DE102008028854A1 - Evaporator for use in e.g. heat pump, to partially or completely evaporating cooling water, has capillary structure provided in heating surface of heating element and is partially submerged in fluid reservoir - Google Patents

Abstract

The evaporator has a heating element (1) e.g. horizontally running cylindrical pipe, with a heating surface (1.1) for transmitting heat streams to a fluid to be evaporated. A fluid reservoir (4) stays in fluid conductive connection with a fluid inlet (2) and a steam outlet (3). The fluid reservoir accommodates a predetermined quantity of the fluid by forming a liquid surface. A capillary structure (5) is provided in the heating surface of the heating element and is partially submerged in the fluid reservoir.

Description

The The present invention relates to an evaporator, in particular for an air conditioning, refrigeration or heat pump, for partial or advantageous complete evaporation of a Liquid, especially at very low saturation vapor pressures.

Around To achieve evaporators with high efficiency, it is necessary large heat transfer coefficients produce the heating surface during evaporation. Of the Heat transfer coefficient is due to the evaporation process in itself (type of boiling process) and the material values of the vaporized Fluid conditionally. Conventionally, ammonia, Carbon dioxide or other hydrocarbons as a refrigerant used in chillers or heat pumps, by high saturation vapor pressures at low Temperatures have a high heat transfer coefficient to reach.

The However, using known refrigerants is concerned their environmental compatibility disadvantageous. So have to Safety measures are taken to an undesirable Leakage of the refrigerant from the refrigerant circuit to prevent.

The Use of water as a refrigerant could indeed the risks of environmental pollution are almost complete However, so far, as a limiting factor for the use of water as a refrigerant in conventional Tube bundle or plate heat exchangers the air conditioning and refrigeration the very low achievable Heat transfer coefficient during evaporation considered. This primarily reduces the efficiency of the evaporator, but in the wake of the entire air conditioning, chiller or heat pump.

In conventional tube bundle or plate heat exchangers the evaporation of the refrigerant takes place at low Pushing through tank boiling. Alternative evaporation processes such as flow boiling or spray cooling can only be implemented with high technical effort (post-evacuation, etc.) because the use of peripherals such as pumps etc. the warranty of container tightness difficult. In addition, the additional mechanical mean Peripherals cost and maintenance, what is undesirable.

In the case of tank boiling, the evaporation is based on the activation of nucleation sites for bubble growth. Only by the formation of vapor bubbles on the solid tube or plate wall, the evaporation of the refrigerant takes place. The quality of the heat transfer thus largely depends on how many active nucleation sites (nucleation sites where continuous bubble growth occurs) are present on the solid wall. The activation of nucleation sites, in turn, depends to a large extent on the overheating of the solid wall with respect to the saturation temperature of the refrigerant and some material values of the refrigerant. When using water as the refrigerant and desired heat flux densities of the order of 10 kW / m ² results at saturation pressures of less than 10 mbar (millibars) very high wall overheating in the order of 10 Kelvin (K) for nuclei activation. This is due to the very high surface tension of water at these pressures. The consequence of this fact is a very low nuclei density on the heating surface and a concomitant low heat dissipation by evaporation of water. In addition, due to the small number of vapor bubbles flowing off, no turbulent flows typical for the container boiling are generated in the boundary layer of the water near the heating surface, so that the convective heat transport is also insufficiently formed. The heat transfer is thus very bad overall.

at to unite a further increase in wall overheating the steam bubbles increasingly in steam cushions. This evaporation form of the Film boiling is unstable if and as long as these areas still local are limited. A closed vapor layer remains stable obtained and leads due to the poor thermal conductivity of the Steam too small heat transfer coefficients. This condition is also known as Leidenfrost's phenomenon.

Of the present invention is based on the object, an evaporator indicate, by means of which also the use of water or a water mixture at low saturation vapor pressures, in particular 20 mbar or 10 mbar or less becomes. The evaporator is characterized by the fact that a high Heat transfer coefficient at the heating surface is achieved and the structural design comparatively easy and inexpensive. Furthermore, should be on peripherals to dispense with forced convection. Rather, should advantageous the evaporation process in the vacuum range without from the outside imposed forced flow done.

The The object of the invention is achieved by an evaporator solved with the features of claim 1. In the dependent and further claims are advantageous embodiments of the invention.

The inventive evaporator, in particular for use in an air conditioning machine or a refrigerator or heat is executed, and which serves for the partial or advantageous for the complete evaporation of a liquid, in particular water, for example pure water, or a water mixture, comprises a heating element comprising a heating surface for transmitting a heat flow to the liquid to be evaporated. According to one embodiment, the heating element is electrically heated. For this purpose, electrical resistance elements can be integrated into the heating element or the heating element itself can form an electrical resistance. Further, it is possible to heat the heating element by means of a liquid or gaseous heating medium by the heating element flows through the heating medium or is flowed over on one side. Other embodiments of heating elements are conceivable.

Of the The evaporator according to the invention has at least one Liquid inlet and at least one steam outlet. The liquid to be evaporated is through the at least introduced a liquid inlet into the evaporator, and the steam generated is discharged through the steam outlet from the Evaporator discharged. In the evaporator is in the flow direction between the liquid inlet and the steam outlet Liquid reservoir executed with the Liquid inlet and with the steam outlet in flow-conducting Compound stands and a certain amount of liquid to be evaporated to form a liquid level. you This liquid reservoir could also act as a fluid pool describe.

The Heating element according to the invention has on its heating surface a capillary structure. The capillary structure is partially in immersed the liquid reservoir. This means that a part of the capillary structure below the liquid level in the liquid reservoir, whereas the remaining part of the capillary structure above the liquid level is arranged and thus not in the liquid reservoir dips. In principle, the part of the heating surface, which is located lower below the liquid level is executed capillary structure. Alternatively, the entire heating surface on a capillary structure.

By the capillary structure according to the invention on the Heating surface is achieved a double function: First means the capillary structure, in particular by a variety of applied to the heating surface ribs and / or in the heating surface incorporated channels is formed, a surface enlargement the heat-transmitting heating surface. On the other hand, this capillary structure causes a distribution of the liquid over it big surface. The liquid of the location at which the corresponding channel in the capillary structure is in contact with the liquid reservoir in the Channel, also against the gravitational force, pulled and advantageous distributed by capillary force on the heating surface. The Evaporation of the liquid then takes place predominantly in that channel section that is not in the fluid reservoir immersed, with the channel in this section advantageous only through the liquid drawn in by the capillary force is wetted. As a result, a very thin liquid film forms on the channel wall, due to the low film thickness a very low heat transfer resistance between the liquid-vapor phase boundary at which the evaporation takes place, and represents the heating surface.

Especially Advantageously, the heating element is a horizontally extending tube or executed as a horizontally extending plate. Advantageous has the heating element on its outside or on its radially outer periphery the heating surface on. However, it is also possible to use the heating surface to perform on an inside of the heating element.

Especially, if the heating element is designed in the form of a tube, It can be an inner, opposite the heating surface having a sealed flow channel, which is a liquid or gaseous heating medium leads. Thus, can the heating element are heated by means of the heating medium and in turn again the liquid to be evaporated, opposite the heating medium is separated by transferring the him vaporized heat flow to the liquid evaporate.

According to one advantageous embodiment, the capillary structure in the heating surface through an angle to the liquid level extending, in particular by perpendicular to the liquid level Channels formed, which the liquid to be evaporated transported by capillary force against the gravitational force from the liquid reservoir. Advantageously, the channels, which extend the capillary structure train, along, especially exclusively along the heating surface. This means that they are the heating element do not penetrate on both sides or from outside to inside.

Especially, if the heating element as a tube, for example as a cylindrical Pipe, executed, can be a variety of spaced from one another arranged, extending in the circumferential direction of the heating channels be provided, which form the capillary structure. alternative it is also possible to provide at least one channel which is helical Running along the pipe running channel.

The evaporator according to the invention can be used in particular for the evaporation of water as a refrigerant at a saturation pressure of 20 mbar, 15 mbar, 10 mbar or less in each case. Greater benefits, however, already result at pressures below one bar. Particularly advantageous is at these low pressures and a low wall overheating, for example, from 1 to 2 Kelvin or up to 3, 4 or 5 Kelvin, a heat flux above the heating surface between 1 and 50 kW / m ² , in particular between 5 and 15 kW / m ² or more preferably set to 9-11 kW / m ^2, for example of 10 kW / m ^2. Wall overheating describes the temperature difference between the temperature of the heating surface of the heating element and the temperature of the evaporating liquid.

A Chiller or a heat pump, the one Evaporator and a condenser in a refrigerant circuit wherein the refrigerant evaporates in the evaporator and in which condenser is liquefied, stands out According to the invention characterized in that the evaporator the heating element according to the invention with the capillary structure the heating surface partly in an accumulation of the Is immersed refrigerant has.

Even though presently proposed as a heating element a pipe or a plate was, wherein an inventive evaporator may also have a plurality of such heating element, the invention is not limited to this form of heating elements. That's the way others are Shapes conceivable, for example, a sponge shape, in particular a Metal sponge immersed in the liquid to be evaporated.

If a liquid or gaseous heating medium as Heat source is used, the inventive Evaporator advantageous next to the liquid inlet and the steam outlet a Heizmediumeinlass and a Heizmediumauslass on. In an electrically heated heating element can according to a Embodiment of course to such a heating medium inlet and dispensed with such Heizmediumauslass.

The Invention will be described below with reference to an embodiment and the accompanying figures are described by way of example.

It demonstrate:

1 a schematic cross section through an inventively designed evaporator with a plurality of heating elements;

2 a schematic longitudinal section through one of the heating elements according to the 1 ;

3 various examples of applicable ranges for the channel width (KB), the channel height (KH) and the relative filling level in an inventively designed evaporator.

The evaporator according to the embodiment according to the 1 has two heating elements 1 each of which has a heating surface 1.1 having. Further, a liquid inlet 2 for introducing the liquid to be evaporated into the evaporator and a steam outlet 3 provided for discharging the vaporized liquid or the vapor from the evaporator. About the fluid inlet 2 the liquid to be evaporated becomes a liquid reservoir 4 fed. The heating elements 1 dive into the liquid reservoir 4 one that is part of the capillary structure 5 on the heating surfaces 1.1 the heating elements 1 below the liquid level of the liquid reservoir 4 whereas the remainder of the capillary structure is positioned 5 the heating elements 1 is positioned above the liquid level.

Heat to evaporate the liquid is through a heating medium, which is inside the heating elements 1 or by the heating elements 1 flows through, introduced into the evaporator, see the per heating element 1 provided flow channel 6 , This flow channel 6 , which in the present case has a circular cross-section or a cylindrical circumference, may be structured on its surface, in particular by means of a capillary structure, or be largely or completely smooth or planar.

Because of the capillary structures 5 the heating elements 1 only partially into the liquid reservoir 4 are submerged, liquid from the liquid reservoir by capillary forces against the gravitational force in the non-immersed areas of the capillary structures 5 transported. In these non-submerged areas of the capillary structures 5 a thin film of liquid forms 7 out. This is especially good in the 2 recognizable.

Furthermore, one recognizes in the 2 in that, according to the embodiment shown, the capillary structures 5 through perpendicular to the liquid level of the liquid reservoir 4 running channels 5.1 be formed.

In the 2 one recognizes further clearly the flow channel 6 , which the heating medium within the heating element 1 separated from the liquid to be evaporated in the liquid reservoir 4 leads. Thus, there is no exchange of vapor or liquid between the interior of the heating element 1 and the environment of the heating element 1 instead of.

In the 3 possible ranges are shown, which can be selected for the channel width (KB) and the channel height (KH), for example in a tubular heating element. Furthermore, possible fill levels are shown in percent (%), with a fill level of 0.1 means that the heating element or the tube is immersed in the liquid reservoir at its lower tenth (10 percent of its height), whereas a fill level of 0.7 means in that the heating element or the pipe with its lower 7/10 (70 percent of its height) is immersed in the liquid reservoir.

Especially high heat transfer coefficients can be achieved when the ratio between channel width to channel height 1: 3 to 1: 2.

The specified size values for the channel width and the channel height are in millimeters.

Of the Inventive evaporator or the inventive Method is particularly advantageous in a so-called solid sorption heat pump executed. Such a solid sorption heat pump, as is the invention according to one embodiment relates, comprises an adsorber-desorber unit with a heat exchanger and a sorbent material, especially solid sorbent material. This adsorber-desorber unit is in a common, to the environment sealed housing together with a capacitor and an evaporator or together with a condenser-evaporator unit arranged, wherein the adsorber-desorber unit and the condenser / evaporator or the condenser / evaporator unit through an adsorptive permeable element are separated from each other.

According to one embodiment, the solid sorption heat pump is designed as in the patent DE 102 17 443 B4 will be shown. The condenser-evaporator unit can then have on its heating surface the capillary structure according to the invention, which is partially immersed in the liquid reservoir, in particular at the bottom in the bottom region of the housing of the solid sorption heat pump. According to an alternative embodiment, a condenser is provided in addition to an evaporator. In this case, in particular, the evaporator can be carried out according to the invention. However, it is alternatively or additionally possible to carry out the condenser with the illustrated capillary structure.

According to one advantageous embodiment is the adsorber-desorber unit arranged between a condenser and an evaporator, in particular the condenser is at the top of the case, including the adsorber desorber unit and below that the evaporator is positioned.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 10217443 B4 [0036]

Claims (11)

Evaporator, in particular for an air conditioning machine, heat pump or chiller, for the partial or complete evaporation of a liquid; 1.1 with a heating element ( 1 ), which has a heating surface ( 1.1 ) for transmitting a heat flow to the liquid to be evaporated; 1.2 with a liquid inlet ( 2 ) and a steam outlet ( 3 ); 1.3 with a liquid reservoir ( 4 ) connected to the liquid inlet ( 2 ) and the steam outlet ( 3 ) is in flow-conducting communication and receives a predetermined amount of liquid to be evaporated to form a liquid level; characterized in that 1.4 the heating element ( 1 ) on its heating surface ( 1.1 ) a capillary structure ( 5 ), which only partially into the liquid reservoir ( 4 ) is immersed. Evaporator according to claim 1, characterized in that the heating element ( 1 ) is designed as a horizontally extending tube, in particular on its outside the heating surface ( 1.1 ) having. Vaporizer according to one of claims 1 or 2, characterized in that the heating element ( 1 ), in particular in the form of a tube, an inner opposite the heating surface ( 1.1 ) sealed flow channel ( 6 ), which leads a liquid or gaseous heating medium. Vaporizer according to one of claims 1 to 3, characterized in that the capillary structure ( 5 ) in the heating surface ( 1.1 ) extending at an angle to the liquid level, in particular perpendicular to the liquid level extending channels ( 5.1 ), which the liquid to be evaporated by capillary force against the gravitational force from the liquid reservoir ( 4 ) transport. Vaporizer according to one of claims 1 to 4, characterized in that the capillary structure ( 5 ) through channels ( 5.1 ) is formed along along, in particular exclusively along the heating surface ( 1.1 ). Evaporator according to one of claims 2 to 5, characterized in that the capillary structure ( 5 ) in the form of running in the circumferential direction of the tube, spaced apart channels ( 5.1 ) or as a helically along the pipe extending channel ( 5.1 ) is executed. Use of an evaporator according to one of Claims 1 to 6 for the evaporation of water in a Saturation pressure of 10 mbar or less. Use according to claim 7, characterized in that a heat flux density above the heating surface ( 1.1 ) between 1 and 50 kW / m ² , in particular between 5 and 15 kW / m ² or 9 to 11 kW / m ^{2 is} set. Chiller or heat pump 9.1 with a refrigerant circuit comprising an evaporator and a capacitor, wherein 9.2 the refrigerant in evaporates the evaporator and liquefied in the condenser becomes, characterized in that 9.3 the evaporator according to one of claims 1 to 6 executed is. Chiller or heat pump according to claim 9, characterized in that the refrigerant is water or a water mixture. Chiller or heat pump according to one of claims 9 or 10, characterized in that the refrigerant in the evaporator has a pressure of 20, 15, 10 mbar or less.