DE4007934A1 - Hollow insulating zones - have absorption units to block condensation development which can be replaced and regenerated - Google Patents

Abstract

The method to give durable inhibition to the development of condensation in the hollow zones between insulating glass panes, hollow wall facings, tubes and the like, has absorption units which can penetrate the gass filling of the hollow zones, from outside, held at dewpoint values below the service temp. The durable absorption effect is maintained by the exchange of used absorption media and/or their regeneration. The absorption unit pref. has pressure compensation with the ambient atmos. through an opening to the outer air or an elastic vessel between the absorption unit and the outer air which can be activated. The absorption unit is directly at the hollow zone to be protected or it extends into it, or is located separately with a tube and/or hose connection. The absorption unit can be at or in the elastic vessel. The absorption unit is a replaceable unit, pref. a visible colour indicator or moisture measurement meter to indicate or control an exchange action. The absorption unit can be regenerated while in position, using heat to expel the moisture wholly or partially and any vapour to be passed to the outer atmosphere through a valve. The heat energy to dry the absorption media can be taken from the electrical power supply, solar energy, regenerated energy or combinations of energy sources. Where the hollow zones are in moving bodies, such as revolving doors, the linkages between the absorption units and the hollow zones are temporarily broken during movement and then reconnected. ADVANTAGE - The vapour pressure from the gas filling in the hollow zones is durably held so low that condensation cannot develop. It also prevents the formation of pressure differences which could lead to distortion of the sides containing the hollow zones.

Description

The invention relates to a method which the formation of For example, condensate between the panes of Insulating glass units, for multi-layer facade walls, in constructive hollow bodies such as pipe constructions or in devices permanently prevented.

Such bodies, summarized below as cavities, are required protection against the formation of condensate. This is too avoid, since condensate attack the walls, the optical Interfering with transparency and as drops can cause frost damage.

The content of the cavities is summarized below as gas designates, regardless of whether it is the gas mixture air or special technical or other gases. Of that A distinction is made as the aim of the invention as water vapor Condensate pictures.

It is known and prior art that, for example, for the drying of air gaps in insulating glass units Desiccant used in the spacers or in Sealants are housed. This will unavoidable residual amounts of water vapor absorbed by the Diffuse the edge bond.

Furthermore, a firmly enclosed air volume exposes the air pressure opposes a force that creates loads when the pressure changes leads the walls of the hollow body. This increases the risk of Formation of microporosity and promotes vapor diffusion sealants that are not completely impermeable to steam.

Using the example of the known application in insulating glass panes the process is obvious: Desiccant is arranged in the area of the cavity. Is this Desiccant exhausted, d. H. increases the dew point in the gas filling between the panes, this begins when the rope is reached point the condensation of water vapor inside the pane. Although it is then possible to drill into and remove such discs rinsing is a reliable longer according to the prior art timely function of the double glazing only by replacing it to reach.  

This deficiency should be countered with OS DE 37 17 843 A1 (May 27, 87) will. The solution should be achieved by the Schei gas gap at least at a lower corner with the external atmosphere is connected. By natural convection the air passes through the space between the panes and at least one of the upper corners leave the space between the panes. Assuming that outside air is always colder than indoor air is, this arrangement could permanently dry the Support the space between the panes. However, everyone returns wet hot weather with cool interiors reversed the effect. Other cavities, such as Wintergär tube structures So far, or supporting parts of car bodies have been used Protective lacquers, special oils or cavity seals before the consequences protected from condensation inside the cavities. Here too protection is temporary.

The invention has for its object the vapor pressure of gas Keep fillings in cavities permanently so low that none Condensation can form. It also allows the inventor the construction to be protected and / or the edge bond of mechanical forces due to fluctuating pressure differences between the cavity and the outside air, because so Deformations are avoided according to the invention, not only are undesirable from the designer's perspective, but also can lead to increased vapor diffusion due to microporosity.

According to the invention, this object is achieved in that inevitably bar diffuses into closed cavities due to the system Moisture is absorbed by absorption devices that accessible from the outside and therefore interchangeable and / or are regenerable.

This procedure is explained by way of example with reference to the block diagrams FIG. 1 to FIG. 4, not all analogous reaction solutions like are illustrated.

The closed cavities ( 3 ) are connected to one or more absorption devices ( 1 ). Fig. 1 shows a desiccant container ( 1 ) which is in direct contact with the enclosed gas volume through an opening in the wall ( 2 ) of the cavity ( 3 ). The example here as a flange formed outer surface of the desiccant container ( 1 ) is screwed against the wall ( 2 ) and sealed and has a sight glass through which you can see a signal device, for example a color that shows the filter before exhaustion turns. This means that replacement is required.

The arrangement according to FIG. 2 has a signal device which delivers a pulse which signals the expected end of the effectiveness of the drying agent. This pulse triggers a visible or audible signal and / or triggers an automatic replacement of the desiccant or the absorption device ( 1 ). The gas content of the cavity ( 3 ) remains in place in the cavity. In the case of larger cavities, it may therefore be advisable to use several absorption devices at different points, or an arrangement according to FIG. 3 is chosen. Here, a pipeline leads from the desiccant container 1 to a possibly vapor-tight and elastic container ( 4 ), shown in FIG. 3 as a corrugated tube. The elasticity of the container ( 4 ) must be substantially greater than that of the walls ( 2 ) of the closed cavity. Fluctuations in temperature from or to the elastic container ( 4 ) are caused by fluctuations in temperature or air pressure. The desiccant is flowed through and an intensive absorption is guaranteed. Fig. 4 shows a similar arrangement, the desiccant container ( 1 ) being arranged outside the cavity ( 3 ) and thus being more easily accessible in many cases. The outlined in Fig. 3 and Fig. 4 approaches cause by the elasticity of the loading container ( 4 ) a substantial relief of the walls ( 2 ) from pressure fluctuations.

According to the invention, other combinations are also possible, for example the connection of the absorption device ( 1 ) to the outside air, which leads to complete relief of the walls ( 2 ) but to higher loads on the absorption medium. The appropriate solution should be determined on a case-by-case basis.

An arrangement according to FIG. 5 is shown as a further example. Here two small insulating glass panes ( 21 ) are connected to a large one ( 22 ) as closed cavities ( 3 ). The glass thicknesses are the same. In the event of fluctuations in air pressure, the large areas of the insulating glass pane ( 22 ) are deformed to a greater extent than the smaller areas of the insulating glass pane ( 21 ). Thus, in the event of pressure fluctuations, volume flows will occur which are conducted through lines through the absorption device ( 1 ), which according to the invention can be replaced and / or regenerated.

An advantageous arrangement for a large number of cavities to be protected also results from FIG. 6. Here, the cavities ( 3 ) are to be regarded as insulating glass panes, for example. The absorption device ( 1 ) is supplemented here by a pump ( 11 ). Here, the gas content of the cavities ( 3 ) is circulated and dried continuously or at intervals through lines. It is also possible to release the pressure by connecting an elastic container ( 4 ). Furthermore, Fig. 6 shows a variant for the moving parts of the system. In the case of double glazing, for example, this would be a sliding double glazed door. Valves ( 6 ) connect the sliding double glazing in the normal position to the pipe system. Such valves can, for example, open each other when touched. For a sufficient time without contact with the absorption device ( 1 ), no condensation is to be expected if the effectiveness of the edge bond with insulating glass corresponds to the state of the art.

Furthermore, using the example of double glazing, solutions are given play about small hoses for swing or tilt and turn windows used near the pivot or tipping points.  

Fig. 7 shows a hollow hinge, for example for Schwenkfen ster, with ( 62 ) is characterized by an elastic seal.

Fig. 8 shows two examples of an advantageous connection of lines to be protected cavities. A plug-in connection results from a hole in the wall ( 2 ) being provided with an elastic grommet which takes a hollow sliding piece in a plug-like manner and tends to accommodate you. A visible connection is also outlined. Here an elastic spout ( 63 ) is used, the conical head of which is pushed into the wall ( 2 ). In the area of the cone edge, a ring made of metal, glass fiber or other non-stretchable materials prevents the elastic cone from expanding when a counterpart is screwed in. As the tightening progresses, the cone is pressed from the inside and the outer part of the elastic grommet ( 63 ) from the outside by the collar of the counterpart against the wall of the body. However, other known connections can also be used according to the invention, for example cone connections as are customary in medicine on hoses of infusion devices.

In addition to the examples in Fig. 1 to Fig. 3 for an absorption device that protrudes into the cavity to be protected, receptacles for desiccant cartridges or for powdered or liquid desiccants are advantageously used for external absorption devices.

Fig. 9 shows an example of an arrangement for receiving a cartouche for granular desiccants. The cartouche is inserted into the receiving tube ( 12 ) made of vapor-tight material and closed by a head piece ( 13 ), a cone being drawn here as a seal. This seal is held together by a force-limiting device, here by two spring-loaded anchor plates ( 14 ). The indicated Stromlei lines ( 15 ) represent contacts to electrodes in the Kartouche, which give a signal for replacement with increasing moisture absorption of the desiccant.

For a low-maintenance regeneration of the desiccant, there is an advantageous embodiment in that the arrangement according to FIG. 9 is made of silica glass or other heat-resistant material which has low thermal expansion, the connectors for supplying and discharging the gases to be dried being insulated or removed from the cartouche are that neither the connections nor the valves ( 16 ) can be damaged by exposure to heat.

In Fig. 9 there is a heat-resistant rod-like connection ( 17 ) between the valves ( 16 ), in which an elastic element limits the force during expansion. When the cartouche is heated for regeneration, connection ( 17 ) also heats up and, by expansion, closes both line connections via the valves ( 16 ). As the heating continues, the pressure in the now closed interior of the receiving tube ( 12 ) increases. This raises head ( 13 ) after overcoming the bias of the springs between the anchor plates ( 14 ) and lets the steam escaped from the Trockenmit tel.

According to the invention, other valves can also be used in the usual way Methods of control technology are used.

The Kartouche can be heated both by electrical heating conductors inside the Kartouche, which are connected to a power supply similar to the measuring contacts ( 15 ), as well as by external heat sources such as electrical heating conductors around the middle part of the receiving tube ( 12 ) by gas flames in the area to be heated or by bringing the area to be heated into a bundled line of sun rays.

In this case, the absorption device either becomes solid installed so that at the time of the greatest sunshine becomes effective or tracks the sun.

In addition to the generation of heating energy, the invention offers also photovoltaic energy to operate the measuring, control and Control devices and any pumps. Such Combination of arrangements would be the goal of the invention the most complete protection against condensation lichen because it can autonomously supply itself with energy and thus is independent of supply disruptions.

Fig. 10 shows, for example a section of a double-glazed winter garden construction, at the same time, the insulating gas space between the panes and the tube construction according to the invention are protected in the. Flat glass panes ( 25 ), single or safety glass, are fastened to the tube supports ( 27 ) of the steel frame with a permanent elastic adhesive ( 26 ). The expansion joints to the next pane are sealed smooth and watertight with permanent elastic putty ( 28 ). Fig. 10 shows sharp-angled glasses ( 29 ) as a corner construction, but other conventional shapes or constructions such as corner pillars or cylindrically curved glasses fulfill their purpose according to the invention if gas exchange in the closed system is possible as indicated by the arrows in Fig. 10.

Claims (9)

1. The method and suitable arrangements for permanent protection against condensation in cavities, characterized in that the gas filling of the cavities is kept at dew point values below the use temperatures by absorption devices accessible from outside the cavities, the permanent absorption effect by exchanging exhausted absorption media and / or their Regeneration is maintained. 2. The method and suitable arrangements according to claim 1, characterized in that the absorption device additionally to claim 1 in pressure equalization with the outside air by an opening to the outside air or an elastic container between Absorption device and outside air is switched. 3. Arrangement according to claim 1 and 2, characterized in that the absorption device directly on the cavity to be protected is arranged or protrudes into it. 4. Arrangement according to claim 1 and 2, characterized in that the absorption device spatially from the cavity to be protected separately disordered and with it by hose and / or Pipelines is connected. 5. Arrangement according to claim 2, characterized in that the Ab sorption device arranged on or in the elastic container is. 6. Arrangement according to claim 1 to 5, characterized in that the absorption device from a replaceable device exists, which is preferably a visible color indicator or a Contains moisture meter, which gives a signal that is for display or to control a change process. 7. Arrangement according to claim 1 to 5, characterized in that the absorption device regenerates when installed can be, for example, by heating the bound Expels all or part of the moisture again, whereby for the vapors formed a way is switched by valves that this into the environment. 8. Arrangement according to claim 7, characterized in that the for Regeneration of the active mass of the absorption device required energy from the power grid, from process heat bundled sun rays as well as other regenerable ones Energies or obtained from combinations of these energy sources becomes. 9. Arrangement according to claim 4 to 8, characterized in that with movable cavities to be protected, for example in Rolling doors or other objects, the gas exchange between Cavity and absorption device via flexible lines, Joints or coupling devices that take place in the normal Position the connection between the cavity and the absorption device ensure the temporary movement of the cavity Disconnect and close the line parts and when you return to the Reconnect and open the starting position.