RU2716552C1 - Plenum air conditioner with non-fluid rotary heating and cooling - Google Patents

Abstract

FIELD: ventilation and air conditioning.

SUBSTANCE: invention relates to supply air conditioners for maintenance of public buildings during cold and warm seasons. Supply air conditioner with non-liquid rotary heating and cooling, comprising inlet chamber and exhaust chamber, separated by horizontal intermediate partition with main and additional rotor channels and arrangement of main rotor channel of horizontal intermediate partition at inlet of outside air into air conditioner, adsorption rotary regenerator and rotary heat exchanger built into horizontal intermediate partition rotor channels and having external air inflow line, at that, adsorption rotary regenerator and rotary heat exchanger of air conditioner have exhaust air line with required values of temperature and moisture content of exhaust air at inlet to exhaust chamber of air conditioner, opposite directed line of external air inflow, adsorption rotary regenerator is built into additional rotor channel of horizontal intermediate partition, and the rotary heat exchanger – into the main rotor channel of the horizontal intermediate partition of the air conditioner, which form in the air conditioner non-liquid rotor heating and cooling.

EFFECT: technical result consists in ensuring in the cold and warm periods of the year of obtaining in the air conditioner zero power consumption of supply air of the specified values of temperature, relative humidity and moisture content without the presence of a hybrid line of hot air drawing.

1 cl, 3 dwg, 2 tbl

Description

The claimed solution relates to the field of supply air conditioners for servicing the premises of public buildings in the cold and warm periods of the year.

Group и роторный теплообменник и имеет противоположно направленные линии притока наружного воздуха и вытяжного воздуха.The air conditioner contains supply and exhaust chambers, an adsorption rotary regenerator

Group and rotary heat exchanger and has oppositely directed lines of influx of external air and exhaust air.

As exhaust air in the inventive air conditioner can be used as removed from the room air and supply air.

The parameters of the outside air (temperature, relative humidity, moisture content and barometric pressure) adopted in the calculations of the proposed solution correspond to the climatic conditions of the city of Tomsk.

Supply air conditioners are known from sources of scientific, technical and patent information. Among them, air conditioners were selected for servicing the premises of public buildings, which do not provide zero energy consumption for heating and cooling the supply air in the cold and warm periods of the year without the presence of a hybrid hot air exhaust line in them, which makes it possible to improve them in the direction indicated in the claims solutions.

Known supply air conditioner for public buildings, described in the patent for invention No. 2668122 "Multifunctional air conditioning system with a hybrid hot air exhaust line", issued by application for invention No. 2017146527 with the priority of the invention dated December 27, 2017, published September 26 2018 to Bul. Number 27. Authors: V.E. Voskresensky, A.M. Grimmitlin.

A multifunctional supply air conditioning system with a hybrid hot air exhaust line, comprising an air conditioner, an outdoor air intake fan, a main exhaust fan for extracting air from the room, a hot air exhaust fan, an air conditioner comprising a supply chamber and a main exhaust chamber separated by a horizontal intermediate partition with a main and additional rotor channels and the placement of the main rotor channel of the horizontal intermediate partition at the inlet of the outdoor air to the air conditioner, an adsorptive rotor regenerator and a rotary heat exchanger heat exchanger built into the rotor channels of the horizontal intermediate partition of the air conditioner, a controller, an adsorptive rotor regenerator has oppositely directed lines of outdoor air inflow and exhaust from the room, the rotor heat exchanger has an outdoor inflow line air, supply and main exhaust chambers contain inlet and outlet pipes, in addition, the air conditioner contains additional a hot air exhaust chamber with inlet and outlet nozzles, characterized in that the supply air conditioning system includes an inlet duct for the air being removed from the room and an air distribution unit for exhausted air from the room, the hybrid hot air exhaust line contains an inlet and outlet air duct, an adsorptive rotor the regenerator contains an inverter and is integrated into the additional rotor channel of the horizontal intermediate partition air conditioner a, and a rotary heat exchanger - into the main rotor channel of the horizontal intermediate partition, an additional hot air exhaust chamber is placed above the horizontal intermediate partition of the air conditioner with a rotary heat exchanger span, which has a hybrid hot air exhaust line opposite to the outside air supply line, while the rotary heat exchanger of the air conditioner provides heating of the supply air to a temperature difference formed between the required supply air temperature the air at the inlet to the adsorption rotary regenerator and the outside temperature at the inlet to the rotary heat exchanger, the air distribution unit contains a suction duct, a main and additional exhaust fans for extracting air from the room, a pressure duct of variable cross section, containing at least two distributing tees of different throughputs, an input the duct of the hybrid hot air exhaust line is made with a variable cross section, contains at least two collecting tees p different throughput and is connected at the outlet to the inlet of the additional exhaust chamber of the hot air conditioner, the inlet duct of the exhaust air from the room at the outlet is connected to the inlet of the main exhaust chamber of the air conditioner, the suction duct of the air distribution unit is connected at the inlet to the outlet of the main exhaust chamber of the air conditioner the outlet with the suction pipe of the main exhaust fan of the exhaust air from the room, the discharge pipe of which connected to the pressure duct of the air distribution unit, distributing and collecting tees of the same flow capacity are paired together by distributing air ducts, the pressure duct of the air distribution unit at the outlet is connected to the suction pipe of an additional exhaust fan for extracting air from the room, and the exhaust pipe of the additional air conditioning exhaust chamber is connected to the exhaust duct hybrid hot air exhaust line, supply air outlet the air conditioning chambers are connected by an air duct to the suction pipe of the outdoor air supply fan, in addition, the supply air conditioning system further comprises a supply air cooler with inlet and outlet pipes, an air inlet and outlet air temperature adjuster containing the supply and exhaust chambers separated by a horizontal partition with rotor channel and rotary heat exchanger heat exchanger integrated in it, supply and exhaust chambers of the closer the supply and exhaust air rounds contain inlet and outlet nozzles, the inlet duct of the air removed from the room contains distributing and collecting tees of air removed from the room, from which the distributing tee contains controllable air valves installed at its exits, a controllable lateral outlet air valve the distributing tee of the air removed from the room is connected by an air duct to the inlet pipe of the exhaust chamber of the closer of the air inlet and outlet temperature the air outlet, the outlet pipe of which is connected to the collecting tee of the air to be removed from the room, the duct connecting the outlet pipe of the air conditioning supply chamber to the suction pipe of the outdoor air supply fan, contains the supply and collecting tees of the fresh air integrated therein, from which the distribution tee is connected at the outlet with the inlet pipe of the supply air cooler, and the collecting tee contains controlled air valves installed at its inlets, exhaust the inlet pipe of the supply air cooler is connected by an air duct to the inlet pipe of the supply chamber of the air inlet and outlet air temperature adjuster, the outlet pipe of which is connected to a controlled air valve of the inlet air intake tee, while the total mass flow rate of the air removed from the room distributed over the distribution ducts is the difference in mass flow rates of air removed from the room at the inlet and outlet of the pressure duct of the air distribution unit, and m the mass flow rate of the air removed from the room at the outlet of the pressure duct is equal to the mass flow of hot air at the inlet of the air conditioning system, which mixes the hot and exhaust air from the room in the tees of the inlet duct of the hybrid hot air exhaust line to obtain the desired temperature range of the mixed air at the entrance to the additional exhaust chamber of the air conditioner and a sixteen-fold increase in its mass flow rate by comparison the mass flow rate of hot air at the entrance to the air conditioning system

Despite the large number of coinciding features of the prototype and the claimed solution, the lack of distinctive features of the latter in the prototype does not provide a technical result consisting in expanding the functionality of the supply air conditioner for the following reasons.

The supply air conditioner adopted for the prototype has functional limitations that do not allow:

1) in the cold season, to ensure zero energy consumption in the air conditioner for heating the supply air to a final temperature of t ₃ = 20 ° C, relative humidity ϕ ₃ = 0.44, moisture content d ₃ = 6.5 g / kg dry. air and outdoor temperature changes in the range t ₁ = (- 40) ÷ 10 ° С, relative humidity ϕ ₁ = 0.8 (in fractions of a unit), moisture content in the range d ₁ = 0.064 ÷ 6.23 g / kg dry . air without a hybrid hot air exhaust line;

2) in the warm season, to ensure in the air conditioner zero energy consumption for cooling the supply air to a final temperature t ₃ = 20 ° C, relative humidity ϕ ₃ = 0.53, moisture content d ₃ = 7.9 g / kg dry. air and outdoor temperature changes in the range t ₁ = 21 ÷ 30 ° C, relative humidity ϕ ₁ = 0.74 (in fractions of a unit), moisture content in the range d ₁ = 11.8 ÷ 20.4 g / kg dry. air without a hybrid hot air exhaust line ..

The task of creating a supply air conditioner with liquid-free rotary heating and cooling for public buildings was to improve the design of the air conditioner - a prototype and to obtain a technical result - expanding the functionality of the air conditioner.

Expanding the functionality of the supply air conditioner includes:

1. obtaining in the air conditioner of supply air during the cold season, zero energy consumption for heating the supply air to a final temperature of t ₃ = 20 ° C, relative humidity ϕ ₃ = 0.44, moisture content d ₃ = 6.5 g / kg dry. air, at a temperature of exhaust air at the inlet to the exhaust chamber of the air conditioner t ₄ = 21.5 ° C, moisture content d ₄ = 7.3 g / kg dry. air and outdoor temperature changes in the range t ₁ = (- 40) ÷ 10 ° С, relative humidity ϕ ₁ = 0.8, moisture content in the range d ₁ = 0.064 ÷ 6.23 g / kg dry. air without a hybrid hot air exhaust line;

2. obtaining in the air conditioner of supply air during the warm season, zero energy consumption for cooling the supply air to a final temperature t ₃ = 20 ° C, relative humidity ϕ ₃ = 0.53, moisture content d ₃ = 7.9 g / kg dry. air, at a temperature of exhaust air at the inlet to the exhaust chamber of the air conditioner t ₄ = 19.8 ° C, moisture content d ₄ = 7.3 g / kg dry. air, and a change in outdoor temperature in the range t ₁ = 21 ÷ 30 ° C, relative humidity ϕ ₁ = 0.74, moisture content in the range d ₁ = 11.8 ÷ 20.4 g / kg dry. air without a hybrid hot air exhaust line.

The achievement of the above technical result is ensured by the fact that the supply air conditioner with liquid-free rotor heating and cooling, comprising a supply chamber and an exhaust chamber separated by a horizontal intermediate partition with the main and additional rotor channels and the placement of the main rotor channel of the horizontal intermediate partition at the outdoor air inlet air conditioning, adsorption rotary regenerator and rotary heat exchanger integrated in the rotor channels horizontal intermediate partition, and having a line of outdoor air supply, characterized in that the adsorption rotary regenerator and rotary heat exchanger of the air conditioner have an exhaust air line with the required values of temperature and moisture content of exhaust air at the inlet to the air conditioner exhaust chamber, opposite to the direction of the outdoor air flow line, adsorption rotor the regenerator is built into the additional rotor channel of the horizontal intermediate partition, and the rotary heat exchanger is integrated into the main implicit channel rotary horizontal intermediate partitions the air conditioner, the air conditioner forming aneroid rotary heating and cooling.

The technical result of the claimed invention is provided by the totality of the essential features.

The algorithm for calculating the parameters of the outdoor, supply and exhaust air, and their values, providing during the cold season receiving in the supply air conditioner zero energy consumption for heating the supply air to the set values of temperature t ₃ = 20 ° C, relative humidity ϕ ₃ = 0.44, and moisture content d ₃ = 6.5 g / kg dry. air, at a temperature of exhaust air at the inlet to the exhaust chamber of the air conditioner t ₄ = 21.5 ° C, moisture content d ₄ = 7.3 g / kg dry. air and outdoor temperature changes in the range t ₁ = (- 40) ÷ 10 ° С and moisture content in the range d ₁ = 0,064 ÷ 6,23 g / kg dry. air, without the presence of a hybrid hot air exhaust line are shown in table 1.

The algorithm for calculating the parameters of the outdoor, supply and exhaust air, and their values, which ensure that in the warm season, the supply air conditioner receives zero energy consumption for cooling the supply air to the specified temperature values t ₃ = 20 ° С, relative humidity ϕ ₃ = 0.53, and moisture content d ₃ = 7.9 g / kg dry. air, at a temperature of exhaust air at the inlet to the exhaust chamber of the air conditioner t ₄ = 19.8 ° C, moisture content d ₄ = 7.3 g / kg dry. air and outdoor temperature changes in the range of t ₁ = 21 ÷ 30 ° C and moisture content in the range of d ₁ = 11.8 ÷ 20.4 g / kg dry. air without the presence of a hybrid hot air exhaust line are shown in table 2.

The proof of the materiality of the differences of the claimed supply air conditioner and the connection of the distinguishing features with the technical result are disclosed in the following sequence.

1. Expanding the functionality of the supply air conditioner in the form of providing in the cold season a zero energy consumption in the air conditioner for heating the supply air to the set temperature t ₃ = 20 ° C, relative humidity ϕ ₃ = 0.44, and moisture content d ₃ = 6 5 g / kg dry air, at a temperature of exhaust air at the inlet to the exhaust chamber of the air conditioner t ₄ = 21.5 ° C, moisture content d ₄ = 7.3 g / kg dry. air and outdoor temperature changes in the range t ₁ = (- 40) ÷ 10 ° С and moisture content in the range d ₁ = 0,064 ÷ 6,23 g / kg dry. air without a hybrid hot air exhaust line.

2. Expanding the functionality of the supply air conditioner in the form of ensuring in the warm season of the year in the air conditioner zero energy consumption for cooling the supply air to preset temperatures t ₃ = 20 ° C, relative humidity ϕ ₃ = 0.45, moisture content d ₃ = 7, 9 g / kg dry air, at a temperature of exhaust air at the inlet to the exhaust chamber of the air conditioner t ₄ = 19.8 ° C, moisture content d ₄ = 7.3 g / kg dry. air and outdoor temperature changes in the range of t ₁ = 21 ÷ 30 ° C and moisture content in the range of d ₁ = 11.8 ÷ 20.4 g / kg dry. air without a hybrid hot air exhaust line.

Expanding the functionality of the supply air conditioner in the form of providing in the cold season a zero energy consumption in the air conditioner to heat the supply air to the set temperature t ₃ = 20 ° C, relative humidity ϕ ₃ = 0.44, moisture content d ₃ = 6.5 g / kg dry air, at a temperature of exhaust air at the inlet to the exhaust chamber of the air conditioner t ₄ = 21.5 ° C, moisture content d ₄ = 7.3 g / kg dry. air and outdoor temperature changes in the range t ₁ = (- 40) ÷ 10 ° С and moisture content in the range d ₁ = 0,064 ÷ 6,23 g / kg dry. air without the presence of a hybrid hot air exhaust line is achieved due to the following advantages of the proposed solution:

1. the adsorption rotary regenerator and rotary heat exchanger of the inventive air conditioner have an exhaust air line opposite to the outside air supply line, which ensures the air conditioner is dual-chamber and when the adsorption rotary regenerator is embedded in an additional rotor channel of the horizontal intermediate partition and the rotor heat exchanger in the main rotor channel of the horizontal intermediate partition conditioner - intake of warm exhaust air leaving the adsor insulating rotary regenerator air conditioner, the input to a rotary heat exchanger, the required amount of recovered heat of the exhaust air, the volumes recovered and transmitting heat to the supply air;

и передаваемой теплоте

;2. the exhaust air line of the inventive air conditioner has the required value of the moisture content of the exhaust air at the inlet to the exhaust chamber of the air conditioner equal to d ₄ = 7.3 g / kg dry. air, and the same with the warm season, which, together with the moisture content of the supply air at the inlet to the adsorption rotary regenerator d ₂ , equal to the moisture content of the outdoor air d ₂ = d ₁ , varying in the range of d ₁ = 0.064 ÷ 6.23 g / kg dry. air, and a given moisture content of the supply air at the outlet of the adsorption rotary regenerator d ₃ = 6.5 g / kg dry. air, provide the calculated values of the efficiency of the adsorption rotary regenerator of the air conditioner for the transmitted moisture

and heat transferred

;

и принятыми высокими значениями эффективности роторного теплообменника кондиционера

при изменении температуры наружного воздуха в диапазоне t₁=(-40)÷10°С обеспечивают получение нулевого перепада температур на нагревание вытяжного воздуха в вытяжной камере кондиционера

, образуемого между требуемой температурой на входе в роторный теплообменник

, определяемой по формуле (18), изменяющейся в диапазоне

, и температурой вытяжного воздуха на выходе из адсорбционного роторного регенератора

, определяемой по формуле (16), изменяющейся в диапазоне

. При этом роторный теплообменник кондиционера в холодный период года рекуперирует требуемые объемы теплоты вытяжного воздуха и передает рекуперированные объемы теплоты приточному воздуху, обеспечивая нагревание приточного воздуха на перепад температур Δt=t₂-t₁, образуемый между требуемой температурой приточного воздуха на входе в адсорбционный роторный регенератор, изменяющейся в диапазоне t₂=9÷19,5°С, и температурой наружного воздуха на входе в роторный теплообменник, изменяющейся в диапазоне t₁=(-40)÷10°С, и получение нулевого энергопотребления на нагревание приточного воздуха, обеспечивающего образование в кондиционере безжидкостного роторного нагревания - Liguidless Rotary Heating.3. the exhaust air line of the inventive air conditioner has the required value of the temperature of the exhaust air at the inlet to the exhaust chamber of the air conditioner equal to t ₄ = 21.5 ° C, determined by the formula (15), which was previously unknown (see table. 1, p. 19). The indicated temperature t ₄ = 21.5 ° C, together with the obtained values of the efficiency of the adsorption rotary regenerator for the transferred heat

and accepted high efficiency values of the rotary heat exchanger of the air conditioner

when the temperature of the outdoor air changes in the range t ₁ = (- 40) ÷ 10 ° С, they provide zero temperature difference for heating the exhaust air in the exhaust chamber of the air conditioner

formed between the required temperature at the inlet to the rotary heat exchanger

determined by formula (18), varying in the range

, and the temperature of the exhaust air at the outlet of the adsorption rotary regenerator

determined by formula (16), varying in the range

. In this case, the rotary heat exchanger of the air conditioner during the cold season recovers the required heat volumes of the exhaust air and transfers the recovered heat volumes to the supply air, heating the supply air to a temperature difference Δt = t ₂ -t ₁ formed between the required supply air temperature at the inlet to the adsorption rotary regenerator varying in the range of t = ₂ 9 ÷ 19.5 ° C and the temperature of the outside air inlet to a rotary heat exchanger, changing in the range t ₁ = (- 40) ÷ 10 ° C, and obtaining zero energopo Use by heating to the supply air, which provides the formation of an air conditioner aneroid rotary heating - Liguidless Rotary Heating.

The values of the parameters of air flows in the cold season in the zones of the inventive air conditioner are shown in FIG. 2.

Expanding the functionality of the supply air conditioner in the form of providing in the warm season, obtaining zero energy consumption in the air conditioner for cooling the supply air to the set temperature t ₃ = 20 ° C, relative humidity ϕ ₃ = 0.53, moisture content d ₃ = 7.9 g / kg dry air, at a temperature of exhaust air at the inlet to the exhaust chamber of the air conditioner t ₄ = 19.8 ° C, moisture content d ₄ = 7.3 g / kg dry. air and outdoor temperature changes in the range of t ₁ = 21 ÷ 30 ° C and moisture content in the range of d ₁ = 11.8 ÷ 20.4 g / kg dry. air without the presence of a hybrid hot air exhaust line is achieved due to the following advantages of the proposed solution:

1. the adsorption rotary regenerator and rotary heat exchanger of the inventive air conditioner in the cold and warm periods of the year have an exhaust air line opposite to the outside air supply line, which ensures that the air conditioner is dual-chamber in the warm season, and when the adsorption rotary regenerator is built into an additional rotor channel of a horizontal intermediate partitions and rotary heat exchanger into the main rotor channel of the horizontal intermediate partition of the air conditioner - post Leniye exhaust air discharged from the adsorption rotary regenerator air conditioner, the input to a rotary heat exchanger that recovers the required amount of the outdoor air heat and transmits the heat recovered volumes colder exhaust air;

и передаваемой теплоте

.2. the exhaust air line of the inventive air conditioner in the warm season has the required value of the moisture content of the exhaust air at the inlet to the exhaust chamber of the air conditioner equal to d ₄ = 7.3 g / kg dry. air, determined by the formula (11), which, together with the moisture content of the supply air at the inlet to the adsorption rotary regenerator d ₂ , equal to the moisture content of the outdoor air d ₂ = d ₁ , varying in the range d ₁ = 11.8 ÷ 20.4 g / kg dry air, and a given moisture content of the supply air at the outlet of the adsorption rotary regenerator d ₃ = 7.9 g / kg dry. moisture, provide high values of the efficiency of the adsorption rotary regenerator of the air conditioner for the transmitted moisture

and heat transferred

.

и принятыми значениями эффективности роторного теплообменника кондиционера

(см. п. 25 табл. 2,) при изменении температуры наружного воздуха в диапазоне t₁=21÷30°С обеспечивают получение нулевого перепада температур на охлаждение вытяжного воздуха в вытяжной камере кондиционера

, образуемого между температурой вытяжного воздуха на выходе из адсорбционного роторного регенератора

, определяемой по формуле (18), изменяющейся в диапазоне

и требуемой температурой вытяжного воздуха на входе в роторный теплообменник

, определяемой по формуле (20), изменяющейся в диапазоне

. При этом роторный теплообменник кондиционера в теплый период года рекуперирует требуемые объемы теплоты наружного воздуха и передает рекуперированные объемы теплоты более холодному вытяжному воздуху, обеспечивая в теплый период года охлаждение приточного воздуха на перепад температур Δt_охл=t₁-t₂, образуемый между температурой наружного воздуха на входе в роторный теплообменник, изменяющейся в диапазоне t₁=21÷30°С, и требуемой температурой приточного воздуха на входе в адсорбционный роторный регенератор, изменяющейся в диапазоне t₂=20,8÷23,4°С, (см. п. 19 табл. 2) и получение нулевого энергопотребления на охлаждение приточного воздуха, обеспечивающего образование в кондиционере безжидкостного роторного охлаждения - Liguidless Rotary Cooling.3. the exhaust air line of the inventive air conditioner in the warm season has the required value of the exhaust air temperature at the inlet of the air conditioner exhaust chamber equal to t ₄ = 19.8 ° C, determined by formula (17), which was previously unknown (see table. 2, p. 20). The indicated temperature t ₄ = 19.8 ° C, together with the obtained values of the efficiency of the adsorption rotary regenerator for the transferred heat

and accepted values of the efficiency of the rotary heat exchanger of the air conditioner

(see p. 25 of Table 2,) when changing the temperature of the outdoor air in the range t ₁ = 21 ÷ 30 ° C, they provide zero temperature difference for cooling the exhaust air in the exhaust chamber of the air conditioner

formed between the temperature of the exhaust air at the outlet of the adsorption rotary regenerator

determined by formula (18), varying in the range

and the required temperature of the exhaust air at the inlet to the rotary heat exchanger

determined by formula (20), varying in the range

. At the same time, the rotary heat exchanger of the air conditioner during the warm season recovers the required heat of the outside air and transfers the recovered heat to the cooler exhaust air, providing cooling of the supply air during the warm season to the temperature difference Δt _cool = t ₁ -t ₂ formed between the outdoor temperature at the inlet to the rotary heat exchanger, varying in the range of t ₁ = 21 ÷ 30 ° C, and the required temperature of the supply air at the entrance to the adsorption rotary regenerator, varying in the range of t ₂ = 20 , 8 ÷ 23.4 ° С, (see p. 19 of Table 2) and obtaining zero energy consumption for cooling the supply air, which ensures the formation of liquid-free rotary cooling in the air conditioner - Liguidless Rotary Cooling.

The values of the air flow parameters in the warm season in the zones of the inventive air conditioner are shown in FIG. 3.

In FIG. 1 is a schematic diagram of a supply air conditioner with liquid-free rotary heating and cooling; in FIG. 2 is a vertical section of the inventive supply air conditioner with the numbering of the zones of the air flow parameters and their values in the cold season; in FIG. 3 is a vertical section of the inventive supply air conditioner with the numbering of the zones of the air flow parameters and their values in the warm season.

In FIG. 1-3 indicated: LDNV - line of outdoor air inflow; LVV - exhaust air line.

A supply air conditioner with liquid-free rotor heating and cooling, comprising a supply chamber 1 and an exhaust chamber 2 separated by a horizontal intermediate partition 3 with a main 4 and an additional 5 rotor channels and a main rotor channel 4 of the horizontal intermediate partition 3 at the outside air inlet to the air conditioner , an adsorption rotary regenerator 6 and a rotary heat exchanger 7, built into the rotor channels 4, 5 of the horizontal intermediate partition 3, and having a line at outside air, characterized in that the adsorption rotary regenerator 6 and the rotary heat exchanger 7 of the air conditioner have an exhaust air line with the required values of temperature and moisture content of exhaust air at the inlet to the exhaust chamber 2 of the air conditioner, the opposite direction of the outdoor air supply line, the adsorption rotary regenerator 6 is built into additional rotor channel 5 of the horizontal intermediate partition 3, and the rotor heat exchanger 7 into the main rotor channel 4 of the horizontal intermediate partition egorodki 3 conditioner, the air conditioner forming aneroid rotary heating and cooling.

The inventive air conditioner can operate in two modes.

Mode 1. The mode of conditioning of the supply air in the warm season when the outdoor temperature changes in the range t ₁ = (- 40) ÷ 10 ° С and moisture content in the range d ₁ = 0,064 ÷ 6,23 g / kg dry. air.

Mode 2. The mode of conditioning of the supply air in the warm season when the outdoor temperature changes in the range t ₁ = 21 ÷ 30 ° C and moisture content in the range d ₁ = 11.8 ÷ 20.4 g / kg dry. air.

Mode 1 The inventive air conditioner in mode 1 operates as follows. The outdoor air supply line and the exhaust air line of the supply air conditioner, the adsorptive rotary regenerator 6 with an inverter and the rotary heat exchanger 7 with an inverter are operating, the outdoor air enters the supply chamber 1, and the exhaust air into the exhaust chamber 2 of the air conditioner with the formation in the air conditioner at the exhaust temperature air at the inlet to the exhaust chamber of the air conditioner t ₄ = 21.5 ° C, and moisture content d ₄ = 7.3 g / kg dry. air, when the temperature of the outside air changes in the range t ₁ = (- 40) ÷ 10 ° С, and moisture content in the range d ₁ = 0,064 ÷ 6,23 g / kg dry. air of non-liquid rotary heating and obtaining at the outlet of the supply chamber 1 of the supply air conditioner with set values of temperature t ₃ = 20 ° C, relative humidity ϕ ₃ = 0.44, moisture content d ₃ = 6.5 g / kg dry. air.

Mode 2. The inventive air conditioner in mode 2 operates as follows. The outdoor air supply line and the exhaust air line of the supply air conditioner, the adsorptive rotary regenerator 6 with an inverter and the rotary heat exchanger 7 with an inverter are operating, the outdoor air enters the supply chamber 1, and the exhaust air into the exhaust chamber 2 of the air conditioner with the formation in the air conditioner at the exhaust temperature air at the inlet to the exhaust chamber of the air conditioner t ₄ = 19.8 ° C, and moisture content d ₄ = 7.3 g / kg dry. air, when the temperature of the outside air changes, in the range of t ₁ = 21 ÷ 30 ° C, and moisture content in the range of d ₁ = 11.8 ÷ 20.4 g / kg dry. air of liquid-free rotor cooling and obtaining, at the outlet of the supply chamber 1, a supply air conditioner with predetermined values of temperature t ₃ = 20 ° C, relative humidity ϕ ₃ = 0.53, moisture content d ₃ = 7.9 g / kg dry. air.

All of the above, including a description of the operation of the inventive air conditioner, confirms the possibility of its use in the premises of public buildings with obtaining high technical indicators in comparison with the well-known air conditioning units. In addition, both in the sources of patent and scientific and technical information, and in the premises of public buildings, such an air conditioner was not found, which indicates the compliance of the claimed invention with all the conditions of patentability.

Sequence listing

(composition of the supply air conditioner with liquid-free rotary heating and cooling)

1. Supply chamber of the supply air conditioner.

2. The exhaust chamber of the supply air conditioner.

3. The horizontal intermediate partition of the supply air conditioner.

4. The main rotor channel of the horizontal intermediate partition of the supply air conditioner.

5. Additional rotor channel of the horizontal intermediate partition of the supply air conditioner.

6. Adsorption rotary regenerator of the supply air conditioner.

7. Rotary heat exchanger of the supply air conditioner.

Claims (1)

A supply air conditioner with liquid-free rotor heating and cooling, comprising a supply chamber and an exhaust chamber separated by a horizontal intermediate partition with a main and additional rotor channels and a main rotor channel of a horizontal intermediate partition at the outdoor air inlet to the air conditioner, an adsorption rotary regenerator and a rotary heat exchanger embedded in the rotor channels of the horizontal intermediate partition and having an external inflow line air, characterized in that the adsorption rotary regenerator and rotary heat exchanger of the air conditioner have an exhaust air line with the required values of temperature and moisture content of exhaust air at the inlet to the air conditioning exhaust chamber, opposite to the outside air supply line, the adsorption rotary regenerator is built into an additional rotor channel of the horizontal intermediate partition and the rotary heat exchanger - into the main rotor channel of the horizontal intermediate partition of the air conditioner forming in the air conditioner non-fluid rotary heating and cooling.

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