DE10351096A1 - Improved heat exchanger for water extraction from air - Google Patents

Abstract

A method and apparatus for recovering water from the moisture content of the ambient air by means of a heat exchanger with a longitudinally flowed through by a gaseous medium housing (5), DOLLAR A in which in this housing a plurality of arranged in the housing longitudinal direction, flowed through by a cooling medium, helical tube strands are arranged in the form of closely spaced evaporator coils (2), and wherein the evaporator coils (2) are secured in the concentric position to the longitudinal axis of the casing, projecting into the pitches of adjacent evaporator coils (2), and the evaporator coils being plural DOLLAR A wherein the flow direction of the gaseous medium is opposite to the flow direction of the coolant, and DOLLAR A wherein at the air outlet side of the housing (1) comprises a device for water separation of water droplets en is provided DOLLAR A and wherein a cleaning device which ensures over the cross section of the housing (1) uniform spraying of the cleaning agent.

Description

Long before Prometheus knew how to bring the fire to man, he knew the human being the water. Since time immemorial it is surrounded by water and he knows, that he is for it needs his life. But just as long he knows that there are floods of water Can threaten life. On the other hand, the soil of river landscapes is therefore very fertile because he is flooding regularly with Minerals is enriched.

To learns today The human water as a treat, as a remedy (baths, drinking cures), but also as Disaster (floods, Icing, blizzards) In the art and literature of all centuries is water in all Shapes are presented and treated, for example as devastating Power, as a life giver, as a dividing border river, or as a transport medium for merchant ships and warships. On the one hand, water serves the earning of the fishermen, On the other hand, it is a metaphor of romance, with the fine Mist of the rainbow is shaped the sign of peace. So it means sinking and radiant new beginning at the same time.

The Totality of all water resources on Earth has been constant for millions of years. Water covers approx. 71% of the earth's surface and is the most common chemical compound. additionally contains still the atmosphere 4% water in the form of water vapor.

The Total water volume of the earth is at about 1383 million cubic kilometers estimated. These are mainly salt water. Only the vanishing small residual of 2.6% is omitted on the fresh water. As fresh water This is water with less than 1 gram evaporation residue designated. If one draws from this crowd the hard to reach for man Polar ice, glacial ice and the very deep groundwater, so it turns out that for Humans, animals and plants only about 8% of the available fresh water are directly usable.

Life in the form known to us is not without water on our planet conceivable.

water accompanies biological development as the most important chemical compound from the beginning. It is essential for the reactions in hydrophilic compartments (Liquid spaces) of all living systems, humans, animals and plants.

• 1. Wasser ist Baustoff bei der Photosynthese der Pflanzen und Bestandteil der Organismen,
• 2 Wasser ist Lösungsmittel, z. B. für die Bodennährstoffe,
• 3 Wasser ist Nahrungsmittel,
• 4 Wasser ist für alle Organismen Lösungsmittel, Transportmittel und Quellungsmittel. Es ermöglicht die zahlreichen chemischen und kolloidchemischen Zellreaktionen.

Water here have the following meaning fields:

• 1. Water is a building material in photosynthesis of plants and part of organisms,
• 2 water is solvent, z. B. for soil nutrients,
• 3 Water is food,
• 4 For all organisms, water is solvent, means of transport and swelling agent. It allows the numerous chemical and colloid chemical cell reactions.

water is not only a hydrophilic reaction space, plastic - elastic fillers, heat storage and cold storage. It is also associated with memory properties and owns interesting interactions with electromagnetic waves and Sound waves.

Ultimate Regulative for the conservation of freshwater resources is the water cycle of nature. This is made up of together the processes of Water evaporation, the precipitation, the drain and the following Again evaporation. From the balance of the global water cycle The Earth shows that on the seas in equal periods one bigger amount Water evaporates as is precipitated by precipitation. On the land on the other hand are inverse conditions in front.

Of the untiring The engine of this water cycle is our central star, the sun. Under the energy-bearing influence of the sun's rays changes Water its state of aggregation (physical appearance) and his location.

Where always it is located, in waters or Oceans, but also in the soil and in plants, it evaporates and rises as water vapor into the atmosphere on. This happens in unimaginable quantities. Alone about the The oceans become an "airfreight" of about one billion every minute due to the sunlight Tons of water into the atmosphere transported. This results in an annual Water mass of 450 quadrillion tons. Another 70 to 75 quadrillion Tons of water go yearly from the mainland into the air envelope over.

So For example, there is a beech forest of one hectare in size during his Growing season on average every day over 10000 liters of water to the the atmosphere off, so a mass of 10 tons. In the upper cold air layers the atmosphere that cools Water vapor again and condenses into small droplets, which, in turn, pile up into clouds. Achieve these droplets one certain size, will they are covered by gravity and fall as rain, snow or Hail back to earth. About 80 percent of this amount reaches the sea, the rest, for example a trillion liters a year, settles on the mainland.

This However, precipitation does not occur evenly.

Millions of people would give a lot for it, even if only once in their region Year would dribble from the sky.

Because without water there are no crops and no food.

The uneven distribution the rainfall on earth is one of the biggest dietary problems of the world Mankind.

Therefore There have long been procedures with simple means of water to win from the air.

A Method basically consists in the water contained in the air on a horizontally clamped, and lowered in one place, Allow foil to condense and drip into a container placed underneath allow. In this way, however, only very small amounts Win water.

The The basic principle used here is that which is available Air at a cool area to let them cool down and cool them down in this way and by forcing it to release parts of the water bound in the air.

Because Air of a certain temperature can only produce a certain amount of water Save as humidity. When that amount is reached, that is Air saturated with water vapor. If the air is then cooled in the sequence, it can only a smaller Save amount of water vapor. That way excess water can not be held by the air and falls off, it condenses. This happens because the excess water vapor in cooler surfaces reflected, compressed into drops that follow gravity.

Technically One uses this principle of action by ensuring that on the one hand will that possible a lot of air on a surface, the cooler is as the current air temperature, and that is the corresponding area as big as made possible becomes.

A such device, with the heat or cold is transferred from one medium to another, one calls one Heat exchanger.

A special, designed for the recovery of water from air, heat exchanger is from the DE 101 35 654 A1 previously known.

in this connection it is essentially a heat exchanger with a longitudinal direction of a gaseous one Medium flowed through casing with a plurality of in the housing longitudinal direction arranged and cooled by a coolant perfused Heat exchanger tubes. Here are the heat exchanger tubes designed as helical tubular strands and the pipe strings are coolant inlet side and coolant outlet side on coolant distribution pipes with coolant inlet and coolant outlet connected.

As a special feature is highlighted in such a heat exchanger, that the running in the housing longitudinal direction pipe strands are arranged in housing end view to form tube bundles, and that two or more tube bundle rings are provided in a concentric arrangement. Furthermore, it is emphasized that the adjacent tube strands of the tube bundle rings engage with their helical coils by a predetermined amount in the pitches between the helical coils
(cf DE 101 35 653 A1 , Claim 1)

at this known device the problem of impending icing of the heat exchanger is not addressed. This is known to be a real danger in practical operation. In addition, the efficiency of the known heat exchanger is suitable activities to improve.

Of the The point of view of the cleaning of the heat exchanger is described in the The prior art also not taken into account.

the inventive heat exchanger is located Therefore, the object of a device or a method indicate the risk of icing in operation largely avoided and the overall efficiency is increased.

These Task is solved with a heat exchanger according to the siblings claims 1 to 4, and the method according to claim 15.

In the from the DE 101 35 654 A1 known heat exchanger may occur in practical operation that under certain operating conditions icing of the cooling coils occurs. Such a process makes the heat exchanger almost ineffective.

Around To prevent this is inventively provided that as trained helical pipe strands Heat exchanger tubes not supplied by a common system with coolant, but in several coolant circuits split in different ways with coolant be supplied.

Another important aspect of the heat exchanger according to the invention is that the flow direction of the coolant is directed opposite to the flow direction of the air flow, and that via a device for water separation The recovered water can be easily discharged.

moreover is by installing a cleaning device whose operation in regular time intervals ensures that the system is functionally reliable in continuous operation remains.

Of the inventive heat exchanger will be closer in the following described. In detail show:

1 a schematic representation of the heat exchanger according to the invention.

2 a plan view and a cross section of this heat exchanger

3 a schematic representation of a defrosting device for cooling coils

In 1 are shown in a lateral plan view schematically the individual components of the heat exchanger according to the invention.

Here is with ( 1 ) denotes the cylindrical evaporator housing or heat exchanger housing.

Under ( 2 ) In principle, parts of cooling coils of different coolant circuits are outlined.

With ( 3 ) and ( 4 ) are marked the positive pole and the negative pole of an electric Kühlwendelauftauvorrichtung.

This device has a similar function as the common electric powered thawing devices for frozen water pipes. The electrically between the connections ( 3 ) and ( 4 ) act as an electrical resistance and consequently heat rapidly by the power loss of the electrical current, causing the thawing.

Under ( 5 ), the connections A, B and C can be seen for three different coolant circuits. The arrangement of the coolant circuits is in 2 The direction of the arrow shown indicates the direction of flow of the coolant. This means that at this point coolant flows into the heat exchanger.

With the arrow ( 6 ) is the principal point of the outflow of coolant.

The Number of coolant circuits is not limited to the number three. It can also according to the invention two or more than three coolant circuits be provided.

On the right side of the in 1 shown heat exchanger is schematically a turbine ( 11 ) drawn, which drives the air flow according to the invention counter to the direction of the coolant flow.

Of the inventive heat exchanger Fulfills but also its function when the flow direction of the air flow with the flow direction of the coolant flow is rectified. Only the efficiency is in this case lower. An improvement in efficiency compared to the state The technique, however, also arises in this case.

With ( 9 ) and ( 10 ) are the electrical connections of a possibly required air heating ( 8th ) with a schematically illustrated heating coil ( 15 ) designated.

On the left side of the heat exchanger is the water separator ( 7 ), on whose obliquely placed against the air flow lamellae, the condensed water drops get stuck and to the water drain ( 16 ) reach.

These inclination The slats are motor-adjustable and can speed the air flow be adjusted. This can be done manually and / or automatically.

Under ( 17 ), a sensor for determining the icing is drawn by way of example. Such sensors are known for example from the aircraft industry.

Except the known dew-point levels with the traditional optical beam Sensors are now known with the SAW (Surface Acoustic Wave = Surface waves) technology work. The SAW signal is sensitive to condensation by dew or frost, but not on impurities.

These Property makes such sensors for the present application particularly suitable.

At the Entrance of the air flow are according to the invention sensors for measuring the humidity and the air temperature. Their readings as well as the measured values of the icing sensors Program structures used for optimal control of water production.

In 2 is a plan view of the heat exchanger according to the invention and an associated view of the cross section drawn.

In the circular structured plan view are next to the evaporator housing ( 1 ) three concentrically arranged, annular supply lines A, B and C, each of which conduct a coolant flow to the individual coolant circuits A, B, and C.

The A, B or C denoted small circles symbolize this in the plan view, the helical tubular strands of individual coolant circuits. The corresponding connection pipes from the supply lines A, B and C, respectively to the individual coolant circuits A, B and C are for reasons the better overview not shown.

The Control of the coolant flow through the individual coolant circuits is hereby controlled in such a way that in each case one or more circles operated on the border with icing. This condition is characterized by a high compressor pressure and a low Coolant flow. The phase of defrosting essentially takes place in that the Coolant flow is stopped. The phases of icing and defrosting take place thus alternately in dependence from the humidity.

It this results in an increase the efficiency of the heat exchanger according to the invention over the State of the art of 25% at a relative humidity of 40%.

at a relative humidity of 75% results in one more increase of the efficiency of 7% to 10%.

In the in 3 shown defrosting device for the respective cooling coils are with ( 12 ) the junctions between the individual cooling coils ( 2 ) and the corresponding Kühlkreiszuläufen.

With ( 13 ) insulate that the cooling circuit junctions ( 12 ) on the one hand ensure the inflow of coolant, but on the other hand it is ensured that no impermissible electrical connection between the live heated line section of a cooling coil ( 2 ) and the housing ( 1 ) consists.

The direct electrical connection between the electrical connections ( 3 ) respectively. ( 4 ) and the cooling coils to be heated ( 2 ) is connected via the connection attachment ( 14 ) produced.

1

Heat exchanger housing, evaporator housing

2

cooling coil

3

connection for Kühlwendelauftauvorrichtung

4

connection for Kühlwendelauftauvorrichtung

5

Intake refrigerant

6

procedure refrigerant

7

water

8th

air heating

9

connection air heating

10

connection air heating

11

turbine (Axial fan)

12

Cooling circuit together

13

insulation element (Cooling coil)

14

terminal fixing (Electric)

15

heating coil (Air)

16

water drain

17

icing sensor

18

Humidity Sensor in association with

temperature sensor

Claims (15)

Heat exchanger with a longitudinally flowed through by a gaseous medium housing ( 1 ), in which in this housing a plurality of arranged in the housing longitudinal direction, flowed through by a cooling medium, helical tube strands in the form of closely spaced evaporator coils ( 2 ) are arranged, and wherein the evaporator coils ( 2 ) in the longitudinal axis of the housing ( 1 ) concentric layer, in the pitches of adjacent evaporator coils ( 2 ), and wherein the evaporator coils are associated with a plurality of different cooling circuits (A, BC), Heat exchanger with a longitudinally flowed through by a gaseous medium housing ( 1 ), in which in this housing a plurality of arranged in the housing longitudinal direction, flowed through by a cooling medium, helical tube strands in the form of closely spaced evaporator coils ( 2 ) are arranged, and wherein the evaporator coils ( 2 ) in the longitudinal axis of the housing ( 1 ) concentric layer, in the pitches of adjacent evaporator coils ( 2 ), and wherein the evaporator coils are associated with a plurality of mutually different cooling circuits (A, BC), and wherein the flow direction of the gaseous medium opposite to the flow direction of the Coolant is. Heat exchanger with a longitudinally flowed through by a gaseous medium housing ( 1 ), in which in this housing a plurality of arranged in the housing longitudinal direction, flowed through by a cooling medium, helical tube strands in the form of closely spaced evaporator coils ( 2 ) are arranged, and wherein the evaporator coils ( 2 ) in the longitudinal axis of the housing ( 1 ) concentric layer, in the pitches of adjacent evaporator coils ( 2 ), and wherein the evaporator coils are associated with a plurality of mutually different cooling circuits (A, BC), and wherein the flow direction of the gaseous medium is opposite to the flow direction of the coolant, and wherein at the air outlet side of the housing ( 1 ) a device ( 7 ) is provided for the separation of water from drops of water. Heat exchanger with a longitudinally flowed through by a gaseous medium housing ( 1 ), in which in this housing a plurality of arranged in the housing longitudinal direction, flowed through by a cooling medium, helical tube strands in the form of closely spaced evaporator coils ( 2 ) are arranged, and wherein the evaporator coils ( 2 ) fixed in concentric position to the longitudinal axis of the housing in (1), in the pitches of adjacent evaporator coils ( 2 ), and wherein the evaporator coils are associated with a plurality of mutually different cooling circuits (A, BC), and wherein the flow direction of the gaseous medium is opposite to the flow direction of the coolant, and wherein at the air outlet side of the housing ( 1 ) a device for water separation of water droplets is provided. and wherein a cleaning device is one which extends across the cross-section of the housing ( 1 ) ensures uniform spraying of the cleaning agent. heat exchangers according to one of the claims 1 to 4, characterized in that for generating a movement of the gaseous Medium a fan or a compressor (reciprocating compressor, screw compressor) or a turbine is used. Heat exchanger according to one of claims 1 to 5, characterized in that as a production material for the outer housing ( 1 ), Aluminum, carbon, magnesium or titanium is used. Heat exchanger according to one of claims 1 to 6, characterized in that as a production material for the evaporator coils ( 2 ) Copper, aluminum, stainless steel, plastic or carbon are used. heat exchangers according to one of the claims 1 to 7, characterized in that the coolant flow to the air flow, instead of opposite, rectified. Heat exchanger according to one of claims 3 to 8, characterized in that the fins of the water separator ( 7 ) are manually and / or automatically adjustable. heat exchangers according to one of the claims 1 to 9, characterized in that the cooling coils via an electric heater are heated. Heat exchanger according to one of claims 1 to 10, characterized in that the cooling coils ( 2 ) are electrically isolated from the Kühlkreiszusammenführungen. Heat exchanger according to one of claims 1 to 11, characterized in that the supplied air via an additional heating ( 8th ) can be heated. heat exchangers according to one of the claims 1 to 12, characterized in that one or more icing sensors monitor the icing of the individual cooling circuits. heat exchangers according to one of the claims 1 to 13, characterized in that sensors for measuring the Humidity and / or temperature as additional monitoring elements to be used. Process for obtaining water from the moisture content of the ambient air by means of a heat exchanger with a housing through which a gaseous medium flows longitudinally ( 1 ), in which in this housing a plurality of arranged in the housing longitudinal direction, flowed through by a cooling medium, helical tube strands in the form of closely spaced evaporator coils ( 2 ) are arranged, and wherein the evaporator coils ( 2 ) in the longitudinal axis of the housing ( 1 ) concentric layer, in the pitches of adjacent evaporator coils ( 2 ), and wherein the evaporator coils of several voneinan the different cooling circuits (A, BC) are assigned, and wherein the flow direction of the gaseous medium is opposite to the flow direction of the coolant, and wherein at the air outlet side of the housing ( 1 ) a device for water separation of water droplets is provided. and wherein a cleaning device is one which extends across the cross-section of the housing ( 1 ) ensures uniform spraying of the cleaning agent.