AT504548A1 - MODULE FOR AN ABSORPTION COOLING MACHINE - Google Patents

Description

The invention relates to a module according to the preamble of claim 1 and a module according to the preamble of claim 2. Furthermore, the invention * relates to an absorption chiller.

The operation of absorption chillers is known. A working medium and a refrigerant are each circulated. The working medium may be, for example, a liquid mixture comprising components with different boiling points. The low boiling point component is the so-called refrigerant. From the working medium, the lower-boiling component can be expelled by heat. As the working medium, e.g. H20-NH3 solutions, H20-LiBr solutions or comparable two-component work equipment in question.

In an evaporator unit, the refrigerant is evaporated with heat, in particular underpressure, and absorbed by heat release in an absorber unit of low-refrigerant working medium. From this refrigerant-rich working fluid is expelled in an output unit under heat refrigerant and this condenses in a condenser unit with heat release and is supplied from this evaporator unit. The working medium as well as the refrigerant is circulated. The structure and the management of the working medium and the refrigerant medium and the heat exchange media and the structure and the circuit of the corresponding units for supplying or discharging the necessary amounts of heat to the individual units, the arrangement of heat exchangers and pumps in the circulation of the refrigerant and the working medium, etc . are known.

Furthermore, modules for absorption refrigerating machines are known in which the individual units are arranged in the form of tubes in a housing opposite each other, which tubes are flowed through by heat exchange medium, wherein on the outer surface of the tubes, the refrigerant or the working medium flows. The supply and removal of the required amount of heat by means of heat exchangers or with appropriate temperatures having heat medium. In Fig. 1, for example, such an arrangement is shown. 1 shows a module 1, in which an evaporator unit 2 is arranged opposite an absorber unit 3. In the upper portion of the evaporator unit 2, a refrigerant supplying unit 5, e.g. Water, arranged, from which the refrigerant via the horizontally disposed tubes 4 of the evaporator unit 2 flows. In the lower region of the housing 6, a corresponding refrigerant outlet 7 is formed. The tubes 4 are flowed through by a heat exchange medium, which is supplied via connections 8 and discharged and corresponding amounts of heat to evaporate the refrigerant pipes 4 feeds. 2 2 ··· ···· »· ··· ··· * ► ··; 9 · · · 9 · ♦ · ♦ ♦ · · ··· ······

The absorber unit 3 comprises tubes 4, which are flowed through via corresponding connections 9 with heat exchange medium for the removal of heat. The tubes 4 of the absorber unit 3 are overflowed by means of a supply unit 5 with low-refrigerant working medium. The draining working medium is discharged in the lower region of the housing 6 via an outlet 10.

A corresponding Austreibe-capacitor unit may have the same structure; a supply unit 5 is not required for the condenser unit.

Instead of horizontally extending tubes 4, also wound tubes or tube coils can be arranged. The housing with the connections must be designed to be pressure-resistant. The production is complicated because the corresponding units must be placed in a housing and connected. In addition, the structural design of such a module affects the efficiency.

According to the invention modules of the type mentioned are characterized by the features mentioned in the characterizing part of claim 1 and claim 2.

An absorption refrigeration machine according to the invention is characterized by the features of claim 15.

The modules according to the invention are easy to manufacture and, in particular because of the possibility of arranging the plates relatively close to each other, have an excellent efficiency. Since the plates do not have to be arranged in a housing, but can themselves form part of the housing and thus no longer have to be connected through a housing wall, the construction and construction of the modules and the absorption chiller are simplified.

In a preferred embodiment of the invention, the features of claim 2 are provided. Also, for such a further module results in improved efficiency and simplified (r) production and construction.

An absorption chiller according to the invention comprises at least one module, as characterized in the characterizing part of claim 1 and at least one module according to the features of claim 2. Thus, an absorption chiller is created, which has a total of simple construction and high efficiency.

The features contained in claims 3 to 14 contribute to a simplification of the construction and to achieve a high efficiency.

In the following the invention will be explained in more detail with reference to the drawing, for example. 3 3 ·· »· • * t« · • · · · ···

FIGS. 2 a and 2 b show the basic structure of a module 1 comprising an evaporator unit 2 and an absorber unit 3. 3 shows a view of a heat exchange surface in the form of a plate 11 with a feed unit 5. FIG. 4 shows a module 1 in which heat exchange surfaces opposite one another and a frame 12 create a module 30. 5a and 5b schematically show the structure of a module 2 comprising an expulsion unit 17 and condenser unit 18. FIG. 6 shows the operation of a module comprising an expulsion unit 17 and a condenser unit 18. Fig. 7a and 7b show the basic structure of an absorption chiller of two modules according to the invention 1 and 30, but without lines and other required for the operation of the absorption chiller accessories. 8 shows the basic mode of operation of an absorption refrigerating machine using a module 1 designed according to the invention, comprising an evaporator unit 2 and an absorber unit 3, and a module 30 designed according to the invention, comprising an expulsion unit 17 and a condenser unit 18. FIGS. 9a, 9b, 9c and 9d show heat exchange surfaces formed by plates 11, which are provided on their rear side with units for the passage of or for contact with a heat exchange fluid. 10 shows a housing construction of a module 1 or 30. FIG. 11 shows an advantageous embodiment for the assembly of several modules of an absorption cooling machine.

In Fig. 2a, the basic structure of a module 1 according to the invention for an absorption cooling machine is shown schematically. The evaporator unit 2 and the absorber unit 3 comprise, in each case at least one heat exchange surface, which is designed in the form of a plate 11. The two plates 11 are as shown in Fig. 2a, In a small distance, preferably arranged parallel to each other. In the position of use, the plates 11 can stand vertically. To form a housing, a frame-like component 12 is provided, whose two-sided recesses or openings are closed by the plates 11. The frame 12 further has connection openings or passages 13 for the supply of refrigerant or working fluid to supply units 5, with which refrigerant and working fluid can be applied to the surfaces of the respective heat exchange surfaces or plates 11. The feed units 5 supply the refrigerant or the working medium to the surface of the respective plate 11 in such a way that it runs off in a thin film to the plates 11, which are vertically or optionally also slightly inclined in the position of use. The supply units 5 are closed on one side and provided on the other side with the supply line for refrigerant or working fluid. Above the holes 19, the refrigerant or the working medium exits and is supplied via an apron or a guide plate 14 of the surface of the respective plate 11.

In the lower region of the frame 12 or of the housing formed by the two plates 11 and the frame 12 there are a partition wall 15 and further collecting chambers or discharges 16 for the separate discharge of each of the two plates 11 respectively running fluid.

The feed units 5 are located in the upper end region of the plates 11 and are either attached to this or carried in a corresponding manner by the frame 12. The connection of the plates 11 to the frame can be made pressure-tight by gluing, welding or soldering. The corresponding feedthroughs for the supply and discharge lines of the fluids are also soldered, welded or glued and are pressure-tight. At the corresponding inlets 13 and outlets 16 and corresponding pipe socket can be attached.

As shown in Fig. 3, the fluid supplied from a supply unit 5 to a plate 11 flows in the form of a thin film into the lower portion of the plate 11. The supply unit 5 comprises a tube 37 provided with outlet openings 19, which is closed at one end. The shape of the outlet openings 19 can be selected; These outlet openings may be circular, elliptical, slot-shaped or otherwise formed. The application of the working medium on the plate 11 can be done via the skirt 14 or directly. The working medium can also be sprayed or sprayed onto the plate through the outlet openings 19.

It is advantageous if elevations and / or depressions and / or microstructures, in particular for enlarging the surface, are formed or provided on the surface of the plates 11 or if a hydrophilic coating is applied to the plate 11.

4 shows the operation of a module 1 according to the invention. The refrigerant charged by the supply unit 5 to the plate 11 of the evaporator unit 2 is heated by heat exchange medium supplied to the rear side of this plate 11, and the refrigerant is vaporized by the low-refrigerant working fluid in the upper one Area of the opposite plate 11 of the absorber unit 3 is received. At the back of the plate 11 of the absorber unit 3 cooling medium is supplied and the heat generated during the absorption heat is dissipated. Excess refrigerant is removed in the lower region of the evaporator unit 2 through an outlet opening 16. The loaded with refrigerant working fluid, which runs off of the plate 11 of the absorber unit 3, is discharged through the outlet opening 16 in the lower region of the housing.

If the working medium is an H 2 O-LiBr solution, water is evaporated in the evaporator unit 2 and the water vapor in the absorber unit 3 is taken up by a low-water lithium bromide solution. 5 ·························································

In Fig. 5a and 5b, the structure of a Austreibe-capacitor module 30 is schematically described. The structure of the heat exchange surfaces or plates 11 and the housing may be identical to the structure of the evaporator absorber units 2, 3. The only difference between a module 1, comprising an evaporator unit 2 and an absorber unit 3, to a module 30, the one Austreibeeinheit 17 and a capacitor unit 18 includes, is that in the upper region of the plate 11 of the capacitor unit 18, no supply unit 5 is provided, since this is not necessary there. In this module 30, as shown in FIG. 6, heat is supplied to the expulsion unit 17 at the back of the plate 11 with a heat exchange medium to expel the refrigerant from the refrigerant-rich working fluid. The vapor of the refrigerant condenses on the plate 11 of the condenser unit 18, which is cooled at its rear side for heat dissipation. Both the refrigerant working fluid and the condensed refrigerant drain into the lower portion of the housing of the module 30 are collected in the limited by the partition wall 15 and are discharged through the respective outlet opening 16.

7a and 7b show a unit consisting of the two modules 1 and 30 constructed according to the invention, wherein the two modules 1, 30 are arranged one above the other and are held together by a common frame unit 12. The required lines are not shown, as they are clear to the expert. The two combined modules 1, 30 represent the core of an absorption refrigerating machine, the structure of which is explained in more detail in FIG. The refrigerant leaving the evaporator unit 2 is circulated and supplemented with the refrigerant leaving the condenser unit 18 and returned to the supply unit 5 of the evaporator unit 2. In the case that all of the refrigerant in the evaporator unit 2 is evaporated, care must be taken that sufficient refrigerant flow is supplied to the evaporator unit 2 from the condenser unit 18.

The refrigerant-rich working medium leaving the absorber unit is fed via a pump 31 via a heat exchanger 32 of the feed unit 5 of the expulsion unit 17 and drains off via the plate 11 of the expulsion unit 17, the refrigerant being expelled or vaporized. The expelled refrigerant is condensed on the cooled plate 11 of the condenser unit 18 and is brought together via an expansion valve 33 with at most the evaporator unit 2 leaving refrigerant. The low-refrigerant working medium from the Austreibeeinheit 17 is fed via an expansion valve 34 and the heat exchanger 32 of the feed unit 5 of the absorption unit 3 and drains through the plate 11 of the absorption unit 3 in the lower part of the module 1 and from there again the Austreibeeinheit 17 is supplied. 6 ········································ #

9a, 9b, 9c and 9d show various embodiments for the design of the plates 11. According to Fig. 9a, a space 35 is formed on the rear side of the plate 11, which can be traversed diagonally by heat exchange fluid. In Fig. 9a right, a section through such a disk unit is shown.

Fig. 9b shows the flow through a molded onto the plate 11 space 36 with side-mounted inlets and outlets for the heat exchange fluid.

9 c shows an embodiment in which the refrigerant or the working fluid and the heat transfer medium flow down in the form of film flow on opposite sides of the plate 11. Both fluids are passed through a supply unit 5 and optionally an apron or guide plate 14 to the plate surface.

Fig. 9d shows the formation of a plate 11, which is cooled on its rear side with air, for which purpose lamellae 37 are formed on this back.

Fig. 10 shows the formation of a module 1, 30 with respect to a mechanical reinforcement. In the interior of the frame 12 and the housing amplifier plates 38 are arranged, which do not hinder the drainage of the working medium or the refrigerant to the side plates 11. For this, the plate-near end portions of the reinforcing members 38 may have recesses, e.g. be shaped like a sawtooth. It is advantageous if the reinforcing parts are roof-like in order to be able to discharge impinging refrigerant or working medium to the respective plate 11.

Fig. 11 shows a possible assembly of modules 1, 30, whereby by means of heat exchange fluid, i. by means of a cooling or heating medium, corresponding plates 11 can be cooled simultaneously. The plates 11 of the units 3 and 18 are filled with cooling medium 43, e.g. Air or water, cooled. The plates 11 of the evaporator unit 2 are separated from the medium 40 to be cooled, e.g. Cooling water, and the plates 11 of the expelling unit 17 are filled with heating medium 41, e.g. Hot water, heated.

Claims (13)

1. Module (1) for an absorption refrigerating machine, comprising at least one evaporator unit (2) for evaporating the refrigerant and one of the evaporator unit (2). arranged opposite absorber unit (3) for absorbing the expelled from the working medium refrigerant in the working medium, characterized in that - both the evaporator unit (2) and the absorber unit (3) each have at least one formed in the form of a plate (11) heat exchange surface or are formed by such a plate (11), - that the front of the plate (11) of the evaporator unit (2) and the plate (11) of the absorber unit (3) facing each other, in particular arranged parallel to each other, - that in the in Use position in the upper end region of the plate (11) of the evaporator unit (2) opens or is arranged at least one supply unit (5) for refrigerant, with the Kä is applied to the surface of the plate (11) and then runs on this, and - that in the position of use upper end of the plate (11) of the absorber unit (3) at least one feed unit (5) for low-refrigerant working medium opens or arranged is, with the working medium is applied to the surface of the plate (11), and runs on this. 2. module for an absorption chiller, comprising at least one Austreibeeinheit (17) for expelling the refrigerant contained in the working medium and a Austreibeeinheit (17) arranged opposite condenser unit (18) for condensing the expelled from the working fluid refrigerant, characterized in that - this further Module (30), optionally together with a module (1) is arranged in an absorption chiller, or optionally combined with a module (1) to form a unit, - that both the Austreibeeinheit (17) and the capacitor unit (18) of this module (30) in each case at least one in the form of a plate (11) formed heat exchange surface or are formed by such a plate, - that the front of the plate (11) of the expulsion unit (17) and the plate (11) of the condenser unit (18) facing each other, - that in the position of use upper end of the plate (11) de expulsion unit (17) at least one feed unit (5) for refrigerant laden working medium opens or arranged and with the feed unit (5) the loaded working medium in the upper end of the plate (11) on the surface of the plate (11) of the expulsion unit ( 17) and then run off on this, and - that the expelled refrigerant condenses on the surface of the plate (11) of the condenser unit (18) and runs on this. 3. Module according to claim 1 or 2, characterized in that - on the back of the respective heat exchange surface or the respective plate (11) of the evaporator unit (2), the absorber unit (3), the Austreibeeinheit (17) and the condenser unit (18 ) at least one contact or supply unit, eg a flow channel for a secondary heat transfer medium, e.g. Water, brine or air for heat supply or removal is formed or formed. 4. Module according to one of claims 1 to 3, characterized in that the supply unit (5) of a (e), in particular parallel to the surface and / or end edge of serving as a heat exchange surface plate (11) extending, provided with Ausströmlöchem (19) (S) pipe or channel is formed, wherein optionally to the supply device (5) to the surface of the plate (11) leading baffle (14) for the supplied refrigerant or working fluid is arranged. 5. Module according to one of claims 1 to 4, characterized in that the supply unit (5) and / or the plates (11) of the evaporator unit (2) and / or the absorber unit (3) and / or the Austreibeeinheit (17) and / or the capacitor unit (18), in particular with respect to their shape and / or dimensions, are the same. 6. Module according to one of claims 1 to 5, characterized in that the plates of the evaporator unit (2) and the absorber unit (3) and / or the plates of the expelling unit (17) and the condenser unit (18) respectively opposite surfaces of a parallelepiped or box-shaped housing form. 7. Module according to claim 6, characterized in that the housing has a frame-like component (12) whose recesses or openings of the plates (11) of the evaporator unit (2) and of the absorber unit (3) or of the plates (11 ) of the expulsion unit (17) and the condenser unit (18) are closed. 8. module according to any one of claims 1 to 7, characterized in that in the lower region of the plates (11) each one, optionally of a partition wall (15) limited, collecting or discharge unit (16), preferably a container, a compartment or a channel, is formed or provided for the working medium or the refrigeration medium. 9. Module according to one of claims 1 to 8, characterized in that on the surface of the plates (11) elevations and / or depressions and / or microstructures, in particular for enlarging the surface, are formed or provided. 10. Module according to one of claims 1 to 9, characterized in that on the plates (11) a hydrophilic coating is applied. 11. Module according to one of claims 1 to 10, characterized in that the frame (12) of the housing in the position of use in the upper region of the plates (11) connections or feedthroughs for the supply line to the feed unit and in the lower end region of the plates (11). Discharge for working fluid or refrigerant has. 12. Module according to one of claims 1 to 11, characterized in that the plates (11) are arranged at a distance of between 5 to 20 mm, preferably between 8 to 12 mm, one opposite. 13. Module according to one of claims 1 to 12, characterized in that the refrigerant and / or the working medium in the form of a thin film over the respective plate (11) are guided. 14. absorption chiller, characterized in that it comprises a module (1) according to claim 1 and / or a module (30) according to claim 2, which modules (1, 30) optionally have the features of at least one of claims 3 to 13. Vienna, November 30, 2006 1 • · · · • • • • • • ·· I Fig. 1 h & ö s. / -1 Γ ι, Γ- 0 o /, 0 0 o / k -'O 0 o 0 0 o 0 0 o Γ o 0 o \ o 0 or ~ o 0 0 / \} 7 io 1: $ p Fig .3 Fig. 4 • ···· • • • ·· Fig. 6 Fig. 7b • ft • ft • «« ft ft • • ft ··· ····· • · • · • ft Fig.8 Fig. 9b Fig. 10 · • · · · · · ·%%%%%%%%%%%% Ο Ο & < 30 36 = Fig. 11 »· · · · · · · · · · · · · ············································································· · · • • • • • • • • 1 · < * · «···· 13738 re: Austrian patent application A1986 / 2006 Austrian Research and Testing Center Arsenal Gesellschaft m.b.H. 1. Module (1) for an absorption chiller, comprising at least one evaporator unit (2) for evaporating the refrigerant and one of the evaporator unit (2) arranged opposite absorber unit (3) for absorbing the expelled from the working fluid refrigerant in the working medium, both the Evaporator unit (2) and the absorber unit (3) each have at least one in the form of a plate (11) formed heat exchange surface or of such a plate (11) are formed, the front of the plate (11) of the evaporator unit (2) and the Plate (11) of the absorber unit (3) facing each other, in particular arranged parallel to each other, are in the use position in the upper end of the plate (11) of the evaporator unit (2) at least one feed unit (5) for refrigerant opens or arranged, with which the refrigerant is applied to the surface of the plate (11), and then runs on this, and in in the use position upper end region of the plate (11) of the absorber unit (3) opens or is arranged at least one supply unit (5) for low-refrigerant working medium, with which the working medium is applied to the surface of the plate (11), and runs on this characterized in that the plates of the evaporator unit (2) and the absorber unit (3) each form opposite surfaces of a cuboid or box-shaped housing. 2. module for an absorption refrigeration machine, comprising at least one expulsion unit (17) for expelling the refrigerant contained in the working medium and a Austreibeeinheit (17) arranged opposite condenser unit (18) for condensing the expelled from the working fluid refrigerant, said further module (30) , optionally together with a module (1) is arranged in an absorption chiller, or optionally combined with a module (1) to form a structural unit, both the Austreibeeinheit (17) and the capacitor unit (18) of this module (30) each at least one in the form of a plate (11) formed heat exchange surface or are formed by such a plate, the front of the plate (11) of the expulsion unit (17) and the plate (11) of the condenser unit (18) facing each other, in the position of use upper end portion of the plate (11) of the expulsion unit (17) at least one feed unit (5) for refrigerant laden working medium opens and is arranged with the FILLED feed unit (5) the loaded working medium in the upper end of the plate (11) on the surface of the plate (11) of the expelling unit (17) and then give flows on this, and the expelled refrigerant condenses on the surface of the plate (11) of the condenser unit (18) and runs on this, characterized in that the plates of the evaporator unit (2) and the absorber unit (3) respectively opposite surfaces of a parallelepiped or box-shaped housing form. 3. Module according to claim 1 or 2, characterized in that - on the back of the respective heat exchange surface or the respective plate (11) of the evaporator unit (2), the absorber unit (3), the Austreibeeinheit (17) and the condenser unit (18 ) at least one contact or supply unit, eg a flow channel for a secondary heat transfer medium, e.g. Water, brine or air for heat supply or removal is formed or formed. 4. Module according to one of claims 1 to 3, characterized in that the supply unit (5) of a (e), in particular parallel to the surface and / or end edge of serving as a heat exchange surface plate (11) extending, provided with Ausströmlöchem (19) (S) pipe or channel is formed, wherein optionally to the supply device (5) to the surface of the plate (11) leading baffle (14) for the supplied refrigerant or working fluid is arranged. 5. Module according to one of claims 1 to 4, characterized in that the supply unit (5) and / or the plates (11) of the evaporator unit (2) and / or the absorber unit (3) and / or the Austreibeeinheit (17) and / or the capacitor unit (18), in particular with respect to their shape and / or dimensions, are the same. 6. Module according to one of claims 1 to 5, characterized in that the housing has a frame-like component (12) whose recesses or openings of the plates (11) of the evaporator unit (2) and of the absorber unit (3) or of the plates (11) of the expulsion unit (17) and the condenser unit (18) are closed. 7. Module according to one of claims 1 to 6, characterized in that in the lower region of the plates (11) each one, optionally of a partition wall (15) limited, collecting or discharge unit (16), preferably a container, a compartment or a channel, is designed or provided for the working medium or the refrigeration medium. FAILURE ····························································································································································· 8. Module according to one of claims 1 to 7, characterized in that on the surface of the plates (11) elevations and / or depressions and / or microstructures, in particular for enlarging the surface, are formed or provided. 9. Module according to one of claims 1 to 8, characterized in that on the plates (11) a hydrophilic coating is applied. 10. Module according to one of claims 1 to 9, characterized in that the frame (12) of the housing in the use position upper region of the plates (11) connections or feedthroughs for the supply line to the feed unit and in the lower end region of the plates (11). Discharge for working fluid or refrigerant has. 11. Module according to one of claims 1 to 10, characterized in that the plates (11) are arranged at a distance of between 5 to 20 mm, preferably between 8 to 12 mm, one opposite. 12. Module according to one of claims 1 to 11, characterized in that the refrigerant and / or the working medium in the form of a thin film over the respective plate (11) are guided. 13. absorption chiller, characterized in that it comprises a module (1) according to claim 1 and / or a module (30) according to claim 2, which modules (1, 30) optionally have the features of at least one of claims 3 to 12. Vienna, 7th January 2008 FOLLOW-UP