DE10114089B4 - Apparatus and method for collecting condensed water - Google Patents

Abstract

Comprising apparatus for collecting condensed water from the ambient air,
a.) at least one body (5) having an inner and an outer surface,
b.) at least one reflective element (6),
being arranged to each other so that from the body (5) over half of the outer surface with an emissivity greater than 0.5 emits heat radiation into the sun-remote area of the sky, and wherein the condensed water running on the outer surface becomes one or more Collecting container collects.

Description

The The present invention relates to an apparatus and a method for collecting condensate from the ambient air.

In the GB 2 199 474 A and the DE 38 30 647 A The heat radiating surfaces also form the condensation surfaces for the surrounding air humidity.

In the GB 2 209 683 A This condensation surface is still isolated against the ground and / or shaded by day. The radiation of heat in the cold, sun-facing sky of these bodies succeeds in the proposed devices but not nearly over the entire solid angle. On the one hand, it is the shading surface or the earth itself which limits the radiation range. For example, in the patent GB 2199474 A emit radiating earth bodies on average only with 50% of its surface in the cold night sky. To the disadvantage, it also has the effect that the air humidity reflecting in the air causes the radiation angle to become less favorable the farther it deviates from the vertical.

The in the GB 2 199 474 A . DE 38 30 647 A or GB 2 209 683 A proposed devices and methods succeed only a low conversion of the cooling power obtained by radiation in the condensation. In most proposed devices, condensation is taking place on the heat radiating surface which directly contacts the ambient air. A large part of the ambient air is cooled by this cold surface, without its dew point temperature is exceeded and condensation occurs. In the GB 2 209 683 A describes devices in which the surface used for condensation is connected by conduction to a heat radiating surface. The ambient air is sucked in there by means of natural convection or with the aid of a sun-heated chimney and passed by this surface. A check whether the air thus performed has fallen below the dew point and a reduction in the amount of air carried in the event that the dew point temperature is not exceeded, is not provided. In addition, the negative pressure generated by the sun-heated chimney reduces the formation of condensation.

task The invention is to achieve optimal condensation.

Is solved this object by devices according to claims 1 or 2.

refinements the devices of the invention are the dependent claims refer to.

description the figures

In 1 is the temporal temperature profile of a heat-insulated to the ground body I and a body 2 same surface and heat capacity could radiate additionally through mirror heat in the cold night sky. Both bodies cool from the daily air temperature 4 at different speeds during the night hours. About the mirror loses the body 2 a twice as high amount of heat. During the day, the collected cooling capacity of both bodies should be used to condense humidity. Condensation is only possible below the dew point temperature. The ambient air heats the two bodies 1 and 2 in the chosen representation different speed. But this is reflected in the colder body during the night 2 opposite the body 1 more than twice as much water can be separated, since its at night reached the lowest temperature in relation to the dew point of the day 3 cheaper. With decreasing air humidity, the dew point temperature drops and condensation is only possible on strongly cooled bodies.

2 shows a simple embodiment of the invention, comprising the body 5 , two reflective elements 6 passing through inflatable struts 11 were directed into a concave mirror shape, as well as two retaining walls 7 ,

3 On the right shows another embodiment of the invention, comprising the body 5 , a reflective element 6 that by inflatable struts 11 was directed into a parabolic mirror shape and a retaining wall 7 ,

4 shows the embodiment 3 after folding the reflective element through which the body during the day can be additionally protected from sunlight.

5 shows an embodiment of the invention comprising a condensate collection vessel 8th , a throttle 9 and a bimetallic strip 10 ,

The invention is not to those in the figures limited embodiments shown

general description the invention

command those who suffer from drought are often clear at night and cloudless and the radiation leads to a strong cooling. Sufficient size body (Stones) are still cold in the morning, the water on your surface condenses (dew). Due to the low mass of this body is the dew point temperature soon exceeded. Bigger bodies can become at night not below the dew point of the humid Cool air of the day because they are in the day by total or partial sunlight a higher amount of heat or due to your situation, only partially reduce your amount of heat gained during the day by heat radiation deliver in the night.

According to the invention, one or more bodies 5 Position this so that your radiate heat in as many directions as possible to the sun away from the sky. These bodies 5 are provided on the part of the radiating surface with or without heat transfer and heat pipe insulation and provided to the mounting surface with or without heat radiation and heat conduction and heat transfer insulation.

Suitable mirrored elements 6 are preferably made of metal such as titanium, aluminum, steel and / or coated glass particularly preferably coated plastic from the group of polyolefins [such as PE, PP], polyesters (PET, PBT), polyacrylates, polycarbonates and polyvinyl chloride, polyamides, Tedlar and PTFE.

suitable Coating materials of these plastics are bright colors and or metals such as preferably gold, silver, platinum, zinc, copper, tin particularly preferably aluminum or mixtures of these substances.

suitable heat transfer and heat radiation and heat pipe insulation the attachment surfaces are preferably made of foamed Plastic from the group of polyolefins [e.g. PE, PP], polyesters (PET, PBT), polyacrylates, polycarbonates and polyvinyl chloride, Polyamides and PTFE particularly preferably from fabric, fur, cork, leather, Straw or their mixtures.

suitable heat transfer and heat pipe insulation are preferably made of plastic from the group of polyolefins [such as. PE, PP], polyesters (PET, PBT), polyacrylates, polycarbonates and polyvinyl chloride, polyamides and PTFE particularly preferably aluminum-coated polyethylene.

The heat radiating body 5 are preferably made of galvanized iron, steel, aluminum, clay, marl, slate, quartzite, regionally occurring stones, cement, masonry, clay, with or without red oil paint or dark paint and more preferably plastic from the group of polyolefins [such as PE , PP], polyesters (PET, PBT), polyacrylates, polycarbonates and polyvinyl chloride, polyamides with or without coloring, with or without a dark finish. These are to be used alone or as an outer shell for materials with good thermal conductivity and high heat capacity such as water, octane, sand, quartzite, slate, marl, loam, and or mixtures thereof.

At in such a way cooled Body condenses after falling below the dew point temperature humidity which at this expiration and into a container collects.

In another embodiment are in the body 5 equipped with one or more tubes by heat conduction from the body 5 be cooled. The body 5 is covered on the part of the heat radiating surface used in the night during the day heat radiant, and Wärmeleitend- and heat transfer insulating. Suitable materials for this cover are the same as suggested for the attachment surface with or without an additional heat ray reflecting material such as those proposed for the reflective elements. Through the tube / tubes, the ambient air is carried out by natural convection or in a special embodiment by means of pressure-increasing blower. The back pressure in the tubes increases the formation of condensation.

In another embodiment, the air passed through the tube (s) must have a temperature sensor and a throttle before leaving it 9 happen. If temperatures higher than the corresponding dew point temperatures, which are calculated in a further embodiment with an air humidity meter remote from the body, are set at the temperature sensor, the air quantity is adjusted with the aid of the throttle 9 reduced. At temperatures that are far below the dew point temperature on the temperature sensor, the amount of air can be increased. This control can medium actuators or fan speed particularly preferred with a bimetallic strip 10 as a temperature sensor and actuator a throttle 9 be carried out actuated. Depending on the humidity of the ambient air is then the attachment point to or from the pivot point of the throttle 9 moved manually. This throttle 9 is in a preferred embodiment in the side wall of a condensate collection vessel 8th integrated. This vessel 8th as long as the body to be used as condensate collector should be plugged or screwed into one or more pipes. Suitable materials for the condensate collector 8th and the throttle 9 are galvanized iron, glass, steel, brass, copper, aluminum and or plastic from the group of polyolefins [such as PE, PP], polyesters (PET, PBT), polyacrylates, polycarbonates and polyvinyl chloride, polyamides, and PTFE.

Should the body 5 eg in the midday hours used for heating and are those in the body 5 used materials heat resistant so is the heat insulating protective cover and possibly the condensate collection tank 9 remove and close the tubes for faster heating. In this way, a sterilization of the tubes is possible.

In a further embodiment are in the body 5 the tube / tubes as laid in loops and filled with a heat-conducting liquid, so that the cold / heat can ever be dissipated to a separate heat-insulated storage. By means of the refrigeration capacity collected in the cold storage can then for condensate formation in a separate condenser, for the air conditioning of buildings and or to operate a Sterling engine available. By means of the amount of heat collected in the heat accumulator can be used for the air conditioning of buildings and or to operate a Sterling engine.

The present invention also relates to a method for collecting water using the apparatus described above. Due to the mirror 6 achieved increased cooling, the method is particularly suitable even at low humidity for water extraction and air conditioning of buildings.

Claims (32)

Device for collecting condensed water from the ambient air, comprising a) at least one body ( 5 ) having an inner and an outer surface, b.) at least one reflecting element ( 6 ), which are arranged to one another such that from the body ( 5 ) emits over half of the outer surface with an emissivity greater than 0.5 radiant heat into the sun-remote area of the sky, and wherein the condensate draining on the outer surface collects in one or more receptacles. Comprising apparatus for collecting condensed water from the ambient air, c.) At least one body ( 5 ) having an inner and an outer surface, d.) at least one reflecting element ( 6 ), which are arranged to one another such that from the body ( 5 ) emit into the sun-facing area of the sky over half of the outer surface having an emissivity greater than 0.5 radiant heat, and wherein the outer surfaces are provided with heat transfer and heat-conducting insulation and the condensate draining on the inner surface into one or more collection vessels collects. Device according to one of claims 1 to 2, characterized in that the body (s) ( 5 ) is provided on the mounting surface with or without heat transfer, heat conduction and heat radiation insulation is / are. Device according to one of claims 1 to 3, characterized in that for the body ( 5 ) is provided with a heat transfer, heat conduction and heat radiation insulating cover. Device according to one of claims 1 to 4, characterized in that the body (s) ( 5 ) is / are provided with one or more tubes which is / are thermally conductively connected thereto or consist of one or more tubes. Device according to one of claims 1 to 5, characterized that moistened through the tube / tubes Ambient air flows. Device according to one of claims 1 to 6, characterized that the tube / tubes at one End with or without pressure increase is / are. Device according to one of claims 1 to 7, characterized in that the tube / tubes at one end with one or more condensate collection vessels ( 8th ) are connected. Apparatus according to claim 8, characterized in that the connection (s) between tube (s) and the condensate collecting vessel (s) ( 8th ) is attached and solvable is / are. Apparatus according to claim 9, characterized in that the condensate collecting vessel one or more adjustable throttle valve (s) ( 9 ) having. Device according to claim 10, characterized in that that within the enclosed space of tube and condensate collecting vessel at least a temperature sensor or temperature and pressure sensors is appropriate. Apparatus according to claim 11, characterized in that the Temperaturfuhler consists of bimetal and with the throttle valve ( 9 ) on the one hand and on the other hand with condensate collecting vessel ( 8th ) or pipe is connected. Apparatus according to claim 12, characterized in that an attachment point of the bimetal to or from the pivot point of the throttle valve ( 9 ) is displaceable. Apparatus according to claim 12, characterized in that an attachment point of the bimetal to and from the suspension of the throttle valve ( 9 ) is displaceable. Apparatus according to claim 11, characterized in that in connection with a mounted in the ambient air pressure and / or humidity meter of the optimum formation of condensate opening of the throttle valve ( 9 ) is determined. Apparatus according to claim 15, characterized in that the dynamic pressure generated by the blower or compressors, the throttle valve ( 9 ) opens into the optimal opening area. Device according to claim 15, characterized in that the throttle valve ( 9 ) is opened by pneumatic, hydraulic or electric actuator in the optimal opening area. Apparatus according to any of claims 1 to 5, characterized in that through the tube / tubes a heat-conducting liquid flows and whose temperature is determined by means of temperature sensors. Device according to claim 18, characterized in that that the liquid is thermally insulated Piping to and from a thermally insulated Lead storage tank. Device according to claim 19, characterized in that that depending on the temperature with the help of a throttle, the flow stopped or reduced. Device according to claim 18, characterized in that that the liquid is thermally insulated Pipelines depending on the temperature to and from two different thermally insulated Lead storage tanks. Apparatus according to claim 21, characterized that depending on the temperature with the help of a throttle and / or directional valve the flow is stopped or reduced. Device according to one of claims 18 to 22, characterized that the cooling capacity off the storage tanks over one or more heat exchangers one or more capacitors is supplied. Device according to one of claims 1 to 23, characterized in that the reflective element ( 6 ) consists of metal, coated glass or coated plastic. Device according to one of claims 1 to 24, characterized in that the reflective element ( 6 ) is brought into shape by inflatable struts. Device according to one of claims 1 to 25, characterized in that the reflective element ( 6 ) by folding over and or shifting the body from heat protects. Device according to one of claims 1 to 26, characterized in that the reflective element ( 6 ) has on the outer wall one or more labels and characters. Device according to one of claims 1 to 27, characterized that the body galvanized iron, steel, aluminum, clay, marl, slate, Quartzite, regionally occurring stones, cement, masonry, clay, with or without red oil paint or dark paint, plastic with or without coloring or without painting alone or as outer shell for water, octane, sand, quartzite, Slate, marl, loam, and or mixtures of these. Device according to one of Claims 1 to 28, characterized that the cover and mounting surface insulation made of foamed plastic, Fabric, fur, cork, leather, straw or mixtures thereof. Device according to one of claims 1 to 29, characterized in that the mirrored elements ( 6 ) consists of metal and or coated plastic. Device according to one of claims 1 to 30, characterized in that the mirrored elements ( 6 ) by inflatable elements ( 11 ) are brought into a mold. Method of collecting water by use a device according to any one of claims 1 to 31.