RU2453774C2 - Conditioning system with heat-exchange devices - Google Patents

Abstract

FIELD: ventilation.

SUBSTANCE: in a conditioning system with heat-exchange devices, comprising heat-exchangers installed serially at the supply, a mixing chamber of external recirculation air, an irrigation chamber, a fan, a sensor to monitor enthalpy of supply air, an air valve to control supply of recirculation air, valves of seasonal switching, a heated water pump, a pump of water cooled by evaporation, a cooling tower, connection pipelines, a water heat exchanger to use waste heat of process water and an automatic valve to control flow of cooled water, the irrigation chamber is arranged in the form of a rotor heat mass exchanger and comprises an inlet and outlet nozzles arranged in a body, rotary discs fixed on the shaft, the lower part of which is in a tray with water, besides, discs are fixed to each other by pins via orifices and arranged from a properly soaked material with thickness of 0.5…1 mm, and the shaft with discs rotates along with air travel with frequency of 4…24 min-1 from a motor; besides, discs may be arranged as corrugated or flat in shape, and in the body there are protective canopies to reduce drop entrainment, and the body of each nozzle is hollow, axisymmetric, the axis of which is perpendicular to the axis of the header pipe hole, and the body shape is in the form of a solid of revolution formed by a curve of the second order, for instance, spherical, in the form of a truncated ellipsoid or paraboloid of revolution, and at the side of the flow hole of the header pipe in the nozzle there is a straightening element arranged in the form of a ring having a central bushing, with which at least three blades are rigidly connected as radially arranged and connected to the nozzle body, besides, the body is arranged with two ledges oppositely arranged to the axis of the nozzle, by means of which via yokes with locks the nozzle is fixed on the header, at the same time in the lower part of the nozzle body there is a conical throttling hole connected to a mixing chamber, which is installed between the throttling hole and the straightening element, and on the inner surface of the mixing chamber there are helical grooves.

EFFECT: higher efficiency and reliability of heat and moisture treatment of air in winter period of time.

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Description

The invention relates to techniques for air conditioning and ventilation and can be used to create comfortable microclimate conditions in domestic, administrative and industrial premises.

The closest technical solution to the claimed object is the air conditioning system according to the patent of the Russian Federation No. 2291356, class. F24F 5/00 (prototype) comprising an air conditioner with sequentially arranged heat exchangers, a fan, an evaporative cooling apparatus and a fan cooling tower.

Its disadvantage is the relatively low efficiency of the process of heat-moisture treatment of air in the winter period of time.

The technical result is an increase in the efficiency and reliability of heat-moisture treatment of air in the winter period of time.

This is achieved by the fact that in an air conditioning system with heat exchangers containing successively installed heat exchangers on the inlet, an external recirculation air mixing chamber, an irrigation chamber, a fan, a supply air enthalpy sensor, a recirculation air control air valve, seasonal switching valves, a heated water pump , evaporated cooling pump, cooling tower, connecting piping, water heat exchanger for using waste heat t of technological water and an automatic valve for regulating the flow of chilled water, the irrigation chamber is made in the form of a rotary heat and mass exchanger and contains inlet and outlet nozzles located in the housing, rotating disks mounted on the shaft, the lower part of which is in a pan with water, and the disks are fastened together by pins through the washers are made of well-wettable material with a thickness of 0.5 ... 1 mm, and the shaft with discs rotates along the air with a frequency of 4 ... 24 min ^-1 from the engine; moreover, the disks can be made corrugated or flat in shape, and there are protective visors in the case to reduce droplet drop, and the body of each nozzle is hollow, axisymmetric, whose axis is perpendicular to the axis of the collector tube hole, and the shape of the body is made in the form of a rotation body formed a second-order curve, for example, spherical, in the form of a truncated ellipsoid or paraboloid of revolution, and on the side of the flow opening of the manifold pipe, a straightening element is installed in the nozzle, made in the form a ring having a central sleeve to which are rigidly connected, at least three blades radially spaced, connected to the nozzle body, the body being made with two, opposite, perpendicular to the nozzle axis, ledges, through which the nozzle is secured to the nozzles through locks collector, while in the lower part of the nozzle body there is a conical throttle hole connected to the mixing chamber, which is located between the throttle hole and the straightening element, and on the inside the surface of the mixing chamber has helical grooves.

Figure 1 shows a schematic diagram of an air conditioning system with heat exchangers, figure 2 is a General view of the nozzle of the cooling tower irrigation unit.

The air conditioning system with heat exchangers (Fig. 1) contains successively installed heat exchangers 1 on the supply side, a mixing chamber 2 for external recirculated air, an irrigation chamber 3 in the form of a rotary heat and mass exchanger, a fan 4, a supply air enthalpy control sensor 5, an air valve 6 for regulating the recirculated air intake , seasonal switching valves 7, heated water pump 8, evaporated cooling pump 9, cooling tower 10 with an irrigation unit consisting of a collector 20 and nozzles 21, as well as connecting piping 11, the water heat exchanger 12 to use the waste heat of the process water, the automatic valve 13 regulating the chilled water flow rate adjustment valve 14 of the supply.

The rotary heat and mass exchanger, which is an irrigation chamber, contains rotating disks 15 fixed to the shaft, while the lower part of the disks 15 is in a pan 16 with water. The disks 15 are made of a well-wettable material (duralumin, plastic with a rough skim surface, etc.) with a thickness of 0.5 ... 1 mm. A shaft with disks 15 rotates from the engine 19 through a belt or chain gear 17; at a lower frequency, incomplete wetting of the disks 15 is observed, and at a higher frequency, droplets are dropped from the surface of the disks. The shape of the discs 15 can be made corrugated to increase the contact surface of heat and mass transfer, and the corrugations in shape can be made in the form of a polygon, sinusoid, semicircle (not shown). Between themselves, the disks 15 are fastened with studs with dividing washers (not shown in the drawing). Protective visors 18 are located in the irrigation chamber 3 to reduce droplets.

Each of the collectors 20 of the irrigation unit has a flow hole 22 and is equipped with nozzles 21 (figure 2). Each of the nozzles 21 is made in the form of a hollow, axisymmetric body 23, the axis of which is perpendicular to the axis of the hole of the collector, and in shape the body is made in the form of a body of revolution formed by a second-order curve, for example, spherical, in the form of a truncated ellipsoid or rotation paraboloid, etc. On the side of the flow-through opening 22 of the manifold pipe 5, a straightening element 27 is installed in the nozzle, which dampens the turbulence of the fluid flow from the manifold 5 to the nozzle. The straightening element is made in the form of a ring having a central sleeve 27, with which at least three vanes 28 are radially spaced and connected to the nozzle body 23. The housing 23 is made with two opposite steps, perpendicular to the axis of the nozzle, with ledges 26, by means of which, through the clamps 24 with the locks 25, the nozzle is fixed to the manifold 5. In the lower part of the nozzle body 23 there is a conical calibrated throttle hole 30 connected to the mixing chamber 29, which located between the hole 30 and the straightening element 27. The mixing chamber 29 is designed to form a vortex turbulent flow formed at the outlet of the nozzle hole 30. For this purpose, there are helical grooves (not shown in the drawing) on the inner surface of the mixing chamber, which can be formed by turning by copying, or obtained by injection molding. As a result of this, a finely dispersed and uniform jet of liquid is formed at the outlet of the nozzle. The flow characteristic of the nozzle is presented in figure 3. The recommended pressure range for a single-nozzle nozzle is from 1.2 to 7.0 meters of water. With this pressure range, the nozzle plume is fully opened and filled with drip moisture.

The air conditioning system with heat exchangers operates as follows.

Heat exchangers 1 are installed in the supply duct, the tubes of which are supplied with water after its evaporative cooling in the fan tower 10. Heat exchangers 1 are connected by pipelines to the fan tower 10 mounted on the roof of the building. Outside air with a wet thermometer temperature, which is the limit of evaporative cooling of water, is sucked into the cooling tower by an axial fan. The temperature of the water cooled by evaporation is always lower than the temperature of the wet thermometer.

Cooled by evaporation of water is taken by the pump 9 and through the connecting pipes 11 is supplied to the tubes of the heat exchanger 1 in the air handling unit. During operation of the fan 4, the supply air is moved through heat exchangers.

The nozzle 21 of the irrigation unit of the cooling tower 10 operates as follows.

Liquid under pressure enters from the nozzle 5 through the orifice 22 and encounters a straightening element 27, which dampens the turbulence of the fluid flow from the manifold 5 to the nozzle. The mixing chamber 29 is intended for the formation of a vortex turbulent flow formed at the outlet of the nozzle opening 30. For this purpose, there are helical grooves on the inner surface of the mixing chamber (not shown in the drawing), as a result of which a finely dispersed and uniform liquid spray is formed at the outlet of the nozzle. The flow characteristic of the nozzle is presented in figure 3. The water flow through the nozzle (m ³ / h) is determined by the following formula:

,

,

where N is the pressure of the water in front of the nozzle (mm of water. Art.).

Excessive pressure in front of the nozzles usually indicates clogging and the need to clean them.

The rotary heat and mass exchanger of the irrigation chamber 3 works as follows. The processed air enters the heat and mass exchanger to the rotating disks 15, passes in the slotted channels between them and goes to the outlet pipe. The lower part of the rotor disks is located in the pan 16 with water, therefore, when the rotor rotates, a thin film of water is formed on the surface of the disks, with which the air flow interacts. The rotor rotates in the air flow with a frequency of 4 ... 24 min ^-1 , since at a lower frequency incomplete wetting of the disks is observed, and at a higher frequency, droplets drop off the surface of the disks 15. When the rotor rotates along the air, a film of water spreads over the surface of the disks under the action of the flow air and is kept without droplet drop at a speed in a live section of 11-17 m / s (depending on the size of the gap between the disks), and with a decrease in the gap, the maximum speed increases. With good quality manufacturing and assembly, the rotor rotates with a frequency of 6 ... 9 min ^-1 under the influence of an incoming air flow. A constant water level in the pan is maintained by replenishing tap water from the pipeline (not shown in the drawing). A pump for this treatment mode is not required at all. In polytropic heating or cooling processes, it is necessary to supply and remove warm or cold water from the sump using a pump, but the required pump head will be very small. The efficiency of heat and mass transfer in the isoenthalpic mode is quite high, and with an increase in the gap between the disks, the efficiency coefficient decreases, and with an increase in diameter. This is explained by the following: thus, with an increase in the gap, the efficiency coefficient does decrease, however, the specific amount of apparent heat transferred from air to water from a unit surface area of the disks increases, i.e. the heat transfer coefficient also increases, which is explained by an increase in the turbulence of the air flow. When changing the diameter of the disks, the specific surface area of the transfer, the throughput of the apparatus and its aerodynamic resistance, change. Therefore, when choosing the diameter of the rotor and the size of the gap between the disks, it is necessary to perform technical and economic calculations. To change the heat treatment mode of the supply air, the circuit provides switching valves 7 on the pipelines 11 and a water heat exchanger 12 for heating the waste heat of the recirculated water. The proposed air conditioning system with heat exchangers is essentially a supply system in which heat exchangers are used in summer for indirect evaporative cooling, and in winter for heating the supply air, which makes it possible to efficiently use waste and cheap low-temperature heat sources in the form of process water or reverse heat supply for heating the supply air water.

Claims (1)

An air conditioning system with heat exchangers, containing successively installed heat exchangers on the supply, an external recirculation air mixing chamber, an irrigation chamber, a fan, a supply air enthalpy control sensor, a recirculation air control air valve, seasonal switching valves, a heated water pump, a water cooled chilled water pump, cooling tower, connecting pipelines, water heat exchanger for the use of waste heat of process water and cars a chilled water flow control valve, and the irrigation chamber is made in the form of a rotary heat and mass exchanger and contains rotating disks fixed to the shaft, the lower part of which is located in a water tray, the disks being fastened to each other with pins through washers and made of 0.5 well-wetted material -1 mm, and the shaft with disks rotates along the air with a frequency of 4-24 min ^-1 from the engine; moreover, the disks can be made corrugated or flat in shape, and there are protective visors in the case to reduce droplet drop, and the liquid tray is connected to the pipeline with a ball valve and an overflow pipe, characterized in that the body of each nozzle is hollow, axisymmetric, whose axis perpendicular to the axis of the hole of the manifold pipe, and the shape of the body is made in the form of a body of revolution formed by a second-order curve, for example spherical, in the form of a truncated ellipsoid or paraboloid of revolution, and with on the side of the flow hole of the manifold pipe, a straightening element is installed in the nozzle, made in the form of a ring having a central sleeve, to which at least three blades radially arranged at least three blades connected to the nozzle body are rigidly connected, the body being made with two steps opposite to the nozzle axis perpendicular to the nozzle axis by means of which, through clamps with locks, the nozzle is fixed to the manifold, while in the lower part of the nozzle body a conical throttle hole is made, connected with a mixing chamber, which is located between the throttle hole and the straightening element, and on the inner surface of the mixing chamber there are helical grooves that are formed by turning by copying, or obtained by injection molding, while the pressure range is in the optimal range of values: from 1.2 to 7.0 meters of water, while the flow rate through the nozzle (m ³ / h) is determined by the following formula:

where N is the pressure of the water in front of the nozzle (mm water. Art.).

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