SU946646A1 - Coating for hydroscopic material of regenerative heat exchangers /its versions/ - Google Patents

Description

The invention relates to the manufacture of coatings for hygroscopic materials of regenerative heat exchangers and can be used in adsorption technology, in air conditioning systems, ventilation, drying and heat trapping,

Hygroscopic nozzles for rotating regenerative heat exchangers (ART) are known, by means of which heat-and-moisture trapping of ventilation systems and air conditioning systems takes place. Hygroscopic tailings are made of sheets of corrugated cardboard, paper, asbestos, plastics, and similar adsorption materials that form ducts or passages for air.

In order to increase the adsorption properties that contribute to the intensification of heat and mass transfer processes, these nozzle materials are coated with a layer of more active substances. Aqueous solutions of hygroscopic salts of lithium chloride, lithium bromide, calcium chloride, etc. are used as coatings in the adsorption technique and ventilation. Cl.

Closest to the proposed technical essence and the achieved result is a coating for hygroscopic material of regenerative heat exchangers, including a solution of lithium chloride in water 2I.

A disadvantage of the known coating is that as the temperature decreases, the hygroscopic properties of the adsorption material deteriorate, heat exchangers with these coatings cannot operate at temperatures below -25 ° Cf, which limits their use in ventilation and air conditioning systems in the northern regions.

The purpose of the invention is to enable the operation of heat exchangers at ambient temperature.

20 below -25 ° C without reducing the efficiency of heat trapping.

This goal is achieved by the fact that the coating for a hygroscopic material of regenerative heat exchangers, B1; including 0.3-0.7 wt.% Lithium chloride, 6.0-8.0% hydroethyl cellulose and water in one embodiment, and 0.3 -0.7% lithium chloride, 21.023, 0% polyvinyl acetate emulsion and

30 water - in another embodiment, the coating

additionally contains 6.0-8.0 wt.% hydroethylcellulose in the first embodiment, in the second embodiment, 21.0-23.0% of the polyvinyl acetate emulsion.

Coatings are made as follows.

The lithium chloride is dissolved in water and, with continuous stirring, poured into hydroxyethyl cellulose or a polyvinyl acetate emulsion. The resulting composition is applied in a thin layer on corrugated cardboard used in regenerative heat exchangers. The impregnated material is dried at 60-70CC for 15 minutes.

In order to determine the optimal ratio of components in the proposed versions of the coating, experiments were conducted to establish the hygrostatic and hygrodynamic characteristics of cardboard covered with various compositions. The studies were carried out according to the method, according to which the hygrostatic properties of the adsorbents are characterized by the value of U, the specific moisture content at the time of completion of the adsorption monolayer, kg / kg. The hydrodynamic properties of adsorbents are characterized by the value of ftq — the mass transfer coefficient at the time of completion of the adsorption monolayer formation, kg-mol / msJ.

In tab. Table 1 shows the results of testing the specific moisture content and mass transfer coefficient for samples of coatings according to the proposed solution and the prototype {nn. ).

Polyvinyl acetate

emulsion (PVA) -21%,

water - 78.8% chloride

lithium - 0.3%

PVA -.22.5%, water - 77% lithium chloride - 0.5%

PVA - 23%, water - 76.3 lithium chloride - O, (57%

Hydroethylcellulose

(HEC) - 6%, water - 93.5%

Have

HEC - 7; 5%, water - 92% lithium chloride - 0.5% lithium chloride - 0.5

From tab. 1 that the optimum hydrodynamic characteristics of the coating compositions are the pattern of the adsorbent p varies Nets 2 and 5. Significantly, since it is mainly

When the content in the solution is poly-determined by the microstructure of the body, the concentration of nitrate emulsion. Increasing the concentration of chloride by 22.5% and hydroethylcellulose - by 7.5% to –60% over 0.5%, the maximum value of adsorption is accelerated, but desorption is deteriorated. .Policy and With a further increase, this accepted optimal concentration of polyvinyl acetate emulsion is 0.5%. Coating in the form of water sap and hydro carbonaceous cellulose in a solution of pure lithium chloride solution has been observed to decrease U. j 65 have lower power factor 10 10

10 10

state content in mass transfer (pp. 7-9). In addition, lithium chloride is not applicable when the outside air temperature is below -25 s. The mechanical properties of the coating are determined by that at. when applied to a cardboard, the solution is absorbed and stiffens the cardboard. It is impossible to separate the coating from the cardboard. Hygienic contraindications for the use of hydroethylcellulose and polyvinyl acetate emulsion, and 10 also lithium chloride in the indicated concentrations are not available.

The use of polyvinyl acetate emulsion or hydroethyl cellulose is advisable mainly by the presence of these components, as well as by the fact that the process of sorption and desorption of moisture by cardboard coated with hydroethyl cellulose is faster, as can be seen from a comparison of the ftf value.

In tab. Figure 2 shows the results of tests of the efficiency of heat trapping of a regenerative heat exchanger (TO) at an air load of 3000 MV4.

table 2

Claims (2)

The claims 50 1. A coating for the hygroscopic material of regenerative heat exchangers, including lithium chloride and water, characterized in that 55, in order to ensure that the heat exchangers can operate at an ambient temperature below -25 ° C without reducing the heat and moisture absorption efficiency, the coating additionally contains hydroethyl cellulose in the following ratios of components, wt.%: Lithium Chloride 0.3-0.7 Hydroethyl cellulose a 6.0-8.0 Water Else 2. A coating for a hygroscopic material of regenerative heat exchangers, including lithium chloride and water, characterized in that, in order to ensure that the heat exchangers can operate at an ambient temperature below -25 ° C without reducing the efficiency of heat absorption, the coating additionally contains a polyvinyl acetate emulsion with the following ratios of components, wt.%: Lithium chloride Polyvinyl acetate emulsion Water