RU2392556C2 - Device for fluid- and/or heat exchange, for example sorption rotor, adsorption fluid absorbing rotor and similar hardware - Google Patents

Abstract

FIELD: heating. ^ SUBSTANCE: invention is intended for fluid- and/or heat exchange and can be used in heat engineering. Proposed device has fluid- and/or heat exchange surfaces to transfer fluid and/or heat to fluid flow, or to allow fluid and/or head be captured by fluid flow, and/or to allow exchange between fluid flows and coat applied onto aforesaid fluid- and/or heat exchange surfaces and made from zeolite material with grain size of <1000 nm and bider. Said zeolite material represents synthetic nano-zeolite. Note that coat thickness varies from 1 to 2 mc (10-6 m). Zeolite material can represent synthetic nano-zeolite with fluid- and/or heat exchange surfaces made from paper and impregnated with suspension that contains synthetic nano-zeolite. Device, after being impregnated with suspension, or in suspension containing synthetic nano-zeolite, consists of at least 30%, preferably, 40% to 80% by weight of nano-zeolite material. ^ EFFECT: higher efficiency. ^ 6 cl

Description

The invention relates to a device for moisture and / or heat transfer, for example, to a plate heat exchanger, a sorption rotor, an adsorption moisture-absorbing rotor and the like, with surfaces for moisture or heat transfer, by which moisture and / or heat can be transferred to a fluid stream, and / or taken up by the fluid stream, and / or exchanged between the fluid flows, and the coating that covers the surfaces for moisture or heat transfer and which is formed from a zeolite material and an astringent.

Such devices for moisture and / or heat transfer are often used to maintain a uniform temperature and air conditioning in the rooms.

In addition, other industrial goals are envisaged for the use of such devices for moisture and / or heat transfer.

Such devices for moisture and / or heat transfer known from the prior art have, in particular, if moisture must be taken in by a fluid stream, respectively, a fluid stream must take in moisture, the disadvantage is that adsorption and / or desorption processes , which respectively occur in moisture and / or heat exchange devices, require a too long period of time, as a result of which the possible power of such devices for moisture and / or heat exchange cannot be realized. Further, the surfaces of coatings under the influence of fluid flows often have a roughness, which leads to the deposition of particles contained in the fluid flows, which negatively affects the efficiency of the respective devices, and accordingly, relatively frequent relatively labor-intensive measures are required for cleaning and maintenance. In addition, often there are difficulties with fixing the substance forming the frame, respectively, the matrix device for moisture and / or heat transfer.

Based on the prior art, the invention is based on the task of creating a device for moisture and / or heat transfer, for example a plate heat exchanger, a sorption rotor, an adsorption moisture-absorbing rotor or the like, which will eliminate the above disadvantages and which can also be made with relatively low costs relating to technical design.

According to the invention, this problem is solved by the fact that in the first embodiment, a device for moisture and / or heat exchange, for example a plate heat exchanger, sorption rotor, adsorption moisture-absorbing rotor, with surfaces for moisture and / or heat exchange, with which moisture and / or heat may be transferred to the fluid stream and / or taken up by the fluid stream and / or exchanged between the fluid flows and the coating that covers the surfaces for moisture or heat transfer and which is formed from a zeolite ma terial with a particle size <1000 nm and a binder, characterized in that the zeolite material is a synthetic nano-zeolite, and the coating thickness is from 1 to 2 microns (10 ^-6 m).

Nanozeolite can be selected in such a way that it has a uniform pore distribution with a pore diameter <1.5 nm, preferably 0.4 nm.

Particles of zeolite material may have a nanocrystalline shape. The binder contains dispersion adhesives, for example acrylate brine, to which colloidal SiO ₂ can be added.

According to a second embodiment, a device for moisture and / or heat exchange, for example a plate heat exchanger, a sorption rotor, an adsorption moisture-absorbing rotor, with surfaces for moisture and / or heat exchange, with which moisture and / or heat can be transferred to the fluid flow, and / or taken by a fluid stream, and / or exchanged between the fluid flows, and the coating that covers the surfaces for moisture or heat transfer, and which is formed from a zeolite material with a particle size <1000 nm and a binder a, characterized in that the zeolite material is a synthetic nano-zeolite, and the surfaces for moisture or heat transfer of the device for moisture and / or heat transfer are made of paper material and impregnated with a suspension containing synthetic nano-zeolite, while the specified device after it is impregnated with a suspension or suspension containing synthetic nanozeolite, consists of at least 30, mainly from 40 to 80 mass% of the nanozeolite material.

The binder contains dispersion adhesives, for example acrylate brine, to which colloidal SiO ₂ can be added.

As a material for creating a surface coating for moisture or heat transfer, synthetic nanozeolite is used, which consists of particles with a particle size <1000 nm. Due to this form of the zeolite material forming the coating, a significantly higher adsorption kinetics can be realized compared to zeolite materials known in the art, which should result in an increase in the amount of adsorbed, respectively desorbed, water vapor per unit time, which will result in increased moisture transfer. Thanks to the use of nano-zeolite, proposed in accordance with the invention as a coating material, an increase in its specific surface is achieved, while this nano-zeolite can adhere well when using an appropriately suitable cementitious agent with polyhedral surfaces. Used in accordance with the invention as a coating material, nanozeolite has a fast ability to regenerate. In the form of a synthetic nano zeolite, a zeolite material with a very uniform particle size distribution can be made. Depending on the choice of the provided particle size distribution for the coating material, the thickness of the coating can be matched to a wide variety of specifications. The small particle size of the synthetic nano-zeolite used in accordance with the invention as a zeolite material has, as a consequence, the coating on the side facing the fluid flows has a very low roughness, as a result of which the correspondingly made device for moisture and / or heat exchange has significant resistance to pollution. The coatings made in accordance with the invention may, depending on the more or less uniform particle sizes chosen for the synthetic nanozeolite, have a high packing density. For applying the zeolite material proposed in accordance with the invention, both a centrifugation method and a dipping method can be used as a coating on the surface for moisture or heat transfer. The coating made in accordance with the invention using nano-zeolite, due to the properties of the nano-zeolite in terms of surface chemistry, can be given a different shape.

Since the heat exchanger plates are provided with a coating according to the invention, it is possible to ensure that the liquid which must be evaporated on the side of the heat exchanger plate in order to receive cooling energy on the other side of the same heat exchanger plate is very evenly distributed on the side of the heat exchanger plate having a coating , so that on the other side of the same plate of the heat exchanger on its surface there is a uniform distribution of cooling energy. This uniform distribution is manifested in that the liquid droplets arising from the coating according to the invention are distributed very evenly on the side of the heat exchanger plate having the coating according to the invention.

According to a preferred embodiment of the device according to the invention for moisture and / or heat transfer, the nanozeolite is selected so that it has a uniform distribution of pore sizes with a pore diameter <1.5 nm, preferably 0.4 nm. Due to this, it can be ensured that such molecules will not be retained in the coating that, under certain conditions, during prolonged operation of the device for moisture and / or heat transfer, an odor can appear. Conversely, water vapor may preferably be perceived by a suitably formed coating and accordingly given off by that coating. Thus, in this embodiment, the coating formed in accordance with the invention from nano-zeolite can be used as particularly suitable for the operation of devices for moisture and / or heat transfer of a molecular sieve.

For the operation of suitably formed devices for moisture and / or heat transfer, it is advisable if the thickness of the coating made in accordance with the invention is from 0.2 to 100 μ, mainly from 1 to 2 μ (10'6 m).

A particularly preferred improvement of the device for moisture and / or heat transfer is achieved when the adsorption moisture-absorbing rotor is made of paper material suitable for this and the material matrix of this adsorption moisture-absorbing rotor, which forms the surfaces for moisture or heat transfer, is impregnated with a suspension containing synthetic nanozeolite.

This impregnation can be carried out for such a long time or in such quantity until, after drying, the matrix of the adsorption moisture-absorbing rotor substance consists of at least 30%, preferably from 40 to 80% by weight, of the nano-zeolite material proposed in accordance with invention.

Of course, it is also possible to use the coating proposed in accordance with the invention when the matrix of the substance of the device for moisture and / or heat transfer is formed from other suitable materials, for example aluminum foil, ceramic materials, etc.

Dispersion adhesives can be used as binders, for example acrylate brine with colloidal silica added under known circumstances. A suitable astringent may also preferably be used with other coating materials.

Below the invention is described in more detail using examples of execution.

In the first embodiment, the device for moisture and / or heat transfer, made as an adsorption moisture-absorbing rotor, is provided with a coating, which is proposed in accordance with the invention, of synthetic nano-zeolite with a particle size in the range of 300 nm. The matrix of the material of the adsorption moisture-absorbing rotor consists of the corresponding paper material. To introduce nano-zeolite into the material matrix of an adsorption moisture-absorbing rotor, it is impregnated with a suspension that contains nano-zeolite with the desired particle size. After drying the adsorption moisture-absorbing rotor, its final weight consists of about 50% of nano-zeolite.

Compared to existing zeolite materials, the zeolite material used to impregnate the matrix of the material of the adsorption moisture-absorbing rotor with particles in the nanocrystalline form has significantly accelerated adsorption / desorption kinetics. The specific surface area of the nanozeolite proposed in accordance with the invention is larger than that of other existing zeolite materials. The crystalline nanozeolite that forms the coating of the adsorption moisture-absorbing rotor is relatively uniform with respect to its pore size, and it is given such a shape that the coating has a uniform pore size with a diameter of, for example, 0.4 nm. Due to this embodiment of the coating structure, it can be ensured that the adsorption moisture-absorbing rotor is protected for a long time from the accumulation of odor-forming molecules, while water vapor molecules can be taken away and given away in the simplest way.

Thanks to the accelerated adsorption / desorption kinetics, the cooling capacity is significantly reduced, which must be installed for the operation of this kind of adsorption moisture-absorbing rotor - in particular, in a tropical climate, namely by about 50%.

The desiccant moisture-absorbing rotor described above, after its coating, has a smooth smooth surface so that pollutants are less likely to linger on it.

Coating in part of its surface chemistry can be done in different ways. It can be applied using centrifugation or dipping techniques.

Due to the small and uniform particle size, the coating has a very large specific surface, and it can be applied to multifaceted surfaces.

As an astringent, an acrylate polymer and colloidal, amorphous silica with stabilization of the surface by sodium ions were used.

Also, sorption rotors, whose material matrix consists of other materials, for example, aluminum, can be provided with the coating described above, while there will be similar advantages as in the previous case associated with the adsorption moisture-absorbing rotor when the material matrix was represented by paper material.

Due to the small particle size of the coating, a relatively high packing density is obtained, and thus the layer thickness can be relatively small. In the exemplary embodiment described above, sufficient layer thickness was from about 1 to 2 μ (10 ^-6 m).

Further, it is possible to use a coating, for example, on heat exchanger plates. When a coating consisting of the crystalline nano-zeolite described above is applied to one side of a heat exchanger plate, it can be achieved with this coating that the moisturizing agent used to moisten this side of the heat exchanger plate is more evenly distributed on this side of the heat exchanger plate. This is due to the fact that drops falling onto the coating are distributed more evenly due to the coating structure. Thus, evaporation heat is uniformly removed on the side of the heat exchanger plate having this coating, so that the fluid flow that passes past the other side of the heat exchanger plate is cooled in the desired manner. Also with this form of application of the coating, the same or similar advantages can be obtained that were achieved in the descriptions regarding adsorption moisture-absorbing and sorption rotors.

Claims (6)

1. A device for moisture and / or heat transfer, for example, a plate heat exchanger, a sorption rotor, an adsorption moisture-absorbing rotor, with surfaces for moisture and / or heat exchange, through which moisture and / or heat can be transferred to the fluid flow, and / or taken by the fluid stream and / or exchanged between the fluid flows and the coating that covers the surfaces for moisture or heat transfer and which is formed from a zeolite material with a particle size <1000 nm and a binder, characterized in that the zeolite the material is a synthetic nanozeolite, while the coating thickness is from 1 to 2 microns (10 ^-6 m). 2. The device according to claim 1, in which the nanozeolite is selected in such a way that it has a uniform pore distribution with a pore diameter <1.5 nm, preferably 0.4 nm. 3. The device according to claim 1 or 2, in which the particles of the zeolite material have a nanocrystalline shape. 4. The device according to any one of claims 1 to 3, in which the binder contains dispersion adhesives, for example, acrylate brine, to which colloidal SiO ₂ can be added. 5. A device for moisture and / or heat exchange, for example, a plate heat exchanger, a sorption rotor, an adsorption moisture-absorbing rotor, with surfaces for moisture and / or heat exchange, through which moisture and / or heat can be transferred to the fluid stream and / or taken away a fluid stream and / or exchange between the fluid flows, and the coating that covers the surface for moisture or heat transfer, and which is formed from a zeolite material with a particle size <1000 nm and a binder, characterized in that the zeolite The material is a synthetic nanozeolite, so that the surfaces for moisture or heat transfer of the device for moisture and / or heat transfer are made of paper material and impregnated with a suspension containing synthetic nanozeolite, wherein the said device is impregnated with a suspension or suspension containing synthetic nanozeolite at least 30, preferably from 40 to 80 wt.% of the nano-zeolite material. 6. The device according to claim 5, in which the binder contains dispersion adhesives, for example acrylate brine, to which colloidal SiO ₂ can be added.