DE19933426C2 - heat exchanger module - Google Patents

Abstract

Heat exchanger module for the passage of two mutually separate media in cross-flow or counter-flow, comprising a number of floors lying parallel to one another, which form gaps, each of which is alternately flowed through by one and the other medium and a plurality of substantially parallel to one another Bottoms ribs that connect them to each other and support each other and divide the gaps into individual parallel channels, whereby molded parts are provided, each of which form a bottom and subsequent ribs in one piece, a plurality of molded parts as intermediate floors with at least one side integrally molded thereon Ribs is formed, and several molded parts are designed as ribless base, end or intermediate floors, and the totality of the floors are set directly to each other with the same orientation of the intermediate floors.

Description

The invention relates to a heat exchanger module for passage two separate media in cross flow or in ge genstrom, comprising a number of parallel to each other the floors that form gaps, each alternating from flow through one and the other medium, and one Variety of substantially parallel to each other ribs lying perpendicular to the floors, these these together connect and support each other and the gaps in divide individual parallel channels, with molded parts are provided, each having a bottom and subsequent rip Train the pen in one piece. Such heat exchanger modules are usually made up of sheets, with the first sheets in the form essential flat floors and zigzag second sheets mig or S-line-shaped corrugation and that between two floors form lying ribs. Heat exchanger modules of this type are described for example in EP 0 448 991 B1. It is also already known to use floors for heat exchanger modules with the ribs projecting vertically on both sides in one piece are shaped. Here are wave formations of the bottoms and ribs provided in the direction of flow of those formed by them Channels run. Floors of the type mentioned are with other levels Bottoms and combi with S-line corrugated rib elements ned. Heat exchangers of this type are in DE 35 21 914 A1 described.  

DE 37 30 137 A1 describes a heat exchanger for use in Flue gas flow of a heating system known, the ceramic Includes base plates in a heat exchanger interior Distance from each other parallel and in a labyrinthine manner fend are used. The base plates carry across to the upper surface flow direction of the first medium other parallel ribs and contain towards the ribs running tubes carrying the second medium. The latter are in Loop shape interconnected.

The present invention has for its object, heat accumulation To provide shear modules that are easier to manufacture and have favorable heat transfer conditions.

According to the solution specified herewith it is provided that a first molded part is designed as a ribless base that a plurality of second moldings as intermediate floors are formed on these integrally molded ribs and that a third molding as a cover with on one side this molded ribs is formed, and that base floor, Intermediate shelves and cover shelf with the same orientation of the ribs directly in relation to their respective bottoms are changed. Intermediate floors can simplify this and cover base must be designed to match, in particular if the module is used as a single element; it can moreover, even the basic soil in complete agreement be designed with the intermediate floors, then functional Project loose ribs on the outside of the module. Since often a plurality of Modules of the type mentioned, however, stacked into larger blocks is the use of flat base and cover to the outside prefer floors.

The invention provides a heat exchanger module, with the least possible number of different ones Individual elements have a correspondingly reduced number of connections has expansion points, so that problems regarding heat conduction  and the tightness at the joints largely are reduced. Due to the one-piece training of the Zwi shelf or cover plate with adjoining ribs given a high strength. The parts mentioned can be used as Molded parts made of ceramic, cast metal or composite material in series manufactured and easily installed together.

In particular, it is contemplated that each form a channel Surface of the bottoms transverse to the longitudinal direction of the ribs, d. H. transverse to the direction of flow, evenly corrugated or corrugated is. Wavy denotes a sinusoidal profile and corrugated a zigzag profile or a sawtooth profile. The latter can also be used as a cross if the height of the teeth is appropriate ribbing can be called. Next are studded Surfaces possible. All of these embodiments are used Enlargement of the surface and generation of turbulence in the flow, which improve the heat transfer. It becomes white further suggested that the ribs formed on the bottoms each in butt joint with the immediately adjacent floors connect. Furthermore, it is preferably provided that the molded ribs opposite surfaces of the intermediate floors and the inner surfaces of the base floor or of the bottom plate transverse to the direction of flow of these closed channels are continuously corrugated or corrugated and that the free end edges of each adjoining it Ribs are corrugated or corrugated accordingly. Alternatively, you can be provided that the surfaces of the molded on Ribbed floors evenly with knobs are occupied and that the free front edges of each  abutting ribs are correspondingly provided with depressions. Due to the positive engagement of the longitudinal face th of the ribs in the surfaces of the adjacent floors is the Assembly easier and a precise positioning of the individual floors ensure each other during assembly.

In a further embodiment, which is particularly corrugated Surfaces of the floors can join, it is provided that the Ribs transverse to their longitudinal direction, d. H. across the flow direction are corrugated substantially parallel wall. in this connection it is particularly provided that the channel forming be neighboring ribs to a longitudinal median plane of the channel mirror form symmetrical surfaces. These features also serve Increase in surface area and increase in turbulence in the flowing media, through which the heat transfer is improved can be.

The ribs are preferably formed in cross-section from the Bottom truncated at least partially towards the free ends tapered shape. In the manufacture of the molded parts this facilitates demolding of the relatively thin-walled and sensitive ribs essential. In the also based on the Embodiments described embodiment as a cross flow heat exchangers are the two surfaces of an intermediate floor corrugated at right angles to each other and the ribs on both sides of an intermediate floor are at right angles to each other. Collector for one medium each can be open to one of the Connect the entire cuboid areas of the heat exchanger module. In a configuration as a counterflow heat exchanger are the two Surfaces of an intermediate floor running parallel to each other corrugated and the ribs on both sides of an intermediate floor run parallel to each other. Here are the two themselves opposite side faces of the module on which the channels emerge, still apply transition elements, with the help of them the alternating layered partial flows of the two media  Direction diversion can be separated, whereby then open collection Connect these transition elements for one medium at a time can eat.

In the counterflow version, the outer ribs can be on each floor on the outside with a rounded inflow profile be provided, these inflow profiles in one piece from the Ribs can be formed or what, for example the demoulding easier, can also be put on afterwards can.

After further training, the floors can be right at their corners have angular notches in which the height of the module Reaching square profiles are used. This can be an old one native or additional measure to facilitate a situation represent exact assembly of the floors. If the square profiles stand back from one outer floor and towards the one protrude other outer floor, become tools formed several modules to facilitate stackability, because the modules then interlock positively.

In a preferred embodiment it is provided that the Molded parts made of ceramic that come together after drying be put and by a subsequent burning at the same time be connected to each other, with a seamless mono lith arises. The use of additional material, i.e. H. insbeson there is no need for solder or the like with this material and in this way of manufacturing.

Alternatively, it is also possible for the molded parts to have metal castings are and welded together after assembly or be soldered or glued. The same applies to molded parts consisting of composite materials made of metal Plastic, in which the plastic, particularly with regard to the formability is provided and the metallic parts ensure the necessary heat conduction and good heat transfer len should.  

If the heat exchanger module according to the invention as an air / air or can be used as a liquid / liquid heat exchanger , it is possible to have all the ribs of the same height and the same Form distance so that only one type of intermediate floors becomes necessary. In contrast, is the use as air / liquid provided heat exchanger, so it makes sense to use the Rip pen, which form channels for the liquid, with a lower height and possibly also with a greater distance from each other form, since here the heat transfer much better than in the Channels for the air will be.

Several modules, especially ceramic ones, can stacked and soldered or welded together. The required collectors already mentioned can be soldered on or welded, especially on modules made of Kera mik, with titanium or ceramic preferred materials for form the collectors.

For the above-mentioned welding of ceramic parts a mortar is used to connect the parts, that when heated in a kiln in an exothermic Reaction hardened, which the ceramic material of the modules in the molten phase transferred so that from welding can be spoken.

A preferred embodiment of the invention will follow shown standing with the drawings.

Fig. 1 shows an inventive heat exchanger module in cross-flow design in an isometric view;

FIG. 2 shows a block of eight modules according to FIG. 1 in an isometric representation;

FIG. 3 shows a heat exchanger module according to the invention similar to FIG. 1

• a) in a first side view;
• b) in a vertical side view;

FIG. 4 shows a base of a module according to FIG. 3

• a) in a first side view;
• b) in a vertical side view;
• c) in top view;
• d) in bottom view;

FIG. 5 shows an intermediate floor of a module according to FIG. 3 with ribs formed on one side

• a) in a first side view of the end faces the ribs;
• b) in a second side view perpendicular thereto;
• c) in top view;
• d) in the enlarged detail Z according to a);
• e) in section A-A according to d);
• f) in section B-B according to d);

FIG. 6 shows a cover base of a module according to FIG. 3

• a) in a first side view of the end faces the ribs;
• b) in a second view perpendicular thereto;
• c) in view of the outer surface;
• d) in section A-A according to a);
• e) in section B-B according to a);

Fig. 7 shows an intermediate floor of a different shape with ribs formed on both sides

• a) in a first side view;
• b) in a second side view perpendicular thereto;
• c) in top view;

Fig. 8 1 shows a heat exchanger module as claimed in Fig Isome tric view obliquely from the front section with a skew.

Fig. 9 shows an insight into three flow channels of a flow plane in perspective view;

An approximately cube-shaped heat exchanger module 11 according to the invention is shown in FIG. 1. The module 11 includes a Grundbo 12 , intermediate floors 13 and a cover 14 as wesentli che components, the details of which will be discussed. The floors are parallel to each other at a distance. The base floor 12 has a flat outer surface 15 , which is not visible, and a completely corrugated surface 17 . With a first base 13 a, on which ribs 19 a are integrally formed, it forms first channels 20 a for a first medium, the inlet openings of which are visible from the front right. The waves in the base floor 12 run transversely to the longitudinal direction of the ribs 19 a and the channels 20 a. It can be seen that the surfaces of the ribs 19 a are corrugated in the same direction with the surface 17 of the base 12 transversely to the longitudinal direction of the channels 20 a. The invisible underside 21 a of the bottom 13 a is corrugated parallel to the surface 17 of the base 12 . The top 18 a of the bottom 13 a is corrugated perpendicular to the surface 17 of the base 12 .

The outer rib 19 'of the intermediate base 13 a visible at the front left is provided with an inflow profile 22 a.

On the bottom 13 a, a bottom 13 b is placed, the upper surfaces 18 b are also corrugated and are integrally formed on the ribs 19 b, the second, to the flow channels 20 a perpendicular flow channels 20 b, the one flow openings in the front are recognizable on the left. The top 18 b of the bottom 13 b is parallel to the surface 17 of the base ge corrugated. The invisible underside 21 b of the base 13 b is corrugated perpendicular to the surface 17 of the base 12 . The surfaces of the ribs 19 b are corrugated corresponding to the surface 18 a of the first bottom 13 a in the same direction transverse to the flow direction of the channels 20 b. The outer rib 19 'of the intermediate base 13 b, visible at the front right, is seen with an inflow profile 22 b. In the same way, two further intermediate floors 13 a and two further intermediate floors 13 b are placed on one another. On the uppermost shelf 13 b ₃ , the cover 14 is placed, which differs from the shelves 13 a only in that its outer surface 16 is flat. The bottoms 12 , 13 , 14 are hen at their corners with right-angled notches, in which square profiles 24 are inserted. These protrude from the invisible outer surface of the base floor 12 by a certain amount and from the visible outer surface 16 of the end floor 14 by the same amount in their longitudinal direction. The axial offset of the ends of the square profiles 24 relative to the outer surfaces of the module 11 facilitates stacking of modules of the same type.

Fig. 2 shows such a stacking of eight modules 11 as shown in FIG. 1, wherein the modules are to be arranged so that the flow channels for each of the media are continuously connected to each other. From this arrangement it is clear that the inflow profiles 22 on the outer ribs 19 'are only to be formed where there is a free flow of the modules, while on the outside of the modules that are intended to abut one another directly, the outer ribs at right angles to the Level of the square profiles are preferable so that there is no interference in the cross-section of the channel.

In Fig. 3 a module is shown similar to Fig. 1, but this has no recesses and square profiles at the corners of the floors. Fig. 3a corresponds to the view in Fig. 1 from the bottom right; Fig. 3b corresponds to the view in Fig. 1 from the bottom left.

In both figures, the base floor 12 with a flat outer surface 15 and a corrugated surface 17 , the intermediate floors 13 a, 13 b with a corrugated upper side 18 and a corrugated underside 21 perpendicular thereto and the cover base 14 with a flat outer surface 16 and a corrugated underside 23 can be seen . On the end faces of the ribs 19 it can be seen that they have a surface corrugation which corresponds to that of the adjoining bottoms, that is to say is executed transversely to the longitudinal direction of the respective channels 20 . It can also be clearly seen that the longitudinal end edges of the ribs engage the corrugation of the surfaces 17 , 18 and are butted to it. Inflow profiles 22 are integrally formed on all external ribs, so that the module shown here can be used individually by collectors being attached directly to all sides. If a module of this type is to be integrated into a block, the inflow profiles 22 shown here must be removed on at least two of the four sides. Instead of the one-piece molding of the inflow profiles 22 shown here, it is also possible to design the module with flat outer ribs and to apply inflow profiles only to external surfaces as required.

Fig. 4 shows a base 12 , on which the flat underside 15 and the corrugated top 17 are identified and recognizable.

Fig. 5 shows an intermediate floor 13 according to the invention, on which the corrugated top 18 and the corrugated bottom 21 are visible and labeled bar. Furthermore, the inflow profiles 22 , which are formed in one piece with the outer ribs 19 ', as well as the alternating pairs of symmetrical ribs 19 a, 19 b can be seen.

In the detail according to d) together with the section AA according to e) it can be seen that the ribs 19 taper in a wedge shape towards the free end. From the section BB according to f) it is further clear that the ribs 19 are essentially parallel-walled and mirror-symmetrical to one another in relation to a longitudinal center plane of a channel formed by them. In particular, in section AA according to e) it can be seen that all Wel lungs, in particular also the surface 21 of the Zwischenbo dens 13 are perpendicular to the flow direction.

In Fig. 6, the cover base 14 is shown as a one-piece part, on which the flat outer surface 16 and the corrugated lower side 23 and on the outer ribs 19 'integrally molded inflow profiles 22 can be seen. The one-piece connection of the inflow profiles 22 with the last rib 19 'can be seen in particular in section BB according to e). The details according to the section AA according to d) correspond to those according to Fig. 5e). The end floor 14 differs from the intermediate floors 13 essentially only by the flat outer surface 16 .

Fig. 7 shows an intermediate floor 25 deviating type, on which a corrugated top 26 is recognizable and labeled. On the upper side symmetrical ribs 28 , 28 'are formed in pairs, on the underside 27 in pairs symmetrical ribs 29 , 29 ' which run at right angles to the former. The ribs each run towards their free end in the shape of a truncated wedge and are essentially parallel-walled. Here, adjacent ribs are symmetrical in relation to a longitudinal median plane of a channel formed by them, as can be seen in the top view according to c). The free ends of the rip pen are corrugated in the longitudinal direction, so that they can be butted against the continuously corrugated surface of a ribless base or end plate or a ribless intermediate plate, the two surfaces of which are corrugated. Intermediate floors 25 can alternately be stacked with ribless intermediate panels. Flow profiles 30 are formed in each case on outer ribs 28 and flow profiles 31 are formed on outer ribs 29 .

In Fig. 8, the same details as in Fig. 1 are given the same reference numerals. To this extent, reference is made to the description thereof. The illustration makes it particularly clear that both in the flow channels 20 a and in the perpendicularly offset planes to the flow channels 20 b, the surfaces formed by the ribs and the bottoms are each corrugated transversely to the longitudinal direction of the channels.

A flow profile 22 and three channels 20 , 20 ', 20 "can be seen in FIG. 9, the surfaces of which are corrugated transversely to the longitudinal direction of the channel. Ribs 19 , 19 ' run downward in the shape of a truncated wedge in cross section.

Modifications to the above are readily apparent to those skilled in the art possible. A characteristic feature is the immediate forman Fit connection of the longitudinal end faces of the ribs to the corrugated th surfaces of the adjoining floor.

Claims (24)

1. Heat exchanger module for the passage of two separate media in cross-flow or counter-flow, comprising a number of floors lying parallel to each other, which form gaps, each of which is alternately flowed through by one and the other medium and a plurality of substantially parallel to each other the ribs lying perpendicular to the floors, which connect these to one another and support one another and the gaps are divided into individual parallel channels, with molded parts being provided, each of which forms a floor and subsequent ribs in one piece, wherein
a first molded part is formed as a ribless base ( 12 ),
a plurality of second molded parts are designed as intermediate floors ( 13 ) with ribs ( 19 ) integrally molded onto them on one side and
a third molded part is designed as a cover base ( 14 ) with ribs ( 19 ) molded onto it on one side, and
said base bottom (12), shelves (13) and cap base (14) in a matching orientation of the ribs (19) with respect to their respective bases (13, 14) are each placed directly on. 2. Heat exchanger module according to claim 1, characterized in that the channel ( 20 ) forming surfaces of the bottoms ( 12 , 13 , 14 , 25 ) and the ribs ( 19 , 28 , 29 ) transverse to the longitudinal direction of the ribs ( 19 , 28 , 29 ), ie to the direction of flow, are evenly corrugated or corrugated or are fitted with smaller transverse ribs. 3. Heat exchanger module according to claim 1, characterized, that the channel-forming surfaces of the floors and the Ribs are studded. 4. Heat exchanger module according to one of claims 1 to 3, characterized in that the ribs ( 19 , 28 , 29 ) formed on the bottoms ( 13 , 14 , 25 ) are each butt-butted against the immediately adjacent bottoms ( 12 , 13 , 14 ) connect. 5. Heat exchanger module according to claims 2 and 4, characterized in
that the surfaces of the ribs ( 19 , 28 , 29 ) attached to the bases ( 12 , 13 , 14 ) transversely to the direction of flow of the channels ( 20 ) closed by these are uniformly corrugated or corrugated and
that the free end edges of the abutting ribs ( 19 , 28 , 29 ) are corrugated or corrugated accordingly. 6. Heat exchanger module according to claims 3 and 4, characterized in
that the surfaces of the bottoms attached to the molded ribs are evenly studded all the time and
that the free end edges of the abutting ribs are provided with depressions accordingly. 7. Heat exchanger module according to one of claims 1 to 6, characterized in that the base ( 12 ) has a flat outer surface ( 15 ). 8. Heat exchanger module according to one of claims 1 to 7, characterized in that the end plate ( 14 ) has a flat outer surface ( 16 ). 9. Heat exchanger module according to one of claims 1 to 8, characterized in that the ribs ( 19 , 28 , 29 ) transversely to their longitudinal extent, ie transversely to the direction of flow, are corrugated or corrugated substantially parallel to the wall. 10. Heat exchanger module according to one of claims 1 to 9, characterized in that the ribs ( 19 , 28 , 29 ) in cross-section from the integrally formed bottom ( 13 , 14 , 25 ) to the free ends are at least partially tapered in the shape of a wedge. 11. Heat exchanger module according to one of claims 9 or 10, characterized in that the one channel ( 20 ) forming adjacent ribs ( 19 a, 19 b, 28 a, 28 b, 29 a, 29 b) to a longitudinal central plane of the channel ( 20 ) form mirror-symmetrical surfaces. 12. Heat exchanger module according to one of claims 1 to 9 as a cross-flow heat exchanger, characterized in that the ribs ( 19 , 28 , 29 ) on both sides of an inter mediate bottom extend at right angles to one another. 13. Heat exchanger module according to one of claims 1 to 9 as Countercurrent heat exchanger, characterized, that the ribs on both sides of an intermediate floor par allel to each other. 14. Heat exchanger module according to one of claims 1 to 13, characterized in that the bottoms ( 12 , 13 , 14 ) have rectangular notches at their corners, into which square profiles ( 24 ) reaching over the height of the module ( 11 ) are inserted. 15. A heat exchanger module according to claim 14, characterized in that the square profiles ( 24 ) project from the one outer floor ( 12 ) and project from the other outer floor ( 14 ). 16. Heat exchanger module according to claim 12, characterized in that in each case the outer ribs ( 19 ', 28 , 29 ) on each floor ( 13 , 14 , 25 ) on the outside with a rounded flow profile ( 22 , 30 , 31 ) are provided and are curled on the inside. 17. Heat exchanger module according to one of claims 1 to 16, characterized, that the molded parts are made of ceramic, which before firing assembled and baked together by burning are. 18. Heat exchanger module according to one of claims 1 to 16, characterized, that the molded parts are metal castings and ver welded or soldered or glued. 19. Heat exchanger module according to one of claims 1 to 16, characterized,  that the molded parts from a composite material made of metal offset plastic and welded together or are soldered or glued. 20. Heat exchanger module according to one of claims 1 to 19, characterized in that for use for media of the same phase (gaseous / gaseous; liquid / liquid) the ribs ( 19 , 28 , 29 ) on all floors ( 13 , 14 , 25 ) are the same Height and the same distance from each other. 21. Heat exchanger module according to one of claims 1 to 19, characterized in that for use for media of different phases (gaseous / liquid) the ribs ( 19 , 28 , 29 ) on both sides of an intermediate base ( 13 a, 13 b, 25 ) have different heights and / or different distances from each other. 22. Heat exchanger, in which several modules - in particular also made of ceramic - are assembled into a larger block according to one of claims 1 to 21, characterized in that the modules ( 11 ) are welded or soldered together. 23. Heat exchanger, in which a block of several modules - In particular also made of ceramic - according to one of the claims 1 to 22 is connected to collectors, characterized,  that the collectors, which consist in particular of titanium, with are soldered to the block. 24. Heat exchanger, in which a block of several modules - In particular also made of ceramic - according to one of the claims 1 to 23 is connected to collectors, characterized, that the collectors, which consist in particular of ceramics, with are welded to the block.