RU2008776C1 - Heat-accumulating material - Google Patents

Abstract

FIELD: individual protection means. SUBSTANCE: material is polymer coat with paraffin filler. The latter is paraffin of C₁₇H₃₆-C₂₀H₄₂ series with melting point from 16.7 C to 36.7 C. The coat is porous substance. EFFECT: improved heat-accumulating ability. 2 cl, 1 tbl

Description

 The invention relates to the accumulation of thermal energy and the use of heat storage materials to optimize the surface temperature of a human body in extreme conditions.

 In order to maintain the optimum temperature of the surface of the human body, mainly passive methods are used. Clothing is a heat-insulating material that regulates the level of heat transfer of the surface of the body with the environment. Under ordinary conditions, heat-insulating clothing in combination with the adaptive capabilities of a healthy person provide a normal level of heat exchange with the environment while maintaining optimal body surface temperatures. However, the possibilities of the well-known method of regulating heat transfer are also limited in extreme climatic conditions (at very low and very high ambient temperatures), the heat-regulating function of clothes is poorly performed.

 Active methods of regulating heat transfer are also known, for example, by using electric heating by passing current through electrically conductive clothes. The application of this method is limited by the complexity and high cost of the corresponding equipment, as well as the safety requirements.

 The action of the heat-accumulating material is based on the storage of heat from an external source during charging and slow discharge at physiologically acceptable temperatures that are optimal for the corresponding parts of the body.

This action is based on a reversible phase transition - melting and solidification of the substance. Due to the latent heat of fusion, when the working substance of the heat accumulator is heated at the melting temperature, thermal energy is stored, while cooling to the melting temperature, the substance solidifies and the stored heat is released. In this case, the phase transition occurs at a constant temperature characteristic of the selected substance. In accordance with the card body temperature to physiological temperatures should include (for different areas of the body) temperature of from 16 to 36 ° ^C.

 You can formulate the basic requirements for the working substance of the heat-accumulating material.

 Melting point - in the range of physiological temperatures.

 High latent heat of fusion.

 Non-toxic, compatible with clothing materials and body surface.

 Almost all of these requirements are met by paraffins.

The table provides reference data on the melting temperatures and latent heat of fusion of a number of paraffins (C ₁₆ -C ₂₀ ), melting in the "physiological" temperature range.

 The use of paraffins for heat therapy is known in modern medicine. The application of a cartridge with molten paraffin on the body provides a slow, deep local heating of the desired area of the body.

 The use of paraffins as the working fluid of a heat accumulator at phase transitions has been systematically studied. Typically, heat storage materials are used in heterophasic heat transfer processes, for example, when heating or cooling air. This problem was solved in the cited work.

The author found that with a number of positive properties of paraffins (the optimum level of phase transition temperatures for humans, the relatively high latent heat of fusion (see table), the use of paraffins as a working medium for heat accumulators is complicated. The fact is that heat is transferred relatively much in liquid paraffin it’s good, however, when cooling along the periphery of the liquid volume, a film of solid paraffin with low thermal conductivity is formed and grows. Therefore, heat is taken from the molten paraffin at a low speed. In order to somewhat improve this process, the author turned paraffin into encapsulated granules ranging in size from tens to hundreds of microns. The integrity of the granules was ensured by a wall (matrix) of another, non-melting material (gelatin, etc.). Naturally, the interface was dramatically increased and significantly heat transfer from paraffin to air increases .. The disadvantages of the described system include:
the difficulty of preparing encapsulated granules.

 For these reasons, a paraffin-based thermal insulating material is not of interest for the purposes of heat supply and air conditioning of homes.

 The aim of the invention is to improve the quality of heat storage material. The purpose of the technical solution is the use of heat-storage materials based on paraffins to regulate surface heat transfer of the body. With this formulation of the problem, the main disadvantages of materials such as paraffins in polymer matrices turn into their advantages. Indeed, the correction of heat transfer on the surface does not require intense heat transfer. The main parameter that determines the quality of the heat-accumulating material is the "protective action time" - the duration of maintaining the optimum temperature on the surface. Intensive heat transfer is harmful here, because one should not violate the body’s own thermoregulation. Therefore, it is advisable to even slow down the heat transfer from paraffin to the environment.

This effect is achieved: Using a thermal storage material in the form of three-dimensional elements, which increases the amount of working substance (paraffin) per unit surface of the body;
using as matrices polymeric materials containing small pores (10 ^-1 -10 ^-2 cm);
using as a working fluid a homogeneous mixture of two paraffins: selected at the optimum melting temperature, which changes the aggregate content during operation (70-90% of the mass) and high-boiling, for example, with _mp > 40 ^о С, which quickly hardens and sharply reduces heat transfer in the matrix with liquid paraffin.

 Based on theoretical considerations and experiments, the requirements for the matrices are formulated.

 The matrix should be filic to liquid paraffin.

 The maximum possible pore volume with a predominance of open porosity, which is necessary to fill the matrix with paraffin.

 Homogeneous porosity with a minimum pore radius.

 These requirements are met by a wide range of industrial gas-filled polymer materials, including foam rubber, some varieties of polyurethane foams, etc.

 Such matrices are well saturated with liquid paraffin, absorbing up to 10 g of liquid per 1 g of matrix material. Homogeneous fine porosity provides good physicochemical properties of the matrix and the product (the element of the thermal storage material as a whole).

Studies of the thermophysical properties of the proposed materials were performed in a laboratory setup. The standard sample (element) is a cylinder with a diameter of 40 mm, a height of 50 mm, cut from a sheet of matrix material, for example, foam rubber, impregnated with paraffin at a temperature above the melting point of paraffin and placed in a measuring cell. The outer surface of the cylinder in contact with the wall of the glass beaker of the same diameter, frozen into ice, which ensured a constant temperature at the periphery of the sample ⁽⁰ ° C). A thermocouple was immersed in the center of the sample to continuously record the temperature. During the experiment, the temperature in the center of the sample rapidly (5-10 min) decreases to the working temperature (melting point of paraffin). In most of our experiments, heptadecane C ₁₇ H ₃₆ (t _PL = 22 ^° C) was such paraffin. Then, for a long time, the temperature in the sample remains constant (22 ° ^C), after separation of the entire latent heat of fusion is relatively rapid cooling of the sample.

The period of preservation of a given working temperature in the sample, which we called the “protective action time”, is the main quantity characterizing the operation of the heat-accumulating material - the clothing element. Examples 1-6 characterize the effect of the composition of the paraffin mixture on the "protective time" of a standard element of heat-accumulating material. In all the examples used weighed wax C ₁₇ H ₃₆ (t _mp = 22 ^{° C)} in which is stored by melting 2400 cal.

Thus, the distinguishing features of the proposed material is the use of paraffin as a working fluid with a melting point + 16- +36 ^о С, and as a matrix of porous elastic materials with a pore size of 0.05-0.5 mm, while adding to the low-melting paraffin 10-30% of high melting point (above 40 ^о С) paraffin.

 Such a combination of features is not known from the prior art, provides long-term maintenance of body surface temperature, and can be classified as “significant differences”.

 PRI me R 1. This is a comparative experiment in which the cooling rate of a sample (60 g of paraffin) in a 40 mm glass cup was measured. Due to the relatively good heat transfer in liquid paraffin, the cooling rate is high and the “protective action time” is from 5 to 10 minutes.

PRI me R 2. A cylindrical sample ⌀ 40 mm and a height of 50 mm from a foam PPM-205-5 with an apparent density of 40-50 kg / m ³ with a fine homogeneous open-cell structure was impregnated with 60 g of paraffin C ₁₇ H ₃₆ . The sample was placed in the cell described above and the temperature curve of its cooling was measured. In this case, the “protective action time” is 20 minutes. Its increase should be attributed to a decrease in the cooling rate of paraffin when it is placed in the matrix cells.

 PRI me R 3. Performed similarly to example 2, but as the matrix used porous rubber with a pore size of not more than 0.4 mm "Protective action time" is 30 minutes.

EXAMPLE EXAMPLE 4 The procedure of Example 2 but impregnated into the matrix is introduced at a temperature of 55 ° ^C a mixture of two paraffin: Desktop C ₁₇ H ₃₆ t _mp = 22 ^o C and the high melting C ₂₄ H ₅₀ t = 50 _Space , 6 ^about C. When using this mixture in a ratio of 90% of the mass. Paraffin C ₁₇ and 10 wt. % paraffin C ₂₄ "protective action" increases to 40 minutes

PRI me R 5. It is carried out analogously to example 4, but the ratio of the corresponding paraffins is 70: 30 (paraffin C ₁₇ -70 wt.%, Paraffin C ₂₄ -30 wt.%). "Protective action time" is 60 minutes.

 PRI me R 6. Performed similarly to example 5, but as the matrix used porous rubber (see example 3). This combination of matrix and composition of the paraffin mixture provides an increase in the "time of protective action" up to 120 minutes

 Thus, the selection of the composition of paraffins and the porous structure of the matrix provides a very effective increase in the retention time of heat in the insulating clothing element. The presented data of model experiments can be used to calculate the real "time of protective action" of heat-insulating clothing materials under conditions of heat exchange with the body and the environment. In this case, as a rule, the operating temperature of the heat accumulator is chosen slightly lower than the temperature of the corresponding part of the body, and clothing limits heat loss (by several orders of magnitude compared to the conditions of model experiments in examples 1-6). The real "time of protective action" of the heat-accumulating elements will be measured in hours and it is possible to design clothes that effectively protect against weather discomfort during, for example, a working day.

In practice, the use of insulating clothing requires an external source of heat to charge. Such a heat source can be any device that provides temperatures above the melting point of a given paraffin. As this is a paraffin with melting points close to "physiological" (16-36 ° ^C), the heat sources in virtually any house enough. It can be a steam (water) heating battery, oven, electric heaters. The heating time is selected for each product separately, based on its size and shape.

 The selected parameter interval is determined by the following considerations.

 The melting point of paraffin is determined by the optimum temperatures of the main heat-transferring areas of the body.

 The choice of elastic polymers as matrices is determined by the fact that these materials are characterized by an open pore structure available for paraffin.

Selecting a heavy fraction (t _mp 50 ° ^C) in a mixture of paraffin (10-30% determined that in this composition range the most significant improvement is observed "time of protective action" With fewer high melting wax its effect weakly pronounced in larger lobe. - cooling retardation does not occur due to a decrease in the amount of working (low melting) paraffin in the sample.

 (56) Manchini N. A. Use of parafins for thermal Storage. International TNO Symposium "Thermal Storage of salare energy". Amsterdam, novembre 1980.

Claims (2)

1. HEAT-ACCUMULATING MATERIAL in the form of a polymer shell and a paraffin filler, characterized in that, in order to improve its quality, low-melting paraffin from the series C ₁₆ H ₃₆ - C ₂₀ H ₄₂ with a melting point of 16.7 - 36 is used as a filler. 7 ^o C, and as a polymer shell - a porous material. 2. The material according to p. 1, characterized in that, in order to reduce the cooling rate, the filler additionally contains high-melting paraffin with a melting point of more than 40 ^o C, while the ratio of the components of the paraffins from the series C ₁₆ H ₃₆ C ₂₀ H ₄₂ and high-melting paraffin is 70/30 - 90/10 wt. h

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