DE19816185C1 - Method of heating and cooling rooms - Google Patents

Abstract

The method uses a flat panel which is hollow with a seam or water permeable membrane. The inner membrane surface absorbs water vapour. The outer surface directs air though perforations. The panels allows heat and material exchange between the room air and absorption medium.

Description

The invention relates to a method for cooling or heating a Room with simultaneous dehumidification of those in the room Indoor air by means of a flat component, which is a Space limitation forms or is suspended or standing freely in the room is arranged in which a system consisting of hollow elements and  through which a coolant or heating medium is integrated, and a cooling or heating element for this.

The cooling of rooms and the dehumidification of the room air takes place in mo their systems energetically economically by the fact that the sensitive Heat over chilled ceilings using a cold water system and the latent Heat dissipated via a ventilation system with treated, dried air leads.

The use of chilled ceilings with window ventilation has not proven itself because especially on hot, humid summer days due to the high dew point the outside air, the cold water temperature must be raised to To avoid condensation on the pipes and panels where due to the performance of the chilled ceiling.

Chilled ceilings with various plastic capillary tube systems Diameters are state of the art. Even the connections between the pipe system and the space-limiting component (panel) practiced in many ways; easy to put on, press on with insulation mats or clamp connections as well as by clipping or pressing in Beading of various shapes is used.

Air treatment with different types of drying systems is also possible men, most often with air coolers, whose surface temperature is below the dew point is sufficiently known. The use of LiCl-Absorpti onsanlagen, which are in the USA as "Kathabar devices" on the market and Airflow in direct contact with the LiCl is possible because of the Lichen aerosol formation in the air and because of the pollution of the Saline solution is not appropriate.

The use of indirect absorption is therefore promising for the future the air and saline solution are separated by a membrane. The dehumidification  room air using membrane absorption hygroscopic aqueous salt solutions in capillary membranes is expe already experimentally tested [R. Hilke et al. a., THE COLD and air conditioning technology, H.1 / 1996, p. 60ff]. It was found that the mass transport of the Water vapor from the air into the absorber liquid under the laws of Gas permeation follows. The partial pressure between the water vapor Air and in the absorption solution therefore have a direct influence on the Dehumidification performance. According to the previous knowledge turns out a LiCl solution in hydrophobic, highly porous hollow membranes as be particularly advantageous.

There are already known proposals for constructive solutions to create an agreeable indoor climate and thus more comfort in living and Realize office area. Overall, it should be noted that - if no central cooling or air conditioning system when building the Ge building and thus the air conditioning as the central Building facility was provided - decentralized, generally transpor climatic chests can be used as retrofits. Practically Inevitably, the cooling of the indoor air is reduced here relative humidity, because when the air cools down i.a. the The dew point is fallen below and this on the cooler densifies. Different versions to provide cheaper and / or energy-saving constructions have been known (e.g. US 4 193 443; U.S. 4,342,569; U.S. 4,761,966).

Such solutions have the disadvantages that - if in a compact leadership realized - this can only be operated with high energy expenditure are always with a noise in the condition to be conditioned Rooms that are actually characterized by increased comfort, are connected, and accumulated, condensed water manually removed or derived from the room. A rather decent central solution in turn requires increased air circulation, which also  - Assuming a good effectiveness of the system - with considerable Ge noise is connected.

A significant advance in the known drying of air in an air conditioner could be achieved by the air to be cooled is dried before cooling so that there is no condensation of Water comes to the cooler (e.g. US 4,708,000; US 4,711,097; US 5,022,241).

Such a technical solution is not too real in a compact design sieren, especially since the moisture headsober in continuous operation in double ter execution (adsorption operation and at the same time regeneration drive) be present and i.a. the regeneration of the adsorber resulting, moist air outside the room to be conditioned must be disposed of. Here too arise from the necessary Forced air circulation unpleasant noises. The energetic Effort is considerable.

Ultimately, space heat exchangers were used for decentralized cooling especially in the form of liquid, non-porous coolant Tubes, preferably made of polypropylene, are proposed which are natural Use air circulation in the room to be conditioned and therefore without Forced air circulation, which is responsible for the undesirable noise level and unpleasant drafts in other conditioning processes is responsible, the air to be conditioned to the heat exchanger bring up. The coolant is from a central or decentralized central system in pipe systems and in the heat exchanger pipes of the conditioning device promoted, which in function a intensive and energy-saving room cooling can be realized (DE 196 13 674 A1).  

The crucial disadvantage of such a construction is that with intensive cooling without simultaneous supply of dried fresh air inevitably water condensation occurs which leads to the formation of drops There is cause for this, the supply of dry fresh air in turn requires this presence of an installed ventilation system. That is why Limitation of this water condensation on the cooling pipes of the Ceiling cooler without fresh air supply usually in moisture sensors integrated the air environment of the ceiling cooler or on the pipes that limit the flow of coolant or preferably up to ge interrupt the desired reduction in the space to be conditioned. In this operating state, the cooling system is practically ineffective and therefore does not fulfill the desired function.

A method is already known from US 4,915,838 in which moisture is extracted from a room by means of a filter, whereby au outside the room using hygroscopic liquids such as B. triethylene glycol or special salt solutions such as lithium bromide Lithium carbonate is dehumidified via a membrane.

In a known radiation ceiling cassette from NovoClima (Drypac) cooling surfaces are provided with a special coating with the moisture on the individual slats in special dry Be rich is led. A continuous dehumidification is with this Radiation ceiling not possible.

The invention is therefore based on the object of a method gangs mentioned in such a way that with a construction element in the room is sensitive and latent heat dissipation without ent condensation on the component surface is made possible.

This object is achieved by those described in claim 1 Features resolved.  

The main idea for the method according to the invention is that it has been recognized that the absorber liquid flow (Absorbent liquid stream) in water and / or water vapor perm ablen hollow elements for absorbing water vapor from the air and can be used for heat transport, the transferable Heat flow from the room through convection and radiation is given by form-fitting, heat-conducting ribs is specifically increased, and the absorbent liquid flow outside of the room - for example in a control center - by cooling the Material flow and at least partially on the original state sizes that were valid at the entrance to the component in the room, brought, so that a stationary circuit is formed. By be influencing the controlled variables temperature and concentration is a lei power control possible in a quasi-stationary cycle. For the rough Power control is a division of the combi located in the room nated cooling and dehumidifying component in several that can be switched on and off Segments possible.

It is another object of the invention to provide a decentralized device Cooling and heating of rooms or parts of buildings based on one to develop so-called chilled ceilings that have no existing ventilation system system required for air conditioning and with simultaneous window opening the hygienic minimum of outside air remains functional. A Another object of the invention is therefore to provide a device realize one without decommissioning the chilled ceiling function continuous operation of the system without droplet formation through the accumulated condensate guaranteed and with as little as possible energetic effort fulfills its function.

This object is achieved by the cooling or Heating element released.  

According to the invention the object is achieved in that on the one hand the conditioning air by radiation and / or natural convection and / or by forced flow according to the known Principle of the ceiling conditioner a surface of the heat exchanger, its exchange surfaces are made entirely or partially of water vapor permeable materials or moldings exist, is supplied and the other surface of the heat exchange materials or molded articles pern is contacted with a water vapor-absorbing liquid which at the same time as a heat / cold carrier medium and as a carrier medium for that which permeates through the heat exchanger materials or moldings Water serves. According to the invention it is provided that the too cool lumbar and / or air to be conditioned on the surface of a water vapor-permeable polymer molded body (pipe, surface) along and at the same time a water vapor absorbing, liquid cooling heat dium with water-absorbing properties the other surface of the Polymer molded body contacted. This cooling or heating element is in front partly for decentralized cooling and / or air conditioning of rooms or parts of buildings. It is particularly beneficial reversible if the rooms or parts of the building to be conditioned have no central ventilation and thus to achieve the Aims to retrofit these building equipments with mostly high opening wall must be installed.

This cooling or heating element according to the invention thus integrates the Advantages of a ceiling conditioner known per se, without it Disadvantage of the formation of condensate and associated, inevitable necessary decommissioning of the function. That forced water generated by cooling during conditioning by permeation of the same through the heat exchanger material into the Liquid cold / heat medium of the contact surface according to the invention deprived of humid air / heat exchanger material, can therefore not in  Form of condensed water can impair the conditioning process. As As a result, continuous operation of the system is guaranteed accomplishes. This constructive solution also has the advantage that with an appropriate choice of the heat exchanger material and / or the water vapor sorbing cold / heat transfer medium and / or the con structural design of the ceiling cooler conditions specifically targeted can be given that the cooling of the room air from their Ent Moisture can be partially decoupled, which means either one or the other parameter can be regulated as desired. The air to be treated can therefore be air-conditioned.

Materials with water vapor permeable properties are sufficiently in described in the literature. However, in order to obtain a che, high stability towards the contacting media and thus to guarantee a practically unlimited durability of the exchanger Most, preferably are not porous, by the cold / heat transfer medium wettable materials that are porous in little or very little have low water vapor permeability, especially in the form of Capillary membranes, used as heat exchanger materials. In a Another, preferred version are hydrophilic, from heat / cold Carrier wettable, porous materials with a thin, non-porous Layer of a hydrophilic, in particular cross-linked material medium to high water vapor permeability coated (composite Membrane) and in this form, especially as capillary membranes, as Heat exchanger material used. In a third preferred Aus leadership are those mentioned in the first preferred embodiment porous and at the same time hydrophobic materials with those in the second preferred execution as coating material called hydro coated with phile materials and, especially as capillary membranes, used as heat exchanger material. In the former, preferred case the transport of the accumulated on the heat exchanger surface takes place Water through the air-filled pore system of the heat exchanger material  into the cold / heat transfer fluid. In the second, preferred case works the non-porous coating layer as a solution / diffusion membrane; the resulting water vapor permeates due to the Permeation properties through this barrier directly into the Cold / heat transfer fluid. In the third preferred embodiment the water vapor first permeates through the hydrophilic barrier layer in the air-filled pore system of the carrier membrane and from there into the cold / heat transfer fluid. In the case of coated heat exchange material becomes practical - combined with only a small amount Decrease in performance due to dehumidification effect - advantageous an additional Barrier for the penetration of cold / heat transfer fluid into the conditioning air system realizes what in the event of an accident as additional Security barrier can be used.

Water-vapor-absorbing heat carriers are known to the expert from the Lite ratur as an absorbent of absorption columns for air drying known. In principle, they are also used as heat transfer media for the invention appropriate cooling or heating element. However, it has been shown that Substances like higher alcohols and polyols like glycerin and polyethylene gly kole and especially concentrated salt solutions with salts such as lithi umchloride, lithium bromide, calcium chloride etc. can be used advantageously, if increased dehumidification is required. Own these solutions at the same time a sufficient heat capacity, so that a high Cooling effect at low flow rates can be guaranteed.

Embodiments of such a cooling ceiling or cooling elements that the ceiling of the room to be cooled and / or air-conditioned are brought are shown in the drawings. Here show pure schematically

Fig. 1 is a capillary tube mat system

Fig. 2 shows a combination of a capillary tube mat system with membrane absorption, and

Fig. 3 shows a system for simultaneous membrane absorption and cooling / heating

In Fig. 1, a known capillary tube mat system is shown, in which non-porous polypropylene capillary tubes are guided in a mat-like manner between the manifolds for the supply of the heat / cold medium and are connected to one another in a liquid-tight manner. Here, cooling water serves as a cooling / heat transfer medium.

Fig. 2 shows an embodiment of the system according to the invention on the basis of the capillary tube mat system, in which - in a technically comparable embodiment - a second mat element is combined with the capillary tube mat system, the one liquid circuit being operated in a known manner as a refrigeration cycle, the second However, the heat exchanger materials according to the invention are used in the circuit and the water vapor-sorbing media according to the invention are used as cold / heat carriers. The air is preferably cooled by the known system. A generated by the cooling effect, he increased water vapor concentration is dissipated by the near-localizing, cooling element according to the invention over the heat / cooling medium used there, so that continuous operation without condensate formation, especially when the cooling capacity fluctuates greatly, can be achieved. Such an arrangement preferably ensures continuous operation of the cooling. In the present case, a parallel arrangement is shown. Other arrangements, such as a crosswise arrangement of both systems in the ceiling element, are also according to the invention.

Fig. 3 shows an arrangement with only one liquid circuit, in which only the heat exchanger materials according to the invention and the cold / heat transfer medium according to the invention are used. In addition to the cooling effect, an air-conditioning effect in a liquid circuit is also guaranteed.

For continuous operation of the device according to the invention must have at least a partial flow of the absorption medium flow itself known techniques of concentration such as evaporation, stripping concentrated and / or by using membrane processes become. This can be done in a continuous or discontinuous form gene.

Claims (19)

1. A method for cooling or heating a room with simultaneous dehumidification of the room air in the room by means of a sheet-like component which forms a room limit or is arranged freely suspended or standing in the room in which a system consisting of hollow elements and flows through a coolant or heating medium is integrated, characterized in that

• a) that in the flat component as a hollow element angeord Nete, water and / or water vapor permeable membrane is contacted on a first, inner membrane surface by a we acting as a cooling medium, water vapor absorbing absorbent, the second, outer membrane surface of the room air directly or after Passage through a perforation in the space-limiting component is wholly or partially washed around,
• b) that a heat exchange and mass transfer between the ambient air and the absorbent is carried out in the flat component, and
• c) that moisture is extracted directly from the room air via the absorbent in the flat component and is removed from the room.

2. The method according to claim 1, characterized, that the system is designed as a capillary tube system and that between between the capillary tube system and the flat Raumele  ment a positive connection by pressing the capil lar tubes in beads, by fastening the capillary tubes with clips or by pressing with a plate. 3. The method according to claim 1 or 2, characterized in

• a) that the sensitive heat flow from the room at least 80% over the active space boundary surface by heat conduction to the part in contact with the outer surface of the hollow element and at most 20% directly over the outer surface of the hollow element bordering the room air and this cools into one Raising the temperature below the room temperature and in the case of heating leads to a lowering of the temperature of the absorption liquid stream lying above the room temperature.
• b) that the moisture flow from the room air comes exclusively via the air-loaded hollow element surface into the absorbent liquid, the water vapor partial pressure of which is below the partial pressure of the water vapor in the room air, the temperature and the concentration of the liquid being freely selectable from one another within limits dependent on the absorbent are and these quantities are used directly for power control for the heat and material flow, and
• c) that the absorbent liquid stream is cooled or heated before and / or after running through the room cooling and room air dehumidification device.

4. The method according to any one of claims 1 to 3, characterized, that at least a partial flow of the absorbent liquid flow after known concentration techniques such as evaporation,  Stripping out and / or by using membrane processes is centered. 5. The method according to any one of claims 1 to 4, characterized, that the room-side boundary surface only from one side of Surrounded by cross-shaped, diagonal or braided air network of capillary tubes, if necessary after optically addressing them The pattern is arranged. 6. The method according to any one of claims 1 to 5, characterized, that at high cooling capacities or heating capacities part of the one placed capillary tubes made of normal, not water vapor permeable There is plastic and with cold water or hot water is applied. 7. The method according to any one of claims 1 to 6, characterized, that the size of the area-related sensitive heat flow by the type of contact between the capillary tubes and the sheet-like component (pressed into cup beads, lying on top) or clipped onto perforated flat or curved surfaces), quantified by the thermal resistance and the design of the Room boundary area as a heat-conducting rib, quantified be deliberately changed by the rib efficiency so that the heat flow over the rib drops to 50% and over the Hollow membrane rises to 50%. 8. The method according to any one of claims 1 to 7, characterized,  that the rib surface on the room side is deliberately changed or chosen is that the ratio of the absorbed or released Radiant heat flows to the absorbed or released Convection heat flow drops to 10%. 9. The method according to any one of claims 1 to 8, characterized, that additionally with high cooling capacities or heating capacities conventional cooling systems or heating systems can be installed. 10. The method according to any one of claims 1 to 9, characterized, that at high dehumidification capacities additionally conventional dehumidification systems can be installed. 11. The method according to any one of claims 1 to 10, characterized, that from a temperature above room temperature sorbent liquid temperature also the heating case with simultaneous Dehumidification is realized. 12. Cooling or heating element as a sheet-like component, in particular for carrying out the method according to one of claims 1 to 11, in which a system for cooling or heating a room and for dehumidifying the room air in the room consisting of hollow elements, which can be flowed through by a liquid, is integrated in the sheet-like component, characterized in that
that a water and / or water vapor permeable membrane is arranged in the flat component as a hollow element so that a first inner membrane surface of the membrane can be contacted by a water vapor absorber acting as a cooling medium or heating medium, with a second outer membrane surface of the membrane being exposed to the ambient air can be wholly or partially flushed directly or after passing through a perforation in the space-limiting component,
that heat exchange and mass transfer between the ambient air and the absorbent can be carried out in the flat component and
that moisture can be directly extracted from the room air via the absorbent of the room air and can be removed from the room. 13. Cooling or heating element according to claim 12, characterized, that as a water vapor permeable membrane capillary membranes be set. 14. Cooling or heating element according to claim 13, characterized, that porous capillary membranes made of polymer materials are used that are not wetted by the absorption medium. 15. Cooling or heating element according to claim 13, characterized, that the capillary membrane has a two-layer structure (Composite membrane), consisting of a porous, absorpti onsmittel wettable layer of material and an unporous what vapor permeable and in particular cross-linked material layer. 16. Cooling or heating element according to claim 13, characterized,  that the capillary membrane has a two-layer structure (Composite membrane) consisting of a porous from the absorpti means of a non-wettable layer of material and a non-porous, Permeable to water vapor and in particular cross-linked material layer. 17. Cooling or heating element according to one of claims 12 to 16 da characterized by that the heat-conducting fin surface with the integrated capillary pipe system or the braid of capillary tubes no wall forms a boundary, but is suspended or standing freely in the room is arranged. 18. Cooling or heating element according to one of claims 12 to 17, characterized, that the size of the area-related sensitive heat flow by the type of contact between the capillary tubes and the Space limitation material (pressed into sheet metal beads, lying on top or clipped onto perforated flat or curved surfaces), quantified by the thermal resistance and the design of the Room boundary area as a heat-conducting rib, quantified be deliberately changed by the rib efficiency so that the heat flow over the rib drops to 50% and over the Hollow membrane rises to 50%. 19. Cooling or heating element according to one of claims 12 to 18, characterized, that the space-defining rib surface is deliberately changed so that the ratio of the radiant heat flow absorbed to the recorded convex tion heat flow drops to 10%.