RU2789397C1 - Heat or cold regenerator of ventilation air - Google Patents

Abstract

FIELD: air conditioning.

SUBSTANCE: invention relates to the field of air conditioning, ventilation equipment for the regeneration of heat or cold of the outgoing air from the room. The heat or cold regenerator of the ventilation air includes two vertical heat exchange columns for supplying air from the room to one of them, from the outside to the other, partially filled by a heat exchange nozzle, and pipelines with an intermediate coolant, as which a solution of calcium chloride of the calculated concentration is used, for sequential supply to the heat exchange columns through sprinklers buried in the nozzle in counterflow to the supplied air, as well as air fans and pumps for saline solution. The calculated concentration is chosen taking into account the known data on the dependence of the humidity of the air above the CaCl₂ solution on the salt concentration, as well as on the normative humidity of the indoor air and the temperature and humidity of the outdoor air. According to the invention, the supply of warm and cold air flows is carried out at the entrance of each of the corresponding columns from the bottom up, and pipelines with an intermediate coolant each connecting the lower part of one of the columns with the upper part of the other column, with the possibility of supplying coolant from top to bottom of both columns alternately, through sprinklers buried in the nozzle, so that the saline solution is not carried away by the air flow, and flows down the nozzle of one column, exchanges heat with the air flow and is piped to the upper part of the other column. A solution of calcium chloride (CaCl₂) of the calculated concentration is used as an intermediate coolant. The concentration of calcium chloride solution is selected taking into account the provision of a standard range of humidity for residential premises, as well as seasonal changes in outdoor air temperature.

EFFECT: increase in the efficiency of the ventilation air regenerator.

3 cl, 1 dwg

Description

Ventilation air heat or cold regenerator refers to ventilation technology for utilizing the heat or cold of the outgoing air from the premises and for heating or cooling the air entering from the street.

With the development of energy saving technologies in ventilation and air conditioning systems, recuperators and air regenerators are increasingly being used - devices for exchanging thermal energy between exhaust and supply air.

The main function of these devices is to reduce energy costs for heating or cooling the supply air, while the flows should not mix, that is, the supply air should not be polluted by the exhaust air. In ventilation and air conditioning systems, such energy savings are relevant both in winter and in summer.

Known design of the heat exchanger with an intermediate heat carrier, in which in a conventional plate heat exchanger the exhaust air gives off its heat to the intermediate heat carrier, and in the second heat exchanger this intermediate heat carrier gives off its heat to the supply air.

Such devices have two key advantages. Firstly, they make it possible to implement the principles of recuperation for separate and even remote supply and exhaust units. Secondly, they can be supplemented with existing ventilation systems, which initially did not include recuperation devices.

Thus, the heat exchanger with an intermediate heat carrier consists of two heat exchangers installed, respectively, in the supply and exhaust ventilation systems, which are connected by pipelines to the intermediate heat carrier.

A device for room ventilation is known, according to patent RU2313733, in which the device is mounted in a frame opening and includes a pipe for removing used air from the room and a pipe for entering fresh air into the room. The device is equipped with a heat pipe with a working fluid (intermediate heat carrier), the evaporative part of which is fixed inside the pipe to remove used air from the room, and the condensing part is inside the pipe for fresh air to enter the room. Gate valves are installed at the ends of both pipes. To turn the device on, the valves are opened, the used warm air rushes through the pipe from the room to the outside, and the cold outside air into the room. In a heat pipe, the working fluid is heated by the warm used air passing through the pipe and evaporated. Vapors of the working fluid move along the heat pipe and enter its condensing part, where they give off heat to the outside air entering the room through the outer pipe and condense. The condensate of the working fluid moves through the capillary structure fixed on the inner surfaces of the heat pipe to its evaporative part. The heat carrier of heat pipes works on the principle of heat carrier evaporation in the hot part and condensation in the cold one. The process is repeated. Thus, the device for ventilation of the room does not require additional energy, but the efficiency of such a device is not sufficient.

A device for heat recovery of exhaust air is known, according to patent RU2655907, which contains a supply heat-extracting plate heat exchanger, at the inlet of which a supply fan is installed, and an exhaust heat-releasing plate heat exchanger with an exhaust fan. The heat exchangers are connected by pipelines through which antifreeze (intermediate coolant) circulates during pump operation. A frequency converter connected to the control device is connected to the pump. This extract air heat recovery unit has a complex structure.

The main purpose of the ventilation system when using recuperative or regenerative heat exchangers is to provide the necessary amount of fresh air, remove harmful substances, bacteria, moisture and dust from the room. Typically, the main requirements for such devices are: high efficiency, simple design, the ability to remove moisture from the heat exchanger, condensed from the exhaust air flow, reliability in conditions of negative outdoor temperatures. These requirements are largely met by new designs of regenerators with drip irrigation and an intermediate coolant.

Known recuperators with an intermediate coolant, where water or saline solutions are used, which can reduce the intensity of evaporation processes and increase the efficiency of the heat exchanger. Salt solution, being an intermediate heat carrier, rather effectively cools the air in one column and heats the air in another.

By changing the concentration of the saline solution, you can control the humidity of the air entering the room. The use of saline solutions allows the heat exchanger to operate at negative outside temperatures without freezing.

For the prototype, the method of ventilation heat recovery according to the application for the invention RU2010121465 was chosen. Ventilation heat recovery method includes heat transfer by means of heat exchangers in the form of two cassettes with expanded clay nozzle, one of which is washed by cold air, the other by warm air, and circulation of an intermediate heat carrier for heat transfer between heat exchangers. According to the invention, the packing in both cassettes is irrigated with a circulating liquid intermediate heat carrier that is in direct contact with air: from the cassette flushed with cold air, the heat carrier is supplied to irrigate the nozzle of the cassette flushed with warm air, and the coolant from the cassette flushed with warm air is fed to irrigate the nozzle cassette, washed by cold air. A saturated sodium chloride solution is used as an intermediate heat carrier.

The disadvantage of the prototype is the use of a saturated solution of common salt, which does not sufficiently provide the required efficiency of the specified method.

The task of the proposed regenerator of heat or cold ventilation air is to increase the efficiency of its operation.

The positive effect occurs due to the reduction of evaporation of water from the salt solution when using calcium chloride (CaCl ₂ ); regulation of the humidity of the incoming air, by changing the concentration of salt in the solution.

The technical solution is provided by the fact that the heat or cold ventilation air regenerator includes two vertical heat exchange columns, for supplying indoor air from the room into one of them, and outdoor air from the street into the other, filled with a heat exchange nozzle and pipelines with an intermediate heat carrier in the form of a saline solution , fed sequentially to the columns from top to bottom through irrigators in counterflow to air supplied from bottom to top, as well as air fans and brine pumps. As a heat exchange nozzle, for example, expanded clay gravel or Raschig rings can be used. According to the invention, the columns are partially filled with a packing limited by a grate at the bottom, and sprinklers are placed in the upper part under the packing layer for supplying an intermediate heat carrier in the form of a solution of calcium chloride (CaCl ₂ ) of the calculated concentration. The concentration of calcium chloride solution is chosen taking into account the normative range of humidity for residential premises, as well as seasonal changes in outdoor air temperature.

In order for the intermediate heat carrier (calcium chloride saline solution) not to be carried away by the flow of oncoming air, the sprinklers are partially buried under the packing layer.

The concentration of calcium chloride solution (CaCl ₂ ) is determined by calculation, taking into account the standard air humidity in the living room and the outside temperature. (GOST 30494-2011 "Residential and public buildings. Indoor microclimate parameters", SP 131.13330.2012 "Construction climatology". Updated version of SNiP 23-01-99 *).

Fig. - shows a diagram of a regenerator for heat or cold ventilation air with an intermediate heat carrier and drip irrigation. The regenerator contains two vertical heat exchange columns 1, 2; grids 3 installed at the bottom of columns 1 and 2, holding the heat exchange nozzle 4, partially filling the heat exchange columns 1 and 2; sprinklers 5 and 6 under the packing layer 4; pipelines with intermediate coolant 7 and 8; air fans 9 and 10; pumps 11 and 12 for an intermediate heat carrier in the form of a salt solution of calcium chloride.

The ventilation air heat or cold regenerator consists of two heat exchange columns 1, 2, installed in the lower part of the lattice columns 3, holding the heat exchange nozzle 4 partially filling the columns 1 and 2. In each column 1 and 2, the air flow is supplied from the bottom upwards by air fans 9 and 10 and is pumped through the heat exchange nozzle 4: one column 1 is pumped by the air flow from the room, the other 2 is pumped by the air from the street. In each of the columns, in the upper part of the heat exchange nozzle 4, through the buried sprinklers 5 and 6, pumps 11 and 12 supply a solution of calcium chloride salt, which flows down the nozzle 4 from top to bottom, exchanging heat on the surface of the nozzle with the air flow coming from bottom to top and then through pipeline 7 is supplied by a brine pump 11 to the top of another column 1, and through pipeline 8 is supplied by a brine pump 12 to the top of column 2. The calcium chloride salt solution is an intermediate heat carrier that cools the air in one column and heats the air in another.

Sprinklers 5 and 6 are partially buried under a layer of heat exchange nozzle 4, each column to reduce the entrainment of salt solution by the flow of oncoming air.

Regenerator heat or cold ventilation air works as follows.

The description is based on experimental laboratory studies carried out at the Institute of Thermal Physics of the Siberian Branch of the Russian Academy of Sciences. The experiments were carried out on laboratory equipment.

A cycle of experimental studies was carried out on a prototype regenerator. The regenerator consisted of two heat exchange columns 0.4 m high with a cross section of 0.2 × 0.2 m ² filled with expanded clay gravel packing with an average grain size of 7 mm. As an intermediate heat carrier, a solution of calcium chloride (CaCl ₂ ) with a mass salt concentration of 26%-28% was used. A solution of this concentration does not freeze at temperatures of -36°С ÷ -41°С, in addition, it has another important advantage that the maximum air humidity above this solution does not exceed 60% -70% relative humidity, which prevented excess moisture entering the room air and increased the thermal efficiency of the regenerator. In the experiments, the air flow through the heat exchange columns was maintained constant and amounted to 110 m ³ /hour, and the flow rate of the salt solution varied from 30 l/hour to 60 l/hour. C, and into the cooling column - from the room at a temperature of about +25°C.

Heating and cooling of air in each heat exchange column is characterized by temperature efficiency, which is determined by the ratio of the absolute value of the air temperature difference at the inlet and outlet of the heat exchange column to the temperature difference between the air temperature in the room and on the street.

In the heating column, the temperature efficiency weakly depended on the flow rate of the intermediate coolant and amounted to 57% - 58%. The cooling tower saw an increase in efficiency as the brine flow rate increased from 49% to 60%. At the same time, the average thermal efficiency of the regenerator increased from 53% to 59% due to an increase in the efficiency of the cooling column.

In the experiments, by changing the concentration of the salt solution of the intermediate heat carrier, the humidity of the air entering the room was regulated.

The technical result of the proposed device for heat or cold ventilation air regenerator.

Advantages of using a calcium chloride solution compared to a saturated common salt solution:

1. As experimental studies have shown, in the cold season, when using this type of regenerator with a saturated sodium chloride solution to heat the air coming from the street due to the air leaving the room, the heating efficiency decreases due to the process of moisture evaporation, which leads to additional cooling of the air and a decrease in efficiency of the regenerator. The use of a calcium chloride solution instead of a saturated common salt solution makes it possible to reduce the intensity of evaporation processes and increase the efficiency of the regenerator.

2. By changing the concentration of the calcium chloride solution, it is possible to regulate the humidity of the air entering the room.

3. The use of a calcium chloride solution allows the regenerator to operate in winter at outdoor temperatures down to -40°C, and on a saturated sodium chloride solution - up to -25°C.

Claims (3)

1. Regenerator of heat or cold ventilation air, including two vertical heat exchange columns for supplying indoor air from the room into one of them, and outdoor air from the street into the other, filled with a heat exchange nozzle, and pipelines with an intermediate heat carrier in the form of a saline solution supplied sequentially to heat-exchange columns from top to bottom through irrigators in counterflow to the air supplied from the bottom up, as well as air fans and pumps for salt solution, characterized in that the heat-exchange columns are partially filled with a heat-exchange nozzle limited from below by a grate, and in the upper part under the nozzle layer there are irrigators for supplying an intermediate coolant. 2. Regenerator of heat or cold ventilation air according to claim 1, characterized in that calcium chloride solution (CaCl ₂ ) of calculated concentration is used as a heat carrier, selected with the possibility of providing a standard range of humidity for residential premises. 3. The ventilation air heat or cold regenerator according to claim 1 or 2, characterized in that the concentration of calcium chloride solution is chosen with the possibility of taking into account seasonal changes in outdoor air temperature.

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