RU2630437C1 - Air conditioner with forced system of drying and evaporation cooling - Google Patents

Abstract

FIELD: ventilation.

SUBSTANCE: air conditioner contains a supply and exhaust chamber separated by a horizontal partition with a main and an additional window, a supply air cooler in the form of a desalinating evaporative cooling system consisting of two rotary heat exchangers - a recuperator-desiccant and a recuperator-cooler and an adiabatic supply air humidifier located in Inlet chamber. The recuperator-desiccant in the form of a rotary regenerator of the adsorption type is built into the main window of the partition and has oppositely directed inflow and outflow lines, and the recuperator-cooler is in the form of a rotary heat exchanger with an inverter that is built into the additional partition wall and has a line of external air inflow. The inlet chamber contains inlet and outlet nozzles, an air cleaner and a fan unit. The exhaust chamber contains an inlet and an outlet branch pipes, an air cleaner and a fan unit. The air conditioner is equipped with two additional exhaust chambers and a window located in the upper panel of the main exhaust chamber between the air cleaner and the recuperator-desiccant. The first chamber is located above the top panel of the main exhaust chamber and contains an inlet and outlet nozzles, an air cleaner, a rotary heat exchanger with an inverter and a fan unit. The rotary heat exchanger-heat exchanger is integrated into the window of the upper panel of the main exhaust chamber, it is installed between the horizontal partition of the air conditioner and the upper panel of the first additional exhaust chamber and has oppositely directed exhaust air lines heated by the exhaust flue gases and the exhaust of the air removed from the room. The second chamber is located above the horizontal intermediate partition and is divided from the main exhaust chamber by a vertical transverse partition installed between the recuperator-desiccant and the recuperator-cooler, contains an inlet and outlet nozzles, an air cleaner and a fan unit and has an additional line for drawing outside air, an oppositely directed inflow line. The second chamber is provided with an adiabatic humidifier of the exhaust air with a supply water pipe, which is located between the air cleaner and the recuperator-cooler, the inlet branch of the main exhaust chamber and the outlet branch of the second additional exhaust chamber are equipped with controlled normally closed air valves, and the vertical transverse air conditioner partition is equipped with a window with a controlled normally open Air valve, which allow the air conditioner controller to supply exhaust air and removed from the premises having a lower temperature than the outside air temperature, the second additional exhaust chamber and normally open air valve in a vertical transverse partition window into the main exhaust chamber.

EFFECT: providing zero energy consumption for cooling and heating the supplied air.

2 cl, 7 dwg, 2 tbl

Description

, необходимой при нагревании и охлаждении приточного воздуха.The invention relates to the field of air conditioners serving the production facilities of both metallurgical plants and foundries, and factories that have a factory boiler room and units for drying various materials. In air conditioners, outside air is used as a heat carrier, heated to a temperature in the recuperator by the exhaust flue gases of the furnaces and drying units

required when heating and cooling the supply air.

Air conditioners are designed to service industrial premises with high relative humidity in the work area (φ _{p. S.>} 75%) and production facilities with a "normal" relative humidity (φ _{p. S.} = 50%) in the case of mixing of conditioned air having high relative humidity (φ _k> 75%) with a dry cleaned in a bag filter recirculating air (φ _{p. s.} = 50%), while working in the warm season in the outside air temperature change range t ₁ = 11 ÷ 32 ° C, and in the cold season when changing uu outdoor air temperature in the range t ₁ = 10 ÷ (-30) ° C.

Air conditioners use exhaust air taken from the working area of the production room:

, относительной влажностью

, и влагосодержанием

сух. возд. в холодный период года;- with temperature

relative humidity

and moisture content

dry air in the cold season;

, относительной влажностью

, и влагосодержанием

сух. возд. в теплый период года.- with temperature

relative humidity

and moisture content

dry air in the warm season.

:Air conditioners use outdoor air heated to the temperature of the flue gas

:

- in the cold season for heating the supply air with its subsequent adiabatic humidification, providing indirect cooling of the supply air to a given final temperature;

- in the warm season to heat the supply air, providing an increased temperature difference in the air flows at the inlets of the recuperator-cooler and, as a result, cooling the supply air to a predetermined temperature value necessary for subsequent adiabatic humidification and additional indirect cooling of the supply air to a given final temperature .

The claimed solution can be used in various industries (metallurgical, foundry, waste incinerator, flour mill, textile, tobacco, pulp and paper, plywood, matchstick, woodworking, chemical, chipboard and drug manufacturing).

From the sources of scientific, technical and patent information, a large number of modifications of air conditioners are known. Among them, air conditioners with dehumidification and evaporative air cooling were selected that do not provide zero energy consumption when heating the supply air in the cold season, and zero energy consumption when cooling the supply air in the warm season, which makes it possible to improve them in the direction indicated in the claims solutions.

A well-known schematic diagram of an air conditioner that implements DEC cooling technology described in an article by N.V. Shilkin “Climate Center Klimahaus in Bremerhaven”, which was published in the journal “AVOK” No. 2, 2012, p. 84-93, and on the Internet at http://www.abok.ru/for_spec/articles.php?nid=5181, adopted as a prototype.

(в долях ед.).The prototype air conditioner consists of a supply and exhaust chambers separated by a horizontal intermediate partition with two windows, a supply air cooler made in the form of a desiccative and Evaporative Cooling (DEC) system consisting of two rotary recuperators (recuperator-dryer and a recuperator-cooler for supply air) built into the windows of the horizontal intermediate partition and having oppositely directed exhaust and supply lines, a regenerative exhaust heater of fresh air placed between rotary recuperators, and two adiabatic humidifiers for extract and supply air with a supply pipe, the supply and exhaust chambers contain air purifiers installed at the inlet to the chambers, and fan units installed at the outlet of the chambers. The lead-in pipelines of demineralized water to adiabatic humidifiers are not shown in a schematic diagram of an air conditioner; In this case, the supply air recuperator-dryer is made by a rotary adsorption-type regenerator, and the supply air recuperator-cooler is made by a rotary heat exchanger. The inverter and the controller to the electric drive of the rotary recuperator-cooler are not shown on the circuit diagram of the air conditioner. An adiabatic extract air humidifier is installed at the inlet to the rotary heat exchanger, and an adiabatic supply air humidifier is installed at the outlet of the rotary heat exchanger. The adsorption type rotary regenerator has cells of the rotor storage matrix coated with a composite material into which the active Selicagel is embedded, which is a sorbent of moisture contained in the outside air. In this case, the storage matrix of the adsorption rotor is heated by the flow of exhaust air. The supply air passing through the heated cells of the adsorption rotor is heated in them and simultaneously dried by adsorption of the moisture contained in it. When the adsorption rotor is rotated, the cells of the storage matrix, the sorbing surface of which is filled with moisture, enter the drawing zone. In this case, the heated stream of exhaust air, passing through the cells of the accumulating rotor matrix, desorbs the moisture contained in them, and in relation to the sorbent - its regeneration, while moistening, after which it is emitted into the atmosphere by the exhaust fan unit. The process of heating and drying the supply air is carried out with dry efficiency of heat recovery of the rotary heat exchanger-dryer, equal to

(in units).

, что обеспечивает увеличение фактического перепада температур на выходах из роторного рекуператора-теплообменника:A rotary recuperator-cooler cools the supply air at a constant moisture content. The heat removed by the accumulating matrix of the rotary heat exchanger from the supply air is transferred when the rotor is rotated to the exhaust air. The adiabatic extract air humidifier provides indirect adiabatic cooling of the extract air ~ 6 ° C, and is designed to increase the temperature difference at the inlets of the rotary regenerator

that provides an increase in the actual temperature difference at the exits from the rotary heat exchanger-heat exchanger:

, °C;- for supply air cooling

° C;

, °C.- for heating exhaust air

, ° C.

Moreover, in the warm season

,

,

- сухая эффективность рекуперации теплоты роторного теплообменника,

(в долях ед.),

- температура вытяжного (удаляемого) воздуха на выходе из адиабатического увлажнителя, т.е. на входе в рекуператор-охладитель, °C,

, t_вх - температура приточного воздуха на входе в рекуператор-охладитель, °C, t_вх=t₂.where -

- dry heat recovery efficiency of the rotary heat exchanger,

(in units),

- temperature of the exhaust (removed) air at the outlet of the adiabatic humidifier, i.e. at the inlet to the recuperator-cooler, ° C,

, t _in - supply air temperature at the inlet to the recuperator-cooler, ° C, t _in = = ₂ .

The article discusses the supply air cooling mode, which, in accordance with the given process schedule in the id diagram, is carried out at constant values of the outdoor temperature t ₁ = 31 ° C and exhaust air t ₅ = 25 ° C, having a moisture content of d ₁ = 11.9 g / kg dry air and d ₅ = 10.3 g / kg dry. air

The DEC cooling system used in the prototype air conditioner provides, at t ₁ = 31 ° C and t ₅ = 25 ° C, the set supply air temperature t ₄ = 19 ° C and relative humidity ϕ ₄ = 60% at the outlet of the adiabatic humidifier (heating of the supply air in the fan is not taken into account).

The indicated parameters of the supply air (t ₄ = 19 ° C and ϕ ₄ = 60%) at specified outdoor temperatures t ₁ = 31 ° C and t ₅ = 25 ° C of exhaust air having a moisture content of d ₁ = 11.9 and d ₅ = 10.3 g / kg dry air The article proposes to carry out:

1) with indirect cooling of the supply and exhaust air by adiabatic humidifiers to a temperature difference Δt _cool = 6 ° C, which provides temperatures:

- exhaust air at the inlet to the supply air recuperator-cooler

,

,

- supply air at the outlet of the recuperator-cooler

,

,

и рекуператора-охладителя приточного воздуха

, которые обеспечивают получение температур:2) at values of dry heat recovery efficiency of the supply air heat exchanger-dryer

and supply air recuperator-cooler

that provide temperatures:

- supply air at the outlet of the recuperator-dryer:

,

,

- exhaust air at the outlet of the supply air recuperator-cooler, which simultaneously heats the exhaust air from temperature t ₆ to t ₇

,

,

- exhaust air at the outlet of the regenerative air heater

,

,

- exhaust air at the outlet of the supply air recuperator-dryer

.

.

Despite the large number of coinciding features of the prototype and the proposed solution, the absence of the distinctive features of the latter in the prototype does not provide a technical result — ensuring zero energy consumption for heating and cooling the supply air for the following reasons.

1. The prototype air conditioner has one exhaust line with the exhaust air temperature of the production room in the cold season t ₅ = 18 ° C and moisture content d ₅ = 6.42 g / kg dry. air, which requires for heating the supply air in the DEC system to a final temperature t ₄ = 15 ° C and its relative humidity ϕ ₄ = 0.868 ÷ 0.832 when the outdoor temperature changes in the range t ₁ = 10 ÷ (-30) ° C without freezing of the adsorption rotor at t ₁ = (- 30) ° C the presence of a regenerative extract air heater, i.e. It does not provide zero energy consumption for heating the supply air in the cold season.

2. The prototype air conditioner has one exhaust line with the exhaust air temperature of the production room in the warm season t ₅ = 18 ÷ 24 ° C and moisture content d ₅ = 6.42 ÷ 9.33 g / kg dry. air, which requires for cooling the supply air in the DEC-system to the final temperature t ₄ = 21 ° C and its relative humidity ϕ ₄ = 0.784 ÷ 0.932 when the outdoor temperature changes in the range t ₁ = 11 ÷ 32 ° C the presence of a regenerative air heater exhaust air i.e. It does not provide zero energy consumption for cooling the supply air in the warm season.

According to claim 1, the disadvantages of the prototype air conditioner.

.The need for a regenerative air heater in the exhaust line of the prototype air conditioner in the cold season is due to the fact that the final temperature of the heated supply air t ₄ = 15 ° C obtained in the air conditioner at the temperature of the exhaust air t ₅ = 18 ° C and outdoor air t ₁ = 10 ÷ (-30) ° C is ensured by additional heating of the exhaust air in the regenerative heater to a temperature of t ₈ = 70 ° C, i.e. temperature difference

.

The exhaust air temperature at the outlet of the regenerative heater t ₈ = 70 ° C is also necessary in the prototype air conditioner to eliminate freezing of the adsorption rotor at an outdoor temperature t ₁ = (- 30) ° C.

и массовому потоку сухого вытяжного воздуха

, кг/ч.At t ₈ = 70 ° C, the rated power of the regenerative air heater N _p , kW is directly proportional to the temperature difference for heating the exhaust air

and mass flow of dry exhaust air

kg / h

The presence of only one exhaust line in the prototype air conditioner with its sequential passage through the recuperator-cooler and recuperator-dryer does not allow extract air with a temperature of t ₈ = 70 ° C and a moisture content of d ₈ = 6.42 g / kg to be supplied to the recuperator-dryer dry air to ensure that the final supply air temperature t ₄ = 15 ° C and relative humidity ϕ ₄ = 0.868 ÷ 0.832% when the outdoor temperature changes in the range t ₁ = 10 ÷ (-30) ° C without the use of an extract air heater.

According to claim 2, the disadvantages of the prototype air conditioner.

.The need for a regenerative air heater in the exhaust line of the prototype air conditioner in the warm season is due to the fact that the final temperature of the cooled supply air t ₄ = 21 ° C obtained in the air conditioner at the temperature of the exhaust air t ₅ = 18 ÷ 24 ° C and outdoor air t ₁ = 11 ÷ 32 ° C is ensured by additional heating of the exhaust air in the regenerative heater to a temperature of t ₈ = 70 ° C, i.e. temperature difference

.

The presence of only one exhaust line in the prototype air conditioner with its sequential passage through the recuperator-cooler and recuperator-dryer does not allow extract air with a temperature of t ₈ = 70 ° C and a moisture content of d ₈ = 6.42 ÷ 9 to be supplied to the recuperator-dryer 33 g / kg dry air to ensure the final supply air temperature t ₄ = 21 ° C and relative humidity ϕ ₄ = 0.784 ÷ 0.932% when the outdoor temperature changes in the range t ₁ = 11 ÷ 32 ° C without the use of an extract air heater.

The task of creating an air conditioner with a forced system of dehumidification and evaporative cooling - Desiccative and Evaporative Cooling (DEC), which provides energy-saving modes of heating the supply air to the specified values of temperature and relative humidity in the production rooms of the plants, the implementation of which the claimed solution is directed, consisted in further improving the known design an air conditioner with a DEC-system for cooling the supply air, and obtaining a technical result - ensuring zero energy otrebleniya for heating and cooling the supply air:

- for heating the supply air in the cold season to a final temperature of t ₅ = 15 ° C and its relative humidity ϕ ₅ = 0.868 ÷ 0.832 at a temperature of exhaust air removed from the production room t ₆ = 18 ° C, moisture content d ₆ = 6, 42 g / kg dry air and changing the outdoor temperature in the range t ₁ = 10 ÷ (-30) ° C without freezing the adsorption rotor at t ₁ = -30 ° C;

- for cooling the supply air in the warm season to a final temperature of t ₅ = 21 ° C and its relative humidity ϕ ₅ = 0.784 ÷ 0.801 at a temperature of exhaust air removed from the production room t ₆ = 18 ° C, moisture content d ₆ = 6, 42 g / kg dry air and changing the outdoor temperature in the range t ₁ = 11 ÷ 25 ° C without adiabatic humidification of the exhaust air;

- for cooling the supply air during the warm season to a final temperature of t ₅ = 21 ° C and its relative humidity ϕ ₅ = 0.848 ÷ 0.932 at a temperature of exhaust air removed from the production room t ₁₃ = 19 ÷ 24 ° C, moisture content d ₁₃ = 6.84 ÷ 9.33 g / kg dry air and a change in outdoor temperature in the range t ₁ = 26 ÷ 32 ° C.

The achievement of the above technical result is ensured by the fact that the air conditioner with a forced system of dehumidification and evaporative cooling, comprising a supply air chamber and a main exhaust chamber of air removed from the production room, separated by a horizontal intermediate partition with the main and additional windows, the supply air cooler, made in the form of a system drainage and evaporative cooling, consisting of two rotary recuperators - recuperator-dryer and p a cooler-cooler and an adiabatic humidifier of supply air with a supply pipe of demineralized water placed in the supply chamber, a control controller, while the recuperator-dryer is made in the form of an adsorption type rotary regenerator that is built into the main window of the horizontal intermediate partition and has oppositely directed supply lines external air and extracts of air removed from the production room, and the recuperator-cooler - in the form of a rotary heat exchanger with the inverter, which is built into the additional window of the horizontal intermediate partition and has a line of external air inflow, the supply chamber contains an inlet and outlet pipe, an air cleaner installed at the inlet to the camera, and a fan unit, the main exhaust chamber contains a top panel, inlet and outlet pipe, an air cleaner installed at the entrance to the chamber, and a fan unit installed at the exit of the chamber, characterized in that the air conditioner is equipped with two additional exhaust chambers and approx Ohm, located in the upper panel of the main exhaust chamber between the air purifier and the recuperator-dryer, the first additional exhaust chamber is located above the upper panel of the main exhaust chamber and contains the upper panel, inlet and outlet pipes, an air purifier located at the inlet of the chamber, a rotary heat exchanger with an inverter and a fan unit located at the outlet of the chamber, while the aforementioned rotary heat exchanger-heat exchanger is integrated in the window of the upper panel of the main exhaust chamber, seal but it is installed between the horizontal intermediate partition of the air conditioner and the upper panel of the first additional exhaust chamber and has oppositely directed exhaust lines of the outdoor air heated by the exhaust flue gases and the exhaust air removed from the production room, and the second additional exhaust chamber is located above the horizontal intermediate partition and is separated from the main exhaust chamber with a vertical transverse partition sealed between the recuperator-dryer and a recuperator-cooler, contains an inlet and outlet pipe, an air purifier and a fan unit and has an additional outdoor air exhaust line opposite the supply line, providing forced cooling of the supply air at an outdoor temperature that varies during the cold season from 10 to (-30 ) ° C and during the warm season in the range from 11 to 25 ° C.

Preferably, when cooling the supply air in the warm season at an outdoor temperature ranging from 26 to 32 ° C, the second additional exhaust chamber is equipped with an adiabatic extractor humidifier with a supply pipe of demineralized water, which is located between the air purifier and the recuperator-cooler chamber the inlet pipe of the main exhaust chamber and the exhaust pipe of the second additional exhaust chamber are equipped with controlled normally closed air valves, and the vertical transverse partition of the air conditioner is equipped with a window with a controlled normally open air valve installed in it, which, when combined with the mentioned controlled air valves of the main and second additional exhaust chambers, allows the control controller of the air conditioner to supply exhaust air removed from the production room having a lower temperature, than the temperature of the outside air, to the second additional exhaust chamber with its passage through camera and a normal open air driven valve installed in a window air conditioner vertical transverse partitions, in the main exhaust chamber and then pass it through the air cleaner, rotary heat exchanger-recuperator and the recuperator dehydrator and providing a forced cooling of the supply air.

The proof of the materiality of the differences of the claimed air conditioner and the relationship of the distinguishing features with the achieved technical result is disclosed in the following order.

1. Ensuring zero energy consumption for heating the supply air in the cold season to a final supply air temperature t ₅ = 15 ° C and its relative humidity ϕ ₅ = 0.868 ÷ 0.832 when the exhaust air temperature removed from the production room t ₆ = 18 ° C, its moisture content d ₆ = 6.42 g / kg dry. air and changing the outdoor temperature in the range t ₁ = 10 ÷ (-30) ° C without freezing the adsorption rotor at f ₁ = (- 30) ° C.

2. Ensuring zero energy consumption for cooling the supply air in the warm season to the final supply air temperature t ₅ = 21 ° C and its relative humidity ϕ ₅ = 0.784 ÷ 0.801 at the temperature of the exhaust air removed from the production room t ₆ = 18 ° C, its moisture content d ₆ = 6.42 g / kg dry. air and a change in outdoor temperature in the range t ₁ = 11 ÷ 25 ° C without adiabatic humidification of the exhaust air.

3. Ensuring zero energy consumption for cooling the supply air in the warm season to the final supply air temperature t ₅ = 21 ° C and its relative humidity ϕ ₅ = 0.848 ÷ 0.932 at the temperature of the exhaust air removed from the production room t ₁₃ = 19 ÷ 24 ° C, its moisture content d ₁₃ = 6.84 ÷ 9.33 g / kg dry. air and a change in outdoor temperature in the range t ₁ = 26 ÷ 32 ° C.

To justify zero energy consumption in the inventive air conditioner for heating and cooling the supply air, algorithms have been developed for calculating the parameters of air flows with formulas for their calculation and the calculation results presented in table. 1 and 2. The calculations given in table. 1 and 2, are made using the extract air temperatures of the production premises in the cold and warm season, characteristic of the woodworking shops of metallurgical plants.

In the table. 1 presents the calculations for the cold season (mode 1), and in table. 2 - calculations for the warm season (modes 2, 3, 4).

Woods, работающий без инвертора и имеющий значения эффективности рекуперации:In the inventive air conditioner as a recuperator-dryer (recuperator No. 1) is used adsorption rotary regenerator

Woods, working without an inverter and having the values of recovery efficiency:

;a) by heat transferred

;

.b) moisture transferred

.

и

приняты по данным статьи: С.А. Панфилов.

Woods «Два колеса - Twin Wheel лучше, чем одно», опубликованной в журнале АВОК №5, 2014 г., с. 52-54 и на сайте http:/www.abok.ru/for_spec/articles.php?nid=5896.Given values

and

taken according to the article: S.A. Panfilov.

Woods “Two Wheels - Twin Wheel is Better Than One,” published in ABOK Magazine No. 5, 2014, p. 52-54 and on the website http: /www.abok.ru/for_spec/articles.php? Nid = 5896.

In fig. Section 2 of this article shows a schematic diagram of the existing Twin Wheel System, which shows the parameters of the supply and exhaust air in different zones of the ventilation unit (temperature t _i , ° C, moisture content d _i g / kg dry air; relative humidity ϕ _i ,%) when cooling the supply air to a final temperature of t ₄ = 15 ° C at an outdoor temperature of t ₁ = 32 ° C. In this case, the supply and exhaust air at the inlet and outlet of the adsorption rotor had the following parameters:

a) supply air at the inlet to the adsorption rotor: t ₁ = 32 ° C, d ₁ = 15 g / kg dry. air., ϕ ₁ = 50%;

b) exhaust air at the inlet to the adsorption rotor: t ₆ = 19.8 ° C, d ₆ = 9.3 g / kg dry. air., ϕ ₆ = 64.7%;

c) supply air at the outlet of the adsorption rotor: t ₂ = 22.7 ° C, d ₂ = 10.6 g / kg dry. air., ϕ ₂ = 61.6%.

и

передаваемой влаге адсорбционного ротора

Woods по известным формулам.Based on the article S.A. In accordance with the Panfilov values of the supply air parameters at the inlet and outlet of the adsorption rotor and the inlet of exhaust air into the adsorption rotor, the values of heat recovery efficiency were calculated

and

moisture transferred to the adsorption rotor

Woods according to well-known formulas.

Woods по передаваемой теплоте составилаAdsorption Rotor Recovery Efficiency

Woods's heat transfer rating was

.

.

Woods по передаваемой влаге составилаAdsorption Rotor Recovery Efficiency

Woods moisture transfer totaled

.

.

и

для адсорбционного ротора были приняты для расчета параметров воздушных потоков по зонам заявляемого кондиционера, приведенных в табл. 1 и 2.Values obtained

and

for the adsorption rotor were taken to calculate the parameters of the air flow in the zones of the inventive air conditioner are given in table. 1 and 2.

Zero energy consumption for heating the supply air in the cold season to a final temperature of t ₅ = 15 ° C and its relative humidity ϕ ₅ = 0.868 ÷ 0.832 at a temperature of exhaust air t ₆ = 18 ° C, its moisture content d ₆ = 6.42 g / kg dry. air., and a change in outdoor temperature in the range t ₁ = 10 ÷ (-30) ° C without freezing the adsorption rotor at t ₁ = -30 ° C is provided by the following advantages of the proposed solution over the prototype.

(п. 46, табл. 1), который является технически достижимым для роторного рекуператора-теплообменника1. The inventive air conditioner is equipped with two additional exhaust chambers. The second additional exhaust chamber is located above the horizontal intermediate partition of the air conditioner and is divided with the main exhaust chamber by a vertical transverse partition with a window in which the normally open air valve is installed, and the inlet pipe of the main exhaust chamber and the exhaust pipe of the second additional exhaust chamber are equipped with controlled normally closed air valves . These design features of the inventive air conditioner allow, with a closed controlled air valve in a vertical transverse partition and open controlled air valves in the inlet pipe of the main exhaust chamber and the outlet pipe of the second additional exhaust chamber, to supply exhaust air to the main exhaust chamber in the cold season, and the second additional exhaust chamber supply of external air with a temperature varying in the range t ₁ = 10 ÷ (-30 ) ° C (mode No. 1), which ensures forced cooling of the supply air and the operation of the heat exchanger-cooler (heat exchanger No. 2) in the range of heat and cold recovery efficiency

(p. 46, table. 1), which is technically feasible for a rotary heat exchanger heat exchanger

2. In the inventive air conditioner, the first additional exhaust chamber of the outdoor air heated by the exhaust flue gases has a rotary heat exchanger-heat exchanger (recuperator No. 3), which is built into the main exhaust chamber of the exhaust air of the production room, with a temperature t ₆ = at the inlet of the heat exchanger No. 3; 18 ° C.

, и передает ее вытяжному воздуху, нагревая его с температуры t₆=18°C до требуемой температуры t₇=70°C на входе в рекуператор-осушитель (рекуператор №1). При указанной температуре вытяжного воздуха t₇=70°C на входе в рекуператор-осушитель будет отсутствовать замерзание адсорбционного ротора при максимальном значении отрицательной температуры наружного воздуха t₁=-30°C, так как выполняется условие

, обеспечивающее устранение опасности замерзания адсорбционного ротора.Recuperator No. 3 performs the function of a regenerative air heater of the prototype air conditioner, recuperates the heat of the outdoor air heated by the exhaust flue gases to a temperature

, and transfers it to the exhaust air, heating it from a temperature of t ₆ = 18 ° C to the required temperature of t ₇ = 70 ° C at the inlet to the recuperator-dryer (recuperator No. 1). At the indicated exhaust air temperature t ₇ = 70 ° C, the adsorption rotor will not freeze at the entrance to the recuperator-dryer at the maximum value of the negative outside temperature t ₁ = -30 ° C, since the condition

, eliminating the danger of freezing of the adsorption rotor.

, где

- температура воздушных потоков на входах в ротор, ниже которой возникает опасность замерзания ротора. Принята по данным компании Hoval, опубликованных в интернете на сайте. Справочник по проектированию, монтажу и эксплуатации. Ротационные теплообменники для рекуперации тепловой энергии в вентиляционных установках. Hoval, 27 с. hoval-rekuperaciyatepla.ru/zoolu-website/media/document/4640/.In the inventive air conditioner at t ₁ = -30 ° C and t ₇ = 70 ° C, this condition has the form

where

- the temperature of the air flows at the entrances to the rotor, below which there is a danger of freezing of the rotor. Adopted according to Hoval, published on the Internet on the site. Handbook of design, installation and operation. Rotary heat exchangers for the recovery of thermal energy in ventilation installations. Hoval, 27 p. hoval-rekuperaciyatepla.ru/zoolu-website/media/document/4640/.

, определяемые по формуле

для температуры нагретого наружного воздуха, изменяющейся в диапазоне

, температуры вытяжного воздуха производственного помещения на входе в роторный рекуператор №3 t₆=18°C и на его выходе t₇=70°C, составляют

(п. 19, табл. 1) и являются технически достижимыми для роторного рекуператора-теплообменника.The values of the heat recovery efficiency of the outdoor air heated by the exhaust flue gases

defined by the formula

for heated outside air temperature, varying in the range

, the exhaust air temperature of the production room at the inlet to the rotary heat exchanger No. 3 t ₆ = 18 ° C and at its outlet t ₇ = 70 ° C, are

(p. 19, table. 1) and are technically feasible for a rotary heat exchanger heat exchanger.

The movement of air flows in the inventive air conditioner in the cold season (mode No. 1) is illustrated in FIG. 6.

The absence in the main exhaust chamber of the inventive air conditioner of a regenerative air heater that causes energy consumption, ensuring that the exhaust air is heated by recuperator No. 3 from a temperature of t ₆ = 18 ° C to a temperature of t ₇ = 70 ° C due to the supply of external air to it,

, а также работ рекуператоров №1, 2, 3 в технически достижимом диапазоне эффективностей рекуперации теплоты обеспечивают нулевое энергопотребление на нагревание приточного воздуха в холодный период года без замерзания адсорбционного ротора при температуре наружного воздуха t₁=-30°C.heated by flue gases, previously emitted into the atmosphere, and having a temperature

As well as the work of recuperators No. 1, 2, 3 in the technically feasible range of heat recovery efficiencies, they provide zero energy consumption for heating the supply air in the cold season without freezing the adsorption rotor at an outdoor temperature of t ₁ = -30 ° C.

Obtaining these advantages in the inventive air conditioner is provided by the totality of the features of the claimed solution.

Zero energy consumption for cooling the supply air in the warm season to a final temperature of t ₅ = 21 ° C and its relative humidity ϕ ₅ = 0.784 ÷ 0.801 at a temperature of exhaust air removed from the production room t ₆ = 18 ° C, its moisture content d ₆ = 6.34 g / kg dry air., and changes in outdoor temperature in the range t ₁ = 11 ÷ 25 ° C without adiabatic humidification of the exhaust air is provided by the following advantages of the proposed solution over the prototype.

(п. 44, табл. 2), который является технически достижимым для роторного рекуператора-теплообменника1. The inventive air conditioner is equipped with two additional exhaust chambers. The second additional exhaust chamber is located above the horizontal intermediate partition of the air conditioner and is divided with the main exhaust chamber by a vertical transverse partition with a window in which the controlled air valve is installed, and the inlet pipe of the main exhaust chamber and the exhaust pipe of the second additional exhaust chamber are equipped with controlled air valves. These design features of the inventive air conditioner allow for a closed controlled air valve in the vertical transverse partition and open controlled air valves on the inlet pipe of the main exhaust chamber and on the exhaust pipe of the second additional exhaust chamber to be carried out in the warm season at an outdoor temperature that varies in the range t ₁ = 11 ÷ 25 ° C supply of exhaust air from the production room to the main exhaust chamber, and to the second additional exhaust chamber of the hearth outside air with a temperature varying in the range t ₁ = 11 ÷ 25 ° C (mode No. 2), which ensures forced cooling of the supply air and the operation of the heat exchanger-cooler (heat exchanger No. 2) in the range of heat and cold recovery efficiency

(p. 44, table. 2), which is technically feasible for a rotary heat exchanger heat exchanger

2. In the inventive air conditioner, the first additional exhaust chamber of the outdoor air heated by the exhaust flue gases has a rotary recuperator-heat exchanger (recuperator No. 3), which is built into the main exhaust chamber of the exhaust air of the production room, having a temperature t ₆ = 18 at the inlet of the recuperator No. 3 ° C.

, и передает ее вытяжному воздуху, нагревая его с температуры t₆=18°C до требуемой температуры t₇=70°C на входе в рекуператор-осушитель (рекуператор №1).Recuperator No. 3 performs the function of a regenerative air heater of the prototype air conditioner, recuperates the heat of the outdoor air heated by the exhaust flue gases to a temperature

, and transfers it to the exhaust air, heating it from a temperature of t ₆ = 18 ° C to the required temperature of t ₇ = 70 ° C at the inlet to the recuperator-dryer (recuperator No. 1).

, определяемые по формуле

для температуры наружного воздуха, нагретого отходящими дымовыми газами до температуры

, температуры вытяжного воздуха на входе в роторный рекуператор №3 t₆=18°C и на его выходе t₇=70°C, составляют

(п. 54, табл. 2) и являются технически достижимыми для роторного рекуператора-теплообменника.The values of the heat recovery efficiency of the outdoor air heated by the exhaust flue gases

defined by the formula

for the temperature of the outdoor air heated by the exhaust flue gases to a temperature

, the exhaust air temperature at the inlet to the rotary recuperator No. 3 t ₆ = 18 ° C and at its outlet t ₇ = 70 ° C, are

(p. 54, table. 2) and are technically feasible for a rotary heat exchanger heat exchanger.

The movement of air flows in the inventive air conditioner during the warm season (mode No. 2) is illustrated in FIG. 6.

, а также работа рекуператоров №1, 2, 3 в технически достижимом диапазоне эффективностей рекуперации теплоты обеспечивают нулевое энергопотребление на нагревание приточного воздуха в теплый период года при температуре наружного воздуха, изменяющейся в диапазоне t₁=11÷25°C.The absence in the main exhaust chamber of the inventive air conditioner of a regenerative air heater that causes energy consumption, ensuring that the exhaust air is heated by recuperator No. 3 from a temperature of t ₆ = 18 ° C to a temperature of t ₇ = 70 ° C due to the supply of outdoor air heated by the exhaust flue gases, previously released into the atmosphere, and having a temperature

as well as the operation of recuperators No. 1, 2, 3 in the technically feasible range of heat recovery efficiencies provide zero energy consumption for heating the supply air in the warm season at an outdoor temperature that varies in the range t ₁ = 11 ÷ 25 ° C.

Obtaining these advantages in the inventive air conditioner is provided by the totality of the features of the claimed solution.

Zero energy consumption for cooling the supply air in the warm period to a final temperature t ₅ = 21 ° C and its relative humidity ϕ ₅ = 0.848 ÷ 0.932 at a temperature of exhaust air removed from the production room t ₁₃ = 19 ÷ 24 ° C, its moisture content d ₁₃ = 6.84 ÷ 9.33 g / kg dry. air., and a change in outdoor temperature in the range t ₁ = 26 ÷ 32 ° C is provided by the following advantages of the proposed solution over the prototype.

, позволяет роторному рекуператору-теплообменнику (рекуператор №3), входящему в ее состав, и встроенному в основную камеру вытяжного воздуха, осуществлять рекуперацию теплоты наружного воздуха, нагретого отходящими дымовыми газами, и передавать ее вытяжному воздуху, поступающему из производственного помещения, в основную вытяжную камеру, нагревая вытяжной воздух до заданной температуры t₇, °C на входе в рекуператор-осушитель без применения регенеративного воздухонагревателя при технически достижимых значениях эффективности рекуперации теплоты

рекуператором №3, равных:1. The inventive air conditioner is equipped with two additional exhaust chambers. The design of the first additional exhaust chamber of outdoor air heated by the exhaust flue gases to a temperature

, allows the rotary recuperator-heat exchanger (recuperator No. 3), which is part of it, and is built into the main chamber of the exhaust air, to recover the heat of the outdoor air heated by the exhaust flue gases, and to transfer it to the exhaust air coming from the production room to the main exhaust chamber, heating the exhaust air to a predetermined temperature t _7, ° C at the inlet of the recuperator drier without the use of a regenerative heater at the technically achievable efficiency values Rekupera uu heat

recuperator number 3, equal to:

2. The presence of a window in the vertical transverse partition with a controlled normally open air valve installed in it, and installation of a controlled normally closed air valves on the inlet pipe of the main exhaust chamber and on the exhaust pipe of the second additional exhaust chamber, allows the control controller of the air conditioner at an outdoor temperature that varies in range t ₁ = 26 ÷ 32 ° C, to supply exhaust air removed from the production room having a lower temperature t ₁₃ = 19 ÷ 24 ° C than the outdoor temperature t ₁ = 26 ÷ 32 ° C, to the inlet pipe of the second additional exhaust chamber with a passage through it and through a normally open controlled air valve installed in the window of the vertical transverse partition into the main exhaust chamber.

, реализуемое двумя режимами заявляемого кондиционера (режимы №3 и №4).This provides, in the presence of an adiabatic humidifier of the extract air in the second additional exhaust chamber, humidification of the exhaust air of the production room and, as a consequence, its indirect cooling to a temperature of t ₁₄ = 13.8 ÷ 18.5 ° C (Section 12, Table 2), that when working together with a recuperator-cooler (recuperator No. 2) provides forced cooling of the supply air at technically achievable values of the efficiency of the recovery of cold exhaust air recuperator No. 2 equal to

implemented by two modes of the claimed air conditioner (modes No. 3 and No. 4).

Mode 3 is assigned at an outdoor temperature that varies in the range t ₁ = 26 ÷ 29 ° C.

Mode 4 is assigned at an outdoor temperature that varies in the range t ₁ = 30 ÷ 32 ° C.

3. In mode No. 3, the movement of air flows in which is shown in FIG. 7, the inventive air conditioner has the ability to supply into the second additional chamber of the exhaust air instead of the outdoor air having high temperature values t ₁ = 26 ÷ 29 ° C, the exhaust air of the production room with a lower temperature varying in the range t ₁₃ = 19 ÷ 23 ° C , which takes place indoors at the specified outdoor temperature t ₁ = 26 ÷ 29 ° C.

In mode number 3. The exhaust air of the production room with a temperature of t ₁₃ = 19 ÷ 23 ° C and a moisture content of d ₁₃ = 6.84 ÷ 8.77 g / kg dry. air enters through the inlet pipe into the second additional exhaust chamber, undergoes adiabatic humidification, cooling indirectly to a temperature of t ₁₄ = 13.8 ÷ 17.2 ° C and enters the recuperator-cooler (recuperator No. 2).

(п. 44, табл. 2).This ensures forced cooling of the supply air by the required amount at technically achievable values of the efficiency of the recovery of cold exhaust air from the heat exchanger-cooler (heat exchanger No. 2) equal to

(p. 44, tab. 2).

, которая в соответствии с п. 45 табл. 2 составляет:In recuperator No. 2, the exhaust air is heated from a temperature of t ₁₄ = 13.8 ÷ 17.2 ° C to a temperature of t ₁₅ at its outlet, determined by the formula

, which in accordance with paragraph 45 of the table. 2 is:

, t₂=59,5°C и t₁₄=13,8°C- for t ₁ = 26 ° C at

, t ₂ = 59.5 ° C and t ₁₄ = 13.8 ° C

t ₁₅ = 13.8-0.648 (13.8-59.5) = 43.3 ° C

, t₂=60,2°C и t₁₄=17,2°C- for t ₁ = 29 ° C at

, t ₂ = 60.2 ° C and t ₁₄ = 17.2 ° C

t ₁₅ = 17.2-0.783 (17.2-60.2) = 50.9 ° C.

After passing through recuperator No. 2, exhaust air with a temperature of t ₁₅ = 43.3 ÷ 50.9 ° C and a moisture content of d ₁₅ = d ₁₄ = 8.92 ÷ 11.1 g / kg dry. air moves from the second additional exhaust chamber through an open controllable air valve in a vertical transverse partition into the main exhaust chamber at the inlet of heat exchanger No. 3 to zone 6 without changing the temperature t ₆ = t ₁₅ = 43.3 ÷ 50.9 ° C and moisture content d ₆ = d ₁₅ = 8.92 ÷ 1.1 g / kg dry. air

4. In mode No. 4, the air flow in which is illustrated in Fig.7, the inventive air conditioner has the ability to supply extract air to the second additional chamber instead of outside air having high temperature values t ₁ = 30 ÷ 32 ° C, exhaust air from the production room with a lower temperature equal to t ₁₃ = 24 ° C, which is maintained indoors at the indicated outdoor temperature t ₁ = 30 ÷ 32 ° C.

In mode 4, the exhaust air of the production room with a temperature of t ₁₃ = 24 ° C and a moisture content of d ₁₃ = 9.33 g / kg dry. air enters through the inlet pipe into the second additional exhaust chamber, undergoes adiabatic humidification, while cooling indirectly to a temperature of t ₁₄ = 18.4 ° C, and enters the recuperator-cooler (recuperator No. 2).

, при котором обеспечивается охлаждение приточного воздуха на максимальную величину.Mode No. 4 is implemented at the maximum value of the recovery efficiency of cold exhaust air recuperator-cooler equal to

at which the supply air is cooled to the maximum value.

,где t₂ - температура приточного воздуха перед рекуператором-охладителем, °C. Определяется из выраженияIn the recuperator-cooler, the exhaust air is heated from a temperature of t ₁₄ = 18.4 ° C to a temperature of t ₁₅ determined by the formula

where t ₂ - supply air temperature in front of the recuperator-cooler, ° C. Defined from expression

,

,

which in accordance with paragraph 43 of the table. 2 is:

- for t ₁ = 30 ° C at t ₃ = 25 ° C; t ₁₄ = 18.4 and

- for t ₁ = 32 ° C at t ₃ = 24.8 ° C; t ₁₄ = 18.4 and

In this case, the exhaust air temperature t ₁₅ , ° C at the outlet of the heat exchanger-cooler in accordance with paragraph 45 of the table. 2 will be:

- for t ₁ = 30 ° C at t ₂ = 51.4 ° C; t ₁₄ = 18.4 ° C and

t ₁₅ = 18.4-0.8 (18.4-51.4) = 44.8 ° C

- for t ₁ = 32 ° C at t ₂ = 50.4 ° C; t ₁₄ = 18.4 ° C and

t ₁₅ = 18.4-0.8 (18.4-501.4) = 44 ° C

After passing through the recuperator-cooler, exhaust air with a temperature of t ₁₅ = 44.8 ÷ 44.0 ° C and a moisture content of d ₁₅ = 12.0 g / kg dry. air moves from the second additional exhaust chamber through an open air valve installed in the window of the vertical transverse partition into the main exhaust chamber at the entrance to the recuperator No. 3 in zone 6 without changing the temperature t ₆ = t ₁₅ = 44.8 ÷ 44.0 ° C and moisture content d ₆ = d ₁₅ = 12.0 g / kg dry. air

Mode 4 is implemented in the inventive air conditioner with the efficiency of heat recovery by recuperator No. 3, which is determined from the expression

,

,

where t ₇ is the temperature of the exhaust air at the outlet of recuperator No. 3, ° C. Defined from expression

в соответствии с п. 49 табл. 2 составляет:which at

in accordance with paragraph 49 of the table. 2 is:

- for t ₁ = 30 ° C and t ₂ = 51.4 ° C

- for t ₁ = 32 ° C and t ₂ = 50.4 ° C

, которые невозможно получить при температуре t₇=70°C.The transition in mode No. 4 from a temperature of t ₇ = 70 ° C at the inlet to the recuperator-dryer used in modes No. 2 and No. 3 to a lower temperature t ₇ = 58.1 ÷ 56.1 ° C, at an outdoor temperature , varying in the range t ₁ = 30 ÷ 32 ° C, due to the need to obtain technically acceptable values of the efficiency of cold recovery with a heat exchanger-cooler

which cannot be obtained at a temperature of t ₇ = 70 ° C.

, а также работа рекуператоров №1, 2, 3 в технически достижимом диапазоне эффективностей рекуперации теплоты и холода обеспечивают нулевое энергопотребление на охлаждение приточного воздуха в теплый период года при температуре наружного воздуха, изменяющейся в диапазоне t₁=26÷32°C.The absence of the inventive air conditioner in the main exhaust chamber when operating in modes 3 and 4 of a regenerative air heater that causes energy consumption, ensuring that the exhaust air is heated by recuperator No. 3 to the required temperature t ₇ , ° C at the inlet of the recuperator-dryer by supplying heated air to it flue gases, previously released into the atmosphere, and having a temperature that varies in the range

as well as the operation of recuperators No. 1, 2, 3 in the technically feasible range of heat and cold recovery efficiencies provide zero energy consumption for cooling the supply air in the warm season at an outdoor temperature that varies in the range t ₁ = 26 ÷ 32 ° C.

Obtaining these benefits in the inventive air conditioner is provided by the totality of the essential features of the proposed solution.

The design of the inventive air conditioner with a forced system of dehumidification and evaporative cooling of the supply air is illustrated in the drawings in FIG. 1-7. In FIG. 1 shows a vertical projection of an air conditioner; in FIG. 2 - view A (in Fig. 1); in FIG. 3 - section AA (in Fig. 2); in FIG. 4 - view B (in Fig. 3); in FIG. 5 is a view C (in FIG. 3); in FIG. 6 is a schematic diagram of an air conditioner with numbering of zones of air flows of the inflow line, the main and additional exhaust lines in modes No. 1 and 2; in FIG. 7 is a schematic diagram of an air conditioner with numbering of zones of air flows of the inflow line, the main and additional exhaust lines in modes No. 3 and 4.

In FIG. 6 zones 1-5 belong to the inflow line, zones 6-9 to the main exhaust line; zones 10-12 to the first additional drawing line, and zones 13-16 to the second additional drawing line.

In FIG. 7 zones 1-5 belong to the inflow line, zones 10-12 to the first additional exhaust line, and zones 13-15, 6-9 to the main exhaust line.

In FIG. 6 and 7, the inflow and exhaust lines are indicated: the inflow line - Lpr, the main exhaust line - VOC; the line of the first extra hood is LDV1, the line of the second extra hood is LDV2.

The air conditioner (Fig. 3) contains a supply 1 and a main exhaust 2 chambers separated by a horizontal intermediate partition 3 with a main 4 and an additional 5 windows, a supply air cooler 6 made in the form of a forced system of drainage and evaporative cooling, consisting of two rotary heat exchangers - recuperator-dryer 7 and recuperator-cooler 8, adiabatic humidifier for supply air 9 with a supply pipe of demineralized water 10, which is located in the supply chamber 1. the cooler-dryer 7 is made in the form of an adsorption-type rotary regenerator, which is built into the main window 4 of the horizontal intermediate partition 3 and has oppositely directed lines of external air inflow and exhaust air removed from the production room, and the recuperator-cooler 8 is in the form of a rotary heat exchanger, which it is built into an additional window 5 of the horizontal intermediate partition 3 and has a line of external air flow. The supply chamber 1 has an inlet 11 and an outlet 12 nozzles, an air purifier 13 installed at the inlet of the chamber, and a fan unit 14. The exhaust chamber 2 of the air removed from the production room (hereinafter the main exhaust chamber) has a top panel 15, an inlet 16 and an outlet 17 nozzles , an air purifier 18 installed at the inlet of the chamber, and a fan unit 19 installed at the outlet of the chamber.

The air conditioner is equipped with a control controller (not shown in FIGS. 1-7), two additional exhaust chambers 20 and 21 and a window 22 located in the upper panel 15 of the main exhaust chamber 2. The first additional exhaust chamber 20 is located above the upper panel 15 of the main exhaust chamber 2 and contains a top panel 23, inlet 24 and outlet 25 nozzles, an air cleaner 26 located at the inlet to the chamber, a rotary heat exchanger-heat exchanger 27 with an inverter (shown in Fig. 1-7) and a fan unit 28 located at the outlet of the chamber. In this case, the aforementioned rotary heat exchanger-heat exchanger is integrated in the window 22 of the upper panel 15 of the main exhaust chamber 2, is hermetically installed between the horizontal intermediate partition 3 of the air conditioner and the upper panel 23 of the first additional exhaust chamber 20 and has oppositely directed exhaust lines of the outdoor air heated by the exhaust flue gases, and exhaust hoods of air removed from the production room.

The second additional exhaust chamber 21 is located above the horizontal intermediate partition 3 of the air conditioner and is separated from the main exhaust chamber 2 by a vertical transverse partition 29 and sealed between the recuperator-dryer 7 and the recuperator-cooler 8, contains inlet 30 and outlet 31 nozzles, an air purifier 32 and a fan unit 33, and has an additional outdoor air exhaust line opposite to the inflow line. The second additional exhaust chamber 21 provides forced cooling of the supply air in the cold season and the warm season at an outdoor temperature that varies from 11 to 25 ° C.

When cooling the supply air in the air conditioner during the warm season at an outdoor temperature that varies in the range t ₁ = 26 ÷ 32 ° C, the second additional exhaust chamber 21 is equipped with an adiabatic humidifier 34 of the exhaust air removed from the production room with a supply pipe of demineralized water 35 , which is placed between the air purifier 32 and the recuperator-cooler 8 of the chamber. In this case, the inlet pipe 16 of the main exhaust chamber 2 and the exhaust pipe 31 of the second additional exhaust chamber 21 are equipped with controlled normally closed air valves 36, 37, and the vertical transverse partition 29 is equipped with a window 38 in which a controlled normally open air valve 39 is installed, which, when interaction with the mentioned controlled air valves 36 and 37 of the main 2 and second additional exhaust 21 chambers allows the control controller of the air conditioner (not shown in Fig. 1-7) supply the exhaust air removed from the production room to the inlet pipe 30 of the second additional exhaust chamber 21, with its humidification in the adiabatic humidifier 34, providing its indirect cooling, and the subsequent passage of humidified exhaust air through the recuperator-cooler 8 and a normally open controlled air valve 39 in the window 38 of the vertical transverse partition 29 into the main exhaust chamber 2. Adiabatic humidification of the exhaust air is provided in conjunction with the recuperation rotor-cooler 8 forced cooling of the supply air and the operation of the heat exchanger-cooler 8 in the technically achievable range of the efficiency of cold recovery.

To service the air conditioner during its operation, the air conditioner is equipped with thirteen service doors: service door 40 for the heat exchanger-dryer, service door 41 for the heat exchanger-cooler, service door 42 for the air cleaner of the main exhaust chamber, service door 43 for the fan unit of the main exhaust chamber; service door 44 for the intake chamber air cleaner, service door 45 for the supply chamber fan unit, service door 46 for the adiabatic supply chamber humidifier, service door 47 for the air cleaner of the second additional exhaust chamber, service door 48 for the rotary heat exchanger-heat exchanger of the main exhaust and first additional exhaust chamber, service door 49 for the fan unit of the first additional exhaust chamber 20, service door 50 for the air cleaner second accessory second exhaust chamber, the service door 51 to an adiabatic humidifier second additional exhaust chamber, the service door 52 to the second fan unit further exhaust chamber.

For regions with outdoor temperatures ranging from 25 to (-30) ° C, the design of the air conditioner has the following features.

1. The vertical transverse partition 29 is made blind without an opening 38 in it and, accordingly, without a controlled air valve 39.

2. The second additional exhaust chamber 21 is performed without an adiabatic humidifier 34 and a supply pipe of demineralized water 35.

3. The inlet pipe 16 of the main exhaust chamber 2 and the exhaust pipe 31 of the second additional exhaust chamber 21 is performed without controllable air valves 36 and 37.

The inventive air conditioner can operate in five modes.

.Mode 1. Air conditioning in the cold season with heating of the supply air in the forced system of dehumidification and evaporative cooling of the air conditioner to a final supply air temperature of t ₅ = 15 ° C and relative humidity ϕ ₅ = 0.868 ÷ 0.832 in the range of outdoor temperature t ₁ = 10 ÷ (-30) ° C at an extract air temperature of the production room t ₆ = 18 ° C, its moisture content d ₆ = 6.42 g / kg dry. air and the temperature of the exhaust air heated by the exhaust flue gases, varying in the range

.

.Mode 2. Air conditioning mode in the warm season with fresh air cooling in the forced system for dehumidifying and evaporative cooling of the air conditioner to a final fresh air temperature t ₅ = 2 ° C and relative humidity ϕ ₅ = 0.784 ÷ 0.801 in the range of outdoor temperature t ₁ = 11 ÷ 25 ° C at an extract air temperature of the production room t ₆ = 18 ° C and its moisture content d ₆ = 6.42 g / kg dry. air., and the temperature of the exhaust air heated by the exhaust flue gases, varying in the range

.

.Mode 3. Air conditioning mode in the warm season with fresh air cooling in the forced system for dehumidifying and evaporative cooling of the air conditioner to a final fresh air temperature t ₅ = 21 ° C and relative humidity ϕ ₅ = 0.848 ÷ 0.897 in the range of outdoor temperature t ₁ = 26 ÷ 29 ° C at an extract air temperature of the production room t ₁₃ = 19 ÷ 23 ° C, its moisture content d ₆ = 6.84 ÷ 8.77 g / kg dry. air and the temperature of the exhaust air heated by the exhaust flue gases, varying in the range

.

.Mode 4. Air conditioning mode in the warm season with fresh air cooling in the forced system for dehumidifying and evaporative cooling of the air conditioner to a final fresh air temperature t ₅ = 21 ° C and relative humidity ϕ ₅ = 0.914 ÷ 0.932 in the range of outdoor temperature t ₁ = 30 ÷ 32 ° C at an extract air temperature of the production room t ₁₃ = 24 ° C of its moisture content d ₁₃ = 9.33 g / kg dry. air and the temperature of the exhaust air heated by the exhaust flue gases, varying in the range

.

Mode 5. Standby.

и

при изменении температуры наружного воздуха t₁ в соответствии с номером режима в диапазоне:The air conditioner in mode 1-2 works as follows. There are four fan units 14, 19, 28, 33 of the supply chamber 1, the main exhaust 2, the first 20 and second 21 additional exhaust chambers, the electric drive of the rotary heat exchanger-dryer 7 at a constant speed of rotation of the adsorption rotor, the electric drives of the rotary heat exchanger-cooler 8 and rotary heat exchanger a heat exchanger 27 with inverters (not shown in FIGS. 1-7) and an adiabatic humidifier for supply air 9 with an inverter (not shown in FIGS. 1-7), and an adiabatic extractor humidifier 34 in the production room, installed second inventive additional exhaust chamber 21, is turned off. At the same time, the controlled air valves 36 and 37 installed on the inlet pipe 16 of the main exhaust chamber 2, the outlet pipe 31 of the second additional exhaust chamber 21 are open, and the controlled air valve 39 installed in the window 22 of the vertical transverse wall 29 is closed. The fan units 14, 19, 28, 33 operate at 100% performance. The air conditioner controller controls the operation of the inverters of the electric drives of the rotary heat exchanger-cooler 8 and the rotary heat exchanger-heat exchanger 27, which provide the calculated values of the heat recovery efficiency

and

when the outdoor temperature changes t ₁ in accordance with the mode number in the range:

- t ₁ = 10 ÷ (-30) ° C in mode 1;

- t ₁ = 11 ÷ 25 ° C in mode 2.

The controller also controls the inverter of the adiabatic humidifier 9 of the supply chamber 1, providing a change in the speed and performance of the high pressure water pump (not shown in Fig. 1-7) for supplying demineralized water to the spray nozzles of the adiabatic humidifier 9 when the outdoor temperature changes in the range of:

- t ₁ = 10 ÷ (-30) ° C in mode 1;

- t ₁ = 11 ÷ 25 ° C in mode 2.

According to the formula

, кг/ч,

kg / h

- массовый поток сухого приточного воздуха, кг/ч;

- перепад влагосодержания приточного воздуха, обеспечиваемый адиабатическим увлажнителем 9 с шагом в один °C при изменении температуры наружного воздуха в диапазонах t₁=10÷(-30)°C в режиме 1 (п. 43 табл. 1) и t₁=11÷25°C в режиме 2 (п. 57 табл. 2); d₄, d₅ - влагосодержания приточного воздуха соответственно на входе и выходе из адиабатического увлажнителя, г/кг сух. возд.Where

- mass flow of dry supply air, kg / h;

- the moisture content difference of the supply air provided by the adiabatic humidifier 9 in increments of one ° C with a change in the outdoor temperature in the ranges t ₁ = 10 ÷ (-30) ° C in mode 1 (paragraph 43 of Table 1) and t ₁ = 11 ÷ 25 ° C in mode 2 (p. 57 of table 2); d ₄ , d ₅ - moisture content of the supply air, respectively, at the inlet and outlet of the adiabatic humidifier, g / kg dry. air

Consider the operation of the main exhaust line (VLW) of the inventive air conditioner in modes 1-2 (Fig. 3 and 6).

The air removed from the production room with a temperature of t ₆ = 18 ° C and a moisture content of d ₆ = 6.42 g / kg dry. air enters through the inlet pipe 16 of the main exhaust chamber 2 into the chamber, is pulled by the fan unit 19 through the air cleaner 18, the rotary heat exchanger-heat exchanger 27 and the heat exchanger-dryer 7, after which it is released into the atmosphere through the exhaust pipe 17. The main exhaust line (VLW) with zones 6-9 in modes 1-2 is shown in FIG. 6, and the values of the exhaust air indicators of the production room in zones 6–9 are given in Table 1 for mode 1, and in Table. 2 for mode 2.

Consider the operation of the additional exhaust line of outdoor air heated by the exhaust flue gases (LDV1) in modes 1-2 (Fig. 3 and Fig. 6).

The external air heated in the exhaust gas recuperator with a temperature of t ₁₀ = 120 ÷ 90 ° C enters the inlet pipe 24 of the first additional exhaust chamber 20 of the air conditioner and is drawn by the fan unit 28 through the air cleaner 26 and the rotary heat exchanger 27, after which it is discharged into the atmosphere.

приведены в табл. 1 для режима 1 и в табл. 2 для режима 2.The rotary recuperator-heat exchanger 27 recovers the heat of the exhaust air heated by the exhaust flue gases, and transfers it to the exhaust air of the production room, heating it from a temperature of t ₆ = 18 ° C to a temperature of t ₇ = 70 ° C at the outlet. An additional drawing line (LDV1) is shown in FIG. 6, and the value of the heat recovery efficiency of the rotary heat exchanger-heat exchanger 27 (heat exchanger No. 3)

are given in table. 1 for mode 1 and in table. 2 for mode 2.

Consider the operation of the line of additional exhaust air (LDV2) in modes 1-2 (Fig. 3 and Fig. 6).

Outside air with a temperature of t ₁ = 10 ÷ (-30) ° C in mode 1 and a temperature of t ₁ = 11 ÷ 25 ° C in mode 2 enters the inlet pipe 30 of the second additional exhaust chamber 21 and is drawn by the fan unit 33 through an air cleaner 32, turned off adiabatic humidifier 34, and a heat exchanger-cooler 8, after which through the outlet pipe 31 is released into the atmosphere.

The line for additional outdoor air extraction (LDV2) with zones 13-16 in modes 1-2 is shown in FIG. 6, and the values of the indicators of the exhaust air outside zones 13-16 are given in Table 1 for mode 1, and in Table 2 for mode 2.

Consider the work of the inflow line (LPR) in modes 1-2 (Fig. 3 and Fig. 6)

Outside air with a temperature of t ₁ = 10 ÷ (-30) ° C in mode 1 and a temperature of t ₁ = 11 ÷ 25 ° C in mode 2 enters the inlet pipe 11 of the supply chamber 1 and is drawn by the fan unit 14 through the air purifier 13, the recuperator dehumidifier 7, recuperator-cooler 8, adiabatic humidifier 9 and is supplied moistened through the exhaust pipe 12 into the air distributor (not shown in Fig. 1-7) installed in the production room.

The inflow line (DM) with zones 1-5 in modes 1-2 is shown in FIG. 6, and the values of the supply air indicators for zones 1 -5 are given in table 1 for mode 1, and in table. 2 for mode 2.

The air conditioner in mode 3-4 works as follows. There are three fan units 14, 19, 28 of the supply chamber 1, the main exhaust 2 and the first additional 20 exhaust chambers. The fan unit 33 of the second additional exhaust chamber 21 is turned off. The electric drive of the rotary heat exchanger-dryer 7 also operates at a constant rotation speed of the adsorption rotor, the electric drives of the rotary heat exchanger-cooler 8 and rotary heat exchanger 27 with inverters (not shown in Fig. 1-7), the adiabatic air supply humidifier 9 and exhaust air 34 with inverters (not shown in FIGS. 1-7). At the same time, a controlled air valve 39 is installed, installed in the window 38 of the vertical transverse partition 29.

и

при изменении температуры наружного воздуха t₁ в соответствии с номером режима в диапазоне:Controlled air valves 36, 37 mounted on the inlet pipe 16 of the main exhaust chamber 2 and the outlet 31 of the second secondary exhaust chamber 21 are closed. Fan units 14, 19, 28 operate at 100% performance. The air conditioner controller controls the operation of the inverters of the electric drives of the rotary heat exchanger-cooler 8 and the rotary heat exchanger-heat exchanger 27, which provide the calculated values of the heat recovery efficiency

and

when the outdoor temperature changes t ₁ in accordance with the mode number in the range:

- t ₁ = 26 ÷ 29 ° C in mode 3;

- t ₁ = 30 ÷ 32 ° C in mode 4.

The controller also controls the operation of the inverters of the adiabatic humidifiers of the supply 9 and exhaust air 34 of the production room, providing a change in the speed and performance of high pressure water pumps (not shown in Fig. 1-7) for supplying demineralized water to the spray nozzles of the adiabatic humidifiers 9 and 34 when changing outdoor temperature in the range:

- t ₁ = 26 ÷ 29 ° C in mode 3;

- t ₁ = 30 ÷ 32 ° C in mode 4

according to the formula:

- for adiabatic supply air humidifier 9:

, кг/ч,

kg / h

- for adiabatic supply air humidifier 34:

, кг/ч,

kg / h

,

- массовые потоки сухого приточного и сухогоWhere

,

- mass flows of dry supply and dry

,

- перепады влагосодержания в приточной 1 и второй дополнительной вытяжной 21 камерах, г/кг сух. возд., обеспечиваемые адиабатическими увлажнителями 9 и 34, с шагом в 1°C при изменении температуры наружного воздуха в диапазонах t₁=26÷29°C в режиме 3 и t₁=30÷32°C в режиме 4 для:exhaust air, kg / h;

,

- moisture content differences in the supply 1 and second additional exhaust 21 chambers, g / kg dry. the air provided by adiabatic humidifiers 9 and 34, in increments of 1 ° C, when the outdoor temperature changes in the ranges t ₁ = 26 ÷ 29 ° C in mode 3 and t ₁ = 30 ÷ 32 ° C in mode 4 for:

- Δd ^5.4 (tab. 2, p. 57);

- Δd ^14.13 (tab. 2, p. 17);

d ₄ , d ₅ - moisture content, respectively, at the inlet and outlet of the adiabatic humidifier of the supply air 9, g / kg dry. air .; d ₁₃ , d ₁₄ - moisture content, respectively, at the inlet and outlet of the adiabatic humidifier extract air 34 of the second additional exhaust chamber 21, g / kg dry. air

Consider the operation of the main exhaust line (BW) of the inventive air conditioner in modes 3-4 (Fig. 3 and 7)

The air removed from the production room with a temperature t ₁ = 19 ÷ 23 ° C in mode 3 and t ₁₃ = 24 ° C in mode 4 enters through the inlet pipe 30 of the second additional exhaust chamber 21 into the chamber, and is drawn by the fan unit 19 of the main exhaust chamber 2 through an air purifier 32, an adiabatic humidifier 34, being moistened therein, a heat exchanger-cooler 8 and through an open controlled air valve 39 installed in the window 38 of the vertical transverse partition 29, enters the zone 6 of the main exhaust chamber 2. Then, the exhaust air passes through an air cleaner 18, rotary heat exchanger-recuperator heat exchanger 27 and dehydrator 7, after which emitted.

In the rotary heat exchanger-heat exchanger 27, the exhaust air of the production room is heated from temperature t ₆ = t ₁₅ = 43.3 ÷ 50.9 ° C in mode 3 to temperature t ₇ = 70 ° C, and in mode 4 it is heated from temperature t ₆ = t ₁₅ = 44.8 ÷ 44.0 ° C to a temperature of t ₇ = 58.1 ÷ 56.1 ° C.

The line of the main hood (VOC) in modes 3 and 4 is presented in Fig.7.

The operation of the first additional exhaust line (LDV1) and the inflow line (LPR) is carried out similarly to modes 1 and 2. The additional exhaust line (LDV1) and the inflow line (LPR) when operating in modes 3 and 4 are presented in FIG. 7.

The air conditioner in mode 5 (standby) does not work. In this case, the electric drives of the rotary recuperators 7, 8 and 27, and the fan units 14, 19, 28 and 33, the electric drives of the high pressure water pumps of the adiabatic humidifiers 9 and 34 are turned off and the controlled air valves 36, 37, 39 installed on the main inlet 16 are closed exhaust chamber, on the exhaust pipe 31 of the second additional exhaust chamber, and in the window 38 of the vertical transverse partition.

All of the above, including a description of the operation of the inventive air conditioner, confirms the possibility of its use in industry with obtaining high technical performance in comparison with the known designs of air conditioners. In addition, both in the sources of patent and scientific and technical information, and in industry, such a design did not occur, which indicates that the claimed invention meets all the criteria of patentability.

The list of sequences (the composition of the air conditioner with a forced system of drainage and evaporative cooling)

1. Supply air chamber

2. The main exhaust chamber of the air removed from the production room

3. Horizontal intermediate partition

4. The main window of the horizontal intermediate partition

5. Additional window of the horizontal intermediate partition

6. Supply air cooler, made in the form of a system of dehumidification and evaporative cooling.

7. Recuperator-dryer

8. Recuperator-cooler

9. Adiabatic supply air humidifier

10. Supply water pipe for demineralized water for an adiabatic supply air humidifier

11. The inlet pipe of the supply chamber

12. The outlet pipe of the supply chamber

13. Air purifier of the supply chamber

14. The ventilation unit of the supply chamber

15. The top panel of the main exhaust chamber

16. The inlet pipe of the main exhaust chamber

17. The exhaust pipe of the main exhaust chamber

18. Air cleaner of the main exhaust chamber

19. The fan unit of the main exhaust chamber

20. The first additional exhaust chamber

21. The second additional exhaust chamber

22. A window located in the upper panel of the main exhaust chamber

23. The top panel of the first additional exhaust chamber

24. The inlet pipe of the first additional exhaust chamber

25. The exhaust pipe of the first additional exhaust chamber

26. Air purifier of the first additional exhaust chamber

27. Rotary recuperator-heat exchanger of the first additional exhaust and main exhaust chambers

28. The fan unit of the first additional exhaust chamber

29. A vertical transverse partition dividing the main and second additional exhaust chambers

30. The inlet pipe of the second additional exhaust chamber

31. The exhaust pipe of the second additional exhaust chamber

32. Air purifier of the second additional exhaust chamber

33. The fan unit of the second additional exhaust chamber

34. Adiabatic humidifier for exhaust air removed from the production room

35. The supply pipe of demineralized water to the adiabatic extractor humidifier of the second additional exhaust chamber

36. Controlled air valve mounted on the inlet pipe of the main exhaust chamber

37. Controlled air valve mounted on the exhaust pipe of the second additional exhaust chamber

38. Window in the vertical transverse partition of the air conditioner

39. Controlled air valve installed in the window of the vertical transverse partition of the air conditioner

40. Service door for recuperator-dryer

41. Service door for recuperator-cooler

42. Service door for the air cleaner of the main exhaust chamber

43. Service door for the fan unit of the main exhaust chamber

44. Service door for the intake air cleaner

45. Service door for supply unit fan unit

46. Service door for the adiabatic humidifier of the supply chamber

47. Service door for the air cleaner of the first additional exhaust chamber

48. Service door for a rotary heat exchanger-heat exchanger of the main exhaust and first additional exhaust chambers

49. Service door for the fan unit of the first additional exhaust chamber

50. Service door for the air cleaner of the second additional exhaust chamber

51. Service door for adiabatic humidifier of the second additional exhaust chamber

52. Service door for the fan unit of the second additional exhaust chamber

Claims (2)

1. An air conditioner with a forced system of dehumidification and evaporative cooling, comprising a supply chamber and a main exhaust chamber of air removed from the production room, separated by a horizontal intermediate partition with main and additional windows, a supply air cooler made in the form of a dehumidification and evaporative cooling system, consisting of from two rotary recuperators - recuperator-dryer and recuperator-cooler, and adiabatic supply air humidifier with a supply pipe of demineralized water placed in the supply chamber, a control controller, the recuperator-dryer being made in the form of a rotary adsorption-type regenerator, which is built into the main window of the horizontal intermediate partition and has oppositely directed lines of outdoor air inflow and exhaust air removed from the production room and the recuperator-cooler - in the form of a rotary heat exchanger with an inverter, which is built into the additional window of the horizontal intermediate an exact partition and has a line of external air supply, the supply chamber contains an inlet and outlet pipe, an air cleaner installed at the inlet to the chamber, and a fan unit, the main exhaust chamber contains a top panel, an inlet and outlet pipe, an air cleaner installed at the inlet of the chamber, and a fan unit installed at the outlet of the chamber, characterized in that the air conditioner is equipped with two additional exhaust chambers and a window located in the upper panel of the main exhaust chamber between the air with a dehumidifier and a recuperator-dryer, the first additional exhaust chamber is located above the upper panel of the main exhaust chamber and contains the upper panel, inlet and outlet pipes, an air cleaner located at the inlet to the chamber, a rotary heat exchanger with an inverter and a fan unit located at the outlet of the chamber while the aforementioned rotary heat exchanger-heat exchanger is integrated in the window of the upper panel of the main exhaust chamber, hermetically installed between the horizontal intermediate partition of the air conditioner the top and the top panel of the first additional exhaust chamber and has oppositely directed exhaust lines of outdoor air heated by the exhaust flue gases, and exhaust air removed from the production room, and the second additional exhaust chamber is located above the horizontal intermediate partition and is divided with the main exhaust chamber by a vertical transverse partition, hermetically installed between the recuperator-dryer and the recuperator-cooler, contains inlet and outlet pipes, air purifier and fan unit and has an additional line for extracting outdoor air, opposite the supply line, providing forced cooling of the supply air at an outdoor temperature that changes during the cold season in the range from 10 to (-30) ° C and in the warm season in the range 11 to 25 ° C. 2. An air conditioner with a forced system of dehumidification and evaporative cooling according to claim 1, characterized in that when the supply air is cooled in the warm season at an outdoor temperature varying from 26 to 32 ° C, the second additional exhaust chamber is equipped with an adiabatic exhaust humidifier air with a supply pipe of demineralized water, which is placed between the air purifier and the recuperator-cooler of the chamber, the inlet pipe of the main exhaust chamber and the exhaust pipe of the second additional of the exhaust chamber are equipped with controlled normally closed air valves, and the vertical transverse partition of the air conditioner is equipped with a window with a controlled normally open air valve installed in it, which, when combined with the said controlled air valves of the main and second additional exhaust chambers, allows the control controller of the air conditioner to supply exhaust air removed from a production room having a lower temperature than the temperature of the outside air, to the second additional exhaust chamber with its passage through the chamber and controlled normal open air valve installed in the window of the vertical transverse partition of the air conditioner, into the main exhaust chamber and subsequent passage through the air cleaner, rotary heat exchanger and heat exchanger, and providing forced cooling of the supply air.

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