DE19539102A1 - Sorption module for refrigerator - Google Patents

Abstract

The sorption module has a heat exchanger arrangement (2) that is at least partially filled with a sorption material and connected to an evaporator/condenser block, a vacuum pump (10) and a ventilating valve (11). There is a common housing (4) around the exchanger and the block. The pump is located on the side and is a single component with the valve. The exchanger is formed by a packet of lamellas (7) at discrete distances with tubes (9) passing through them at right angles. It is the space between the lamellas that is filled with the sorption material.

Description

The invention relates to a sorption module with an at least partially with a fixed Sorption material filled sorption block and with a flow with this connected evaporator / condenser block and a method for operating such.

From DE-OS 34 25 419 a sorption refrigeration system is known in which separate zeolite and water fillings are present. After loosening the separator, water vapor can flow to the zeolite filling, which releases the steam releasing heat of adsorption adsorbed. The water cools down due to the evaporation process and freezes over Ice cream. Such systems place high demands on the vacuum tightness of the used housing walls and separators.

The invention has for its object a sorption module and method for operating to provide one which is particularly simple and therefore inexpensive to set up is.

A sorption module according to the invention is characterized in that it is for operation is permanently equipped with a vacuum pump and with a valve for ventilation. A single use of vacuum pumps for the production of with sorption material filled sorption heat exchangers is known from DE-OS 36 04 910. The sorption module according to the invention is not by the opening and closing of Steam flaps, but by evacuating using a vacuum pump  taken and taken out of operation by venting with a valve. Thereby, that a vacuum pump is firmly connected to the sorption module will not be inflated Requirements are placed on the vacuum tightness of the system, since the vacuum passes through everyone Vacuum pump operation resets during an adsorption phase. Beneficial Embodiments of the invention can be found in the subclaims.

A particularly simple and compact design of a sorption module results from that the sorption heat exchanger arrangement and the evaporator / condenser block of are surrounded by a common housing.

To ensure quick operational readiness for an adsorption process as well to terminate such, it is advantageous if the vacuum pump on the side of the Adsorption heat exchanger arrangement is arranged. This will remove the existing air sucked off by the adsorption heat exchanger arrangement during operation of the vacuum pump and at the same time sucked water vapor into the adsorption heat exchanger arrangement. If the valve advantageously combined with the vacuum pump to form a component for ventilation also on the side of the adsorption heat exchanger arrangement is arranged, at the end of an adsorption process by opening the Vent valve the incoming air first the adsorption heat exchanger assembly flow through and thereby quickly end the adsorption process.

According to an advantageous embodiment, the sorption block consists of a package mutually spaced slats and penetrating them substantially perpendicular Pipes, the spaces between the fins being filled with sorbent granules, which is advantageously connected to a ceramic adhesive to increase the thermal conductivity is.

The evaporator / condenser block advantageously also consists of a package mutually spaced lamellae and these penetrate essentially perpendicularly Pipes, where the fins with an absorbent coating to absorb water are provided as work equipment. The known use of zeolite granules and  Water as a sorption material / working material pairing enables a particularly effective, environmentally friendly operation of a sorption module.

In particular for use in vehicles, it is advantageous if the housing follows has bulging side walls on the inside. Since with such a housing also during Evacuating only tensile stresses occur in the walls, the side walls in particular thin-walled and therefore easy to carry out.

A cover plate delimiting the housing upwards and downwards is preferably with the penetrating pipes and the intermediate layer of a seal connected by crimping.

A method for operating a sorption module is characterized in that a start an adsorption process by evacuating the sorption block by commissioning the vacuum pump and ending an adsorption process by means of aeration of the valve.

An exemplary embodiment of the invention is described below with reference to the drawings. It shows:

Fig. 1 shows a longitudinal section through a Sorptionsmodul,

Fig. 2 is an enlarged partial section through a Adsorptionswärmeübertrageranordnung,

Fig. 3 shows the connection of a cover plate and a tube in the disconnected state,

Fig. 4 shows the connection of a cover plate and a tube in the flanged state and

Fig. 5 shows the operation of a sorption module in a vapor pressure diagram.

A sorption module 1 is composed of an adsorption heat exchanger arrangement 2 and an evaporator / condenser block 3 which is connected to this in terms of flow and which are accommodated in a common housing 4 .

The housing 4 has inwardly bulging side walls 5 and a cover plate 6 which delimits the same upwards and downwards. The side walls 5 are arched inwards, so that there is a further deflection of the side walls 5 inwards when there is a decrease in pressure within the housing, as a result of which only tensile stresses occur. This enables a particularly thin-walled design of the side walls 5 .

The adsorption heat exchanger arrangement 2 is formed by a package of horizontally arranged, spaced-apart fins 7 and tubes 9 which penetrate them essentially vertically. As can be seen clearly from FIG. 2, the spaces between the lamellae 7 are filled with a sorption granulate 13 . To improve the heat conduction to one another and to the fins 7 and the walls of the tubes 9 , the sorption granulate 13 is preferably connected by means of a ceramic adhesive.

The evaporator / condenser block 3 is also formed by a package of horizontally superimposed, spaced-apart fins 8 , which are likewise penetrated by tubes 9 essentially perpendicularly. The fins 8 of the evaporator / condenser block 3 are provided with an absorbent coating, not shown. The absorbent coating serves to absorb water as a working fluid.

The outer ends of the tubes 9 penetrate the cover plates 6 of the housing 4 . For an essentially vacuum-tight connection between the tubes 9 and the cover plates 6 , an intermediate layer of a seal 14 is provided according to FIGS. 3 and 4, which by means of a subsequent flaring process together with the part of the cover plate 6 resting against the wall of the tube 9 to form a tight collar is deformed.

On the side of the adsorption heat exchanger arrangement 2 , a valve 11 for ventilation and a vacuum pump 10 for evacuating the adsorption heat exchanger arrangement 1 are provided on the sorption module 1 in the region of the side wall 5 . Both components are preferably connected to the sorption module with a single connecting line. They are also advantageously combined into a single component and attached to the sorption module 1 .

The sorption module is desorbed by heating by means of heating gas through the pipes 9 in the area of the adsorption heat exchanger arrangement 2 or an electrical heater arranged there, whereby water vapor is expelled from the sorption granulate 13 and passed via the transition area 12 into the evaporator / condenser block 3 , where it releases heat condensed. The heat of condensation can be absorbed by a gaseous heat transfer medium through the tubes 9 of the evaporator / condenser block 3 and can be used.

During the desorption process, the valve 11 can be opened for aeration at the same time, so that the pressure in the sorption module after desorbing is in the region of the curve indicated by B in FIG. 5. This curve B lies some distance above the vapor pressure curve A of the liquid working fluid A, here water. The vacuum pump 10 is started up to initiate an adsorption process. It sucks off air on the side of the adsorption heat exchanger arrangement 2 , the pressure in the system correspondingly decreasing isothermally in accordance with curve C in FIG. 5. As soon as the vapor pressure curve A of the water is reached during the pressure reduction, the evaporation of water begins in the evaporator / condenser block 3 , which water is sucked into the adsorption heat exchanger arrangement 2 by the vacuum pump 10 which remains in operation and the air flowing out at it. During the adsorption, a gaseous heat transfer medium is sent through the tubes 9 in the area of the adsorption heat exchanger arrangement 2 , which absorbs the heat of adsorption released by the accumulation of water vapor in the area of the sorption granulate 13 and supplies it to a purpose for heating. If the adsorption process is to be ended, the vacuum pump 10 is switched off and at the same time the valve 11 is opened for aeration. This increases the pressure in the system according to curve D due to the inflowing air, and after leaving the vapor pressure curve A, the evaporation of water in the evaporator / condenser block 3 stops. Since there is therefore no further water vapor available for accumulation in the sorption granulate 13 in the adsorption heat exchanger arrangement 2 , the adsorption process is put to an end by such aeration.

This process can be resumed at any time by closing the valve 11 and operating the vacuum pump 10 again, as long as the sorption granulate 13 in the adsorption heat exchanger arrangement 2 has not been completely saturated. If this is the case, the sorption module 1 must be desorbed again by the supply of heat in the manner described above and thus be put into operational readiness.

The previously described sorption module 1 is particularly well suited for use in cooling or heating a vehicle interior due to its compact and light construction and its simple operation.

Reference list

1 sorption module
2 adsorption heat exchanger arrangement
3 evaporator / condenser block
4 housing
5 sidewall (of 4 )
6 cover plates (of 4 )
7 slats (of 2 )
8 slats (of 3 )
9 tubes
10 vacuum pump
11 valve
12 transition area
13 sorbent granules
14 seal
A water vapor pressure curve
B partially ventilated condition
C evacuate
D Vent

Claims (5)

1. sorption module ( 1 ) with an at least partially filled with a solid sorption material adsorption heat exchanger arrangement ( 2 ) and with a flow-connected evaporator / condenser block ( 3 ) for receiving a liquid working fluid, with a vacuum pump ( 10 ) connected to the sorption module ( 1 ) ) and with a valve ( 11 ) for venting the sorption module ( 1 ). 2. Sorption module according to claim 1, characterized in that the adsorption heat exchanger arrangement ( 2 ) and the evaporator / condenser block ( 3 ) are surrounded by a common housing ( 4 ). 3. Sorption module according to claim 1 or 2, characterized in that the vacuum pump ( 10 ) is arranged on the side of the adsorption heat exchanger arrangement ( 2 ). 4. Sorption module according to one of the preceding claims, characterized in that the vacuum pump ( 10 ) and the valve ( 11 ) are combined into one component. 5. Sorption module according to one of the preceding claims, characterized in that the adsorption heat exchanger arrangement ( 2 ) from a package of mutually spaced fins ( 7 ) and these substantially perpendicularly penetrating tubes ( 9 ) is formed, the spaces between the fins ( 7 ) with Sorption granules ( 13 ) are filled as sorption material.