BG66929B1 - A hybrid anisotropic micro net - Google Patents

Abstract

The invention relates to a hybrid anisotropic micro net, consisting of bronze and polyester microfibers, which can find application in energetics, in particular as a regenerant material for Stirling heat pumps, working in temperatures of -5oС to 55оC, and has a maximal mechanical work durability in dynamic range with maximal working pressure of up to 30 at. It consists of perpendicularly intertwined fibers based on bronze and polyester weft. The warp fibers are made entirely of bronze and the weft fibers are made entirely of polyester, and each of the bronze and polyester fibers consists of a single thread. The content of bronze in the net is 81%, and of polyester is 19% per square meter, as the thickness of the bronze fiber is from 75 to 85 µm, and of the polyester from 95 to 105 µm. The network combines high mechanical properties with high porosity and is characterized by maximum volumetric heat capacity and maximum difference in thermal conductivity of the two components, which leads to high efficiency of its work.

Description

Field of technology

The invention relates to a hybrid anisotropic microarray consisting of bronze and polyester microfibers, which will find application in energy, in particular as a regenerative material for Stirling heat pumps operating at relatively low temperatures. The microgrid can also be used in electronics, as a two-dimensional medium with anisotropic electrical conductivity and others.

BACKGROUND OF THE INVENTION

The Stirling heat pump is a cyclically operating heat engine operating between two different temperatures, the efficiency being given by the Carnot formula. There are two types of heat pumps: straight, which converts heat into work, and vice versa - in it the work of expansion and compression of gas creates a temperature difference. It is known that the efficiency of Stirling heat pumps is significantly increased in the presence of a regenerator (high-efficiency micro-heat exchanger), which cyclically retains part of the heat of the hot gas flow and transfers it to the cold gas flow. Modern Stirling heat pumps are not considered to be efficient without a heat regenerator, see West, S. D., Principles and Applications of Stirling Engines, New York, Van Nostrand Reinhold Company, 1986. Therefore, a large number of different mesh regenerative heat pumps are known. materials, see e.g. in Knowless, T. Composite-Matrix Regenerators for Stirling Engines. USA: NASA, 1997, p. 78, Vol. Contrator Report 202322, which are based on impregnated polymer layers, stacked metal meshes, unordered metal meshes, sintered ceramic composites and carbon fibers and composites.

U.S. Pat. No. 6,475,935 describes regenerative materials used to produce regenerators operating at a temperature between - 270 ° C and 0 ° C, which are of high productivity, uniform performance and reliability. In general, the regenerative materials described in this patent are a web woven in the form of a canvas, using flexible and very long fine conductors for longitudinal conductive elements (base) made of one or more types of heat-capable material having high specific heat per unit volume in the operating temperature range, and fine conductors for transverse conductive elements (weft), each containing a core conductor consisting of either a single filament made of at least one type of ceramic fiber, carbon fiber and synthetic fiber a resin having a higher hardness than that of the longitudinal conductive element, suitable elasticity and extremely low thermal conductivity, or a filamentary composite formed by packing multiple single threads in one body with a fixing agent such as synthetic resin or glass, and a synthetic polymer resin covering the heart cord. In one embodiment of the invention, the diameter of the transverse conductive elements is 0.06 to 0.5 mm, and the distance between them is three to ten times their diameter in order to achieve a fluid flow resistance less than a predetermined level. Also, for an embodiment of the invention shown in FIG. 1 (c) in the cited patent, it is stated that the transverse conductive element composed of a filament composite is coated in particular with polyester, the diameter of this fiber being 0.06 to 0.5 mm, preferably about 0.06 to 0.08 mm, from the point of view of point flow resistance and productivity. The thickness of the polymer resin is preferably 20 to 50 pm. In the described embodiment, the second fine conductor for the longitudinal conductive element also comprises a core element, which is preferably made of bronze, the outer surface of which is coated with a neodymium, lead, lead alloy or other material by bonding, joining or coating. The diameter of this element is 0.02 to 0.5 mm, preferably 0.02 to 0.08 mm, in terms of creating the network, given its heat transfer efficiency and productivity, and the thickness of the coating is from a few microns to tens of microns.

The network described in this way is designed to operate in a low temperature range (temperatures close to the temperatures of liquid helium or nitrogen), which requires the use of fibers with complex

Descriptions of issued patents for inventions № 09.1 / 16.09.2019 structure (multicomponent fibers coated with neodymium or similar alloy).

Working in this low-temperature range requires the presence of solid-phase components with a high magnetic component of the heat capacity, allowing cooling of the system, by analogy with the evaporation of liquids in conventional refrigeration. The described network is suitable for operation at very low temperatures, where it is possible to work with a very high efficiency, requiring the metal component of the regenerator to be a composite material.

These composite fibers are unsuitable for use in Stirling pump regenerators operating in the temperature range from -5 ° C to 55 ° C and at high pressure change dynamics, as in such conditions they show:

- reduced mechanical properties at elevated pressures, for example up to 30 at, especially in conditions of high dynamics of pressure change;

- the presence of a layered structure reduces the thermal conductivity of the composite material compared to that of a single component single fiber, due to the presence of a separating surface and low-conductivity components such as organic binder or air between the core and the coating component, and due to the presence of fibers one thread. The decrease in the heat transfer coefficient can be estimated by the Maxwell method adapted to hybrid composites, see, for example, K. Dimitrov, B. Radoev and R. Tsekov, Transfer coefficients in composite media, Yearbook of Sofia University, Faculty of Chemistry, 82 (1992) 209-218.

Therefore, there is a need to develop a new hybrid anisotropic micronetwork that can be used under temperature conditions set by the average ground surface temperature in the temperate climate zone and the water temperature in the pipes of a conventional district heating system, for example from -5 ° With up to 55 ° C, and which has maximum mechanical stability when working in dynamic mode with a maximum operating pressure of up to 30 at, to be highly efficient and durable.

Technical essence of the invention

The hybrid anisotropic microarray of the present invention consists of perpendicularly interwoven fibers based on bronze and polyester weft. The warp fibers are made entirely of bronze and the weft fibers are made entirely of polyester, and each of the bronze and polyester fibers consists of a single thread. The content of bronze in the net is 81% and that of polyester is 19% per square meter, with a thickness of 75 to 85 pm for the bronze fiber and 95 to 105 pm for the polyester fiber.

In one embodiment of the invention, the microgrid has a contact area of 2.20 to 2.50 m ² per square meter and a degree of filling of the microgrid with threads from 65% to 75%.

In another embodiment of the invention, the microgrid has openings having an optimal size of 125 ± 12 pm x 105 ± 10 pm, with a distance of 125 ± 12 pm being bronze-bronze and a distance of 105 ± 10 pm being polyester-polyester.

In another embodiment of the invention, the microarray has a three-dimensional (3D) porosity of 70 to 80% under operating conditions, namely, after winding around the regenerative core of a Stirling pump regenerator.

The invention is illustrated in more detail by the example that follows.

Explanation of the attached figures

Figure 1 represents: a) an electron microscope and b) a fluorescence microscope image of the network of the present invention.

Figure 2 shows a regenerator in which the network of the invention is embedded.

An embodiment of the invention

An embodiment of the present invention for a hybrid anisotropic microarray is shown in FIG. 1 (a) and (b) representing, respectively, an electron microscope and a fluorescence microscope image of the network. It consists of all-bronze fibers forming a base,

Descriptions of issued patents for inventions № 09.1 / 16.09.2019 interwoven perpendicularly with all-polyester fibers forming a weft, as the content of bronze in the net is 236 g (81%) and polyester is 56 g (19%), relative to the square meter. Bronze and polyester fibers are fibers, each of which consists of a single thread. The thickness of the bronze fiber can vary from 75 to 85 pm, and of the polyester from 95 to 105 pm, and in the specific example these thicknesses are 80 pm and 100 pm, respectively.

The network thus described has a contact area of 2.20 to 2.50 m ² per square meter, and in the specific example shown in FIG. 1, the calculated contact area is 2.45 t ² , per square meter. The hybrid microgrid of the invention has openings with an optimal size of 125 ± 12 pmx 105 ± 10 μm, the distance 125 ± 12 pm being bronze-bronze and the distance 105 ± 10 pm being polyester-polyester.

The mesh has a three-dimensional (3D) porosity of at least 70% under operating conditions, when winding around the regenerative core of a Stirling pump regenerator, and in this example it is 80%. The 3D porosity of the network in the wound state on the regenerator represents the ratio between the volume of the gaps in the micronetwork and the volume it occupies, wound around the cylindrical core, in percent.

The two-dimensional porosity of the network (2D), in percent, is defined as the difference between 100% and the degree of filling of the network with fibers. It varies from 25% to 35%, and for the present example it is 31%.

The bronze fibers for the mesh are bronze fibers of tin bronze CuSn6 with a composition of 94% Cu and 6% Sn, with a density p = 8.8 g / cm ³ , with the above thickness and thermal conductivity, as shown in Table 1.

The polyester fibers for the net are polyethylene terephthalate fibers with a chemical composition of C ₁₀ H _g O ₄ , with a density of p = 1.38 g / cm ³ and the thickness and thermal conductivity given above, as shown in Table 1.

This net in the form of a canvas can be made on a loom, for example one of the company GKD - Gebr. Kufferath AG, Hotel Germany.

The hybrid anisotropic microarray of the present invention is characterized by the thermal properties shown in Table 1. It shows the heat capacities experimentally determined by differential scanning calorimetry at different temperatures.

The contact area is calculated as the sum of the areas of the two fibers per square meter, which is reduced by about 15%, representing the experimentally determined area of contact of the two fibers in the web (fiber overlap) per square meter. The thermal conductivities of the two network components are also given.

Table 1

Thermal SEOYSTGShch 30 X <0 60 ^l s 1 _: λΐ Dvuannsnsi- 4NSh1№1 porosity Contact surface J / & - K W / τϊγΚ % n? Паί Steam on anisitrcpna gut 0.6 0.6 5.5 - 0.6 Iilnesger 55-65 bronze 31 2.45

The hybrid anisotropic microarray of the present invention is particularly suitable for use in Stirling pump regenerators, where it operates in the temperature range from -5 ° C to 5 5 ° C, limited by the physical properties of the polymer component.

As shown in FIG. 2, a micronetwork in the form of a woven fabric of polyester fibers with a diameter of: d = 100 pm and bronze fibers with a diameter of: d = 80 pm, and holes with dimensions of 125 pm x 105 pm, is used as part of a regenerator that can has dimensions: diameter from 6 to 10 cm and height from 3 to 7 cm. The network thus described operates in dynamic mode with a pressure difference of up to 30 at

Descriptions of issued patents for inventions № 09.1 / 16.09.2019 and has a contact surface of 2.2 to 2.5 w ² , per square meter of canvas.

The advantages of the created hybrid anisotropic micronetwork are that it combines high mechanical properties with high porosity and optimal for the selected temperature range thermal properties due to the chemical composition and thickness of the fibers used. These qualities of the network allow it to operate in dynamic mode at high pressures up to 30 at, as an integral part of a Stirling heat pump for not less than 10,000 hours. It is characterized by maximum volume heat capacity and maximum difference in thermal conductivity of the two components, which together with its high porosity of at least 70% and contact surface of more than 2.2 t ² , leads to high efficiency of its work.

Claims (4)

Patent claims Hybrid anisotropic microarray consisting of perpendicularly interwoven bronze and polyester warp fibers, characterized in that the warp fibers are made entirely of bronze and the weft fibers are made entirely of polyester, and each of the bronze and polyester consists of a single thread, in which the bronze content in the net is 81% and the polyester is 19% in terms of square meter, and the thickness of the bronze fiber is from 75 to 85 μηι. and polyester from 95 to 105 μηι. Hybrid anisotropic microarray according to Claim 1, characterized in that it has a contact area of 2.20 to 2.50 μ ² per square meter and has a two-dimensional porosity of 25% to 35%. Hybrid anisotropic microarray according to Claim 1 or 2, characterized in that it has holes in the mesh, with an optimal size of 125 ± 12 μηι x 105 ± 10 μηι. as the distance 125 ± 12 μηι is bronze - bronze, and the distance 105 ± 10 μηι is polyester - polyester. Hybrid anisotropic microarray according to any preceding claim, characterized in that it has a three-dimensional porosity of 70 to 80% under operating conditions.