UA21754U - System for ventilation and air conditioning - Google Patents

Abstract

A system for ventilation and air conditioning that includes incoming and exhaust air ducts, central station that has at least one filtration chamber placed as direction of flow of incoming air outer air, chambers of incoming and exhaust fans, heat exchange chamber with plate recuperation heat exchanger provided with appliance for condensate utilization, indicators of temperature control for incoming outer and exhaust air and shutoff means, and control system, and maintenance objects, at that central station additionally includes chambers for noise absorption, chambers-collectors, one of those is equipped with drive air multi-fold valve for control of exhaust air flow, means for measurement of flow rate of incoming outer and of exhaust air, device for supply and transfer of additional heat or cooling energy to incoming outer air placed in the chamber of heat exchange and arranged as multi-contour heat exchanger.

Description

Description of the invention

The utility model refers to ventilation and air conditioning systems, mainly to systems that are used for heat treatment of air flows coming from the atmosphere into the service facility and from the service facility into the atmosphere, in which the primary and exhaust air transfer means, means of heat regeneration and means of supplying additional heat and cooling energy to the incoming air are located at one central station, which carries out organized air exchange in the service facility, and can be used to obtain the necessary climatic parameters of the air in both office and production 70 premises and structures, as well as in residential buildings.

Known system of ventilation and air conditioning (KO 2119129 C1, P2409/00, E24E5/00, publication date 09/20/1998), which includes supply and exhaust air ducts for supply of supply air and removal of exhaust air, a central station connected by means of the specified air ducts with a service object and with an atmosphere containing filtering chambers for supply and exhaust air, chambers of 19 supply and exhaust fans, a heat exchange chamber with a heat transfer device, a means for supplying and transferring additional heat or cooling energy to supply external air, connected to the energy source located in the service facility and the shut-off and regulating means, and the control system made with the possibility of adjusting the direction of travel, the flow rate and the temperature of the incoming and exhaust air in the central station and the service facility.

In an analogous system, the means of supplying and transferring additional heat and/or cooling energy to the supply air and exhaust air is connected to the heat exchanger of the heating system, located in the service facility, and the preheating, subsequent heating and cooling of the supply air is generally heat transfer device The central station includes additional channels with driven multi-valve air valves for heat exchange between incoming outside air and 22 exhaust air with the help of heat transfer devices. -at

The disadvantages of the analogue system are: - low energy efficiency of the system, since the use of additional thermal energy from a source located in the service facility is mainly intended for forced heating of the air in it, only in the morning; M 30 - increased noise level during system operation, as a result of which, to ensure the necessary comfort in the service facility, it is necessary to isolate the central station from the service facility, which additionally reduces the convenience of its installation and maintenance; c - relatively large dimensions and weight of the central station; "-- - a decrease in the level of comfort in the service facility, especially when it has an increased energy load 35 or a high concentration of harmful emissions and carbon dioxide in the air, since only exhaust air from the service facility is used for circulation in the forced mode; - insufficient level of automation of system operation Due to the lack of sensors for monitoring the temperature of supply and exhaust air, which reduces the energy efficiency of the system. "

Known system of ventilation and air conditioning |KO 2244882 C1, Е24Е5/00, Е24ГЕ11/00, date of publication С 40 01.20.2005), which includes supply and exhaust air ducts for supply of supply air and removal of exhaust air, a central station, connected with the help of the specified ducts with the object of service

With" and with the atmosphere, and which contains a filter chamber for supply and exhaust air, chambers of supply and exhaust fans, a heat exchange chamber with a plate recuperative heat exchanger equipped with a device for condensate disposal, means for supplying and transferring additional heat or 45 cooling energy to the supply external air connected to energy sources located in the maintenance facility, supply air and exhaust air temperature control sensors and shut-off and regulating devices, and a control system made with the ability to adjust the flow direction, flow rate, and temperature of supply air and exhaust air air in the central station and service facility. and In the well-known system, along the supply air flow in the central station, there are an air s 20 valve, a filtering chamber, a heat exchange chamber with a plate recuperative heat exchanger,

And" equipped with a condensate disposal device, an air cooler, and a supply fan chamber.

In the service facility, the supply air ducts are connected to the means for transferring additional heat energy, equipped with ejector closers with nozzles and heat exchangers, connected by circular pipelines to the central or autonomous heating system in the service facility.

An automatic reversing valve is mounted on the supply pipeline in front of the heat exchanger, connected to the air temperature control sensor in the service facility. The lamellar recuperative heat exchanger is made with a bypass air channel, a multi-valve drive air valve and an ice formation control sensor. The drive of the multi-valve air valve is pulse-connected to the sensor for monitoring the temperature of the incoming outside air in the air duct. 60 A filter chamber, a heat exchange chamber with an electric air heater connected to the electrical network from the pulse of the ice formation control sensor, and a recuperative plate heat exchanger, an exhaust fan chamber and an exhaust duct connected to the atmosphere

The control system with the help of ice formation control sensors, the temperature control sensor of the incoming outside air in the air duct and the air temperature control sensors in the service facility, as well as the electric air heater switch connected to them, the automatic reversing valve and the multi-leaf air valve actuator, regulates the direction of movement , flow rate and temperature of supply air and exhaust air in the central station and service facility.

The prototype system has sufficiently wide functional and technological possibilities for thermal treatment of air and allows you to effectively fight frost on the plate heat exchanger without impairing the recovery coefficient, and also slightly reduces the energy consumption for heating the incoming outside air compared to the analogue.

Disadvantages of the system are: 70 - the need to use electrical energy to heat the exhaust air in winter to defrost the recuperative plate heat exchanger, which reduces the energy efficiency of the system; - increased noise level during system operation, as a result of which, in order to ensure the necessary comfort in the service facility, it is necessary to locate the central station at some distance from 7/5 of the service facility or to equip it with special noise-absorbing devices, which additionally reduces the convenience of its installation and maintenance; - the location of means for the transfer of additional heat or cooling energy in each of the service facilities, which reduces the convenience of system maintenance during operation and leads to additional costs for the arrangement of the system; - large dimensions and weight of the central station.

The specified shortcomings reduce the energy efficiency of the specified system, the convenience and manufacturability of its installation and maintenance, as well as reliability in operation. In addition, the mentioned shortcomings lead to an increase in costs for the installation and operation of the prototype system and do not allow to obtain the required level of comfort in the service facility without additional measures for noise absorption of the central station.

The basis of a useful model is the task of creating such a ventilation and air conditioning system, in which, due to a different design of the central station and a different design relationship of its elements with each other and with the elements of the system as a whole, high energy efficiency of the system is ensured in combination with a low level noise, small overall dimensions, convenience and manufacturability of installation and maintenance, increased operational reliability and comfortable conditions in the service center.

The task is solved by the fact that in the ventilation and air conditioning system, which includes supply and exhaust air ducts for supply of supply air and extraction of exhaust air, a central p station connected by means of the specified air ducts to the object of service and to the atmosphere, and which contains at least one filtering chamber placed along the flow of incoming outside air, chambers - with 5 supply and exhaust fans, a heat exchange chamber with a recuperative plate heat exchanger, equipped with a device for condensate disposal, means for supplying and transferring additional heat or cooling energy in external supply air connected to energy sources located in the service facility, external and exhaust air temperature control sensors and shut-off and regulating devices, and a control system made with the ability to adjust the direction of travel, flow rate and "temperature of supply external and exhaust air in central station and service facilities, c according to the useful model, the central station additionally includes noise absorption chambers, collector chambers, one of which is equipped with a drive air multi-leaf valve to control the flow of exhaust air, c means for measuring the flow of incoming external and exhaust air, a means for supply and transfer of additional heat or cooling energy to the incoming external air, located in the heat exchange chamber and made in the form of a multi-circuit heat exchanger, which includes a heat carrier circuit with liquid, a heat carrier circuit with antifreeze and a heat carrier circuit with refrigerant connected in series for heat exchange, and two the latter are connected to a device for condensate disposal, while in the flow of supply - outside air in the central station there are a noise absorption chamber, a filtering chamber, chamber -I of the supply fan, a plate recuperative heat exchanger, a coolant circuit with antifreeze, a chamber ector, a noise absorption chamber, a device for measuring the flow of incoming external air and a blocking and regulating device, and a blocking and regulating device, a device for measuring the flow of exhaust air, a noise absorption camera, a collector chamber with drive air multi-leaf valve and, depending on the position of the drive air multi-leaf valve, the circuit of the heat carrier with a refrigerant or plate recuperative heat exchanger and the circuit of the heat carrier with a refrigerant, the chamber of the exhaust fan and the noise absorption chamber.

To improve air quality, which largely determines the comfort conditions in the service facility, the central station includes an ionization chamber located along the flow of outside air in the heat exchange chamber between the circuit of the coolant with antifreeze and the collector chamber.

It is advisable for the ionization chamber to include a dielectric plate with needle coronal electrodes connected to a high voltage source.

To increase the convenience of maintenance, the central station includes a control chamber located in the heat exchange chamber.

To increase the reliability of operation, the central station includes an exhaust air filtering chamber installed along its course between the means for measuring the exhaust air flow rate and the noise absorption chamber. 65 In order to clean the incoming outdoor air while simultaneously increasing the convenience and manufacturability of installation and maintenance, each filter chamber includes at least one filter for cleaning the incoming outdoor air, made in the form of a membrane with a rectangular cross-section made of moisture-resistant porous material that is elastically deformable, located with an overlap the perimeter of the corresponding chamber at an angle o; to the direction of the air flow.

For more effective noise absorption, the outer surface of the central station and the inner surfaces of the cameras are covered with a layer of material with sound-absorbing and heat-insulating properties, for example, porous rubber.

In order to increase the convenience and manufacturability of installation and maintenance, the chambers of the central station along the flow of incoming external and exhaust air are made in the form of hollow boxes connected to each other, 7/0, for example, with the help of elastic connecting flanges.

To reduce overall dimensions of the system in the heat exchange chamber, the plate recuperative heat exchanger, heat carrier circuits of the multi-circuit heat exchanger, the ionization chamber and the control chamber are separated from each other by means of elastic and/or rigid airtight diaphragms to form the corresponding sections.

In order to prevent noise generation, the supply and exhaust fan chambers are equipped with radial fans fixed on the shafts of the corresponding drives, for example, electric motors, while the drives are mounted inside the specified chambers with the help of independent suspensions made with the possibility of eliminating vibration and resonant oscillations during operation.

To increase the efficiency of heat exchange, the recuperative plate heat exchanger is made of plates, for example, of aluminum, mounted together to form cross and exhaust channels with the possibility of stable air passage in a wide pressure range and the exclusion of mixing of supply air and exhaust air with each other, with flat surfaces plates contain protruding point jumpers made of moisture-resistant elastic material, for example, silicone, which form chaotic obstacles in the supply and exhaust channels between the plates.

To ensure the natural flow of condensate into the device for its disposal, a plate recuperative heat exchanger is installed in the heat exchange chamber at a small angle to its base. t

For more effective noise absorption while ensuring the possibility of stable air passage in a wide pressure range, the system includes at least four noise absorption chambers, which include at least three plates made of sheet dense moisture-resistant material, for example, from double-sided laminated wood chipboard or cellulose board, covered on both sides with a layer of elastic material with sound-absorbing and/or heat-insulating properties, for example, porous rubber, while the plates are fixed with an offset relative to each other on the opposite walls of the chambers with the formation of gaps 5 between adjacent surfaces plates and 54 between their free sides and the walls of the chambers closest to them.

To increase the energy efficiency of the system, the circuit of the heat carrier with a liquid is connected by means of a circulation pipeline for heat exchange with a central or autonomous heating system located in the service facility, and is equipped, for example, with a hydraulically controlled valve, the circuit of the coolant with antifreeze includes, for example , a heat exchange air-liquid battery, an expansion tank with a tachogenerator and a hydraulic circular pump, and the circuit of the coolant with the coolant is made, for example, in the form of a heat pump and includes a coolant-air heat exchanger and a compressor, while

The circuit of the heat carrier with liquid is connected to the circuit of the heat carrier with antifreeze by means of a plate-c liquid-liquid heat exchanger, and the circuit of the heat carrier with antifreeze is connected to the circuit of the heat carrier with c refrigerant through a plate heat exchanger liquid-refrigerant. "» To increase the energy efficiency of the system, sensors for monitoring the temperature of supply air and exhaust air are located in front of the exhaust air duct from the service facility, in the chambers of the supply | exhaust fans, at the outlet of the supply air from the recuperative plate heat exchanger, at the inlets and outlets of the circuits of the multi-circuit heat exchanger , before and after -3 of the shut-off and regulating means, respectively, along the flow of incoming outside air and exhaust air.

To increase the convenience of maintenance, the shut-off and regulating means are made in the form of gravity-and non-return air valves, installed, respectively, before the supply and after the exhaust air ducts from the service facility. i-th To increase the convenience and manufacturability of installation and maintenance, the condensate disposal device c" is made in the form of two condensate collectors connected according to the principle of connected vessels, a water filter, a chamber hydraulic pump with a non-return valve and a pipeline for exiting the sewage system, at the same time, one condensate collector is located under the recuperative plate heat exchanger 5' | the circuit of the heat carrier with refrigerant, and the second under the circuit of the coolant with antifreeze of the multi-circuit heat exchanger. c It is desirable that the device for the disposal of condensate should include an anti-icing device, equipped with an electric heater and an ice control sensor.

In order to increase the energy efficiency of the system, the means for measuring the consumption of supply 60 external and exhaust air are made in the form of tachogenerators located at the outlet of supply external air after the noise absorption chamber and at the inlet of exhaust air in front of the noise absorption chamber.

To increase the convenience and technological efficiency of maintenance, the control system includes a control panel containing a display, a push-button keyboard and a logic controller, a remote control panel with a keyboard connected to the specified remote control, as well as a power cabinet with executive bodies, while the logic controller 65 is connected with sensors for monitoring the temperature of supply air and exhaust air, sensors for monitoring the temperature of coolants of a multi-circuit heat exchanger, tachogenerators, a sensor for monitoring ice formation and needle coronal electrodes of the ionization chamber, and through the executive bodies of the power cabinet with drives for supply and exhaust fans, an air multi-leaf valve drive, a hydraulically controlled valve coolant circuit with liquid, hydraulic circular pump of coolant circuit with antifreeze, coolant circuit compressor with refrigerant, chamber hydraulic pump and electronic heater of condensate disposal device.

The logic controller and cabinet with power executive bodies are located in the control room, and the remote control panel is located in the service facility.

The set of general and distinctive essential features of the claimed useful model allows to implement high energy efficiency in the ventilation and air conditioning system, including through the implementation of means for supplying and transferring additional thermal or cooling energy to the incoming external air in the form of a multi-circuit heat exchanger , which includes a circuit connected in series by heat exchange of a heat carrier with a liquid, connected to energy sources located in the service facility, and operating in reversible heating or cooling mode, a circuit of a heat carrier with antifreeze and a circuit /5 Heat carrier with a refrigerant. At the same time, due to the introduction of noise-absorbing chambers, making the outer surface of the central station and the inner surfaces of the chambers covered with a layer of material with sound-absorbing and heat-insulating properties, as well as fastening the supply and exhaust fan drives with the help of independent suspensions made with the possibility of eliminating vibration and resonant oscillations, it is ensured a significant reduction in the level of noise during system operation, which allows you to place it in the immediate vicinity of the service object and, due to this, additionally reduce the costs associated with laying and connecting air ducts and pipelines, as well as their further maintenance in operation. Placement in one heat exchange chamber of a plate recuperative heat exchanger, three heat exchange circuits of a multi-circuit heat exchanger, an ionization chamber and a control chamber separated from each other, for example, by means of elastic and/or rigid air-tight diaphragms with the formation of appropriate sections, and installation of two disposal devices in this chamber of condensate allow to ensure the small dimensions and compactness of the central station, the convenience and manufacturability of its installation and maintenance, as well as increased operational reliability.

Equipping chambers with means of processing supply and exhaust air with air and coolant temperature control sensors, tachogenerators and an ice formation control sensor, and their communication by "g" with the help of a control panel and a power cabinet with supply and exhaust fan drives, air multi-leaf valve drive, needle coronary electrodes of the ionization chamber, a hydraulic controlled valve of the heat carrier circuit with liquid, a hydraulic circular pump of the heat carrier circuit with antifreeze, a compressor of the heat carrier circuit with a refrigerant, a chamber hydraulic pump and an electronic heater of the device for condensate disposal allow to adjust the direction of movement, - zv Costs and temperature of supply air and exhaust air in the central station and facility with maintenance both in automatic and semi-automatic modes, which, accordingly, also increases both the energy efficiency of the system and the convenience of its maintenance.

The essence of the useful model is explained by the presented figures of the drawing: in fig. 1 shows the schematic diagram of the ventilation and air conditioning system; " in fig. 2 - schematic diagram of a multi-circuit heat exchanger; from c in fig. C - schematic diagram of the condensate disposal device; in fig. 4- scheme of the noise absorption chamber; ;" Fig. 5 is a diagram of the filtering chamber; in fig. 6- scheme of the honing fan chamber; fig. 7 - a schematic diagram of the control system. The ventilation and air conditioning system includes (Fig. 1) supply 1, 2 and exhaust Z, 4 air ducts for supply of supply air A and exhaust air B, respectively, central station 5, - connected by means of the specified air ducts 2 and Z with service object 6, and air ducts 1 and 4 with -I atmosphere 7. The central station 5 in the course of incoming external air A contains a noise absorption chamber 8, a filtering chamber 9 of incoming external air, a chamber of incoming air fan 10, a heat exchange chamber 11 connected in series with a plate recuperative heat exchanger 12, a heat carrier circuit with antifreeze 13 of a multi-circuit heat exchanger and an ionization chamber 14, a collector chamber 15 and a noise absorption chamber 16, connected to the supply air duct 2 through a means for measuring the flow of supply outside air, made in the form of a tachogenerator 17, and gravity return air valve 18.

The central station 5 in the course of the exhaust B air from the service facility b includes a gravity non-return air valve 19, a means for measuring the exhaust air flow, made in the form of a tachogenerator 20, a noise absorption chamber 21, a collector chamber 22 with a drive air multi-valve valve 23, a circuit the coolant with the refrigerant 24 of the multi-circuit heat exchanger or the lamellar recuperative heat exchanger 12 and the specified circuit 24 depending on the position of the air multi-leaf valve 23, the exhaust fan chamber 25 and the noise absorption chamber 26 connected to the atmosphere 7 through the exhaust air duct 4. With increased dustiness of the air in the service object 6, the central station 5 is mounted with an additional filter chamber 27, which is installed along the exhaust air path between the tachogenerator 20 and the noise absorption chamber 21. 65 The outer surface of the central station 5 and the inner surfaces of the chambers are covered with a layer of sound-absorbing material (not shown) with them and heat-insulating properties, for example, porous rubber, and the chambers along the flow of incoming external air A and exhaust air B are made in the form of hollow boxes connected to each other by elastic connecting flanges 28.

Noise absorption chambers 8, 16, 21 and 26 include (Fig. 1, 4) three plates 29 each, made of a dense moisture-resistant material, for example, of double-sided laminated chipboard or cellulose board with a thickness of 3 to 5 mm, covered on both sides a layer of elastic material with sound-absorbing and heat-insulating properties, for example, porous rubber. The plates are fixed with an offset relative to each other on the opposite walls of the respective chambers with the formation of gaps 6 between the adjacent surfaces of the plates 29 and gaps 5, between their free sides and the walls of the chambers closest to them, which provide the possibility of stable air passage 70 in a wide pressure range. Specified gaps 5 and 54 can be equal to each other.

The filtering chambers 9 and 27 are equipped (Fig. 1, 5) with plate filters 30 for mechanical air cleaning, each of which is made of moisture-resistant porous material that is elastically deformable, in the form of a membrane with a rectangular cross-section, located overlapping the perimeter of the chamber at an angle A to the direction of the flow of incoming external air A. The value of the angle a is 159-205,

The chambers of the supply 10 and the exhaust fan 25 (Fig. 1, 6) are equipped with radial fans 31, fixed on the shafts of the corresponding electric motors 32, which are mounted inside the specified chambers 10 and 25 with the help of independent suspensions 33, made with the possibility of eliminating vibration and resonant oscillations during operation .

The heat exchange chamber 11 (Fig. 1, 2) includes a plate recuperative heat exchanger 12 and a multi-circuit heat exchanger, which contains a circuit of a heat carrier with a liquid 34, a circuit of a heat carrier with antifreeze 13 and a circuit of a heat carrier with a refrigerant 24 connected in series by heat exchange. In the same heat exchange chamber 11, the ionization chamber 14, the Z5 control chamber and the condensate disposal device 36 are located.

The lamellar recuperative heat exchanger 12 is made of plates (not shown) 0.5 mm thick, for example, from aluminum of the AMCN-2 brand, mounted together to form cross channels (not shown) for stable passage of incoming outside and exhaust air in a wide pressure range and exclusion from mixing their streams with each other. The flat surfaces of the plates include protruding point jumpers (not shown) made of a moisture-resistant elastic material, for example, silicone, which form chaotic obstacles in the channels between the plates. The lamellar recuperative heat exchanger 12 is installed in the heat exchange chamber 11 at a small angle to its base to ensure the natural flow of condensate into the "I" device for its disposal 36.

The multi-circuit heat exchanger (Fig. 2) includes three circuits of heat carriers connected to each other by heat exchange o by means of plate heat exchangers liquid-liquid c and liquid-refrigerant E-(3. The circuit of the heat carrier with h-liquid 34 includes an inlet 37 and an outlet 38 nozzles of the circulation pipeline, which through the control hydraulic valve 39 are connected to the central or autonomous heating system (not shown) in the service facility 6. The circuit of the coolant with antifreeze 13 consists of a heat exchange air-liquid battery Ge 40, made of copper tubes with aluminum fins (not shown) and located further along the liquid coolant expansion tank 41 with a tachogenerator 42, a hydraulic circular pump 43 and two serially connected outputs of heat exchangers (z and B-03. The circuit of the coolant with the refrigerant 24 is made in the form of a thermal pump and includes a refrigerant-air heat exchanger 44 and a compressor 45. As a refrigerant in the specified circuit 70, 24 uses sia freon The air-liquid battery 40 of the heat carrier circuit with antifreeze - c 13 is connected by heat exchange with the liquid-liquid heat exchanger C of the heat carrier circuit with liquid 34 and with the liquid-refrigerant heat exchanger E-c of the heat carrier circuit with refrigerant 24. At the same time, the heat carrier circuit "» with liquid 34 is made with the possibility of operation in a reversible temperature mode, that is, both in the heating mode and in the cooling mode.

The device for the utilization of condensate Zb (Fig. 3) contains two condensate collectors 46 and 47, one of which 46 is mounted under the plate recuperative heat exchanger 12 and the refrigerant-air heat exchanger 44 - coolant circuits with the refrigerant 24, and the second 47 - under the air-liquid battery 40 of the coolant circuit with antifreeze 13. Condensate collectors 46 and 47 are connected to each other by a pipeline 48 according to the principle of connected - I vessels. Under the condensate collector 46, a device for preventing ice formation with an electronic heater sl 50 (not shown) and an ice formation control sensor 49 are mounted. The condensate disposal device 36 is also equipped with a water filter 50, a chamber hydraulic pump 51, a non-return valve 52 and a pipeline 53,

ChT" related to the sewage system. Pipelines 48 and 53 are made with heat-insulating coating.

The ionization chamber 14 includes a dielectric plate with needle coronal electrodes (not shown) connected to a high voltage source.

Located in the heat exchange chamber 11, the plate recuperative heat exchanger 12, the heat carrier circuits 13, 24 and 34 multi-circuit heat exchangers, the ionization chamber 14, the control chamber 35 and the condensate recovery device 36 are separated from each other by means of elastic and/or rigid air-tight diaphragms (not shown) .

To control the heat exchange modes in the service facility 6, the 60o air ventilation and conditioning system includes (Fig. 1, 2) sensors for monitoring the temperature T1-1T13 of the incoming outside and exhaust air and the temperature of the coolants in the multi-circuit heat exchanger, located respectively in front of the exhaust air duct Z from the service object 6, after and before the reverse gravity air valves 18 and 19, in the chambers of the supply 10 and exhaust 25 fans, at the outlet of the supply external air from the recuperative plate heat exchanger 12, at the inlet 37 and outlet 38 nozzles of the coolant circuit 65 with liquid 34, on the nozzles before and after the hydraulic circular pump 43 of the circuit of the coolant with antifreeze 13 Й between the two outputs of the heat exchangers C and E- connected in series with it, as well as on the nozzles before and after the heat exchanger of the coolant-air 44 of the circuit of the coolant with the coolant 24. Circulation of antifreeze in the corresponding circuit 13 is controlled and generator 42, located in the expansion tank 41.

Heat exchange modes are controlled by a control system (Fig. 7) connected to a single-phase or three-phase power supply network with a voltage of 220 or 380V and a frequency of 50 or 6bOHc through the power supply unit 54, which ensures its conversion to the working voltages of electrical circuits according to the type and amount of electricity (constant or alternating voltage, current amplitude and frequency) within the permissible limits, according to deviations, as well as protection against overvoltage and other emergency factors. Connections of the power supply unit 54 with objects of control and management are provided by the appropriate electrical circuit (not shown). The control system includes a control panel 55, which contains a display 56, a push-button keyboard 57 and a logic controller 58, as well as a remote control panel 59 with a keyboard connected to the control panel 55.

The control panel 55 through the logic controller 58 is connected to the temperature control sensors T 4-T4z, the ice formation control sensor 49, tachogenerators 17 and 20 and needle coronal electrodes of the ionization chamber 14.

Control objects are electric motors 32 in supply chambers 10 and exhaust fans 25, compressor 44 circuits of heat carrier with refrigerant 24, hydraulic pump of circuit of heat carrier with liquid 34 (not shown), hydraulic circulation pump 43 circuits of heat carrier with antifreeze 13, chamber hydraulic pump 51 condensate disposal device 36, control hydraulic valve 39 of the coolant circuit with liquid 34, drive (not shown) air multi-leaf valve 23 in the collector chamber 22, electric heater of the device to prevent ice formation (not shown).

Control of the specified objects can be carried out from the control panels 55 or 59 with the help of power executive bodies in the cabinet 60. The logic controller 58 and the cabinet 60 with power executive bodies are located in the control chamber 35, in which due to the natural heat exchange between the supply air and the exhaust air a stable temperature regime is maintained, corresponding to the regime in the service facility 6. The remote control panel 59 is located in the service facility 6.

The control system provides regulation of the flow direction, flow rate and temperature of supply air and exhaust air in the central station and service facility, including: - switching on the system's power circuits; - debugging mode of operation; "Ezo - automatic and semi-automatic modes of operation; - protective blocking, including temporary shutdown of the electric motor 32 in the exhaust fan chamber for the period of automatic defrosting of the recuperative plate heat exchanger 12; i- - emergency shutdown of the entire system in the event of the occurrence of relevant factors, for example, in the absence of one of the phases in the power supply network. --

The design of the ventilation and air conditioning system described in this example and presented in the drawings is not the only one possible to achieve the above-mentioned technical result and does not exclude other options for its implementation, which contain a set of design features included in the claims of the invention. For example, the central station can be made in the form of a modular or sectional design.

For example, other types of heat exchangers can be used in the heat exchange chamber. For example, fans "

May include other drives and a different design of their fastening in the cameras. For example, noise-absorbing chambers with c can be made with a different design of noise-absorbing elements. For example, the control system may include other consoles and control bodies. ;" The claimed system for ventilation and air conditioning works as follows.

Example 1. In the peak summer load period - maximum cooling of incoming outside air. The ventilation and air conditioning system is turned on from control panels 55 or 59 and continues to operate in automatic or semi-automatic modes to maintain a set comfortable temperature, for example - 209, and air exchange in the service facility 6. -And in the coolant circuit with liquid 34, connected by circular pipelines 37 and 38 with the corresponding source of thermal energy 5r in the heating system of the service facility b, the temperature control sensors T7 and Tvini automatically determine the presence of a cold liquid coolant with a temperature of -15...-20 oС and at in its presence, the control hydraulic valve 39 is fully opened. At the same time, through the heat exchanger o, heat exchange takes place between the cold liquid heat carrier of the heat carrier circuit with liquid 34 and the antifreeze of the heat carrier circuit with antifreeze 13, the temperature of which is monitored by sensors TT 9-G44, and through the heat exchanger E- O - between the antifreeze of the mentioned circuit 13 and the refrigerant of the heat carrier circuit with the refrigerant 24, which works in autonomous mode with the possibility of temperature reversal. c The incoming outside air A with a temperature of, for example, 1402, enters the central station 5 through the incoming air duct 1, where it successively passes through the noise absorption chamber 8, the filtering chamber 9, the inlet fan chamber 10 with temperature measurement by a TT sensor, the heat exchange chamber 11 with a recuperative plate heat exchanger 12, at the outlet of which the air temperature, measured by the T b sensor, decreases to approximately Zht30...-3329С, and then further decreases to 209 after passing through the heat exchange air-liquid battery 40 of the coolant circuit with antifreeze 13 due to separate or common operation of heat exchangers C and B-C in the circuits of heat carrier with refrigerant 24 and heat carrier with liquid 34.

Next, the cooled external honing air sequentially passes through the ionization chamber 14, the collector chamber 15, 65 the noise absorption chamber 16, the tachogenerator 17 and the gravity return air valve 18, which is connected to the service object 6 by the supply air duct 2.

The exhaust air B from the service object 6 with a temperature of 20...4-22 "С enters through the air duct C to the central station 5, where the gravity return air valve 19, the tachogenerator 20, the noise absorption chamber 21, the collector chamber 22, with which, in the closed position of the air multi-leaf valve 23, goes to the recuperative plate heat exchanger 12 and after it to the refrigerant-air heat exchanger 44 of the coolant circuit with the coolant 24, at the exit of which, depending on the joint or separate operation of heat exchangers C and G-C in the coolant circuits with refrigerant 24 and coolant with liquid 34, heated to k35...-4396.

Further, the exhaust air through the exhaust fan chamber 25 and the noise absorption chamber 26 enters the exhaust duct 4 70, from where it is disposed into the atmosphere 7.

In the absence of a cold liquid coolant in the circuit of the coolant with liquid 34, the control hydraulic valve 39 is in a slightly open position to exclude air jams and hydraulic shocks. In this case, based on the indicators of the temperature control sensors T and Tv located in this circuit, and sensors T42 and T4z3 installed in the coolant circuit with the refrigerant 24, the compressor 45 and 75 are turned on, the technological increase in the temperature of the exhaust air is carried out in the refrigerant-air heat exchanger 44.

Lowering the temperature of the incoming outside air to the required value is achieved by heat exchange from the heat carrier circuit with refrigerant 24 to the heat carrier circuit with antifreeze 13 through the B-o heat exchanger.

The intensity of air exchange in the service facility 6 is regulated by the indicators of the tachogenerators 17 and 20 and the temperature difference recorded by the temperature control sensors T 4 and T5, respectively, in the service facility 6 and in the exhaust fan chamber 25.

The moisture formed as a result of heat exchange on the recuperative plate heat exchanger 12 and the refrigerant-air heat exchanger 44 circuits of the heat carrier with the refrigerant 24, as well as on the heat exchange air-liquid battery 40 of the circuit of the heat carrier with liquid 13 naturally enters 285 condensate collectors 46 and 47, connected connected to each other by a pipeline 48, from where, with the help of a chamber hydraulic pump 51, through a water filter 50 and a non-return valve 52, it is discharged into the sewage system through the pipeline 53. Chamber hydraulic pump 51 works in pulse mode, which prevents it from overheating.

Example 2. In the peak winter load period - maximum heating of external air for honing. "AND

To maintain a set comfortable temperature, for example -0 9C, and air exchange in the service facility b at the outside air temperature of honing A, equal to -40 oC, the multi-circuit o heat exchanger works in reversible mode, using heat in the facility's heating system - maintenance 6 In the collector chamber 22, the multi-leaf air valve 23 is in the closed position. The course of incoming external A and exhaust B air at the central station 5 is similar to their course at peak summer load. with

To prevent ice formation in the condensate collectors 46 and 47, at the command of the ice formation control sensor 49, the electric heater in the condensate disposal device is periodically turned on. In addition, during peak periods of negative temperatures, a restriction is introduced into the control system on the use of the compressor 45 " of the coolant circuit with the refrigerant 24, controlled by the temperature sensor T 425 and an additional sensor (not shown), which can be installed at the outlet of the exhaust air from the refrigerant-air heat exchanger 44 in - with this contour. and Example 3. In the transitional spring and autumn periods, when the temperatures of the external air supply A and the exhaust B air are close, the heat transfer between their flows at the central station 5 is carried out without the participation of the recuperative plate heat exchanger 12. The multi-leaf air valve 23 in the collector chamber 22 is located in in the open position and the main flow of exhaust air enters Through the heat exchanger i.e.) coolant-air 44 circuits of coolant with coolant 24. The flow of inflow external A and exhaust B - air through the rest of the chambers of the central station 5 is similar to their flow, considered in example 1.

The proposed design of the ventilation and air conditioning system has high energy efficiency and ensures a significant reduction in the noise level during operation with small overall dimensions of sl 50 of the Central Station and the system as a whole. Research and industrial operation of the specified structure showed that with the overall dimensions of the central station no more than 2.25x2.3x1.9 m, it provides effective air exchange" and a high level of comfort in an energy-intensive service facility, in particular, in a cosmetic salon with an area of about 200 m ", which contains several rooms and is located in a residential building. The central station is located in a separate room in the immediate vicinity of the service facility without its special noise-absorbing devices, which made it possible to reduce the costs of laying air ducts and pipelines. The air productivity of the system is up to 3000-3500 m/h for both incoming outside air and exhaust air with the consumed input power of drives and exhaust fans in the range of 350...700 W, which is 2-3 times lower than their nominal power. The results of operation simultaneously confirmed the convenience and manufacturability of installation and system maintenance us, as well as Its 60 increased operational reliability.

Claims (21)

Formula of the invention bo (21) and 2007 00960 (57) 1. The ventilation and air conditioning system, which includes supply and exhaust air ducts for the supply of external supply and removal of exhaust air, a central station connected by means of the specified air ducts to the object of service and to the atmosphere, which contains at least one filter chamber, placed in the direction of the incoming outside air, the chamber of the incoming and exhaust fans, the heat exchange chamber with a recuperative plate heat exchanger equipped with a device for condensate disposal, a means for supplying and transferring additional heat or cooling energy to the incoming outside air, connected to the energy sources placed in the service objects, supply air and exhaust air temperature control sensors and shut-off and control devices, a control system made with 7/0 ability to adjust the direction of travel, flow rate and temperature of supply air and exhaust air in the central station and service facility, which is removed by the fact that the central station additionally includes noise absorption chambers, collector chambers, one of which is equipped with a drive air multi-leaf valve for controlling the flow of exhaust air, means for measuring the flow rate of incoming external and exhaust air, a means for supplying and transferring additional heat or cooling energy in supply /5 External air, located in the heat exchange chamber and made in the form of a multi-circuit heat exchanger, which includes a heat carrier circuit with a liquid, a heat carrier circuit with antifreeze and a coolant circuit with a refrigerant connected in series by heat exchange, and the last two are connected to a disposal device condensate, while in the direction of the incoming outside air in the central station there is a noise absorption chamber, a filtering chamber, an intake fan chamber, a plate recuperative heat exchanger and a heat carrier circuit with antifreeze, a collector chamber, a noise absorption chamber, a device for measuring flow supply air and a shut-off and regulating device, and a shut-off and regulating device and a device for measuring the flow of exhaust air, a noise absorption chamber, a collector chamber with a drive air multi-leaf valve and, depending on the position of the drive air multi-leaf valve, heat carrier circuit with a refrigerant or a plate recuperative heat exchanger and a heat carrier circuit with a refrigerant, an exhaust fan chamber and a noise absorption chamber. 2. The system according to claim 1, which is characterized by the fact that the central station includes an ionization chamber located along the flow of incoming outside air in the heat exchange chamber between the coolant circuit with antifreeze and the collector chamber. "E from Z. The system according to claim 2, characterized in that the ionization chamber includes a dielectric plate with needle coronal electrodes connected to a high voltage source. i am 4. The system according to any one of claims 1-3, which is characterized by the fact that the central station includes a control chamber M located in the heat exchange chamber. 5. The system according to any of claims 1-4, which is characterized by the fact that the central station includes a chamber - c5 for filtering the exhaust air, installed along its course between the means for measuring the flow of exhaust air and the noise absorption chamber. b. The system according to any of claims 1-5, which is characterized by the fact that each filtering chamber includes at least one filter for cleaning incoming outside air, made in the form of a membrane of rectangular cross-section made of moisture-resistant porous material that is elastically deformed, "located overlapping the perimeter of the corresponding cameras at an angle o; to the direction of the air flow. from the village 7. The system according to any of claims 1-6, which is characterized by the fact that the outer surface of the central station and the inner surfaces of the cameras are covered with a layer of material with sound-absorbing and heat-insulating properties, for example, porous rubber. 8. The system according to any of claims 1-7, which is characterized by the fact that the chambers of the central station in the course of incoming external and exhaust air are made in the form of hollow boxes connected to each other, for example, by means of elastic connecting flanges. 9. The system according to any of claims 1-8, which is characterized by the fact that in the heat exchange chamber, the plate-regenerative heat exchanger, the coolant circuits of the multi-circuit heat exchanger, the ionization chamber and the control chamber are separated from each other by means of elastic and/or rigid airtight diaphragms with 5 years by the formation of the relevant sections. others 10. The system according to any of claims 1-9, which differs in that the chambers of supply and exhaust fans Ta" are equipped with radial fans fixed on the shafts of the corresponding drives, for example, electric motors, while the drives are mounted inside the said chambers with the help of independent suspensions, made with the possibility of eliminating vibration and resonant oscillations during operation. 11. The system according to any one of claims 1-10, which is characterized by the fact that the lamellar recuperative heat exchanger is made of plates, for example, of aluminum, mounted together to form cross and exhaust channels with the possibility of stable air passage in a wide pressure range and the exclusion of mixing supply air and exhaust air between themselves, while the flat surfaces of the plates include protruding point jumpers made of moisture-resistant elastic material, for example silicone, which form chaotic obstacles in both the supply and exhaust channels between the plates. 12. The system according to any one of claims 1-11, which is characterized by the fact that the plate recuperative heat exchanger is installed in the heat exchange chamber at a small angle to its base. 13. The system according to any one of claims 1-12, which is characterized by the fact that it includes at least four noise absorption chambers, which include at least three plates made of sheet dense moisture-resistant material 65, for example, from double-sided laminated wood-chipboard, with their coating on both sides with a layer of elastic material with sound-absorbing and/or heat-insulating properties, for example, porous rubber, while the plates are fixed with an offset relative to each other on the opposite walls of the chambers with the formation of gaps 5 between the adjacent surfaces of the plates and 5.4 and between their free sides and those closest to them by the walls of the cells. 14. The system according to any of claims 1-13, which is characterized by the fact that the circuit of the heat carrier with liquid is connected by means of a circulation pipeline for heat exchange with the central or autonomous heating system of the service facility and is equipped, for example, with a hydraulically controlled valve, the circuit of the heat carrier with antifreeze includes, for example, a heat exchange air-liquid battery, an expansion tank with a tachogenerator and a hydraulic circular pump, and the coolant circuit with the refrigerant is made, for example, 7/0 In the form of a heat pump and includes a refrigerant-air heat exchanger and a compressor, while the circuit of the coolant with fluid is connected to the heat carrier circuit with antifreeze using a liquid-liquid plate heat exchanger, and the coolant circuit with antifreeze is connected to the heat carrier circuit with refrigerant through a liquid-refrigerant plate heat exchanger. 15. The system according to any of claims 1-14, which is characterized by the fact that the sensors for monitoring the temperature of supply 7/5 External and exhaust air are located in front of the exhaust air duct from the service facility, in the chambers of the supply and exhaust fans, at the outlet of the supply external air from the recuperative plate heat exchanger, at the inlets and outlets of the circuits of the multi-circuit heat exchanger, before and after the shut-off and regulating means, respectively, along the supply air and exhaust air. 16. The system according to any one of claims 1-15, which is characterized by the fact that the closing and regulating means are made in the form of gravity return air valves installed, respectively, before the supply and after the exhaust air ducts from the service facility. 17. The system according to any one of claims 1-16, which is characterized by the fact that the condensate disposal device is made in the form of two condensate collectors connected according to the principle of connected vessels, a water filter, a chamber hydraulic pump with a non-return valve and a pipeline for exit into the sewage system, while one condensate collector is located under the plate recuperative heat exchanger and the heat carrier circuit with refrigerant, and the second - under the heat carrier circuit with antifreeze of the multi-circuit heat exchanger. WITH 18. The system according to any one of claims 1-17, characterized in that the condensate disposal device includes an ice formation prevention device equipped with an electronic heater and an ice formation control sensor. "AND 19. The system according to any one of claims 1-18, which is characterized by the fact that the means for measuring the flow of incoming and exhaust air are made in the form of tachogenerators located at the outlet of incoming and external air after the noise absorption chamber and at the inlet of exhaust air in front of the noise absorption chamber. uh- 20. The system according to any one of claims 1-19, which is characterized by the fact that the control system includes a control panel containing a display, a push-button keyboard, a logic controller connected to the specified remote control, a remote control panel with a keyboard, and also a power cabinet with executive bodies, at the same time a logic controller. su is connected to sensors for monitoring the temperature of the supply and exhaust air, sensors for controlling the temperature of the coolants of the multi-circuit heat exchanger, tachogenerators, the sensor for controlling ice formation and needle coronal electrodes of the ionization chamber, and through the executive bodies of the power cabinet - with the drives of the supply and exhaust fans, the drive of the air multi-blade valve, "hydraulic controlled valve of the circuit of the heat carrier with liquid, hydraulic circular pump of the circuit of 8 s heat carrier with antifreeze, heat pump of the circuit of heat exchange with refrigerant, chamber hydraulic and pump and electronic heater of the condensate disposal device. "" 21. The system according to claim 20, which is characterized by the fact that the logic controller and the cabinet with power executive bodies are located in the control chamber, and the remote control panel is located in the service facility. Head of department V.A. Melnyk Performer M.I. Yatsenko - -I p 50 "z" p 60 b5