, the anti-freezing spraying liquid 17 uniformly sprays the anti-freezing spraying liquid 17 to the cooling tower heat exchange filler 16 through the spraying liquid distribution device 19, at the moment, the cooling tower fan 20 runs, air is sucked from the cooling tower heat exchange filler 16 and is in friction heat exchange with the anti-freezing spraying liquid 17 in the cooling tower heat exchange filler 16, the heat of the air is converted into the spraying liquid 17, when the spraying liquid 17 representing the heat of the air flows through the water side of the evaporator 30, the refrigerant flowing at the refrigerant side of the evaporator 30 evaporates and absorbs the heat, the overheated refrigerant gas is compressed by the refrigeration compressor 27, the high-temperature and high-pressure compressed exhaust gas is condensed by the refrigerant side of the condenser 28 to release the heat, the heating water circulated by the air conditioner, and zero-emission heating is realized. The condensed refrigerant is throttled by the expansion valve 29 and then is input into the refrigerant side of the evaporator 30 to continue to repeat the evaporation and absorption of the heat in the spray liquid 17, so that zero-emission heating operation is maintained. Above-mentioned cooling tower fan 20 during operation, haze contaminated air is at the cooling tower heat transfer filler 16 with prevent frostbite spray 17 friction heat transfer in-process, the haze pollutant is sprayed and is prevented frostbite spray 17 washing purification, the pollutant falls into among the spray 17, its purification degree is not high through the atmosphere that cooling tower 15 purified, continue to open and close air valve 33 through cooling tower tuber pipe 31 to the rain spray tower tuber pipe, the air valve 32 is in the closed condition to the cooling tower air-out is opened and close this moment, the atmosphere that is tentatively purified by cooling tower 15 sends into through rain spray tower tuber pipe 34 and removes haze tower 1 perpendicularly, remove haze tower 1 perpendicularly and continue to purify, reach required purification degree. If the vertical haze removal tower 1 and the cooling tower 15 simultaneously operate, the cooling tower spray pump 21 stops operating, the deluge liquid spray valve 24 is opened, the deluge liquid 2 replaces the cooling tower spray pump 21 to spray and operate through the deluge liquid spray pump 94, and the anti-freezing spray liquid 17 flows back to the vertical haze removal tower 1 through the spray liquid return valve 23. When the vertical haze removal tower 1 and the cooling tower 15 operate simultaneously, the same antifreezing solution is adopted for the rain liquid 2 and the spray liquid 17. Atmospheric severe haze is through removing haze tower 1 and cooling tower 15 two-stage washing purification perpendicularly, and the purification degree improves greatly, if the purification grade still does not reach standard, can increase again and remove in the haze tower 1 perpendicularly and drench the spraying assembly 4 and drench the quantity that purifies increase filler 88 with drenching, increases the purification grade, makes it reach satisfied purification degree requirement.

When the vertical haze removal tower 1 and the cooling tower 15 operate simultaneously, the rain-spray tower opening and closing air valve 80 is closed, and all air sucked by the vertical haze removal tower 1 is air from the cooling tower 15. If in spring, summer, autumn, when removing haze tower 1 independent operation perpendicularly and purifying the atmosphere, rain tower tuber pipe is opened and close air valve 33 and is closed, and rain tower is opened and close air valve 80 and is opened, and the atmosphere is opened and close air valve 80 by rain tower and gets into and remove haze tower 1 perpendicularly, independently accomplishes the atmosphere and purifies the operation. When the refrigeration air conditioner operates in summer, the rain tower air pipe open-close air valve 33 is closed, the cooling tower air outlet open-close air valve 32 is opened, and when the cooling tower fan 20 operates, air passes through the cooling tower air outlet pipe 31, passes through the cooling tower air outlet open-close air valve 32, and is exhausted to the atmosphere from the cooling tower rain and snow prevention air outlet elbow 84. The cooling tower 15 is in a normal cooling tower operation mode, and the operation principle of the cooling and air conditioning in summer is completely the same as that in fig. 11, and the description is not repeated here. When the refrigerating air conditioner operates in summer, the spray liquid 17 should be replaced by tap water.

FIG. 20 is a haze treatment addressing implementation schematic diagram combining a rain-type haze removal tower and a cooling tower type cold and hot air type air conditioner. In the figure, a haze removing tower 1, a rain liquid 2, a rain pump 3, a rain spraying component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spraying liquid 17, a water receiving disc 18, a spraying liquid distribution device 19, a cooling tower fan 20, a cooling tower spraying pump 21, a spraying liquid outlet valve 22, a spraying liquid return valve 23, a rain liquid spraying valve 24, a refrigeration compressor 27, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a rain tower air pipe opening and closing air valve 33, a rain tower air pipe 34, an indoor cold and hot air heat exchanger 37, an indoor air conditioner fan 38, a blow-down valve 54, a blow-down interface 63, an equipment room 79, a rain tower opening and closing air valve 80, a cold and hot air type air conditioner terminal 81, a cooling tower rain and snow outlet, The cold and hot air type haze treating system comprises a blowdown valve 85, a blowdown port 86, a deluge purification synergistic filler 88, a tap water injection valve 89, a tap water port 90, an antifreeze raw material adding door 91, an antifreeze treatment valve 92, an antifreeze discharging port 93, a deluge spray pump 94 and a cold and hot air type heat pump air conditioner 95. Fig. 20 is substantially the same as fig. 19 except that fig. 19 is operated by a condenser 28 outputting cold and hot water to blow cold and hot air through a fan coil 36 into an air-conditioned room. In fig. 20, the condenser 28 is replaced by an indoor cold and hot air heat exchanger 37, and the indoor cold and hot air heat exchanger 37 blows cold and hot air directly to the air-conditioned room through an indoor air-conditioning fan 38 for air-conditioning operation. The operation principle is the same as that of fig. 16 and 19, and the description is not repeated here.

Fig. 21 is a schematic view of an embodiment of the shower-type haze removal tower and cooling tower combined domestic hot water unit. In the figure, a haze removing tower 1, a deluge liquid 2, a deluge pump 3, a deluge spraying component 4, an air inlet 5, a deluge fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, a cooling tower heat exchange filler 16, a spray liquid 17, a water receiving tray 18, a spray liquid distribution device 19, a cooling tower fan 20, a cooling tower spray pump 21, a spray liquid outlet valve 22, a spray liquid return valve 23, a deluge liquid spray valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a deluge tower air pipe opening and closing air valve 33, a deluge tower 34, a domestic hot water heat storage circulating pump 39, a domestic hot water heat storage and heat preservation water tank 40, a tap water interface 41, a domestic hot water output interface, The system comprises an on-off air valve 80 of the rain-sprinkling tower, a rain-snow preventing air outlet elbow 84 of the cooling tower, a blow-down valve 85, a blow-down interface 86, rain-sprinkling purification synergistic packing 88, a tap water injection valve 89, a tap water interface 90, an antifreeze raw material adding door 91, an antifreeze treatment valve 92, an antifreeze discharging interface 93 and a rain-sprinkling spray pump 94. Fig. 21 is substantially the same as fig. 19 except that in fig. 21, a domestic hot water heat-storage circulation pump 39 and a domestic hot water heat-storage holding water tank 40 replace the air-conditioning output circulation pump 35 and the fan coil 36 of fig. 19. When the drawing 21 is operated, the hot water output by the condenser 28 is stored in the domestic hot water heat storage and preservation water tank 40 through the domestic hot water heat storage circulating pump 39 and the water side of the condenser 28, and the domestic hot water is supplied to the domestic hot water system at any time through the domestic hot water output interface 42. The tap water interface 41 is connected with a tap water system to supplement tap water to the domestic hot water heat storage and preservation water tank 40 in real time. The refrigeration and heating conversion device shown in fig. 21 can also be used to form an energy storage air conditioning application system, which is the same as that shown in fig. 19, and the description is not repeated here.

FIG. 22 is a schematic view of the deluge-type haze removal tower and cooling tower combined air conditioner with refrigeration and heating conversion implemented on the refrigerant side; in the figure, the haze removing tower comprises a vertical haze removing tower 1, a rain liquid 2, a rain pump 3, a rain spraying component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spraying liquid 17, a water receiving disc 18, a spraying liquid distribution device 19, a cooling tower fan 20, a cooling tower spraying pump 21, a spraying liquid outlet valve 22, a spraying liquid return valve 23, a rain liquid spraying valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a cooling tower snow air outlet elbow 84, a rain tower opening and closing air valve 33, a rain tower air pipe 34, an air conditioner output circulating pump 35, a fan coil 36, a blow-down valve 54, a blow-down interface 63, an equipment room 79, a rain tower opening and closing air, The haze treating system comprises a blow-down valve 85, a blow-down connector 86, a deluge purification synergistic filler 88, a tap water injection valve 89, a tap water connector 90, an antifreeze raw material adding door 91, an antifreeze treatment valve 92, an antifreeze discharging connector 93, a deluge spray pump 94, a cooling and heating change-over valve 98, a cooling and heating change-over valve 99, a cooling and heating change-over valve 100, a cooling and heating change-over valve 101, a cooling tower water injection valve 109 and a tap water connector 110. Fig. 22 is substantially the same as fig. 19, except that the cooling/heating conversion device is disposed in the refrigerant circuit, and the other operation is the same as fig. 18 and 19, and will not be described again.

Fig. 23 is an implementation schematic diagram of the air conditioner combining the rain-type haze removing tower and the cooling tower, and provided with an antifreeze solution storage tank and an antifreeze solution concentration detection control device. In the figure, a vertical haze removal tower 1, a rain liquid 2, a rain pump 3, a rain spray component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spray liquid 17, a water receiving disc 18, a spray liquid distribution device 19, a cooling tower fan 20, a cooling tower spray pump 21, a spray liquid outlet valve 22, a spray liquid return valve 23, a rain liquid spray valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a cooling tower rain and snow outlet elbow 84, a rain tower air pipe opening and closing air valve 33, a rain tower air pipe 34, an air conditioner output circulating pump 35, a fan coil 36, an antifreeze concentration control valve 43, an antifreeze concentration control valve 44, an antifreeze concentration control valve 45, an antifreeze liquid storage proportioning tank 46, an antifreeze liquid stirring valve 47, an antifreeze liquid concentration proportioning pump 48, an antifreeze liquid concentration proportioning valve 49, a tap water injection valve 50, a tap water interface 51, an antifreeze liquid concentration automatic monitoring device 52, a blow-down valve 54, a blow-down interface 63, an equipment room 79, a deluge tower on-off air valve 80, diluted antifreeze liquid 82, a blow-down valve 85, a blow-down interface 86, deluge purification synergistic packing 88, a tap water injection valve 89, a tap water interface 90, an antifreeze liquid raw material adding door 91, an antifreeze liquid treatment valve 92, an antifreeze liquid discharge interface 93 and a deluge liquid spray pump 94 form a haze treatment and treatment system. FIG. 23 is a view substantially similar to FIG. 19, except that FIG. 23 includes an antifreeze reservoir tank 46 and an antifreeze concentration automatic monitoring device 52 for improving the quality of antifreeze operation.

When the air purification and heating operation is performed in winter, the antifreeze used by the rain liquid 2 and the spray liquid 17 can be diluted, and when the antifreeze is diluted to a certain degree, the freezing point temperature is reduced, so that the normal operation in winter is influenced. The antifreeze concentration automatic monitoring device 52 detects the antifreeze concentration value in real time, and when the antifreeze concentration is diluted to the preset freezing point value, the antifreeze concentration automatic monitoring device 52 displays the concentration value in real time and gives an audible and visual alarm to prompt an operator on duty to add and treat antifreeze through the antifreeze raw material adding gate 91 or the antifreeze storage and proportioning tank 46. And an automatic antifreezing solution raw material adding device can be also configured, and an automatic antifreezing solution raw material adding device which is configured in a linkage manner can automatically add antifreezing solution raw materials to the system of the deluge liquid 2 and the spray liquid 17 through the output signal of the automatic antifreezing solution concentration monitoring device 52.

In the operation of fig. 23 in winter, when the antifreeze is diluted to the preset critical value, the liquid level of the antifreeze rises and is much higher than the normal liquid level, the antifreeze concentration control valves 44 and 45 are closed, the antifreeze concentration control valve 43 is opened, the higher part of the diluted antifreeze 82 is discharged to the antifreeze liquid storage proportioning tank 46, the antifreeze concentration control valves 44 and 45 are opened, the antifreeze concentration control valve 43 is closed, and the cooling tower 15 returns to the normal operation. Antifreeze solution raw materials are added into an antifreeze solution storage proportioning tank 46, an antifreeze solution stirring valve 47 is opened, diluted antifreeze solution 82 and the antifreeze solution raw materials are fully stirred and fused by an antifreeze solution concentration proportioning pump 48, an antifreeze solution concentration proportioning valve 49 is opened, and high-concentration antifreeze solution is injected into the water pan 18 through the antifreeze solution concentration proportioning valve 49, so that the concentration of the spray solution 17 is increased, and the process of adjusting the concentration of the antifreeze solution is changed. When the cooling tower 15 needs the tap water, the tap water is supplied from the tap water connection 51 to the cooling tower 15 through the tap water supply valve 50. The operation of the other parts is the same as that of fig. 19, and the description thereof is not repeated.

FIG. 24 is an implementation schematic diagram of an antifreeze solution storage and proportioning tank air conditioner configured by the combination of the rain-type haze removal tower and the cooling tower and the cold and hot air type heat pump according to the present invention; in the figure, a vertical haze removal tower 1, a deluge liquid 2, a deluge pump 3, a deluge spraying component 4, an air inlet 5, a deluge fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange packing 16, a spray liquid 17, a water receiving disc 18, a spray liquid distribution device 19, a cooling tower fan 20, a cooling tower spray pump 21, a spray liquid outlet valve 22, a spray liquid return valve 23, a deluge liquid spray valve 24, a refrigeration compressor 27, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet on-off air valve 32, a deluge tower air pipe on-off air valve 33, a deluge tower air pipe 34, an indoor cold and hot air heat exchanger 37, an indoor air conditioner fan 38, an antifreeze liquid concentration control valve 43, an antifreeze liquid concentration control valve 44, an antifreeze liquid concentration control valve 45, an antifreeze liquid proportioning tank 46, An antifreeze concentration proportioning pump 48, an antifreeze concentration proportioning valve 49, a tap water injection valve 50, a tap water interface 51, an antifreeze concentration automatic monitoring device 52, a blow-down valve 54, a blow-down interface 63, an equipment room 79, a deluge tower on-off air valve 80, a cold and hot air type air conditioner terminal 81, a cooling tower rain and snow prevention air outlet elbow 84, a blow-down valve 85, a blow-down interface 86, a deluge purification synergistic filler 88, a tap water injection valve 89, a tap water interface 90, an antifreeze raw material adding door 91, an antifreeze treatment valve 92, an antifreeze discharge interface 93, a deluge spray pump 94 and a cold and hot air type heat pump air conditioner 95 form a cold and hot air type haze simultaneous treatment system. Fig. 24 is substantially the same as fig. 20, except that fig. 24 is additionally provided with an antifreeze treatment device such as an antifreeze solution storage tank 46, and the operation process thereof is completely the same as that of fig. 20 and 23 and is not repeated.

Fig. 25 is a schematic diagram of an implementation of the rain-type haze removal tower and cooling tower water source heat pump air conditioner combined type antifreeze solution storage proportioning tank and a refrigeration and heating conversion device on the refrigerant side. In the figure, the device comprises a vertical haze removal tower 1, a rain liquid 2, a rain pump 3, a rain spraying component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spraying liquid 17, a water receiving disc 18, a spraying liquid distribution device 19, a cooling tower fan 20, a cooling tower spraying pump 21, a spraying liquid outlet valve 22, a spraying liquid return valve 23, a rain liquid spraying valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a cooling tower snow air outlet elbow 84, a rain tower opening and closing air valve 33, a rain tower air pipe 34, an air conditioner output circulating pump 35, a fan coil 36, an antifreeze concentration control valve 43, an antifreeze concentration control valve 44, an antifreeze concentration control valve 45, a, An antifreeze liquid storage and proportioning tank 46, an antifreeze liquid stirring valve 47, an antifreeze liquid concentration proportioning pump 48, an antifreeze liquid concentration proportioning valve 49, a tap water injection valve 50, a tap water port 51, an antifreeze liquid concentration automatic monitoring device 52, a blow-down valve 54, a blow-down port 63, an equipment room 79, a deluge tower on-off air valve 80, a blow-down valve 85, a blow-down port 86, deluge purification synergistic filler 88, a tap water injection valve 89, a tap water port 90, an antifreeze liquid raw material adding door 91, an antifreeze liquid processing valve 92, an antifreeze liquid discharge port 93, a deluge liquid spray pump 94, a refrigeration and heating switching valve 98, a refrigeration and heating switching valve 99, a refrigeration and heating switching valve 100 and a refrigeration and heating switching valve 101 form a haze treatment system. FIG. 25 is a view showing an antifreeze treatment apparatus such as an antifreeze storage tank 46 disposed in addition to FIG. 22, and the operation procedures except for the antifreeze treatment are the same as those in FIG. 22 and will not be described again.

FIG. 26 is a schematic diagram of the implementation of the deluge haze removal tower and cooling tower water source heat pump combined domestic hot water unit; in the figure, a haze removing tower 1, a rain liquid 2, a rain pump 3, a rain spraying component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spray liquid 17, a water receiving disc 18, a spray liquid distribution device 19, a cooling tower fan 20, a cooling tower spray pump 21, a spray liquid outlet valve 22, a spray liquid return valve 23, a rain liquid spray valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a cooling tower snow and rain outlet air outlet elbow 84, a rain tower air pipe opening and closing air valve 33, a rain tower air pipe 34, a domestic hot water circulating pump 39, a domestic hot water heat-preserving water tank 40, a tap water interface 41, a domestic hot water output interface 42, an antifreeze concentration control valve 43, the antifreeze solution concentration control valve 44, the antifreeze solution concentration control valve 45, the antifreeze solution storage tank 46, the antifreeze solution stirring valve 47, the antifreeze solution concentration proportioning pump 48, the antifreeze solution concentration proportioning valve 49, the tap water injection valve 50, the tap water interface 51, the automatic antifreeze solution concentration monitoring device 52, the drain valve 54, the drain interface 63, the equipment room 79, the on-off air valve 80 of the raining tower, the diluted antifreeze solution 82, the drain valve 85, the drain interface 86, the deluge purification synergistic filler 88, the tap water injection valve 89, the tap water interface 90, the antifreeze solution raw material addition door 91, the antifreeze solution treatment valve 92, the antifreeze solution discharge interface 93 and the deluge solution spray pump 94 form a haze treatment system for treating both principal and secondary aspects of haze. FIG. 26 is identical to FIG. 23 except for the end. In fig. 26, if a cooling/heating conversion device is provided, an energy storage air conditioning application system can be further configured, cold and hot water is output from the domestic hot water heat storage and heat preservation water tank 40, at this time, the domestic hot water heat storage and heat preservation water tank 40 becomes an energy storage and heat preservation water tank, and the tap water interface 41 and the domestic hot water output interface 42 are connected with the tail end of the air conditioner. The rest is identical to that of fig. 23, and the description thereof is not repeated here.

Fig. 27 is an implementation schematic diagram of the energy storage type air conditioner with the combination of the rain type haze removal tower and the cooling tower water source heat pump and the configuration of the antifreeze solution storage and proportioning tank. In the figure, a vertical haze removal tower 1, a rain liquid 2, a rain pump 3, a rain spray component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spray liquid 17, a water receiving disc 18, a spray liquid distribution device 19, a cooling tower fan 20, a cooling tower spray pump 21, a spray liquid outlet valve 22, a spray liquid return valve 23, a rain liquid spray valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a cooling tower rain and snow outlet elbow 84, a rain tower air pipe opening and closing air valve 33, a rain tower air pipe 34, an air conditioner output circulating pump 35, a fan coil 36, an antifreeze concentration control valve 43, an antifreeze concentration control valve 44, an antifreeze concentration control valve 45, an antifreeze liquid storage proportioning tank 46, an antifreeze liquid stirring valve 47, an antifreeze liquid concentration proportioning pump 48, an antifreeze liquid concentration proportioning valve 49, a tap water injection valve 50, a tap water interface 51, an antifreeze liquid concentration automatic monitoring device 52, a blow-down valve 54, a blow-down interface 63, an energy storage circulating pump 72, an energy storage heat preservation water tank 73, an air conditioner output isolation heat exchanger 74, a domestic hot water output pump 75, a domestic hot water output interface 76, a tap water injection valve 77, a tap water interface 78, an equipment room 79, a deluge tower on-off air valve 80, a diluted antifreeze liquid 82, a blow-down valve 85, a blow-down interface 86, a deluge purification synergistic filler 88, a tap water injection valve 89, a tap water interface 90, an antifreeze liquid raw material adding door 91, an antifreeze liquid treatment valve 92, an antifreeze liquid discharge interface 93 and a deluge liquid spray pump 94. Fig. 27 is a diagram showing an energy storage device provided in addition to fig. 23, and the energy storage device can be operated by using low-cost valley electricity energy storage, and the process is as follows.

In winter, during heat storage operation, heating water enters the energy storage and heat preservation water tank 73 from the water side of the condenser 28 through the energy storage circulating pump 72, then flows back to the energy storage circulating pump 72 through the primary side of the air conditioner output isolation heat exchanger 74, heating hot water is stored in the energy storage and heat preservation water tank 73, meanwhile, the air conditioner output circulating pump 35 circulates the heating water at the tail end of an air conditioner, the heating water flows through the air conditioner output isolation heat exchanger 74 for two times and is heated by the primary side, the heated heating hot water is input into the fan coil 36, hot air is blown to an air-conditioned room through the fan coil 36 for heating, heating water after heat dissipation through the fan coil 36 returns to. Because the heating hot water stored in the energy-storing and heat-preserving water tank 73 and the heating circulating hot water system of the heating tail end fan coil are isolated by the air conditioner output isolation heat exchanger 74, the energy-storing and heat-preserving water tank 73 is clean tap water, the heating water stored in winter can be used as domestic hot water, and the investment for building a domestic hot water heat storage device is saved. Domestic hot water is supplied to the domestic hot water system by a domestic hot water output pump 75 through a domestic hot water output interface 76. Tap water is replenished through tap water connection 78 by tap water fill valve 77.

When the cold storage operation in summer, eight conventional refrigerating and heating conversion valves arranged on the water sides of the evaporator and the condenser convert the heating state in winter into the refrigerating state. During cold storage operation, the energy storage circulating pump 72 passes through eight conventional refrigerating and heating conversion valves from the water side of the evaporator 30 to the energy storage and heat preservation water tank 73, and flows back to the energy storage circulating pump 72 from the energy storage and heat preservation water tank 73 through the primary side of the air conditioner output isolation heat exchanger 74, so that the chilled water is stored in the energy storage and heat preservation water tank 73, and meanwhile, the chilled water is output from the secondary side of the air conditioner output isolation heat exchanger 74, so that the operation of the refrigerating air conditioner is completed. The rest is identical to that of fig. 23, and therefore, the description will not be repeated.

Fig. 28 is an implementation schematic diagram of the rain-type haze removal tower and cooling tower combined water source heat pump air conditioner provided with an antifreeze solution storage proportioning tank and a heating and drying device. In the figure, a vertical haze removal tower 1, a rain liquid 2, a rain pump 3, a rain spray component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spray liquid 17, a water receiving disc 18, a spray liquid distribution device 19, a cooling tower fan 20, a cooling tower spray pump 21, a spray liquid outlet valve 22, a spray liquid return valve 23, a rain liquid spray valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a cooling tower rain and snow outlet elbow 84, a rain tower air pipe opening and closing air valve 33, a rain tower air pipe 34, an air conditioner output circulating pump 35, a fan coil 36, an antifreeze concentration control valve 43, an antifreeze concentration control valve 44, an antifreeze concentration control valve 45, an antifreeze liquid storage proportioning tank 46, an antifreeze liquid stirring valve 47, an antifreeze liquid concentration proportioning pump 48, an antifreeze liquid concentration proportioning valve 49, a tap water injection valve 50, a tap water interface 51, an antifreeze liquid concentration automatic monitoring device 52, a blow-down valve 54, a blow-down interface 63, an equipment room 79, a deluge tower on-off air valve 80, diluted antifreeze liquid 82, a blow-down valve 85, a blow-down interface 86, an antifreeze liquid drying heating coil 87, a deluge purification synergistic filler 88, a tap water injection valve 89, a tap water interface 90, an antifreeze liquid raw material adding door 91, an antifreeze liquid treatment valve 92, an antifreeze liquid discharging interface 93, a deluge liquid spraying pump 94, an antifreeze liquid drying heating coil water supply valve 96 and an antifreeze liquid drying heating coil water return valve 97 form a haze treatment system. FIG. 26 is a view similar to FIG. 22, except that FIG. 26 is provided with an antifreeze solution drying heating coil 87 for heating and drying the diluted antifreeze solution 82 discharged into the antifreeze solution storage tank 46 to evaporate water from the diluted antifreeze solution 82 for increasing the concentration thereof. During the drying operation, the antifreeze solution drying heating coil heats the water supply valve 96, the heating hot water output from the water side of the condenser 28 passes through the antifreeze solution drying heating coil water supply valve 96 and is input into the antifreeze solution drying heating coil 87, the hot water heats the diluted antifreeze solution 82 through the antifreeze solution drying heating coil 87, and the water in the heated diluted antifreeze solution 82 is evaporated, so that the concentration of the water is increased. The heat-released heating hot water returns to the air conditioner output circulating pump 35 through the antifreeze drying heating coil water return valve 97 and returns to the water side input end of the condenser 28, and the aim of heating and drying antifreeze by using heating hot water circulation is fulfilled. The other parts are identical to those of fig. 23, and the description thereof will not be repeated.

FIG. 29 is an implementation schematic diagram of the rain-type haze removal tower and cooling tower combined water source heat pump combined air conditioner and the antifreeze solution storage and proportioning tank provided with a purification heat exchanger; in the figure, a vertical haze removal tower 1, a rain liquid 2, a rain pump 3, a rain spray component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spray liquid 17, a water receiving disc 18, a spray liquid distribution device 19, a cooling tower fan 20, a cooling tower spray pump 21, a spray liquid outlet valve 22, a spray liquid return valve 23, a rain liquid spray valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a cooling tower rain and snow outlet elbow 84, a rain tower air pipe opening and closing air valve 33, a rain tower air pipe 34, an air conditioner output circulating pump 35, a fan coil 36, an antifreeze concentration control valve 43, an antifreeze concentration control valve 44, an antifreeze concentration control valve 45, an antifreeze liquid storage proportioning tank 46, an antifreeze liquid stirring valve 47, an antifreeze liquid concentration proportioning pump 48, an antifreeze liquid concentration proportioning valve 49, a tap water injection valve 50, a tap water interface 51, an antifreeze liquid concentration automatic monitoring device 52, a blow-down valve 54, a purification heat exchanger 58, a purification heating primary pump 59, a purification heating secondary pump 60, a blow-down interface 63, an equipment room 79, a deluge tower on-off air valve 80, a diluted antifreeze liquid 82, a blow-down valve 85, a blow-down interface 86, deluge purification synergistic filler 88, a tap water injection valve 89, a tap water interface 90, an antifreeze liquid raw material addition door 91, an antifreeze liquid treatment valve 92, an antifreeze liquid discharge interface 93 and a deluge liquid spray pump 94 form a haze treatment system. FIG. 29 is substantially the same as FIG. 28 except that it is heated in a different manner, and FIG. 29 is a view showing the purification heat exchanger 58 being used to introduce heat from the hot heating water into and heat the dilute antifreeze solution 82. During heating operation, the purification heating primary pump 59 exchanges heat of heating hot water on the water side of the condenser 28 to the secondary side through the primary side of the purification heat exchanger 58, the heat-released heating water flows back to the water side of the condenser 28 through the air conditioner output circulating pump 35, heat of the heating water is exchanged to the secondary side through the heat exchange of the heating water, and then the heat is sent to the antifreeze solution storage proportioning tank 46 through the secondary purification heating secondary pump 60 to heat and dry the diluted antifreeze solution 82. The other parts are identical to those of fig. 28, and description thereof will not be repeated.

FIG. 30 is a schematic diagram of an implementation of the independent purification device configured by the rain-type haze removal tower and the cooling tower combined with the water source heat pump air conditioner. In the figure, a haze removing tower 1, a rain liquid 2, a rain pump 3, a rain spraying component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spraying liquid 17, a water receiving disc 18, a spraying liquid distribution device 19, a cooling tower fan 20, a cooling tower spraying pump 21, a spraying liquid outlet valve 22, a spraying liquid return valve 23, a rain liquid spraying valve 24, a rain liquid spraying pump 25, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing valve 32, a cooling tower rain and snow air outlet elbow 84, a rain tower air pipe opening and closing valve 33, a rain tower air pipe 34, an air conditioner output circulating pump 35, a fan coil 36, an antifreeze concentration control valve 43, an antifreeze concentration control valve 44, a water, An antifreeze solution concentration control valve 45, an antifreeze solution storage and proportioning tank 46, an antifreeze solution stirring valve 47, an antifreeze solution concentration proportioning pump 48, an antifreeze solution concentration proportioning valve 49, a tap water injection valve 50, a tap water interface 51, an antifreeze solution concentration automatic monitoring device 52, an antifreeze solution drying and purifying device 53, a blow-down valve 54, a diluted antifreeze solution injection valve 55, a purified antifreeze solution output pump 56, a purified antifreeze solution output valve 57, a purification heat exchanger 58, a purification heating primary pump 59, the purification heating secondary pump 60, the sewage discharge interface 63, the equipment room 79, the deluge tower on-off air valve 80, the diluted antifreeze solution 82, the purification antifreeze solution 83, the sewage discharge valve 85, the sewage discharge interface 86, the deluge purification synergistic filler 88, the tap water injection valve 89, the tap water interface 90, the antifreeze solution raw material adding door 91, the antifreeze solution treatment valve 92, the antifreeze solution discharge interface 93 and the deluge spray pump 94 form a haze treatment system. FIG. 30 is a view substantially similar to FIG. 29, except that FIG. 30 is provided with an antifreeze solution drying and purifying apparatus 53 constituting an independent diluted antifreeze solution heating, drying and purifying system. During purification operation, the diluted antifreeze solution 82 is injected into the antifreeze solution drying and purifying device 53 through the diluted antifreeze solution injection valve 55, and the diluted antifreeze solution injection valve 55 is closed when the upper limit of the liquid level is reached. The heating hot water passes through the primary side of the purification heat exchanger 58 by the purification heating primary pump 59 to exchange heat with the heating hot water to the secondary side of the purification heat exchanger 58, the secondary side hot water heated by the primary side is circulated by the purification heating secondary pump 60 and releases the heat of the heating hot water into the diluted antifreeze fluid 82 to heat and dry the diluted antifreeze fluid 82, the supercooled secondary side hot water passes through the purification heat exchanger 58 to continue to be heated by the primary side, and the process of heating and drying the diluted antifreeze fluid 82 by the heating hot water passing through the purification heat exchanger 58 is repeated. The dried purified antifreeze liquid 83 is injected into the water pan 18 through the purified antifreeze liquid outlet valve 57 by the purified antifreeze liquid outlet pump 56 to change the concentration of the spray liquid 17. The operation of other parts is the same as that of fig. 29, and the description is not repeated.

FIG. 31 is a schematic diagram of an embodiment of a two-stage water source heat pump air conditioner configured by combining the deluge-type haze removal tower and the cooling tower according to the present invention. In the figure, a vertical haze removal tower 1, a rain liquid 2, a rain pump 3, a rain spray component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spray liquid 17, a water receiving disc 18, a spray liquid distribution device 19, a cooling tower fan 20, a cooling tower spray pump 21, a spray liquid outlet valve 22, a spray liquid return valve 23, a rain liquid spray valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a cooling tower rain and snow outlet elbow 84, a rain tower air pipe opening and closing air valve 33, a rain tower air pipe 34, an air conditioner output circulating pump 35, a fan coil 36, an antifreeze concentration control valve 43, an antifreeze concentration control valve 44, an antifreeze concentration control valve 45, an antifreeze liquid storage and proportioning tank 46, an antifreeze liquid stirring pump 47, an antifreeze liquid concentration proportioning pump 48, an antifreeze liquid concentration proportioning valve 49, a tap water injection valve 50, a tap water port 51, an antifreeze liquid concentration automatic monitoring device 52, an antifreeze liquid drying and purifying device 53, a blow-down valve 54, a diluted antifreeze liquid injection valve 55, a purified antifreeze liquid output pump 56, a purified antifreeze liquid output valve 57, a purifying heat exchanger 58, a purifying and heating primary pump 59, a purifying and heating secondary pump 60, a third single-double stage switching valve 61, a coupling heat exchange circulating pump 62, a blow-down port 63, a fourth single-double stage switching valve 64, a first single-double stage switching valve 65, a second-stage heat pump 66, a second-stage refrigeration compressor 67, a second-stage condenser 68, a second-stage expansion valve 69, a second-stage evaporator 70, a second single-double stage switching valve 71, an equipment room 79, a rain tower on-off air valve 80, a diluted antifreeze liquid 82, a purified antifreeze liquid, The haze treatment system comprises a blow-down valve 85, a blow-down interface 86, a deluge purification synergistic filler 88, a tap water injection valve 89, a tap water interface 90, an antifreeze raw material adding door 91, an antifreeze treatment valve 92, an antifreeze discharging interface 93 and a deluge spraying pump 94. In the attached figure 31, on the basis of the attached figure 29, a primary heat pump is additionally arranged, and a secondary water source heat pump is arranged, so that an ultralow temperature heating system can be formed, and the system is suitable for efficient heating in winter in northern areas of China. The attached figure 31 is suitable for the high-efficiency heating operation at the atmospheric environment temperature of less than or equal to-35 ℃, outputs 65 ℃ heating hot water and is compatible with the temperature of the heating water of a northern coal-fired hot water boiler.

When the two-stage heating operation is performed in winter, the fourth single/double-stage switching valve 64 and the first single/double-stage switching valve 65 are closed, the third single/double-stage switching valve 61 is opened, the coupling heat exchange circulating pump 62, the water source heat pump 26 and the second-stage heat pump 66 are operated simultaneously, hot water output from the water side of the condenser 28 passes through the water side of the condenser 28 by the coupling heat exchange circulating pump 62, the water side of the condenser 28 passes through the water side of the second-stage evaporator 70 by the third single/double-stage switching valve 61, hot water output from the water side of the condenser 28 is subjected to heat exchange to the refrigerant side of the second-stage evaporator 70, the hot water is evaporated by the refrigerant flowing through the refrigerant side of the second-stage evaporator 70 to absorb heat, superheated refrigerant vapor is compressed by the second-stage refrigeration compressor 67, high-temperature and high-pressure exhaust gas is condensed by the refrigerant side of the second-stage condenser 68, the heat of the hot water flowing through the water side of the second-stage evaporator 70 is continuously evaporated and absorbed, and the heat output by the water source heat pump 26 is input to the second-stage heat pump 66 by the coupling heat exchange circulating pump 62 in a coupling circulating manner, so that the double-stage heating operation is completed.

When the refrigerating and air-conditioning operation is carried out in summer, the water side of the condenser 28 of the water source heat pump 26 is converted into the water side of the evaporator 30 through the conventional eight winter/summer conversion valves, and the output is chilled water. When the air conditioner is operated, the third single-double stage change-over valve 61 and the second single-double stage change-over valve 71 are closed, the chilled water circulated by the air conditioner output circulating pump 35 is conveyed to the fan coil 36 from the fourth single-double stage change-over valve 64 through the first single-double stage change-over valve 65, and the chilled water blows cold air to the air-conditioning room through the fan coil 36 for refrigeration, so that the single-stage refrigeration air-conditioning operation is completed. Because the temperature of the summer environment is less than about 35 ℃ in most areas, the refrigeration operation in summer is energy-saving, double-stage operation is not needed, and the single-stage operation can completely meet the refrigeration requirement.

Fig. 31 is an ideal air renewable energy zero-emission heating boiler or air conditioning device for a northern severe cold area, and is also a northern haze treatment and treatment system, and if the system is popularized and applied in a large area, northern haze can be eliminated at low cost in an instant. Meanwhile, the system can save very objective heating operation cost for users, can save immeasurable coal and natural gas resources for China, can improve the existing electric energy utilization rate of China, and has great social contribution significance.

FIG. 32 is a schematic view of a two-stage water source heat pump air conditioner configured by combining the deluge-type haze removal tower and the cooling tower according to the present invention, with refrigeration and heating conversion implemented on the refrigerant side; in the figure, a vertical haze removal tower 1, a rain liquid 2, a rain pump 3, a rain spray component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spray liquid 17, a water receiving disc 18, a spray liquid distribution device 19, a cooling tower fan 20, a cooling tower spray pump 21, a spray liquid outlet valve 22, a spray liquid return valve 23, a rain liquid spray valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a cooling tower rain and snow outlet elbow 84, a rain tower air pipe opening and closing air valve 33, a rain tower air pipe 34, an air conditioner output circulating pump 35, a fan coil 36, an antifreeze concentration control valve 43, an antifreeze concentration control valve 44, an antifreeze concentration control valve 45, an antifreeze liquid storage and proportioning tank 46, an antifreeze liquid stirring pump 47, an antifreeze liquid concentration proportioning pump 48, an antifreeze liquid concentration proportioning valve 49, a tap water injection valve 50, a tap water port 51, an antifreeze liquid concentration automatic monitoring device 52, an antifreeze liquid drying and purifying device 53, a blow-down valve 54, a diluted antifreeze liquid injection valve 55, a purified antifreeze liquid output pump 56, a purified antifreeze liquid output valve 57, a purifying heat exchanger 58, a purifying and heating primary pump 59, a purifying and heating secondary pump 60, a third single-double stage switching valve 61, a coupling heat exchange circulating pump 62, a blow-down port 63, a fourth single-double stage switching valve 64, a first single-double stage switching valve 65, a second-stage heat pump 66, a second-stage refrigeration compressor 67, a second-stage condenser 68, a second-stage expansion valve 69, a second-stage evaporator 70, a second single-double stage switching valve 71, an equipment room 79, a rain tower on-off air valve 80, a diluted antifreeze liquid 82, a purified antifreeze liquid, The haze treating system comprises a blow-down valve 85, a blow-down connector 86, a deluge purification synergistic filler 88, a tap water injection valve 89, a tap water connector 90, an antifreeze raw material adding door 91, an antifreeze treatment valve 92, an antifreeze discharging connector 93, a deluge spray pump 94, a cooling and heating change-over valve 98, a cooling and heating change-over valve 99, a cooling and heating change-over valve 100 and a cooling and heating change-over valve 101. Fig. 32 is substantially the same as fig. 31, except that the cooling-heating conversion of the water-source heat pump 26 is performed by the refrigerant side return, and the other parts are the same as fig. 31, and the description thereof will not be repeated.

Fig. 33 is an implementation schematic diagram of a two-stage water source heat pump domestic hot water unit configured by combining the deluge-type haze removal tower and the cooling tower. In the figure, a haze removing tower 1, a rain liquid 2, a rain pump 3, a rain spraying component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spray liquid 17, a water receiving disc 18, a spray liquid distribution device 19, a cooling tower fan 20, a cooling tower spray pump 21, a spray liquid outlet valve 22, a spray liquid return valve 23, a rain liquid spray valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a cooling tower snow and rain outlet air outlet elbow 84, a rain tower air pipe opening and closing air valve 33, a rain tower air pipe 34, a domestic hot water circulating pump 39, a domestic hot water heat-preserving water tank 40, a tap water interface 41, a domestic hot water output interface 42, an antifreeze concentration control valve 43, an antifreeze solution concentration control valve 44, an antifreeze solution concentration control valve 45, an antifreeze solution storage tank 46, an antifreeze solution stirring valve 47, an antifreeze solution concentration proportioning pump 48, an antifreeze solution concentration proportioning valve 49, a tap water injection valve 50, a tap water port 51, an antifreeze solution concentration automatic monitoring device 52, an antifreeze solution drying and purifying device 53, a blow-down valve 54, a diluted antifreeze solution injection valve 55, a purified antifreeze solution output pump 56, a purified antifreeze solution output valve 57, a purification heat exchanger 58, a purification heating primary pump 59, a purification heating secondary pump 60, a third single-double-stage switching valve 61, a coupling heat exchange circulating pump 62, a blow-down port 63, a fourth single-double-stage switching valve 64, a first single-double-stage switching valve 65, a second-stage heat pump 66, a second-stage refrigeration compressor 67, a second-stage condenser 68, a second-stage expansion valve 69, a second-stage evaporator 70, a second single-double-stage switching valve 71, an equipment room 79, The rain tower is provided with an air valve 80 for opening and closing, a diluted antifreeze 82, a purified antifreeze 83, a drain valve 85, a drain interface 86, a rain purification synergistic filler 88, a tap water injection valve 89, a tap water interface 90, an antifreeze raw material adding door 91, an antifreeze treatment valve 92, an antifreeze discharging interface 93 and a rain spray pump 94, so that the haze treatment system is formed. Fig. 31 is substantially the same as fig. 30 except that fig. 31 replaces the air conditioner output circulation pump 35 and the fan coil 36 of fig. 30 with a domestic hot water heat storage circulation pump 39 and a domestic hot water heat storage holding water tank 40. Fig. 33 is an ultra-low temperature domestic hot water system, which has the same working principle as fig. 26 and fig. 31, and the description thereof is not repeated. In fig. 33, if a conventional cooling/heating conversion device is provided, an ultra-low temperature energy storage air conditioning system can be formed, cold and hot water is output from the domestic hot water heat storage and heat preservation water tank 40, at this time, the domestic hot water heat storage and heat preservation water tank 40 becomes an energy storage and heat preservation water tank, and the tap water interface 41 and the domestic hot water output interface 42 are connected with the tail end of the air conditioner.

FIG. 34 is a schematic diagram of an embodiment of a two-stage water source heat pump energy storage air conditioner configured by combining a deluge-type haze removal tower and a cooling tower according to the present invention. In the figure, a vertical haze removal tower 1, a rain liquid 2, a rain pump 3, a rain spray component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spray liquid 17, a water receiving disc 18, a spray liquid distribution device 19, a cooling tower fan 20, a cooling tower spray pump 21, a spray liquid outlet valve 22, a spray liquid return valve 23, a rain liquid spray valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a cooling tower rain and snow outlet elbow 84, a rain tower air pipe opening and closing air valve 33, a rain tower air pipe 34, an air conditioner output circulating pump 35, a fan coil 36, an antifreeze concentration control valve 43, an antifreeze concentration control valve 44, an antifreeze concentration control valve 45, an antifreeze liquid storage and proportioning tank 46, an antifreeze liquid stirring valve 47, an antifreeze liquid concentration proportioning pump 48, an antifreeze liquid concentration proportioning valve 49, a tap water injection valve 50, a tap water port 51, an antifreeze liquid concentration automatic monitoring device 52, an antifreeze liquid drying and purifying device 53, a blow-down valve 54, a diluted antifreeze liquid injection valve 55, a purified antifreeze liquid output pump 56, a purified antifreeze liquid output valve 57, a purifying heat exchanger 58, a purifying and heating primary pump 59, a purifying and heating secondary pump 60, a third single-double stage switching valve 61, a coupling heat exchange circulating pump 62, a blow-down port 63, a fourth single-double stage switching valve 64, a first single-double stage switching valve 65, a second stage heat pump 66, a second stage refrigeration compressor 67, a second stage condenser 68, a second stage expansion valve 69, a second stage evaporator 70, a second single-double stage switching valve 71, an energy storage circulating pump 72, an energy storage and heat preservation water tank 73, an air conditioner output isolation heat, The haze treating system comprises a domestic hot water output pump 75, a domestic hot water output interface 76, a tap water injection valve 77, a tap water interface 78, an equipment room 79, a deluge tower opening and closing air valve 80, diluted antifreeze 82, purified antifreeze 83, a drain valve 85, a drain interface 86, deluge purification synergistic fillers 88, a tap water injection valve 89, a tap water interface 90, an antifreeze raw material adding door 91, an antifreeze treatment valve 92, an antifreeze discharge interface 93 and a deluge spray pump 94. . Fig. 34 is substantially the same as fig. 31, except that fig. 34 is configured with an energy storage device. The energy storage working principle is as follows:

in winter, during heat storage operation, heating water enters the energy storage and heat preservation water tank 73 from the energy storage circulating pump 72 to the water side of the second-stage condenser 68 through the second single-stage and double-stage switching valve 71, then flows back to the energy storage circulating pump 72 through the primary side of the air conditioner output isolation heat exchanger 74, heating hot water is stored in the energy storage and heat preservation water tank 73, meanwhile, the air conditioner output circulating pump 35 circulates the heating water at the tail end of the air conditioner, the heating water is heated by the primary side when flowing through the air conditioner output isolation heat exchanger 74 for two times, the heated heating hot water is input into the fan coil 36, hot air is blown to the air-conditioned room through the fan coil 36 for heating, the heating water after being. Because the heating hot water stored in the energy-storing and heat-preserving water tank 73 and the heating circulating hot water system of the heating tail end fan coil are isolated by the air conditioner output isolation heat exchanger 74, the energy-storing and heat-preserving water tank 73 is clean tap water, the heating water stored in winter can be used as domestic hot water, and the investment for building a domestic hot water heat storage device is saved. Domestic hot water is supplied to the domestic hot water system by a domestic hot water output pump 75 through a domestic hot water output interface 76. Tap water is replenished through tap water connection 78 by tap water fill valve 77.

In the cold storage operation in summer, the energy storage circulating pump 72 passes through the first single-double stage switching valve 65, flows from the water side of the condenser 28 to the energy storage heat preservation water tank 73 through the fourth single-double stage switching valve 64, flows back to the energy storage circulating pump 72 from the energy storage heat preservation water tank 73 through the primary side of the air conditioner output isolation heat exchanger 74, stores the chilled water in the energy storage heat preservation water tank 73, and simultaneously outputs the chilled water from the secondary side of the air conditioner output isolation heat exchanger 74 to finish the single-stage refrigeration air conditioner operation. The rest is identical to that of fig. 31 and therefore will not be described again.

FIG. 35 is a schematic view of an embodiment of a dual-stage water source heat pump configuration coupling circulation tank device configured by combining the deluge-type haze removal tower and the cooling tower according to the present invention. In the figure, a vertical haze removal tower 1, a rain liquid 2, a rain pump 3, a rain spray component 4, an air inlet 5, a rain fan 6, an air outlet 7, a fan silencer 8, a silencing hood 9, a gas-water separation device 10, a dust screen 11, a cooling tower 15, cooling tower heat exchange filler 16, spray liquid 17, a water receiving disc 18, a spray liquid distribution device 19, a cooling tower fan 20, a cooling tower spray pump 21, a spray liquid outlet valve 22, a spray liquid return valve 23, a rain liquid spray valve 24, a water source heat pump 26, a refrigeration compressor 27, a condenser 28, an expansion valve 29, an evaporator 30, a cooling tower air outlet pipe 31, a cooling tower air outlet opening and closing air valve 32, a cooling tower rain and snow outlet elbow 84, a rain tower air pipe opening and closing air valve 33, a rain tower air pipe 34, an air conditioner output circulating pump 35, a fan coil 36, an antifreeze concentration control valve 43, an antifreeze concentration control valve 44, an antifreeze concentration control valve 45, an antifreeze liquid storage and proportioning tank 46, an antifreeze liquid stirring pump 47, an antifreeze liquid concentration proportioning pump 48, an antifreeze liquid concentration proportioning valve 49, a tap water injection valve 50, a tap water port 51, an antifreeze liquid concentration automatic monitoring device 52, an antifreeze liquid drying and purifying device 53, a blow-down valve 54, a diluted antifreeze liquid injection valve 55, a purified antifreeze liquid output pump 56, a purified antifreeze liquid output valve 57, a purifying heat exchanger 58, a purifying and heating primary pump 59, a purifying and heating secondary pump 60, a third single-double stage switching valve 61, a coupling heat exchange circulating pump 62, a blow-down port 63, a fourth single-double stage switching valve 64, a first single-double stage switching valve 65, a second-stage heat pump 66, a second-stage refrigeration compressor 67, a second-stage condenser 68, a second-stage expansion valve 69, a second-stage evaporator 70, a second single-double stage switching valve 71, an equipment room 79, a rain tower on-off air valve 80, a diluted antifreeze liquid 82, a purified antifreeze liquid, The haze treatment system comprises a blowdown valve 85, a blowdown port 86, deluge purification synergistic fillers 88, a tap water injection valve 89, a tap water port 90, an antifreeze raw material adding door 91, an antifreeze treatment valve 92, an antifreeze discharging port 93, a deluge spray pump 94 and a coupling circulating tank 114. Fig. 35 is added with a coupling circulation tank 114 on the basis of fig. 31, and the effect is to improve the operation stability. Because the coupling circulating water quantity of the front stage and the second stage of the coupling circulating tank 114 is increased, when the front stage is unstable temporarily, the temperature change of the coupling circulating water cannot be changed immediately, so that the influence of the change of the front stage and the rear stage can be buffered, and the heating stability in winter can be improved. In winter, when the double-stage operation is performed, the coupling circulating water is fed from the coupling heat exchange circulating pump 62 to the coupling circulating tank 114 through the water side of the condenser 28, and then fed back to the coupling heat exchange circulating pump 62 from the coupling circulating tank 114 through the third single-stage and double-stage switching valve 61, so as to form a coupling circulating loop. When the single-stage refrigerating air conditioner runs in summer, the air conditioner output circulating pump 35 passes through the first single-stage and double-stage switching valve 65 to the water side of the condenser 28, the chilled water passes through the second single-stage and double-stage switching valve 64 to the fan coil 36, cold air is blown into the room through the fan coil 36 to refrigerate the air conditioner, the overheated chilled water returns to the air conditioner output circulating pump 35, and the single-stage refrigerating air conditioner runs repeatedly.

In conclusion, the vertical haze removal tower 1 and the horizontal haze removal tower 111 can independently remove haze; the haze-removing tower heat pump system can be formed by combining the haze-removing tower heat pump system with a water source heat pump, zero-emission heating and heat supply and elimination of atmospheric pollutants are realized, and a haze treatment and symptom addressing system is formed; the system can be combined with the existing cooling tower central air-conditioning refrigeration system, and can be reformed into a system which can realize zero-emission heating and eliminate atmospheric pollutants, thereby forming a haze treatment system. The heating operation in winter does not use coal or natural gas, and the power generation capacity of the traditional Chinese is not increased, so that the haze treatment in winter is realized. If the invention is popularized and applied in a large area, the urban haze can be eliminated instantly, the atmospheric quality can be improved rapidly, fresh air can be provided for cities, and the invention has great significance in environmental protection.

The technical principle of the present invention is described above in connection with specific embodiments. The description is made for the purpose of illustrating the principles of the invention and should not be construed in any way as limiting the scope of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without inventive effort, which would fall within the scope of the present invention.

Claims (33)

1. A rain-type haze removal tower is characterized by comprising a tower body (1), wherein an air outlet (7) and an air inlet (5) are formed in the tower body (1), and a rain fan (6) is arranged at the air outlet (7);

the upper part in the tower body (1) is provided with a rain spray assembly (4), the lower part is provided with rain liquid (2), and the rain spray assembly (4) is communicated with the rain liquid through a circulating pipeline; the rain spray assembly (4) is at least composed of a group of downward spray nozzles, or is composed of a plurality of groups of nozzles for spraying at a plurality of angles or nozzles with adjustable spray angles;

the tower body (1) is a vertical haze removal tower or a horizontal haze removal tower, when the tower body is the vertical haze removal tower, the tower body has vertical height and is used for increasing rain washing time and way, and when the tower body is the horizontal haze removal tower, the tower body has horizontal length and is used for increasing rain washing time and way;

the number of tower bodies is two at least, including at least one vertical haze tower and at least one horizontal haze tower that removes, horizontal haze tower that removes disposes on the roof of building, utilizes the height on building roof, and the haze that removes high altitude and low latitude is removed with the vertical cooperation of haze tower.

2. A deluge-type haze removal tower according to claim 1, wherein a fan silencer (8) is arranged at the top of the tower body (1), the deluge fan (6) is arranged in the fan silencer (8), and the air outlet (7) is arranged at the upper end of the side wall of the fan silencer (8);

the top end of the fan silencer (8) is provided with a silencing hood (9);

the rain spray component (4) is arranged at the lower part of the rain fan (6), and a gas-water separation device (10) is arranged between the rain spray component and the rain fan;

a deluge purification synergistic filler (88) is arranged between the deluge spraying component (4) and the air inlet (5).

3. The deluge-type haze removal tower according to claim 2, wherein the upper portion of the fan silencer (8) is a silencing static pressure chamber (12), a silencing air pipe (13) is arranged on the silencing static pressure chamber (12), and a silencing rainproof elbow (14) is arranged at the free end of the silencing air pipe (13);

one end of the silencing rainproof elbow (14) is communicated with the silencing air pipe (13), and the air outlet (7) is obliquely and downwards arranged at the other end of the silencing rainproof elbow (14).

4. A deluge-type haze removal tower as claimed in claim 2, wherein the lower part of the tower body (1) is provided with an upper liquid storage tank (106) and a lower liquid storage tank (107), the upper liquid storage tank (106) is used as a deluge liquid (2) circulation tank for summer clear water, and the lower liquid storage tank (107) is used for recovering winter antifreeze liquid deluge liquid (108) in summer;

the upper liquid storage tank (106) and the lower liquid storage tank (107) are arranged in parallel, the upper liquid storage tank (106) and the lower liquid storage tank (107) are respectively connected with the deluge spraying component (4) through pipelines, and the upper liquid storage tank (106) and/or the lower liquid storage tank (107) are/is used for providing deluge liquid (2) for the deluge spraying component (4).

5. A rain-type haze removal tower according to claim 3, wherein an upper liquid storage tank (106) and a lower liquid storage tank (107) are arranged at the lower part of the tower body, the upper liquid storage tank (106) is used as a rain liquid (2) circulating tank for summer clear water, and the lower liquid storage tank (107) is used for recovering winter antifreeze liquid rain liquid (108) in summer;

the upper liquid storage tank (106) and the lower liquid storage tank (107) are arranged in parallel, the upper liquid storage tank (106) and the lower liquid storage tank (107) are respectively connected with the deluge spraying component (4) through pipelines, and the upper liquid storage tank (106) and/or the lower liquid storage tank (107) are/is used for providing deluge liquid (2) for the deluge spraying component (4).

6. The deluge-type haze removal tower as claimed in claim 1, wherein: the tower body (1) comprises a horizontal tower body (111) and a vertical air pipe (113) which is arranged at one end of the horizontal tower body (111) and communicated with the horizontal tower body (111);

the air outlet (7) is arranged on the side wall of the upper end of the vertical air pipe, and the air inlet (5) is arranged on the side wall of the horizontal tower body (111);

the rain spray assembly (4) is arranged on the upper portion of the horizontal tower body (1), the rain liquid (2) is arranged on the lower portion of the horizontal tower body (111), and the rain spray assembly (4) is communicated with the rain liquid (2) through a circulating pipeline.

7. The deluge-type haze removal tower according to claim 1, wherein the tower body (1) comprises a horizontal tower body (111), and a horizontal air pipe which is arranged at one end of the horizontal tower body (111) and communicated with the horizontal tower body (111);

the air outlet (7) is arranged at the end part of the horizontal air pipe, and the air inlet (5) is arranged on the side wall of the horizontal tower body (111);

the rain spray assembly (4) is arranged at the upper part of the horizontal tower body (1), the rain liquid (2) is arranged at the lower part of the horizontal tower body (111), and the rain spray assembly (4) is communicated with the rain liquid (2) through a circulating pipeline;

one end of the horizontal tower body (111) close to the horizontal air pipe is provided with a deluge purification synergistic filler (88), and the upper end of the deluge purification synergistic filler (88) is provided with a deluge liquid distribution device (112).

8. The deluge-type haze removal tower according to claim 6, wherein the two ends of the horizontal tower body (111) are provided with deluge purification synergistic fillers (88), and a deluge liquid device (112) is arranged at the upper end of the deluge purification synergistic fillers (88);

the top of the vertical air pipe (113) is provided with a fan silencer (8), the deluge fan (6) is arranged in the fan silencer (8), and the air outlet (7) is arranged at the upper end of the side wall of the fan silencer (8);

the top end of the fan silencer (8) is provided with a silencing hood (9), and the air inlet end of the fan silencer (8) is provided with an air-water separation device (10);

a deluge purification synergistic filler (88) is arranged between the deluge spraying component (4) and the air inlet (5).

9. The deluge-type haze removal tower according to claim 1, wherein the tower body (1) comprises a horizontal tower body (111), and a vertical air pipe (113) arranged at the upper part of the horizontal tower body (111) and communicated with the horizontal tower body (111);

the air inlet (5) is arranged on the side wall of the horizontal tower body (111);

an air outlet (7) is arranged on the vertical air pipe (113), and a rain fan (6) is arranged below the air outlet (7);

both ends of the horizontal tower body (111) are provided with the deluge purification synergistic filler (88), and the upper end of the deluge purification synergistic filler (88) is provided with a deluge liquid device (112);

the rain spray assembly (4) is arranged on the upper portion of the horizontal tower body (111), the rain liquid (2) is arranged on the lower portion of the horizontal tower body (111), and the rain spray assembly (4) is communicated with the rain liquid (2) through a circulating pipeline.

10. The deluge-type haze removal tower according to claim 1, wherein the tower body (1) comprises a horizontal tower body (111), and a vertical air pipe (113) arranged at the upper part of the horizontal tower body (111) and communicated with the horizontal tower body (111);

the air inlet (5) is arranged on the side wall of the horizontal tower body (111);

a fan silencer (8) is arranged at the upper part of the vertical air pipe (113), a silencing static pressure chamber (12) is arranged at the upper part of the fan silencer (8), a silencing air pipe (13) is arranged on the silencing static pressure chamber (12), and a silencing rainproof elbow (14) is arranged at the free end of the silencing air pipe (13);

one end of the silencing rainproof elbow (14) is communicated with the silencing air pipe (13), and the air outlet (7) is obliquely and downwards arranged at the other end of the silencing rainproof elbow (14);

the rain spray assembly (4) is arranged at the upper part of the horizontal tower body (111), the rain liquid (2) is arranged at the lower part of the horizontal tower body (111), and the rain spray assembly (4) is communicated with the rain liquid (2) through a circulating pipeline;

both ends of the horizontal tower body (111) are provided with the deluge purification synergistic filler (88), and the upper end of the deluge purification synergistic filler (88) is provided with a deluge liquid device (112);

an upper liquid storage tank (106) and a lower liquid storage tank (107) are arranged at the lower part of the horizontal tower body (111), the upper liquid storage tank (106) is used as a circulating tank of the rain liquid (2) by using summer clear water, and the lower liquid storage tank (107) is used for recovering the anti-freezing rain liquid (108) in summer;

and the upper liquid storage tank (106) and the lower liquid storage tank (107) are arranged in parallel and are connected with the deluge spraying component (4) through pipelines.

11. A heat pump system comprising the deluge-type haze removal tower of any one of claims 1-10, and a heat pump in energy exchange with the deluge-type haze removal tower.

12. The heat pump system according to claim 11, wherein the heat pump is a water source heat pump (26), the water source heat pump (26) is formed by connecting a refrigeration compressor (27), a condenser (28), an expansion valve (29), an evaporator (30), an air conditioner output circulation pump (35) and a fan coil (36) in sequence through pipelines, one end of the air conditioner output circulation pump (35) is connected with one end of the water side of the condenser (28), the other end of the water side of the condenser (28) is connected with one end of the fan coil (36), the other end of the fan coil (36) is connected with the other end of the air conditioner output circulation pump (35),

both ends of the water side of the evaporator (30) are communicated with the tower body (1), and one end of the water side of the evaporator is provided with a deluge circulating pump (25).

13. The heat pump system according to claim 11, wherein the heat pump is a hot and cold air type heat pump air conditioner (95), and the hot and cold air type heat pump air conditioner (95) comprises a refrigeration compressor (27), a hot and cold air type air conditioner end (81), an expansion valve (29) and an evaporator (30) which are connected;

the cold and hot air type air conditioner tail end (81) is formed by assembling an indoor cold and hot air heat exchanger (37) and an indoor air conditioner fan (38), one end of the indoor cold and hot air heat exchanger (37) is connected with an exhaust end of a refrigeration compressor (27), the other end of the indoor cold and hot air heat exchanger is connected with an expansion valve (29), and the cold and hot air type air conditioner tail end (81) at least forms a one-stage or multi-stage cold and hot air type air conditioner system;

both ends of the water side of the evaporator (30) are communicated with the tower body (1), and one end of the water side of the evaporator is provided with a deluge circulating pump (25).

14. The heat pump system according to claim 11, wherein the heat pump is a water source heat pump (26), and the water source heat pump (26) comprises a refrigeration compressor (27), a condenser (28), an expansion valve (29), an evaporator (30), a domestic hot water heat storage circulating pump (39), a domestic hot water heat storage and insulation water tank (40), a tap water interface (41) and a domestic hot water output interface (42);

one end of the domestic hot water heat-storage heat-preservation water tank (40) is connected with one end of the water side of the condenser (28), the other end of the water side of the condenser (28) is connected with one end of a domestic hot water heat-storage circulating pump (39), the other end of the domestic hot water heat-storage circulating pump (39) is connected with the domestic hot water heat-storage heat-preservation water tank (40), one end of the domestic hot water heat-storage heat-preservation water tank (40) is connected with a tap water system through a tap water interface (41), and the other end of the domestic hot water heat-storage heat-preservation water tank (40) is connected with a domestic hot water supply system through a;

both ends of the water side of the evaporator (30) are communicated with the tower body (1), and one end of the water side of the evaporator is provided with a deluge circulating pump (25).

15. The heat pump system according to claim 12, wherein the water source heat pump (26) further includes a first cooling/heating switch valve (98), a second cooling/heating switch valve (99), a third cooling/heating switch valve (100), and a fourth cooling/heating switch valve (101), one end of the first cooling/heating switch valve (98) is connected to one end of the second cooling/heating switch valve (99) and then connected to a discharge end of the refrigerant compressor (27), the other end of the first cooling/heating switch valve (98) is connected to one end of the fourth cooling/heating switch valve (101) and then connected to one end of the condenser (28) on a refrigerant side, the other end of the condenser (28) on the refrigerant side is connected to one end of the expansion valve (29), the other end of the expansion valve (29) is connected to one end of the evaporator (30) on the refrigerant side, and the other end of the evaporator (30) on the refrigerant side is connected to the second cooling/heating switch valve (99) and the third cooling/heating (100) And the other end of the third cooling/heating switch valve (100) is connected to the other end of the fourth cooling/heating switch valve (101) and then connected to the suction end of the refrigerant compressor (27).

16. The heat pump system according to claim 12, 13, 14 or 15, further comprising an antifreeze solution reservoir tank (46), wherein the antifreeze solution reservoir tank (46) comprises an inlet end and an outlet end, and the inlet end and the outlet end are both communicated with the tower body (1).

17. The heat pump system according to claim 12 or 14, further comprising a cooling tower (15), wherein the cooling tower (15) is composed of a cooling tower heat exchange filler (16), a spray liquid (17), a water pan (18), a spray liquid distribution device (19) and a cooling tower fan (20);

one end of the water side of the evaporator (30) is connected with the spraying and liquid distributing device (19), the other end of the water side of the evaporator (30) is communicated with the water receiving disc (18) and the tower body (1), and the water receiving disc (18) is communicated with the tower body (1) through a pipeline.

18. The heat pump system according to claim 13 or 15, further comprising a cooling tower (15), wherein the cooling tower (15) is composed of a cooling tower heat exchange filler (16), a spray liquid (17), a water pan (18), a spray liquid distribution device (19) and a cooling tower fan (20);

one end of the water side of the evaporator (30) is connected with the spraying and liquid distributing device (19), the other end of the water side of the evaporator (30) is communicated with the water receiving disc (18) and the tower body (1), and the water receiving disc (18) is communicated with the tower body (1) through a pipeline.

19. The heat pump system according to claim 17, further comprising an antifreeze solution storage and proportioning tank (46), wherein one end of the antifreeze solution storage and proportioning tank (46) is communicated with the spraying and liquid distributing device (19) and one end of the water side of the evaporator (30) through a pipeline, and the other end of the antifreeze solution storage and proportioning tank (46) is communicated with the water pan (18);

the system also comprises an automatic antifreeze solution concentration monitoring device (52), wherein two ends of the automatic antifreeze solution concentration monitoring device (52) are respectively communicated with two ends of the evaporator (30).

20. The heat pump system of claim 19, wherein the water source heat pump (26) further comprises a storage circulation pump (72), a storage holding water tank (73), and an air conditioning output isolation heat exchanger (74);

one end of the energy storage heat preservation water tank (73) is connected with one end of the water side of the condenser (28), the other end of the water side of the condenser (28) is connected with one end of the primary side of the air conditioner output isolation heat exchanger (74) through an energy storage circulating pump (72), and the other end of the primary side of the air conditioner output isolation heat exchanger (74) is connected with the other end of the energy storage heat preservation water tank (73);

one end of the secondary side of the air-conditioning output isolation heat exchanger (74) is connected with one end of an air-conditioning output circulating pump (35), the other end of the air-conditioning output circulating pump (35) is connected with one end of a fan coil (36), and the other end of the fan coil (36) is connected with the other end of the secondary side of the air-conditioning output isolation heat exchanger (74).

21. Heat pump system according to claim 19 or 20, further comprising an antifreeze drying heating coil (87) arranged in the antifreeze reservoir tank (46), both ends of said antifreeze drying heating coil (87) being in communication with both ends of the water side of the condenser (28), respectively.

22. A heat pump system according to claim 19 or 20, further comprising a purge heat exchanger (58), a purge heat primary pump (59) and a purge heat secondary pump (60);

one end of the purification heating primary pump (59) is connected with one end of the condenser (28) and one end of the fan coil (36), the other end of the purification heating primary pump (59) is connected with one end of the primary side of the purification heat exchanger (58), and the other end of the primary side of the purification heat exchanger (58) is connected with one end of the air conditioner output circulating pump (35) and one end of the fan coil (36);

one end of the secondary side of the purification heat exchanger (58) is connected with one end of a purification heating secondary pump (60), the other end of the purification heating secondary pump (60) is connected with an antifreeze liquid storage and proportioning tank (46), and the other end of the secondary side of the purification heat exchanger (58) is also connected with the antifreeze liquid storage and proportioning tank (46).

23. The heat pump system according to claim 19 or 20, further comprising an antifreeze solution drying and purifying device (53), a purifying heat exchanger (58), a purifying heating primary pump (59) and a purifying heating secondary pump (60);

one end of the primary side of the purification heat exchanger (58) is connected with one end of the condenser (28) and one end of the fan coil (36), the other end of the purification heating primary pump (59) is connected with one end of the primary side of the purification heat exchanger (58), and the other end of the primary side of the purification heat exchanger (58) is connected with one end of the air conditioner output circulating pump (35) and one end of the fan coil (36); one end of the secondary side of the purification heat exchanger (58) is connected with an antifreeze solution drying and purifying device (53), and the other end of the secondary side of the purification heat exchanger (58) is connected with the antifreeze solution drying and purifying device (53) through a purification heating secondary pump (60);

one end of the antifreeze solution drying and purifying device (53) is communicated with the antifreeze solution storage and proportioning tank (46), and the other end of the antifreeze solution drying and purifying device is communicated with the water pan (18) and is used for purifying the antifreeze solution in the antifreeze solution drying and purifying device (53) and then injecting the purified antifreeze solution into the water pan (18).

24. The heat pump system of claim 23, further comprising a second stage heat pump (66) disposed in series with the water source heat pump (26), the second stage heat pump (66) including a second stage refrigerant compressor (67), a second stage condenser (68), a second stage expansion valve (69), and a second stage evaporator (70);

one end of the water side of the second-stage evaporator (70) is connected with one end of the water side of the condenser (28) and then is connected with one end of the fan coil (36), one end of the water side of the second-stage condenser (68) and the purification heating primary pump (59), the other end of the second-stage condenser (68) is connected with one end of a second single-double stage switching valve (71), the other end of the second single-double stage conversion valve (71) is connected with one end of the first single-double stage conversion valve (65) and one end of an air conditioner output circulating pump (35), the other end of the air-conditioning output circulating pump (35) is connected with one end of the fan coil (36) and the primary side of the purifying heat exchanger (58), the other end of the first single-double stage switching valve (65) is connected with the other end of the water side of the condenser (28) and one end of the coupling heat exchange circulating pump (62), the other end of the coupling heat exchange circulating pump (62) is connected with the other end of the water side of the second-stage evaporator (70).

25. The heat pump system according to claim 24, wherein the water source heat pump (26) further includes a first cooling/heating switch valve (98), a second cooling/heating switch valve (99), a third cooling/heating switch valve (100), and a fourth cooling/heating switch valve (101), wherein one end of the first cooling/heating switch valve (98) is connected to one end of the second cooling/heating switch valve (99) and then connected to a discharge end of the refrigerant compressor (27), the other end of the first cooling/heating switch valve (98) is connected to one end of the fourth cooling/heating switch valve (101) and then connected to one end of the refrigerant side of the condenser (28), the other end of the refrigerant side of the condenser (28) is connected to one end of the expansion valve (29), the other end of the expansion valve (29) is connected to one end of the refrigerant side of the evaporator (30), and the other end of the refrigerant side of the evaporator (30) is connected to the second cooling/heating switch valve (99) and the third cooling/heating switch (100) And the other end of the third cooling/heating switch valve (100) is connected to the other end of the fourth cooling/heating switch valve (101) and then connected to the suction end of the refrigerant compressor (27).

26. The heat pump system according to claim 24, further comprising a domestic hot water heat storage circulation pump (39), a domestic hot water heat storage and heat preservation water tank (40), a tap water interface (41), and a domestic hot water output interface (42).

27. The heat pump system according to claim 24 or 25, further comprising an energy storage heat preservation water tank (73) and an air conditioner output isolation heat exchanger (74), wherein one end of the water side of the second stage evaporator (70) is connected with one end of the water side of the condenser (28) and then connected with one end of the energy storage heat preservation water tank (73), one end of the water side of the second stage condenser (68) and the purification heating primary pump (59), the other end of the second stage condenser (68) is connected with one end of the second single-double stage switching valve (71), the other end of the second single-double stage switching valve (71) is communicated with one end of the first single-double stage switching valve (65) and one end of the energy storage circulation pump (72), the other end of the energy storage circulation pump (72) is connected with one end of the primary side of the air conditioner output isolation heat exchanger (74) and the primary side of the purification heat exchanger (58), the other end of the primary side of the air conditioner output isolation heat exchanger (74) is communicated with the other end of the energy storage heat preservation water tank (73); the other end of the first single-stage and double-stage switching valve (65) is connected with one end of a coupling heat exchange circulating pump (62) and one end of the water side of the condenser (28);

one end of the secondary side of the air conditioner output isolation heat exchanger (74) is communicated with one end of the fan coil (36), the other end of the secondary side of the air conditioner output isolation heat exchanger is connected with one end of the air conditioner output circulating pump (35), and the other end of the air conditioner output circulating pump (35) is communicated with the other end of the fan coil (36).

28. The heat pump system according to claim 24, 25 or 26, further comprising a coupling circulation tank (114), wherein one end of the coupling circulation tank (114) is connected to one end of the water side of the condenser (28), the other end of the water side of the condenser (28) is connected to one end of a coupling heat exchange circulation pump (62), the other end of the coupling heat exchange circulation pump (62) is connected to one end of the water side of the second stage evaporator (70), the other end of the water side of the second stage evaporator (70) is connected to the coupling circulation tank (114) through a pipe, the coupling circulation tank (114) is further connected to one end of a first single/double switching valve (65), the other end of the first single/double switching valve (65) is connected to one end of a second single/double switching valve (71) and one end of an air conditioner output circulation pump (35), and the coupling circulation tank (114) is further connected to one end of a second stage condenser (68) through a pipe, One end of the purification heating primary pump (59) is connected with one end of the fan coil (36).

29. The heat pump system of claim 22, wherein the heat source required for the purification heat exchanger (58) is replaced with an electric heating, waste heat, solar or boiler heat source.

30. The heat pump system of claim 23, wherein the heat source required for the purification heat exchanger (58) is replaced with an electric heating, waste heat, solar or boiler heat source.

31. The heat pump system of claim 24, wherein the heat source required for the purification heat exchanger (58) is replaced with an electric heating, waste heat, solar or boiler heat source.

32. The heat pump system of claim 25, wherein the heat source required for the purification heat exchanger (58) is replaced with an electric heating, waste heat, solar or boiler heat source.

33. The heat pump system of claim 26, wherein the heat source required for the purification heat exchanger (58) is replaced with an electric heating, waste heat, solar or boiler heat source.

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