CN213542702U - Heat recovery type of adjusting temperature radiation system - Google Patents

Abstract

The utility model discloses a heat recovery type radiation system that adjusts temperature, the utility model discloses the system is except including the module that adjusts temperature, capillary water supply module, will radiate other required equipment of air conditioning system, contains all integrations such as new trend module, controller and is in the utility model discloses an in the system. The utility model discloses be difficult to guarantee the drawback of reliability and stability to the high system of integrated level simultaneously, done a great deal of technical means and the measure that promote stability and reliability to reduce system fault rate reduces the maintenance cost in later stage, promotes whole capillary radiation system's travelling comfort and user experience.

Description

Heat recovery type of adjusting temperature radiation system

Technical Field

The utility model relates to a heating and ventilation technical field, concretely relates to heat recovery type radiation system that adjusts temperature.

Background

Capillary radiation air conditioning system, mainly need handle three major functions, firstly capillary temperature is adjusted, secondly fresh air treatment, three concentrate intelligent control, the general way in the industry is, do capillary temperature with independent equipment and adjust, do fresh air treatment with independent equipment, reuse independent switch board does concentrate intelligent control, so not only increased equipment fixing area, increased the engineering construction volume, also increased the degree of difficulty of engineering construction, still there is the hidden danger that construction quality is difficult to guarantee.

To some units that have integrateed fresh air treatment function and capillary water supply temperature regulatory function, because the increase of function, the unit inner space is limited, under the circumstances that reliability and stability are difficult to guarantee, simple will be independent fresh air treatment equipment in the past and independent capillary temperature regulating apparatus piece together in a unit system, the fault rate of unit system increases, maintains the difficulty, influences later stage user experience.

SUMMERY OF THE UTILITY MODEL

Therefore, the utility model provides a heat recovery type of adjusting temperature radiation system has reduced equipment fixing area, has solved the difficulty of engineering construction, has reduced the construction degree of difficulty, more does benefit to the whole quality of guaranteeing whole capillary radiation system.

In order to achieve the above object, the present invention provides the following technical solutions:

the embodiment provides a heat recovery temperature-regulating radiation system, which comprises an accommodating space, a fresh air module, a temperature regulating module and a capillary water supply module;

the accommodating space is provided with a fresh air area, a temperature adjusting area and a capillary water supply area, the fresh air module is arranged in the fresh air area, the temperature adjusting module is arranged in the temperature adjusting area, and the capillary water supply module is arranged in the capillary water supply area;

the fresh air area is provided with a fresh air inlet, an air outlet, a return air inlet and a communicating air inlet, the temperature adjusting area is communicated with the capillary water supply area, and the capillary water supply area is provided with an air supply outlet.

Furthermore, the fresh air module comprises a fresh air valve, a fresh air primary high-efficiency filter screen, a total heat exchanger, a blower, an exhaust fan, an exhaust primary filter screen, a finned condenser, an exhaust valve and a bypass air valve;

the fresh air valve is arranged in the fresh air opening, the fin condenser and the exhaust valve are arranged in the exhaust opening, and the blower is arranged in the communicated air opening;

the total heat exchanger is provided with a first inlet, a first outlet, a second inlet and a second outlet, wherein the first inlet is communicated with the first outlet, and the second inlet is communicated with the second outlet;

the air return inlet is communicated with a first inlet of the total heat exchanger through an exhaust fan and an exhaust primary filter screen;

the exhaust valve is communicated with a first outlet of the total heat exchanger;

the fresh air valve is communicated with a second inlet of the total heat exchanger through a fresh air primary high-efficiency filter screen and is communicated with the air return inlet through a bypass air valve;

the inlet of the blower is communicated with the second outlet of the total heat exchanger.

Further, the fresh air module further comprises an ultraviolet light source, and the ultraviolet light source is arranged between the fresh air primary high-efficiency filter screen and the bypass air valve.

Further, the fresh air module further comprises a surface cooler, an evaporator, a reheater and a humidifier, wherein the surface cooler, the evaporator, the reheater and the humidifier are sequentially arranged between the communicated air port and the temperature adjusting area.

Further, the temperature adjusting module comprises a compressor, a four-way valve, a first filter, an expansion valve and a gas-liquid separator, the compressor is provided with an air suction pipe and an exhaust pipe, the four-way valve is provided with a first valve opening, a second valve opening, a third valve opening and a fourth valve opening, the exhaust pipe of the compressor is connected with the first valve opening of the four-way valve, the second valve opening of the four-way valve is connected with the inlet of the finned condenser, the outlet of the finned condenser is connected with the inlet of the reheater, the outlet of the reheater is connected with the inlet of the evaporator through the first filter and the expansion valve in sequence, the outlet of the evaporator is connected with the third valve opening of the four-way valve, the fourth valve opening of the four-way valve is connected with the inlet.

Further, the capillary tube water supply module comprises a second filter, a water mixing tank, a proportional bypass valve, a water pump, a hot water electric valve, a plate heat exchanger, a gate valve, a cold water electric valve, a humidifying electric valve and a water supplementing electric valve;

the capillary water supply area is provided with a heat pump water outlet, a municipal hot water inlet, a heat pump water return port, a soft water inlet, an indoor water outlet, an indoor water supply port, a water discharge port and a water discharge port;

the water mixing tank is provided with a first opening, a second opening, a third opening and a fourth opening, the proportional bypass valve is provided with a first opening, a second opening and a third opening, and the plate heat exchanger is provided with a first opening, a second opening, a third opening and a fourth opening;

the first opening of the water mixing tank is communicated with the second opening of the proportional bypass valve, the second opening of the water mixing tank is communicated with the second opening of the plate heat exchanger, the second opening of the water mixing tank is communicated with the inlet of the surface cooler through a cold water electric valve, the third opening of the water mixing tank is communicated with the third opening of the proportional bypass valve, the third opening of the water mixing tank is communicated with an indoor water outlet through a second filter, the fourth opening of the water mixing tank is communicated with a heat pump water return opening through a gate valve, the fourth opening of the water mixing tank is communicated with the outlet of the surface cooler through a gate valve, the first opening of the plate heat exchanger is communicated with a municipal hot water inlet through a hot water electric valve, the third opening of the plate heat exchanger is communicated with a municipal hot water outlet, and the fourth opening of the plate;

the soft water entry is through the indoor delivery port of moisturizing motorised valve intercommunication, the soft water entry is through the water inlet of humidification motorised valve intercommunication humidifier, the first opening of water pump intercommunication proportion bypass valve is passed through to indoor water supply port, the outlet intercommunication the first opening of proportion bypass valve, the outlet intercommunication the delivery port of humidifier.

Furthermore, the capillary water supply module further comprises a pressure switch and a return water temperature sensor, and a third opening of the water mixing tank is communicated with the indoor water outlet through the return water temperature sensor, the pressure switch and the second filter in sequence.

Further, the capillary water supply module also comprises a water supply temperature sensor, and the indoor water supply port is communicated with the first opening of the proportional bypass valve through the water supply temperature sensor and the water pump.

Further, the heat recovery temperature-adjusting radiation system further comprises a controller for controlling the fresh air module, the temperature adjusting module and the capillary water supply module.

The utility model has the advantages of as follows:

the utility model discloses be difficult to guarantee the drawback of reliability and stability to the high system of integrated level simultaneously, done a great deal of technical means and the measure that promote stability and reliability to reduce system fault rate reduces the maintenance cost in later stage, promotes whole capillary radiation system's travelling comfort and user experience.

The utility model discloses an equipment for radiation air conditioning system of high integration degree is exactly, the utility model discloses the system is except including the module that adjusts the temperature, capillary water supply module, will radiate other required equipment of air conditioning system, contains all integrations such as new trend module, controller and is in the utility model discloses an in the system.

On the fresh air processing equipment, the functions of fresh air filtration, sterilization, heat recovery, dehumidification, humidification and temperature regulation are included. Wherein, the dehumidification adopts precooling dehumidification by a total heat exchanger, secondary dehumidification by a surface cooler and tertiary dehumidification by a direct expansion evaporator; the capillary water supply module has the functions of indoor water supply temperature adjustment, cold and heat source selection and constant pressure water supply; the centralized control function of the radiation air-conditioning system can comprise control, operation monitoring, fault processing and remote cloud platform monitoring and maintenance of fresh air equipment, water temperature processing equipment, indoor temperature and humidity and air quality monitoring equipment.

The total heat exchanger used for precooling and dehumidifying utilizes the characteristics that when a heat recovery temperature-regulating radiation system is in dehumidifying operation, the indoor air is low in temperature, low in humidity and low in enthalpy value, and the outdoor fresh air is high in temperature, high in humidity and high in enthalpy value, so that the outdoor fresh air is subjected to total heat exchange with the indoor exhaust air firstly, the enthalpy value of the outdoor fresh air is reduced, and then the outdoor fresh air is dehumidified by the surface cooler and the evaporator, the heat load of subsequent dehumidification of the surface cooler and the evaporator is reduced, and the purposes of reducing energy consumption and improving energy consumption efficiency are achieved. Because the enthalpy difference between the outdoor fresh air and the indoor exhaust air is large, the total heat exchange process can reach high efficiency, the fresh air dehumidification process can reduce more energy consumption, and the energy consumption efficiency is greatly improved. In the season of heating, outdoor new trend is earlier the same great difference with the enthalpy value of indoor exhaust both, and the total heat exchange process still has higher efficiency, consequently, to the new trend dehumidification humidification equipment that heat recovery temperature regulating type radiation system used, increase leading total heat exchanger and can effectively reduce the annual operation energy consumption, improve the annual operation energy consumption efficiency, also be favorable to stabilizing the air inlet operating mode of second grade dehumidification surface cooler, tertiary dehumidification evaporimeter simultaneously, improved the stability and the reliability of system.

The water inlet pipeline of the secondary dehumidification surface cooler is provided with the proportional two-way valve, water flow entering the surface cooler is controlled through the proportional two-way valve, the air supply moisture content of the system can be always kept at a stable value under various dehumidification working conditions, and the stability and the reliability of the system are improved.

The fin condenser and the exhaust valve are arranged on the exhaust side in parallel, the air volume passing through the fin condenser is increased or reduced by adjusting the opening of the exhaust valve, the heat dissipation capacity of the fin condenser is adjusted, and further the heat dissipation capacity of the reheater is adjusted, so that the air supply temperature of the system is always kept at a stable value under various dehumidification working conditions, and the stability and the reliability of the system are improved.

The direct expansion evaporator is arranged in a steam compression circulating system, the four-way valve is additionally arranged at an exhaust port of the compressor, and when the evaporator frosting heat exchange efficiency is reduced under certain specific working conditions, the flow direction of a high-temperature refrigerant discharged from the compressor is changed by controlling the conversion of the four-way valve, the defrosting on the evaporator can be rapidly cleared, the dehumidifying efficiency of the evaporator is recovered, the dehumidifying efficiency of the system is improved, and the stability and the reliability of the system are also improved.

The fresh air valve is arranged at the fresh air inlet, the bypass air valve is arranged between the return air inlet and the fresh air inlet, the fresh air valve can be closed through control, the bypass air valve is opened, the system can enter a return air recirculation mode when running under a specific working condition, the energy consumption of the system is reduced, the annual running energy consumption efficiency of the system is improved, and the stability and the reliability of the system are improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structure, ratio, size and the like shown in the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by people familiar with the technology, and are not used for limiting the limit conditions which can be implemented by the present invention, so that the present invention has no technical essential significance, and any structure modification, ratio relationship change or size adjustment should still fall within the scope which can be covered by the technical content disclosed by the present invention without affecting the efficacy and the achievable purpose of the present invention.

Fig. 1 is a schematic structural diagram of a heat recovery temperature-regulating radiation system provided by the present invention;

fig. 2 is a schematic view of the ventilation cooling and refrigeration dehumidifying mode of the heat recovery temperature-regulating radiation system provided by the present invention;

fig. 3 is a schematic diagram of a cooling and dehumidifying mode of the heat recovery temperature-regulating radiation system provided by the present invention;

fig. 4 is a dehumidification and temperature-rise mode diagram of the heat recovery and temperature-regulation type radiation system provided by the present invention;

fig. 5 is a ventilation pattern diagram of the heat recovery and temperature adjustment type radiation system provided by the present invention;

fig. 6 is a schematic diagram of ventilation heating and heating humidification mode of the heat recovery temperature-regulating radiation system provided by the present invention;

fig. 7 is a heating and humidifying pattern diagram of the heat recovery temperature-regulating radiation system provided by the present invention;

in the figure:

the system comprises a fresh air valve 1, a fresh air primary high-efficiency filter screen 2, a total heat exchanger 3, a blower 4, a surface cooler 5, an evaporator 6, a reheater 7, a humidifier 8, an exhaust fan 9, an exhaust primary filter screen 10, a fin condenser 11, an exhaust valve 12, a bypass air valve 13 and an ultraviolet light source 14;

a compressor 201, a four-way valve 202, a first filter 203, an expansion valve 204, a gas-liquid separator 205, a second filter 101, a pressure switch 102, a backwater temperature sensor 103, a water mixing tank 104, a proportional bypass valve 105, a water supply temperature sensor 106, a water pump 107, a hot water electric valve 108, a plate heat exchanger 109, a gate valve 110, a cold water electric valve 111, a humidifying electric valve 112 and a water supplementing electric valve 113;

a heat pump water outlet 301, a municipal hot water outlet 302, a municipal hot water inlet 303, a heat pump water return inlet 304, a soft water inlet 305, an indoor water outlet 306, an indoor water supply inlet 307, a water drain outlet 308 and a water drain port 309;

the air conditioner comprises an accommodating space 400, a fresh air area 401, a temperature adjusting area 402, a capillary water supply area 403, a fresh air inlet 404, an air outlet 405, an air return inlet 406 and an air supply outlet 407;

a controller 500.

Detailed Description

The present invention is described in terms of specific embodiments, and other advantages and benefits of the present invention will become apparent to those skilled in the art from the following disclosure. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example 1

As shown in fig. 1, the present embodiment provides a heat recovery temperature-adjusting radiation system, which includes an accommodating space 400, a fresh air module, a temperature adjusting module, and a capillary water supply module;

the accommodating space 400 is provided with a fresh air area 401, a temperature adjusting area 402 and a capillary water supply area 403, the fresh air module is arranged in the fresh air area 401, the temperature adjusting module is arranged in the temperature adjusting area 402, and the capillary water supply module is arranged in the capillary water supply area 403;

the fresh air area 401 is provided with a fresh air inlet 404, an air outlet 405, an air return inlet 406 and a communication air inlet, the temperature adjusting area 402 is communicated with the capillary water supply area 403, and the capillary water supply area 403 is provided with an air supply outlet 407.

The embodiment integrates the fresh air module, the temperature adjusting module and the capillary water supply module in the accommodating space, reduces the occupied area of equipment installation, solves the difficulty of engineering construction, reduces the construction difficulty, and is more favorable for ensuring the overall quality of the whole capillary radiation system.

Example 2

As shown in fig. 1, the fresh air module includes a fresh air valve 1, a fresh air primary high-efficiency filter screen 2, a total heat exchanger 3, a blower 4, an exhaust fan 9, an exhaust primary filter screen 10, a finned condenser 11, an exhaust valve 12, and a bypass air valve 13;

the fresh air valve 1 is arranged in a fresh air opening 404, the finned condenser 11 and the exhaust valve 12 are arranged in an exhaust opening 405, and the blower 4 is arranged in the communicated air opening;

the total heat exchanger 3 is provided with a first inlet, a first outlet, a second inlet and a second outlet, wherein the first inlet is communicated with the first outlet, and the second inlet is communicated with the second outlet;

the air return port 406 is communicated with a first inlet of the total heat exchanger 3 through an exhaust fan 9 and an exhaust primary filter screen 10;

the exhaust valve 12 is communicated with a first outlet of the total heat exchanger 3;

the fresh air valve 1 is communicated with a second inlet of the total heat exchanger 3 through a fresh air primary high-efficiency filter screen 2, and the fresh air valve 1 is communicated with the air return port 406 through a bypass air valve 13;

the inlet of the blower 4 is communicated with the second outlet of the total heat exchanger 3.

This embodiment is just high-efficient filter screen 2 through the new trend and is realized the new trend and filter, cools down the return air through finned condenser 11, and through the filtration of the first effect filter screen 10 of airing exhaust to airing exhaust, carry out the heat exchange through total heat exchanger to new trend and return air, make full use of the efficiency of return air.

This embodiment is at the side of airing exhaust and is set up a fin condenser and an exhaust valve side by side, increases or reduces the amount of wind through the fin condenser through the aperture of adjusting the exhaust valve, adjusts the heat dissipation capacity of fin condenser, and then has adjusted the heat dissipation capacity of re-heater, can make the system under various dehumidification operating modes, and the air supply temperature remains a more stable value all the time, has improved the stability and the reliability of system.

Example 3

As shown in fig. 1, the fresh air module further includes an ultraviolet light source 14, and the ultraviolet light source 14 is disposed between the fresh air primary high-efficiency filter screen 2 and the bypass air valve 13. The embodiment sterilizes the fresh air through the ultraviolet light source 14, and reduces the number of bacteria and viruses in the fresh air.

Example 4

As shown in fig. 1, the fresh air module further includes a surface cooler 5, an evaporator 6, a reheater 7 and a humidifier 8, and the surface cooler 5, the evaporator 6, the reheater 7 and the humidifier 8 are sequentially arranged between the communicating air port and the temperature adjusting region 402. This embodiment is cooled down, is dehumidified, is heated and is humidified the new trend through surface cooler 5, evaporimeter 6, re-heater 7 and humidifier 8, has improved the comfort level that the supply-air outlet sent out the air.

Example 5

As shown in fig. 1, the tempering module includes a compressor 201, a four-way valve 202, a first filter 203, an expansion valve 204, and a gas-liquid separator 205, compressor 201 has a suction line and a discharge line, four-way valve 202 has a first valve port, a second valve port, a third valve port, and a fourth valve port, the exhaust pipe of compressor 201 is connected to the first valve port of four-way valve 202, the second valve port of four-way valve 202 is connected to the inlet of finned condenser 11, the outlet of the fin condenser 11 is connected to the inlet of the reheater 7, the outlet of the reheater 7 is connected to the inlet of the evaporator 6 through the first filter 203 and the expansion valve 204 in this order, the outlet of the evaporator 6 is connected to the third valve port of the four-way valve 202, the fourth valve port of the four-way valve 202 is connected to the inlet of the gas-liquid separator 205, and the outlet of the gas-liquid separator 205 is connected to the suction pipe of the compressor 201.

The two-stage dehumidification surface cooler water inlet pipeline of this embodiment sets up a proportion two-way valve, comes the control to get into the discharge of surface cooler through the proportion two-way valve, can make the system under various dehumidification operating modes, and the air supply moisture content remains throughout at a more stable value, has improved the stability and the reliability of system.

The direct expansion evaporator of this embodiment is in vapor compression circulation system, has increased the cross valve at the gas vent of compressor, and under certain specific operating mode, if the evaporimeter frosting heat exchange efficiency drops, through the conversion of control cross valve, changes the flow direction of the high temperature refrigerant that the compressor discharged, and the dehumidification efficiency of the frost recovery evaporimeter on the clear evaporimeter that can be rapid has both improved the dehumidification efficiency of system, has improved the stability and the reliability of system again.

Example 6

As shown in fig. 1, the capillary water supply module includes a second filter 101, a water mixing tank 104, a proportional bypass valve 105, a water pump 107, a hot water electric valve 108, a plate heat exchanger 109, a gate valve 110, a cold water electric valve 111, a humidifying electric valve 112 and a water supplementing electric valve 113;

the capillary water supply area 403 is provided with a heat pump water outlet 301, a municipal hot water outlet 302, a municipal hot water inlet 303, a heat pump water return inlet 304, a soft water inlet 305, an indoor water outlet 306, an indoor water supply inlet 307, a water drain outlet 308 and a water drain outlet 309;

the water mixing tank 104 is provided with a first opening, a second opening, a third opening and a fourth opening, the proportional bypass valve 105 is provided with a first opening, a second opening and a third opening, and the plate heat exchanger 109 is provided with a first opening, a second opening, a third opening and a fourth opening;

the first opening of the water mixing tank 104 communicates with the second opening of the proportional bypass valve 105, the second opening of the water mixing tank 104 is communicated with the second opening of the plate heat exchanger 109, the second opening of the water mixing tank 104 is communicated with the inlet of the surface air cooler 5 through a cold water electric valve 111, the third opening of the water mixing tank 104 is communicated with the third opening of the proportional bypass valve 105, the third opening of the water mixing tank 104 is communicated with the indoor water outlet 306 through the second filter 101, the fourth opening of the water mixing tank 104 is communicated with a heat pump water return opening 304 through a gate valve 110, the fourth opening of the water mixing tank 104 is communicated with the outlet of the surface cooler 5 through a gate valve 110, the first opening of the plate heat exchanger 109 is communicated with a municipal hot water inlet 303 through a hot water electric valve 108, the third opening of the plate heat exchanger 109 is communicated with a municipal hot water outlet 302, and the fourth opening of the plate heat exchanger 109 is communicated with a heat pump water outlet 301;

the soft water inlet 305 is communicated with an indoor water outlet 306 through a water supplementing electric valve 113, the soft water inlet 305 is communicated with a water inlet of the humidifier 8 through a humidifying electric valve 112, the indoor water inlet 307 is communicated with a first opening of the proportional bypass valve 105 through a water pump 107, the water drainage opening 308 is communicated with the first opening of the proportional bypass valve 105, and the water drainage opening 309 is communicated with the water outlet of the humidifier 8.

The capillary water temperature adjustment of the capillary water supply module in this embodiment includes indoor water supply temperature adjustment, cold and heat source selection, and constant pressure water supplement function, and has powerful function and good practicability, and the specific use manner is described in detail in embodiments 10 to 16.

Example 7

As shown in fig. 1, the capillary water supply module further includes a pressure switch 102 and a return water temperature sensor 103, and a third opening of the water mixing tank 104 is communicated with the indoor water outlet through the return water temperature sensor 103, the pressure switch 102 and the second filter 101 in sequence.

According to the embodiment, the return water temperature and pressure detection and filtration can be realized through the return water temperature sensor 103, the pressure switch 102 and the second filter 101, the accuracy of return water temperature regulation and pressure regulation is improved, and particulate matters are reduced.

Example 8

As shown in fig. 1, the capillary water supply module further includes a water supply temperature sensor 106, and the indoor water supply port 307 is communicated with the first opening of the proportional bypass valve 105 through the water supply temperature sensor 106 and the water pump 107. The present embodiment achieves accurate adjustment of the supply water temperature by providing the supply water temperature sensor 106.

Example 9

As shown in fig. 1, the heat recovery temperature-adjusting radiation system further includes a controller 500 for controlling the fresh air module, the temperature adjusting module and the capillary water supply module. The present embodiment controls three modules with air 500 to accommodate the needs of different modes.

Example 10

As shown in fig. 1, the present embodiment provides a connection mode of the system:

the outdoor fresh air duct is connected to the system fresh air inlet 404, the indoor return air duct is connected to the system return air inlet 406, the indoor exhaust duct is connected to the system exhaust outlet 405, and the fresh air supply duct is connected to the system supply air outlet 407. The fresh air inlet 404 is provided with a fresh air valve 1, a total heat exchanger 3 is arranged between the fresh air valve 1 and an air outlet 405 in the system, a fresh air primary high-efficiency filter screen 2 is arranged on a fresh air inlet side of the total heat exchanger 3, an ultraviolet light source 14 is arranged near the fresh air primary high-efficiency filter screen 2, an air exhaust primary filter screen 10 is arranged on a return air inlet side of the total heat exchanger 3, a blower 4 is arranged on a fresh air outlet side of the total heat exchanger 3, a fin condenser 11 and an air exhaust valve 12 are arranged between the air outlet 405 and the total heat exchanger 3 in the system in parallel, a return air temperature and humidity sensor 300 is arranged in a return air inlet 406 of the system, an air exhaust fan 9 is arranged between the return air inlet 406 and the air exhaust primary filter screen 10 of the system, a bypass air valve 13 is arranged between the return air inlet and the fresh air valve 1 in the system, and, A reheater 7, a humidifier 8.

A compressor 201 is provided in the internal air passage between the humidifier 8 and the system air supply port 407, a first valve port of the four-way valve 202 is connected to an exhaust pipe of the compressor 201, a second valve port of the four-way valve 202 is connected to an inlet of the finned condenser 11, an outlet of the finned condenser 11 is connected to an inlet of the reheater 7, an outlet of the reheater 7 is connected to an inlet of the first filter 203 and an inlet of the expansion valve 204 in this order, an outlet of the expansion valve 204 is connected to an inlet of the evaporator 6, an outlet of the evaporator 6 is connected to a third valve port of the four-way valve 202, a fourth valve port of the four-way valve 202 is connected to an inlet of the gas-liquid separator.

A water pump 107 is provided in the internal air passage between the humidifier 8 and the system air supply outlet 407, the inlet of the water pump 107 is connected to the first opening of the proportional bypass valve 105, a water supply temperature sensor 106, a drain pipe, and a drain shutoff valve are provided in the passage between the water pump 107 and the proportional bypass valve 105 by a three-way joint, the second opening of the proportional bypass valve 105 is connected to the first opening (left outlet) of the water mixing tank 104, and the third opening of the proportional bypass valve 105 is connected to the passage between the second filter 101 and the water mixing tank 104 by a three-way joint. The third opening (left inlet) of the water mixing tank 104 is connected with the outlet of the second filter 101, the inlet of the second filter 101 is connected with the indoor water outlet stop valve, a pressure switch 102 and a backwater temperature sensor 103 are arranged on a pipeline between the second filter 101 and the water mixing tank 104 and close to the second filter 101, the outlet of a water supplementing electric valve 113 is connected with a pipeline between the second filter 101 and the indoor water outlet stop valve through a tee joint, the inlet of the water supplementing electric valve 113 is connected with the outlet of a one-way valve, the inlet of the one-way valve is connected with a soft water stop valve, the inlet of a humidifying electric valve 112 is connected with a pipeline between the inlet of the one-way valve and the soft water stop valve through a tee joint, and the outlet of the humidifying electric valve 112. The second opening (right inlet) of the water mixing tank 104 is connected with the second opening (right outlet) of the plate heat exchanger 109, the fourth opening (right inlet) of the plate heat exchanger 109 is connected with the heat pump water outlet stop valve, the inlet of the cold water electric valve 111 is connected with the pipeline between the plate heat exchanger 109 and the water mixing tank 104 through a tee joint, the outlet of the cold water electric valve 111 is connected with the inlet of the surface air cooler 5, the second opening (right outlet) of the water mixing tank 104 is connected with the inlet of the gate valve 110, the outlet of the gate valve 110 is connected with the heat pump water return stop valve, and the outlet of the surface air cooler 5 is connected with the pipeline between the gate valve 110 and the heat pump. The first opening (left inlet) of the plate heat exchanger 109 is connected with the outlet of the hot water electric valve 108, the inlet of the hot water electric valve 108 is connected with the municipal hot water supply stop valve, and the third opening (left outlet) of the plate heat exchanger 109 is connected with the municipal hot water return stop valve.

The controller 500 of the system is disposed in the system air duct on the side of the air supply outlet 407, and controls the actions of the fresh air valve 1, the air blower 4, the exhaust valve 12, the bypass air valve 13, the ultraviolet light source 14, the exhaust blower 9, the compressor 201, the four-way valve 202, the proportional bypass valve 105, the water pump 107, the hot water electric valve 108, the cold water electric valve 111, the humidification electric valve 112, and the water supplement electric valve 113 according to the sensing data of the sensors such as the return air temperature and humidity sensor, the supply air temperature and humidity sensor, the fresh air temperature and humidity sensor, the pressure switch 102, the supply water temperature sensor, and the return water temperature sensor, and controls the actions of the cold heat source heat pump unit, the user side end operation panel, the end water path valve, and the like according to.

Example 11

As shown in fig. 2, the present embodiment describes the cooling-by-air and cooling-by-cooling dehumidification modes of the system:

when the controller judges that the air conditioner enters the ventilation cooling and refrigeration dehumidification modes, the fresh air valve 1 is opened, the bypass air valve 13 is closed, the air blower 4 is started, the exhaust fan 9 is started, the ultraviolet light source 14 is started, the cold and heat source heat pump unit starts refrigeration, the water pump 107 is started, the hot water electric valve 108 is closed, the humidification electric valve 112 is closed, the compressor 201 is started, and the four-way valve 202 is powered off.

After the blower 4 is started, outdoor fresh air enters the system through the fresh air valve 1, is sucked by the blower 4 after sequentially passing through the fresh air primary high-efficiency filter screen 2 and the total heat exchanger 3, is pressurized and then is sent out, and finally is sent to the indoor from the air supply outlet 407 through an air channel inside the system after sequentially passing through the surface cooler 5, the evaporator 6, the reheater 7 and the humidifier 8, so that a continuous fresh air treatment process is formed. After the exhaust fan 9 is started, indoor return air enters the system through the return air inlet 406, enters the total heat exchanger 3 from the primary exhaust filter screen 10 after being pressurized by the exhaust fan 9, is subjected to total heat exchange with fresh air in the total heat exchanger 3, then is discharged outdoors through the fin condenser 11 from the exhaust outlet 405, and the indoor exhaust process is completed.

After the compressor 201 is started, the discharged high-temperature and high-pressure refrigerant gas enters the finned condenser 11 through the four-way valve 202, under the heat dissipation effect of the exhaust air of the finned condenser 11, the refrigerant is discharged after heat release and temperature reduction, enters the reheater 7, exchanges heat with the fresh air passing through the reheater 7, realizes further heat release and temperature reduction, is condensed into liquid, is discharged, enters the expansion valve 204 through the first filter 203, is changed into a low-temperature and low-pressure refrigerant gas-liquid mixture after expansion and throttling of the expansion valve 204, enters the evaporator 6, is completely changed into low-temperature and low-pressure refrigerant gas after evaporating and absorbing the heat of the fresh air passing through the surface cooler 5 in the evaporator 6, enters the gas-liquid separator 205 through the four-way valve 202, enters the suction end of the compressor 201, and is compressed and discharged again by the compressor 201, forming a continuous refrigerant vapor compression cycle.

After the cold and heat source heat pump unit starts refrigeration, cold water with the temperature of 7 ℃ is provided and enters the system through the heat pump water outlet stop valve, a part of cold water enters the water mixing tank 104 after passing through the plate heat exchanger 109, the cold water is mixed in the water mixing tank 104 after heat exchange, and then comes out from a fourth opening (a right side outlet) of the water mixing tank 104, and returns to the cold and heat source heat pump unit through the heat pump water return stop valve, the other part of cold water coming out from the plate heat exchanger 109 enters the surface air cooler 5 through the tee joint and the cold water electric valve 111, after the fresh air is cooled and dehumidified in the surface air cooler 5, the cold water comes out and returns to a pipeline between the water mixing tank 104 and the heat pump water return.

After the water pump 107 is started, cold water with the temperature of 18 ℃ is provided and enters the tail end of the indoor capillary tube through the indoor water supply stop valve, the cold water after heat exchange is completed at the tail end of the indoor capillary tube comes out from the tail end of the indoor capillary tube, passes through the indoor water outlet stop valve and then enters the system, enters the water mixing tank 104 through the second filter 101, completes water mixing and heat exchange with the cold water coming from the cold and heat source heat pump unit in the water mixing tank 104, and returns to the inlet of the water pump 107 after being adjusted by the proportional bypass valve 105.

After the ultraviolet light source 14 is started, the emitted ultraviolet light with specific wavelength continuously irradiates the surface of the fresh air primary high-efficiency filter screen 2, harmful bacteria and viruses attached to the surface of the fresh air primary high-efficiency filter screen 2 are eliminated, and air is purified. Meanwhile, a photocatalyst component can be added to release negative oxygen ions and refresh air.

The centralized controller of the system adjusts the opening of the proportional bypass valve 105 according to the value of the water supply temperature sensor to realize the accurate control of the indoor water supply temperature, adjusts the opening of the cold water electric valve 111 according to the value of the air supply moisture content to realize the accurate control of the air supply humidity, and adjusts the opening of the exhaust valve 12 according to the value of the air supply temperature to realize the accurate control of the air supply temperature.

Example 12

As shown in fig. 3, the present embodiment describes the cooling and dehumidifying modes of the system:

when the controller judges that the air conditioner enters the refrigeration and dehumidification mode, the fresh air valve 1 is closed, the bypass air valve 13 is opened, the air blower 4 is started, the exhaust fan 9 is started, the ultraviolet light source 14 is started, the cold and heat source heat pump unit starts refrigeration, the water pump 107 is started, the hot water electric valve 108 is closed, the humidification electric valve 112 is closed, the compressor 201 is started, and the four-way valve 202 is powered off.

After the blower 4 is started, indoor return air enters the system through the return air inlet 406, sequentially passes through the bypass air valve 13, the fresh air primary high-efficiency filter screen 2 and the total heat exchanger 3, is sucked by the blower 4, is pressurized and then is sent out, sequentially passes through the surface air cooler 5, the evaporator 6, the reheater 7 and the humidifier 8, and finally is sent to the indoor through the air supply outlet 407 through an air duct inside the system, so that a continuous return air reprocessing process is formed. After the exhaust fan 9 is started, indoor return air enters from the return air inlet 406 and exits from the exhaust outlet 405 in the same mode as the ventilation cooling and refrigeration dehumidifying modes, and the indoor exhaust process is completed.

After the compressor 201 is started, the refrigerant cycle is the same as the ventilation cooling and cooling dehumidification mode, and a continuous vapor compression cycle is formed among the compressor 201, the four-way valve 202, the first filter 203, the expansion valve 204, the gas-liquid separator 205, the fin condenser 11, the reheater 7 and the evaporator 6.

After the cold and heat source heat pump unit starts refrigeration, as in the ventilation cooling and refrigeration dehumidification mode, cold water is continuously circulated among the cold and heat source heat pump unit, the plate heat exchanger 109, the water mixing tank 104 and the surface cooler 5.

After the water pump 107 is started, as in the ventilation cooling and cooling dehumidification mode, cold water is continuously circulated among the capillary tube at the indoor tail end, the water mixing tank 104, the proportional bypass valve 105 and the water pump 107.

The ultraviolet light source 14 is activated to purify and freshen the return air recirculated air as in the aeration cooling and cooling dehumidification mode.

The centralized controller of the system is the same as the ventilation cooling and refrigeration dehumidification modes, and can accurately control the air supply humidity and the air supply stability of the system and the indoor water supply temperature.

Example 13

As shown in fig. 4, the present embodiment introduces a dehumidification warming mode of the system:

when the controller judges that the dehumidification and temperature rise mode is entered, the fresh air valve 1 is closed, the bypass air valve 13 is opened, the blower 4 is started, the exhaust fan 9 is closed, the ultraviolet light source 14 is started, the cold and heat source heat pump unit is closed, the water pump 107 is closed, the hot water electric valve 108 is closed, the humidification electric valve 112 is closed, the compressor 201 is closed, and the four-way valve 202 is powered off.

After the blower 4 is started, as in the refrigeration and dehumidification mode, the indoor return air enters the system through the return air inlet and is delivered to the indoor from the air supply outlet, so that a continuous indoor return air reprocessing process is formed.

After the compressor 201 is started, the refrigerant cycle is the same as the ventilation cooling and cooling dehumidification mode, a continuous steam compression cycle is formed among the compressor 201, the four-way valve 202, the first filter 203, the expansion valve 204, the gas-liquid separator 205, the fin condenser 11, the reheater 7 and the evaporator 6, because the exhaust fan 9 is closed, the fin condenser 11 does not play a role in heat dissipation, the reheater 7 plays a role in heat dissipation of the refrigerant, and therefore the indoor return air temperature after passing through the reheater 7 is increased.

After the cold and heat source heat pump unit starts refrigeration, as in the ventilation cooling and refrigeration dehumidification mode, cold water is continuously circulated among the cold and heat source heat pump unit, the plate heat exchanger 109, the water mixing tank 104 and the surface cooler 5.

The ultraviolet light source 14 is activated to purify and freshen the return air recirculated air as in the aeration cooling and cooling dehumidification mode.

And a centralized controller of the system only adjusts the opening of the cold water electric valve 111 according to the value of the moisture content of the air supply, so that the accurate control of the air supply humidity is realized.

Example 14

As shown in fig. 5, the present embodiment introduces the ventilation mode of the system:

when the controller judges that the air conditioner enters the ventilation mode, the fresh air valve 1 is opened, the bypass air valve 13 is closed, the blower 4 is started, the exhaust fan 9 is started, the ultraviolet light source 14 is started, the cold and heat source heat pump unit is closed, the water pump 107 is closed, the hot water electric valve 108 is closed, the humidification electric valve 112 is closed, the compressor 201 is closed, and the four-way valve 202 is powered off.

The ultraviolet light source 14 is activated to purify and freshen the return air recirculated air as in the aeration cooling and cooling dehumidification mode.

After the blower 4 is started, outdoor fresh air enters the system through the fresh air valve 1 and is delivered to the indoor from the air supply outlet in the same mode as a ventilation cooling and refrigeration dehumidification mode, and a continuous fresh air treatment process is formed. After the exhaust fan 9 is started, as in the ventilation cooling and refrigeration dehumidification modes, indoor return air enters the system through the return air inlet and is exhausted outdoors from the exhaust outlet, and the indoor exhaust process is completed.

Example 15

As shown in fig. 6, the present embodiment describes the ventilation heating plus heating and humidifying mode of the system:

when the controller judges that the ventilation heating-up and heating humidification mode is entered, the fresh air valve 1 is opened, the bypass air valve 13 is closed, the blower 4 is started, the exhaust fan 9 is started, the ultraviolet light source 14 is started, the cold and heat source heat pump unit is started for heating, the water pump 107 is started, the hot water electric valve 108 is opened, the humidification electric valve 112 is opened, the compressor 201 is closed, and the four-way valve 202 is powered off.

After the blower 4 is started, outdoor fresh air enters the system through the fresh air valve 1 and is delivered to the indoor from the air supply outlet in the same mode as a ventilation cooling and refrigeration dehumidification mode, and a continuous fresh air treatment process is formed. After the exhaust fan 9 is started, as in the ventilation cooling and cooling dehumidification mode, the indoor return air enters the system through the return air inlet 406 and is exhausted to the outside from the exhaust outlet 407, and the indoor exhaust process is completed.

After the cold and heat source heat pump unit is started to heat, cold water with the temperature of 45 ℃ is provided and enters the system through the heat pump water outlet stop valve, a part of cold water enters the water mixing tank 104 after passing through the plate heat exchanger 109, the cold water is mixed in the water mixing tank 104 after heat exchange, then comes out from the right side outlet of the water mixing tank 104 and returns to the cold and heat source heat pump unit through the heat pump water return stop valve, the other part of cold water after coming out from the plate heat exchanger 109 enters the surface air cooler 5 through the tee joint and the cold water electric valve 111, after the temperature of fresh air is raised in the surface air cooler 5, the cold water comes out and returns to a pipeline between the water mixing tank 104 and the heat pump.

After the hot water electric valve 108 is opened, municipal hot water enters the system through the hot water supply stop valve, enters the plate heat exchanger 109 through the hot water electric valve 108, exchanges heat with hot water sent by the cold and heat source heat pump unit in the plate heat exchanger 109, and then flows out of the system from a third opening (left side outlet) of the plate heat exchanger 109 and returns to a municipal hot water pipeline through the hot water return stop valve.

After the water pump 107 is started, hot water at 35 ℃ is provided and enters the tail end of the indoor capillary tube through the indoor water supply stop valve, the hot water after heat exchange is completed at the tail end of the indoor capillary tube comes out from the tail end of the indoor capillary tube and passes through the indoor water outlet stop valve, then enters the system, enters the water mixing tank 104 through the second filter 101, completes water mixing and heat exchange with the hot water from the cold and heat source heat pump unit in the water mixing tank 104, and returns to the inlet of the water pump 107 after being adjusted by the proportional bypass valve 105.

After the humidifying electric valve 112 is opened, water from the water softener enters the system through the soft water stop valve, enters the humidifier 8 through the humidifying electric valve 112, humidifies hot air sent from the surface air cooler 5 in the humidifier 8, and discharges residual water after humidification out of the system through a drain pipe from a drain pan of the system.

The ultraviolet light source 14 is activated to purify and freshen the return air recirculated air as in the aeration cooling and cooling dehumidification mode.

The centralized controller of the system adjusts the opening of the proportional bypass valve 105 according to the value of the water supply temperature sensor, realizes the accurate control of the indoor water supply temperature, adjusts the start and stop of the humidifying electric valve 112 according to the value of the air supply humidity, realizes the accurate control of the air supply humidity, adjusts the opening of the cold water electric valve 111 according to the value of the air supply temperature, and realizes the accurate control of the air supply temperature.

Example 16

As shown in fig. 7, the present embodiment describes the heating and humidifying mode of the system:

when the controller judges that the heating and humidifying mode is entered, the fresh air valve 1 is closed, the bypass air valve 13 is opened, the air blower 4 is started, the exhaust fan 9 is closed, the ultraviolet light source 14 is started, the cold and heat source heat pump unit is started for heating, the water pump 107 is started, the hot water electric valve 108 is opened, the humidifying electric valve 112 is opened, the compressor 201 is closed, and the four-way valve 202 is powered off.

After the blower 4 is started, as in the cooling and dehumidifying mode, the indoor return air enters the system through the return air inlet 406 and is sent to the indoor from the supply air outlet 407, so that a continuous indoor return air reprocessing process is formed.

After the cold and heat source heat pump unit starts heating, the hot water completes continuous circulation among the cold and heat source heat pump unit, the plate heat exchanger 109, the water mixing tank 104 and the surface cooler 5 in the same mode as the ventilation heating and heating humidification mode.

After the hot water electric valve 108 is opened, municipal hot water completes continuous circulation among the municipal hot water pipeline, the hot water electric valve 108 and the plate heat exchanger 109 in the same ventilation heating and heating humidification mode.

After the water pump 107 is started, the hot water completes continuous circulation among the capillary tube at the indoor tail end, the water mixing tank 104, the proportional bypass valve 105 and the water pump 107, as in the ventilation heating and humidifying mode.

After the humidifying electric valve 112 is opened, the air reprocessed from the indoor return air is humidified by soft water in the same manner as in the ventilation heating and humidifying mode.

The ultraviolet light source 14 is activated to purify and freshen the return air recirculated air as in the aeration cooling and cooling dehumidification mode.

Although the invention has been described in detail with respect to the general description and the specific embodiments, it will be apparent to those skilled in the art that modifications and improvements can be made based on the invention. Therefore, such modifications and improvements are intended to be within the scope of the invention as claimed.

Claims (9)

1. A heat recovery temperature-regulating radiation system is characterized by comprising an accommodating space (400), a fresh air module, a temperature regulating module and a capillary water supply module;

the accommodating space (400) is provided with a fresh air area (401), a temperature adjusting area (402) and a capillary water supply area (403), the fresh air module is arranged in the fresh air area (401), the temperature adjusting module is arranged in the temperature adjusting area (402), and the capillary water supply module is arranged in the capillary water supply area (403);

the fresh air area (401) is provided with a fresh air inlet (404), an air outlet (405), an air return inlet (406) and a communication air inlet, the temperature adjusting area (402) is communicated with the capillary water supply area (403), and the capillary water supply area (403) is provided with an air supply outlet (407).

2. The heat recovery temperature-regulating radiation system according to claim 1, wherein the fresh air module comprises a fresh air valve (1), a fresh air primary high-efficiency filter screen (2), a total heat exchanger (3), a blower (4), an exhaust fan (9), an exhaust primary filter screen (10), a finned condenser (11), an exhaust valve (12) and a bypass air valve (13);

the fresh air valve (1) is arranged in a fresh air opening (404), the finned condenser (11) and the exhaust valve (12) are arranged in an exhaust opening (405), and the blower (4) is arranged in the communicated air opening;

the total heat exchanger (3) is provided with a first inlet, a first outlet, a second inlet and a second outlet, wherein the first inlet is communicated with the first outlet, and the second inlet is communicated with the second outlet;

the air return opening (406) is communicated with a first inlet of the total heat exchanger (3) through an exhaust fan (9) and an exhaust primary filter screen (10);

the exhaust valve (12) is communicated with a first outlet of the total heat exchanger (3);

the fresh air valve (1) is communicated with a second inlet of the total heat exchanger (3) through a fresh air primary high-efficiency filter screen (2), and the fresh air valve (1) is communicated with the air return inlet (406) through a bypass air valve (13);

the inlet of the blower (4) is communicated with the second outlet of the total heat exchanger (3).

3. The heat recovery temperature-regulating radiation system according to claim 2, wherein the fresh air module further comprises an ultraviolet light source (14), and the ultraviolet light source (14) is arranged between the fresh air primary high-efficiency filter screen (2) and the bypass air valve (13).

4. The heat recovery attemperation radiation system of claim 2, wherein the fresh air module further comprises a surface cooler (5), an evaporator (6), a reheater (7) and a humidifier (8), the surface cooler (5), the evaporator (6), the reheater (7) and the humidifier (8) being sequentially arranged between the communicating tuyere and the attemperation region (402).

5. The heat recovery temperature-adjusting type radiation system according to claim 4, wherein the temperature-adjusting module includes a compressor (201), a four-way valve (202), a first filter (203), an expansion valve (204), and a gas-liquid separator (205), the compressor (201) has a gas suction pipe and a gas discharge pipe, the four-way valve (202) has a first valve port, a second valve port, a third valve port, and a fourth valve port, the gas discharge pipe of the compressor (201) is connected to the first valve port of the four-way valve (202), the second valve port of the four-way valve (202) is connected to an inlet of a finned condenser (11), an outlet of the finned condenser (11) is connected to an inlet of a reheater (7), an outlet of the reheater (7) is connected to an inlet of the evaporator (6) sequentially through the first filter (203) and the expansion valve (204), and an outlet of the evaporator (6) is connected to the third valve port of the four-way valve, and a fourth valve port of the four-way valve (202) is connected with an inlet of a gas-liquid separator (205), and an outlet of the gas-liquid separator (205) is connected with a gas suction pipe of the compressor (201).

6. The heat recovery attemperation-type radiant system of claim 5, wherein the capillary water supply module comprises a second filter (101), a water mixing tank (104), a proportional bypass valve (105), a water pump (107), a hot water electric valve (108), a plate heat exchanger (109), a gate valve (110), a cold water electric valve (111), a humidification electric valve (112) and a water replenishment electric valve (113);

the capillary tube water supply area (403) is provided with a heat pump water outlet (301), a municipal hot water outlet (302), a municipal hot water inlet (303), a heat pump water return port (304), a soft water inlet (305), an indoor water outlet (306), an indoor water supply port (307), a water discharge port (308) and a water discharge port (309);

the water mixing tank (104) is provided with a first opening, a second opening, a third opening and a fourth opening, the proportional bypass valve (105) is provided with a first opening, a second opening and a third opening, and the plate heat exchanger (109) is provided with a first opening, a second opening, a third opening and a fourth opening;

the first opening of the water mixing tank (104) is communicated with the second opening of the proportional bypass valve (105), the second opening of the water mixing tank (104) is communicated with the second opening of the plate-type heat exchanger (109), the second opening of the water mixing tank (104) is communicated with the inlet of the surface cooler (5) through a cold water electric valve (111), the third opening of the water mixing tank (104) is communicated with the third opening of the proportional bypass valve (105), the third opening of the water mixing tank (104) is communicated with an indoor water outlet (306) through a second filter (101), the fourth opening of the water mixing tank (104) is communicated with a heat pump water return opening (304) through a gate valve (110), the fourth opening of the water mixing tank (104) is communicated with the outlet of the surface cooler (5) through a gate valve (110), the first opening of the plate-type heat exchanger (109) is communicated with a municipal hot water inlet (303) through a hot water electric valve (108), the third opening of the plate heat exchanger (109) is communicated with a municipal hot water outlet (302), and the fourth opening of the plate heat exchanger (109) is communicated with a heat pump water outlet (301);

soft water entry (305) communicate indoor delivery port (306) through moisturizing motorised valve (113), soft water entry (305) communicate the water inlet of humidifier (8) through humidification motorised valve (112), indoor water supply port (307) are through the first opening of water pump (107) intercommunication proportion bypass valve (105), outlet (308) intercommunication the first opening of proportion bypass valve (105), outlet (309) intercommunication the delivery port of humidifier (8).

7. The heat recovery temperature-regulating radiation system according to claim 6, wherein the capillary water supply module further comprises a pressure switch (102) and a return water temperature sensor (103), and the third opening of the water mixing tank (104) is communicated with the indoor water outlet sequentially through the return water temperature sensor (103), the pressure switch (102) and the second filter (101).

8. The heat recovery thermostatted radiant system as claimed in claim 6, characterized in that the capillary water supply module further comprises a water supply temperature sensor (106), the indoor water supply (307) communicating with the first opening of the proportional bypass valve (105) through the water supply temperature sensor (106) and the water pump (107).

9. The heat recovery attemperation radiation system of claim 1, further comprising a controller (500) that controls the fresh air module, the attemperation module, and the capillary water supply module.

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