DE102011108467B4 - Adsorption heat exchanger module and an adsorption heat exchanger arrangement - Google Patents

Abstract

Adsorption heat exchanger module with a flow distribution pipe (5), a return flow distribution pipe (5') arranged at a distance from the flow distribution pipe (5), a plurality of pipe elements (1, 1') arranged at a distance from one another, each pipe element (1, 1') between the flow distribution pipe (5) and the return flow distribution pipe (5') and a flow area (1v, 1v') which can be fluidly connected or is connected to the flow distribution pipe (5) and a return flow area (1r, 1r') which can be fluidly connected to the return flow distribution pipe (5') or is connected, characterized by at least one lamellar profile component (2a, 2b) arranged between at least two adjacent pipe elements (1, 1'), by means of which a sorbent (4) present in the form of a bed can be received or received, the flow distribution pipe (5 ) and / or the return distribution pipe (5 ') is designed as a round pipe, wherein at least one pipe element (1, 1') has a forward end portion, the one e seen from the inside of the flow distribution pipe (5), has a concave rounding and/or has a return end section (7a, 7b) which has a concave rounding, seen from the inside of the return distribution pipe (5').

Description

The invention relates to an adsorption heat transfer module and an adsorption heat transfer arrangement according to the preambles of the independent patent claims.

Conventional refrigeration systems with an integrated compressor are able to reliably provide cooling capacity over a wide range of climatic conditions. However, depending on the type and the respective operating conditions, the operation of these systems requires the provision of fuel or electrical energy. An alternative to such conventional refrigeration systems are adsorption refrigeration systems, which can be operated using a refrigerant reversibly adsorbing and desorbing sorbent by means of engine waste heat, process heat or thermal energy from solar collectors.

Adsorption chillers essentially consist of three components: a condenser, an evaporator and an adsorption heat exchanger. From the DE 10 2004 053 436 A1 For example, a passenger car air conditioning system with an adsorption heat pump is known, in which a heat exchanger is provided, in which heat that can be obtained from the drive engine and/or from a parking heater can be supplied to a sorption material to be desorbed. In this case, adsorber chambers are provided which contain adsorbers which comprise a carrier material which is coated with a sorbent, with which better heat conduction is to be achieved than when the sorbent is in bulk form. From the DE 195 39 104 A1 an adsorption heat exchanger with interspaces filled with sorption material is known, which comprises a pack of lamellae arranged horizontally one above the other, which form interspaces. The spaces between the lamellae are almost completely filled with zeolite granules, with the individual zeolite particles being connected to one another and to the walls of the lamellae and to pipes by means of a binder. The stack of fins is penetrated by tubes, with the fins being in thermal contact with the tubes.

An adsorption heat exchange module is also from the U.S. 7,704,305 B2 known with a first distribution tube and a second distribution tube and arranged between the distribution tubes flat tubes, wherein said tubes are in fluid communication for a heat exchange fluid. Wavy ribs are arranged between the flat tubes and are provided with a moisture-absorbing layer as sorbent. It goes without saying that this known adsorption heat exchange module contains only a limited amount of sorbent and can therefore bind only a relatively small amount of refrigerant.

From the JP 2001 - 201 211 A an adsorption chiller is known with inlet-side tube parts that form a heating medium inlet, which are inserted into a first closure plate and connected to it, while outlet-side tube parts that form a heating medium outlet are inserted into a second closure plate and connected to it. Consequently, the inlet-side pipe parts can be connected to the first sealing plate and the outlet-side pipe parts can be connected to the second sealing plate regardless of the manufacturing variation in the distance between the inlet-side pipe parts and the outlet-side pipe parts.

In the U.S. 2004/0 200 603 A1 discloses an adsorber for an adsorption type refrigerator in which aluminum heat exchangers arranged in a case are provided with films which do not transmit moisture, e.g. B. SiO ₃ films, anodic oxide coating films, and the water sealed in the housing are added inorganic negative ions such as PO ₄ ^3- SiO ₃ ^2- .

It is the object of the present invention to enable, in a space-saving manner, adsorption heat transfer which is inexpensive and easy to provide and which at the same time is improved in relation to the prior art in terms of mass and heat transfer.

The object is achieved according to the invention with the features of the independent patent claims. Advantageous embodiments of the invention are summarized in the dependent claims.

The adsorption heat exchanger module with a flow distribution pipe, a return flow distribution pipe arranged at a distance from the flow distribution pipe, a plurality of pipe elements arranged at a distance from one another, each pipe element being arranged between the flow distribution pipe and the return flow distribution pipe, and a flow area which can be or is connected to the flow distribution pipe in terms of fluidity, and a return area which is connected to the is characterized by at least one lamellar profile component arranged between at least two adjacent pipe elements, by means of which a sorbent present in the form of a bed can be or is received.

The adsorption heat exchanger module according to the invention therefore comprises a plurality of tubular elements which are arranged at a distance from one another and are made, for example, of an aluminum, copper or stainless steel material and through which a secondary fluid can flow. A plurality of rows of flat tube elements arranged in parallel are preferably provided. Lamella profile components, for example made of aluminum, copper or stainless steel material, are arranged between adjacent tube elements. For a given pair of adjacent tubular members, a fin profile component disposed between them has a portion in mechanical and thermal contact with a first tubular member of the pair, a second portion in mechanical and thermal contact with the second tubular member of the pair, and a third Area in mechanical and thermal contact with a sorbent placed between the two tubular elements. According to the invention, the sorbent is in the form of a bed, for example a pellet or a granulate, in particular made of a zeolite or silica gel. Large amounts of sorbent can be accommodated between pairs of tubular elements with the aid of the lamellar profile components arranged between them, the lamellar profile components simultaneously increasing the heat conduction between the sorbent and the tubular elements and the mechanical stability of the arrangement of the tubular elements. Furthermore, the sorbent accommodated between the tubular elements is prevented from shifting by the lamellar profile component. By means of suitable lines, the sorbent can be charged with refrigerant, for example water or R134a, which can also be discharged again via other lines.

A further embodiment of the invention is characterized in that at least one tube element is designed as a flat tube element, which means that simple and cost-effective production can be achieved.

A further embodiment of the invention is characterized in that the flow distribution pipe and/or the return flow distribution pipe is designed as a pipe divided in two along its length, with a first and a second partial pipe, so that the pipe elements can be easily assembled and fastened in the distribution pipes.

According to the invention, the flow distribution pipe and/or the return flow distribution pipe is designed as a round pipe.

The invention is characterized in that at least one pipe element has a flow end area which, viewed from the inside of the flow distribution pipe, has a concave rounding and/or has a return end area that, viewed from the inside of the return flow distribution pipe, has a concave rounding, with which the flow resistance within of the distribution pipes can be reduced.

The flow distribution pipe and/or the return flow distribution pipe is expediently designed as a rectangular pipe.

A further embodiment of the invention is characterized in that at least one of the lamellar profile components has a rectangular contour, with which a structurally simple solution has been found which also enables the use of sorbent with a relatively large grain size.

A further embodiment of the invention is characterized in that at least one lamellar profile component has a triangular contour, with a relatively small-grained sorbent being provided.

The adsorption heat exchanger arrangement according to the invention comprises a vacuum shell, it being provided that the vacuum shell encloses at least partial areas of at least one adsorption heat exchanger module according to one of the preceding claims, so that thermal insulation from the environment is ensured.

A further embodiment of the invention is characterized in that at least two adsorption carrier modules arranged stacked on top of one another are enclosed by the vacuum envelope, with which the heat exchange capacity of the adsorption heat exchanger arrangement can be increased in a simple manner.

The vacuum envelope expediently encloses at least parts of a flow distribution pipe, a return flow distribution pipe and/or a pipe element of the adsorption support module.

Further aspects, features and advantages of the invention result from the following description, in which at least one exemplary embodiment is described in detail with reference to the drawings. Described and/or illustrated features form the invention on their own or in any meaningful combination, possibly also independently of the claims and can in particular also be the subject of one or more separate inventions. Identical or analogous components or features can also be provided with the same reference symbols in the drawings.

• 1 eine Prinzipdarstellung eines Adsorptionszyklus einer Adsorptionskälteanlage,
• 2 eine Prinzipdarstellung eines Desorptionszyklus einer Adsorptionskälteanlage,
• 3 eine zwischen zwei Flachrohren angeordnete Lamellenprofilkomponente mit Rechteckkontur,
• 4 eine zwischen zwei Flachrohren angeordnete Lamellenprofilkomponente mit Dreieckkontur,
• 5 ein Adsorptionswärmeübertragermodul mit einer Mehrzahl von Flachrohrelementen,
• 6 einen Schnitt der 5 entlang der Schnittebene S-S' mit einem als Rundrohr ausgebildeten Rücklaufverteilrohr,
• 7 eine Darstellung entsprechend 6 mit einem als Rechteckrohr ausgebildeten Rücklaufverteilrohr,
• 8 eine Darstellung entsprechend 7 mit einem zweigeteilten Rücklaufverteilrohr,
• 9 ein Adsorptionswärmeübertragermodul mit einer Vakuumhülle.

It show in schematic representation

• 1 a schematic diagram of an adsorption cycle of an adsorption chiller,
• 2 a schematic diagram of a desorption cycle of an adsorption chiller,
• 3 a lamellar profile component with a rectangular contour arranged between two flat tubes,
• 4 a lamella profile component with a triangular contour arranged between two flat tubes,
• 5 an adsorption heat exchanger module with a plurality of flat tube elements,
• 6 a cut of 5 along the section plane SS' with a return distribution pipe designed as a round pipe,
• 7 a representation accordingly 6 with a return distribution pipe designed as a rectangular pipe,
• 8th a representation accordingly 7 with a two-part return distribution pipe,
• 9 an adsorption heat exchanger module with a vacuum envelope.

1 shows a schematic diagram of an adsorption refrigeration system in an adsorption cycle with a condenser 1a, an adsorption heat exchanger 1b, an evaporator 1c, a closed flap 1d' arranged between the adsorption heat exchanger 1b and the condenser 1a, and an open flap 1d' arranged between the adsorption heat exchanger 1b and the evaporator 1c. '. Condenser 1a, adsorption heat exchanger 1b and evaporator 1c are connected to one another by means of flaps 1d' and 1d'' or can be separated from one another. The adsorption heat exchanger 1b contains a sorbent 4, for example a zeolite or a silica gel, which is able to adsorb a refrigerant and to desorb it at a later point in time. In the adsorption cycle, the refrigerant 1f is evaporated by the action of heat from outside by means of a heat flow 1e and is adsorbed by the sorbent 4, with the heat flow 1e transported with the refrigerant vapor being withdrawn from the evaporator 1c and thus from a space that is in thermal contact with the evaporator and is to be cooled. A heat flow 1j absorbed by the refrigerant vapor is withdrawn from the sorbent 4 in the heat exchanger 1b by means of a secondary circuit (not shown) of a coolant, such as water or a water-glycol mixture, and discharged to the environment. In this way it is possible to bind the largest possible amounts of refrigerant in the sorbent 4 until the sorbent 4 is saturated with refrigerant, at which point the evaporation process comes to a standstill.

2 shows a schematic diagram of a desorption cycle following the adsorption cycle, in which the flap 1d' is opened and a connection is thus established between the adsorption heat exchanger 1b and the condenser 1a. In the secondary circuit, a heat flow 1h is supplied to the sorbent 4, for example by means of a hot liquid, in order to expel the refrigerant 1f accumulated in the sorbent 4 from the sorbent. In order to then be able to feed the refrigerant 1f back to the evaporator 1c, it is liquefied in the condenser 1a 2 is indicated by the reference numeral 1g. A heat flow 1i is thereby dissipated to the environment.

3 shows a lamella profile component 2a arranged between a flat tube 1 and a further flat tube 1′, which has a rectangular contour and is connected to the surface of the flat tube 1 at at least one connection point 10, for example a soldered connection. A secondary fluid, indicated as an arrow, can flow through the flat tube 1 and the flat tube 1'. The sorbent 4 is arranged in the spaces between the lamellae between the flat tubes 1, 1'. For example, the sorbent 4 can be poured into the interstices and is then in bulk form.

4 shows a further embodiment of an adsorption heat exchanger component with a fin profile component 2b with a triangular contour arranged between two flat tubes 1, 1'.

The falling out of the sorbent 4 from the area between the flat tubes 1, 1' is prevented by a steel mesh or a perforated plate not shown in the figures, which partially or completely encloses the area of the adsorption heat exchanger component in which the sorbent 4 is accommodated.

5 shows an adsorption heat exchanger module according to the invention with a flow distribution pipe 5, a return flow distribution pipe arranged parallel to the flow distribution pipe 5, a plurality of flat pipe elements 1, 1′ arranged spaced apart from one another with lamellar profile components 2a arranged between the flat pipe elements 1, 1′ for receiving the sorbent 4. Each flat pipe element 1, 1 'Has a flow area 1v, 1v', which is fluidly connected to the flow distribution pipe 5. Furthermore, the flat tube elements 1, 1' are fluidly connected to a return area 1, 1' with the return flow distribution pipe 5'. The flow distribution pipe 5 therefore has openings into which the flat pipe elements 1, 1' can be pushed with their flow area 1, 1v'. Accordingly the return distribution pipe 5' has openings into which the flat pipe elements 1, 1' can be pushed with their return area 1r, 1r'. A firm connection between the flat tubes 1, 1' and the distribution tubes 5, 5' is ensured by a connection, for example a soldered connection. The adsorption heat exchanger module 20 preferably comprises a plurality of flat tubes stacked one on top of the other, with lamellar profile components arranged between the flat tubes. The sorbent 4 is placed in the space between the flat tube elements and the profile components. Several adsorption heat exchanger modules of the in 5 The form shown can also be stacked on top of one another, for which purpose spacers 11 are arranged on the top and/or bottom of the distribution pipes.

6 shows a section of the 6 along the sectional plane ss' with a return flow distribution pipe 5' designed as a round pipe. A return area 1r′ protrudes through a connection opening 6 into the distribution pipe 5′, the return end area 7a having a rounding which is concave when viewed from the inside, ie from the inner area of the return flow distribution pipe 5′. Such a rounding reduces the flow resistance within the distribution pipe 5'. As mentioned, there are spacers 11, 11' on the top and bottom of the distribution pipe 5'.

7 shows one of the 6 Corresponding representation with a return distribution pipe 5′ designed as a rectangular tube, the return end region 7b not being concave.

8th shows one of the 7 Corresponding representation with a two-part distribution pipe 5 ', which consists of a partial pipe 5a and a partial pipe 5b, which are connected to each other via connecting elements 5c. Such a two-part distributor pipe facilitates the assembly of the distributor pipe and the pipe element, and in particular the production of a connection between the pipe element and the distributor pipe in the area of the connection opening, in the case of the 8th So the production of a connection between the return area 1r and the distribution pipe 5 'in the area of the connection opening 6. A corresponding to the 8th A two-part distributor pipe is of course also conceivable in the case of distributor pipes with a circular or other cross-section.

9 shows an adsorption heat exchanger arrangement with a vacuum envelope 21 which encloses a number of adsorption heat exchanger modules which are arranged stacked one on top of the other in the vacuum envelope 21, with 21a denoting a front surface, 21b a side surface and 21c a top surface of the vacuum shell 21. A refrigerant opening 22 is arranged in the end face 21a, through which refrigerant can enter the interior of the vacuum envelope and act on the sorbent. Secondary fluid 3 can flow through the flow distribution pipes 5 into the adsorption heat exchanger module and be discharged through the return distribution pipes 5′, with the heat exchanger modules arranged inside the vacuum envelope 21 being flown through in parallel. It goes without saying that the invention also encompasses a different, for example serial flow through the heat transfer modules.

Reference List

1a

capacitor

1b

adsorption heat exchanger

1c

Evaporator

1d'

flap

1d''

flap

1e

heat flow

1f

refrigerant

1g

refrigerant

1 hour

heat flow

1i

heat flow

1y

heat flow

1

flat tube

1'

flat tube

1v

lead area

1v'

lead area

1r

return area

1r'

return area

2a

slat profile component

2 B

slat profile component

3

secondary fluid

4

sorbent

5, 5'

distribution pipe

5a

partial pipe

5b

partial pipe

5c

fastener

5d

fastener

6

port opening

7a, 7b

return end area

10

connection point

11,11'

spacer element

15

adsorption heat exchanger component

20

adsorption heat exchanger module

21

vacuum envelope

21a

end face

21b

side face

21c

top surface

22

refrigerant port

Claims (9)

Adsorption heat exchanger module with a flow distribution pipe (5), a return flow distribution pipe (5') arranged at a distance from the flow distribution pipe (5), a plurality of pipe elements (1, 1') arranged at a distance from one another, each pipe element (1, 1') between the flow distribution pipe (5) and the return flow distribution pipe (5') and a flow area (1v, 1v') which can be fluidly connected or is connected to the flow distribution pipe (5) and a return flow area (1r, 1r') which can be fluidly connected to the return flow distribution pipe (5'). or is connected, characterized by at least one lamellar profile component (2a, 2b) arranged between at least two adjacent pipe elements (1, 1'), by means of which a sorbent (4) present in the form of a bed can or can be accommodated, the flow distribution pipe ( 5) and/or the return flow distribution pipe (5') is designed as a round pipe, wherein at least one pipe element (1, 1') has a forward end area which has a concave rounded edge as seen from the inside of the flow manifold (5) and/or has a return end portion (7a, 7b) which has a concave rounded edge as seen from the inside of the return manifold (5'). adsorption heat exchanger module claim 1 , characterized in that at least one tube element (1, 1 ') is designed as a flat tube element. adsorption heat exchanger module claim 1 or 2 , characterized in that the flow distribution pipe (5) and/or the return flow distribution pipe (5') is designed as a pipe divided in two along its length, with a first and a second partial pipe (5a, 5b). Adsorption heat exchanger module according to one of Claims 1 until 3 , characterized in that the flow distribution pipe (5) and / or the return distribution pipe (5 ') is designed as a rectangular tube. Adsorption heat exchanger module according to one of the preceding claims, characterized in that at least one of the lamella profile components (2a) has a rectangular contour (2a'). Adsorption heat exchanger module according to one of the preceding Claims 1 until 4 , characterized in that at least one blade profile component (2b) has a triangular contour (2b'). Adsorption heat exchanger arrangement with a vacuum shell (21), characterized in that the vacuum shell (21) encloses at least partial areas of at least one adsorption heat exchanger module (20) according to one of the preceding claims. Adsorption heat exchanger according to claim 7 , characterized in that at least two stacked adsorption carrier modules (20) are enclosed by the vacuum envelope (21). Adsorption heat exchanger according to claim 7 or 8th , characterized in that the vacuum envelope (21) encloses at least parts of a flow distribution pipe (5), a return distribution pipe (5') and/or a tubular element (1, 1') of the adsorption carrier module (20).

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