DE102004056409B3 - Heat exchanger for evaporation or condensation has three-part block with inner concentric arrangement of heat exchange interfaces - Google Patents

Abstract

A flat surface evaporator or condenser consists of a three-part block with a base, an interlocking medium feed unit and a cover plate. The base block inner face has an array of concentric grooves that engage with matching profiles on the medium feed unit. When presented to each other, the base block and medium feed unit form a series of concentric heat exchange channels and faces. The base block has a fluid inlet and a fluid outlet and the medium feed unit has a fluid inlet and a fluid outlet. The cover plate closes the medium feed unit and has a seal. The three heat exchanger components are held together by bolts.

Description

common and known apparatuses with which media are evaporated are evaporators. appliances in which media condense, referred to as a condenser (condenser). It is known that by means of the evaporator or condensers the media thermal energy take or give off, the media evaporate or condense. The most common Evaporators and condensers are those that are affected by exposure to thermal energy always under the action of energy or Energy extraction.

The common Design are single or multi-pipe systems, from one pipe or more Tubes or single or multi layered plate systems from one or more plates.

The Application and use of the systems takes place under the influence of thermal Energy, in which a medium evaporates in the tube or on the plate or condensed. flows or flows in the tube to be evaporated or condensing medium, so is transfer the thermal energy of the medium to the pipe and from there mostly to another medium, which flows around the pipe passed. The same is given at the plate evaporator or plate capacitor. The to be evaporated or condensing medium flows or flows over one Plate. The thermal energy is transferred to the plate, these in turn on another medium, on the opposite side the plate flows or flows, convicts.

It is based on the problem that the Evaporation processes unfavorable and thus an inadequate and incomplete change of media status bring with it, what an unfavorable thermal efficiency has the consequence.

otherwise the problem is that at Systems that are based on the Carnotic cycle process, in particular this cold vapor processes such as heat pumps, Refrigerators and similar, the tuning of the compressor to the peripheries like evaporator, Condenser (condenser) and others must be respected. Consequently, the evaporators or condensers always apply to the compressor adapt to a favorable Efficiency, here referred to as coefficient of performance to obtain.

Of others are common flat cooling surfaces required to assemble flat structures as given in electronics and these to a sufficient extent through the standardized device parts how to temper compressor.

Of Another problem is that in standardized and thus inexpensive compressors an integration of any surface evaporators not functional and the coefficient of performance is insufficient is.

Around the requirement of a tempered surface and an adaptation of the Evaporator or the condenser to the compressor, happens frequently an indirect tempering by adaptation of a tube or more Pipes on or in a plate.

Often the pipe or pipes in the meandering course in good conductive Materials such as aluminum applied or the tube in a material given groove pressed. Otherwise, this course will be through holes or millings in imitated and incorporated in the plate.

Other Arrangements are those that Medium in a cavity, which is equipped with a baffle, is injected. Often the aperture is at the same time the thermal transmission plane, where the objects are mounted. Still other arrangements are from the shape that that Medium like refrigerant over one Level flows or streams, this being the mounting plane for For example, represents electronic elements.

outgoing The above prior art is based on the problem that on the one hand by the indirect heat transfer additional Thermal resistances occur and secondly because of the very short route (pipe routing), as is the case with small evaporators or condensers insufficient evaporation or condensation takes place. Consequently, it is the transferred thermal performance unfavorable. To meet the requirements of sufficient power output with the existing standard compressors to meet, will be a remedy often the evaporator surface or condensate surface enlarged, therefore will thermal over a larger area Transfer energy. The related power density, power per area is correspondingly low, what kind of the objects to be tempered are usually insufficient. This applies equally for capacitor and evaporator.

Unfavorable acts also the heat conduction away for meandering, because the thermal resistance growing with the distance and unfavorable the temperature distribution of the plane affects.

consequently are over the entire surface tempered levels with integrated evaporators demanded that a large power density exhibit.

object The present invention is a surface evaporator or area condenser with an inside structure, which is suitable both for expanding Evaporating and imploding when condensing takes into account, as also by the internal structure an additional enlargement of the Media contact surface includes, where power, pressure and temperature through the variation the inner distance are controllable.

These The object is achieved by the Features of the claims 1 to 8 solved.

According to the present Invention, the evaporator or the condenser consists of two main parts, the evaporator effect part and the media guide part, wherein the evaporator active part or capacitor active part for the user represents the usable area. The evaporator effect member is structured so that in its inner side concentric arranged one or more wells. This structure corresponds to an open-topped channel system, which does not have any Inflow and outflow features. One all around extending cavity communicates with the outermost Deepening by a round inward open slot. Prefers this cavity is placed under the sealing surface to increase the size of the textured surface to obtain. The structure of the second evaporator or condenser part, that has the job, the media management within the evaporator effect part, the media guide part, is thermally unfavorable conductive material and forms the appropriate counterpart. It has surveys, their arrangement and distances correspond to those of the wells in the evaporator active part and contains no cavity. The media guide part is completed with the evaporator active part, wherein the elevations in introduced the wells and kept in the distance. A seal encloses the structure and seals to the outside off, being outside the seal rest the parts. By means of a on the media guide part Outside Overlying plate and several screws are the plate and the media leadership part fixed and clamped on the evaporator active part. The evaporator active part or the media guide part have one or multiple media feeds and media transfers or the additions and removals are divided on the evaporator active part and media guide part.

The Structure of an evaporator effect part or condenser effect part and a media guide part is parallel as often as desired, and then creates a composite represents.

By a slightly curved inward Plate, a pressure plate, is the inner distance from the media guide part, the ceiling to the opposite Evaporator active part, adjustable to the bottom. Otherwise, the inner distance of the recesses to the surveys by means of a Mechanics vary, with a linked stamp passing through the plate carried out is and rests on the underlying media guide part, here force exercises. Again otherwise, there is the variation of the distance in which a plate and the media guide part form a pressure box. The pressure cell has one or more inputs and or outlet nipple, wherein an enclosing Seal between the media guide part and plate comes to rest, seals to the outside. By or the inlet and outlet nipples a medium such as gas (compressed air) is introduced and / or discharged.

While the media inflows be taken in the middle of the system in the evaporator done at the condenser the media inflows from the outside. The media outflows in each case reversed.

According to the invention is of Advantage that at the given arrangement the vaporizing medium, which from the inside outward passed and correspondingly conversely a condensing medium, which from the outside is directed to the inside, a continuous area expansion and in discrete intervals, this is preferably equidistant are, a volume expansion undergoes and correspondingly when condensing vice versa. The vaporizing or condensing medium becomes volumes favorable invoice carried.

One Another and essential inventive advantage is that by the distance variation of the media flow is variably determined by the inner space in the space between the media guide part - the ceiling - to the Evaporator active part - the Floor - varies is, which reduces power, pressure and temperature in the evaporator are adjustable to the requirements.

One Another advantage achieved by the invention is that the apparatus as well as the evaporation as well for the condensing of media is usable.

According to the invention is the structure of the evaporator effect, the wells an enlargement of the Media contact surface given, which increases the heat transfer area.

An inventive advantage is the miniaturization of the inner wall spacings that are located between the elevation walls of the media guide part and the well walls of the evaporator effect part. The heat transfer from the medium to the structural surface of the evaporator active part and thus the dissipation of thermal energy of the flowing or flowing media film on the surface will be improved.

One Another and significant inventive advantage is that in relation to the mounting surface the medial contact surface is much bigger, wherein the medial contacting surface is directly opposite the mounting surface and thus given a short thermal discharge to the mounting surface is.

One Another inventive advantage is that the media flow during evaporation in centric direction and when condensing in the reverse centric Direction takes place and that one Media flow along the surrounding seal is prevented.

According to the invention the media guide part from thermally unfavorable conductive material.

Innovative The advantage is that the Distance variation by means of a curved pressure plate or a Mechanics with one or more connected punches or with one Pressure cell, is achievable.

Innovative The advantage is that a uniform temperature distribution prevails at the user level.

By the invention is given a very flat and very small design in which the evaporation and condensation processes run extremely low.

A further appropriate and advantageous embodiment and application of the invention is characterized given that one double-sided structure is used, wherein the evaporator active part contains two identical or different structures on both sides, each covered by the media guide parts become.

Of the achieved by this inventive embodiment advantage is that a medium evaporated on one side of the evaporator effect and a medium on the other side of the evaporator active condenses.

applications and applications finds the above-mentioned invention or their Embodiments in the field of evaporation and Kondensierunssysteme such as distillation apparatus, heat pumps, Cold vapor chillers, Refrigerators and others. Systems that are in the fields of heating or cooling bspw. of electronic components, as heating and / or cooling tables or in condensation, for example. Drying of gases, filtering of moist Air or gas mixtures, fractionation of media, or in the Air conditioning technology and the like applied become.

Especially is the evaporator for the optoelectronics applicable, for the dissipation of thermal energy (heat) that develops through the flat LED's.

The Inventions are described below with reference to the accompanying drawings Drawings described. Show it:

1 an area evaporator in an exploded view (area condenser), which consists of two main parts, the evaporator effect part and the media guide part, wherein the media guide part is provided with a pressure cell and

2 the inside of the media guide part in perspective.

1 shows the evaporator active part 1 in which in the inside and from the center starting concentrically arranged open recesses 2 . 3 are incorporated. An all-round cavity passing through the holes 4 . 5 that with stopper 6 . 7 are closed, is through an inwardly open slot in communication with the outer recess 3 , A seal 8th is placed over the cavity.

The in the media management section 9 incorporated hollow cylinder form the Hauptzufluß 10 and the main drain 11 , where these in the media guide part 9 do not cut. While the main influx 10 in the middle in the direction of the evaporator active part 1 has an opening, has the main drain 11 in the direction of the evaporator active part 1 Connection to the outside of the outermost depression 3 and to the enclosing cavity. An enclosing seal 12 comes between media management section 9 and upright plate 13 to lie and seals to the outside. In the plate 13 is an inlet nipple 14 appropriate. The plate 13 and the media guide part 9 are by means of connecting screws 15 on the evaporator active part 1 fixed and braced.

2 shows in perspective the inside of the media guide part 9 with its concentrically arranged elevations starting from the center 16 . 17 , The inflow opening 18 is centered, and with the main inflow 10 connected. The round drainage channel 19 has connections to the main drain 11 on.

Claims (8)

Surface evaporator for evaporating media for cooling equipment or media, characterized in that in an evaporator, which consists of two main parts, a part, the evaporator active part ( 1 ), is structured so that concentrically arranged in the inside of one or more wells ( 2 . 3 ), which correspond to an upwardly open channel system, which has no inflow and outflow, and wherein a circumferential cavity communicates with the outermost recess ( 3 ) by an inwardly open slot, said cavity below the for the seal ( 8th ) is placed, and wherein the matching, thermally unfavorable conductive counterpart, the media guide part ( 9 ) is structured such that there are corresponding intervals in the depressions over enclosing elevations ( 16 . 17 ) but has no cavity, both parts rest on each other so that the surveys ( 16 . 17 ) into the depressions ( 2 . 3 ) and held at a distance and the seal ( 8th ) seals the structure to the outside, wherein evaporator active part ( 1 ) and media guide part ( 9 ) outside this seal ( 8th ), wherein the media guide part has one or more inflows or outflows, wherein a plate ( 13 ) on the media guide part ( 9 ) and wherein these three parts with connecting screws ( 15 ) in the evaporator active part ( 1 ) are fixed and clamped on each other. Surface evaporator according to claim 1, characterized in that the evaporator active part ( 1 ) includes a double-sided structure, wherein the same or different structures are present, which are equipped with appropriate counterparts, the media guide parts. Surface evaporator according to Claims 1 and 2, characterized in that the structure of the evaporator active part ( 1 ) and media guide part ( 9 ) are parallel to each other several times mutually reihbar. Surface evaporator according to claim 1 and 2, characterized in that by means of the connecting screws ( 15 ) and a minimally inwardly curved plate ( 13 ) an adjustable force on the media guide part ( 9 ), which maintains the distance in the space between the media guide part ( 9 ) - the ceiling and evaporator effect ( 1 ) - of the soil - determined. Surface evaporator according to claim 1 and 2, characterized in that a pressure cell is formed in such a way that in the space of the media guide part ( 9 ) and plate ( 13 ) a seal ( 12 ), which encloses the center, and wherein the plate ( 13 ) via an inlet nipple ( 14 ), is fed or removed via the medium, and thus the distance in the space between the evaporator active part ( 1 ) and media guide part ( 9 ) is varied. Surface evaporator according to claim 5, characterized in that between the plate ( 13 ) and media guide part ( 9 ) lying over one or more in the plate ( 13 ) is carried out a punch connected to a mechanism, the force on the media guide part ( 9 ) and so the distance in the space between the media guide part ( 9 ) and evaporator active part ( 1 ) changed. Surface evaporator according to claim 1, characterized in that the wall distance between the elevations ( 16 . 17 ) of the media guide part ( 9 ) and the depressions ( 2 . 3 ) of the evaporator active part ( 1 ) is kept small. surface evaporator according to the claims 1 to 7, characterized in that the surface evaporator as a surface capacitor functions and for heating devices or media is used.