DE694724C - Device for electro-osmotic cold generation - Google Patents

Description

Device for electroosmotic refrigeration It is known for cold generation with electro-osmotic conveyance of the refrigerant the I, '- älternantampfeldampf to sorb by a dry active substance and by an electrical potential difference to convey electro, osmotically through the sorbent.

The invention is based on the object in the electroosmotic effective system to keep electrical losses to a minimum. The invention relates to a device for electroosmqtischen cold generation, at which sorbs the evaporated refrigerant through a sorption, substance and through that , elektroosmotis.che effect of two electrodes removed from the sorbent again where the cross-section: of the sorbent, the, the vaporized refrigerant ; siorbert, is several times larger than the cross-section of the electrode. -This will be the permanent existing between the electrodes of the @electroosmotic acting systems Energy losses are reduced and. the further advantage achieved in that in the sorption soff: the degree of saturation that is maintained for the electroosmotic The most favorable effect is. With the same cross-sections of the effective layers not only will greater electrical losses occur, but also the 'elektr oosmotisch @ e Kind of time of the: electric field will convey much more refrigerant than can be replenished by sorption, so that. : the sorbent of refrigerant more impoverished than @es for a good efficiency of the electroosmotic work is required.

To solve the existing problem, the subject matter of the invention be designed in different ways. So is z. B. a device for electroosmotic Cold generation in which the evaporated refrigerant is sorbed by a sorbent and therefore the @electroosmotic effect of two electrodes, the sorbent is removed again, especially effective when the one cross-section of the sorbent, which sorbs the evaporated refrigerant, is several times larger than the cross section of an electrode. The same effect is also due to its similar Facility achieved in which the cross-sections of the sorption and the electroosmotic effective layer are approximately equal to each other, but a number of which are electrical Separate electroosmotic cells, which are permanently gaseous refrigerant sorb, for the purpose of the electroosmotic effect only periodically to an electrical one Tension to be put. In the case of this last-mentioned facility, the over The sorption layer lying only against the various electroosmotic layers the point or points removed from the refrigerant that are currently connected to the power supply. If there has been a strong depletion of the refrigerant in the sorbent at these points, so the corresponding electrodes are switched off and the electrodes of the electroosmotic System of another cell applied to voltage. The rinn occurs at these points Separation of the refrigerant through the electroosmotic layer, while in the meantime the previously switched on electroosmotic cells bnv. which sorbent can absorb the vaporous refrigerant again.

The well-known substances such as clay, silica gel, active charcoal, etc., used alone or in mixtures. It can according to the invention the arrangement of two or more different types of sorbent in the Wise hit -be, - @ that the refrigerant is on the way from the sorbing surface up to the exit surface first finds a sorbent that is particularly good Has sorbent effect and is later transported through a sorbent, which has a particularly good electroosmotic effect. For the former case is z. B. Silik.agel and for the last-mentioned z. B. active charcoal especially suitable. The sequence of these substances is generally such that the vaporous Refrigerant first of a fine-pored layer and then of one or more layers a Sorptioriss.tofes with larger pores is absorbed.

The sorbents can be used in the device for electroosmotic Cooling can be arranged in a particularly advantageous manner so that the material is held between two walls made of: a porous material. Through this are losses of the sorbent, such as. B. by atomization or washing away can arise, avoided. As a suitable means for these walls comes z. B. plaster of paris or porcelain in question. The sorbent can be used together with powder or granular, porous material of this carrier material are pressed into a solid plate. The electrodes can also lie between the porous walls. It can System be designed so that the electrodes directly on the porous walls or it can be between the inlet electrode - or also between a thin layer of the exit electrode and the adjacent porous wall Sorbent must be present to facilitate the transition of the refrigerant between the in To improve the substances in question. The one between an electrode and her sorbent material present in each adjacent wall can be the same or different of that present between the electrodes. Be fabric. The loose, e.g. B. powdery or granular sorbent can with the help of a mechanically solid substance to a fixed plate pressed in an advantageous manner can be used as a diaphragm.

In FIGS. R to 6 are some exemplary embodiments of the subject matter of the invention shown.

In Fig. R is shown in cross section and in corresponding Designated container of the device with the number i. In this Container is the refrigerant to be evaporated a ,, z. B. water. In it can a pipe coil ¢ for guiding the brine. The refrigerant evaporates in the container in the direction of the arrow and is taken up by a sorbent 3. A cooling line q. ' intended, which is embedded in the sorption layer 3. The sorption layer 3 rests on it the electroosmotic -active layer 5 with the associated electrodes 6 and 7 and. Together with these forms an electroosmotic cell. Layer 3 is spatially designed so that 'that cross-section of the sorbent which the evaporated refrigerant sorbed, is several times larger than the cross-section of the electroosmotic effective layer or: as one of the associated electrodes. In the picture the layer 3 has a cross-section similar to that which widens sharply upwards an inverted truncated cone, which is delimited by the entry electrode 6 at the bottom will. The two are above and below the electroosmotic layer 5 Electrodes 6 and 7 arranged, for example made of wire mesh or perforated Sheets are made. About the sorbent present between the electrodes takes place with the help of the electrodes connected to the terminals of a power source the Pumping the refrigerant out of the actual sorption layer 3 in the room below, in which a renewed evaporation of the refrigerant z enters, instead of.

In Fig. Z an embodiment of the electroosmotic system is shown, in which above the entry electrode 6 and below the exit electrode 7, in their immediate vicinity, each a wall 8, and made of porous, inactive material, such as plaster of paris or porcelain, is arranged. The electroosmotic sorbent 5 is located between the electrons 6 and 7.

In the device according to Figure 3 is between the electrode 6 and the Wall 8 still another thin layer io of a sorbent introduced-. These Layer can be related to its nature or composition with the actual electroosmotic layer 5 match. Unless the exit electrode 7 @ also at a certain distance from the lower porous wall i i is arranged, the space can also be filled with a sorbent be. The layers can consist of granular material of the same size; expedient but is the space between the inlet electrode 6 and the wall 8 with a fine-pored and the space between the exit electrode and the wall i i filled with a coarse-pored material. The one between the electrodes 6 and 7 Sorbent 5 is best used in powder form.

Fig.q. shows another form of the: electroosmotic Device for cold generation according to the invention. In the one shown in cross section Container i, which in this case has a rectangular shape, are three electro.osmotic Cells a, b and c housed. Each of these cells consists of an electroosmotic effective system with the electrodes 6 and 7 and the sorption layer in between 5. The actual sorption layer 3 lies on the inlet electrode 6 The sorption layers are embedded in cooling pipes 13 to dissipate the heat of sorption. In this device, the sorption layers 3 have the @electroosmotic Systems 5 have approximately the same cross-sections. To reduce the electrical Losses i- "in the electro-osmotic system become electro-osmotic in this device Cells that are electrically separated from each other only have periodic voltage placed. Of course, my appropriately sized container can also a greater number of such cells housed the leg. When operating the facility the procedure is such that the cells., are always switched on at which the actual sorption layers have absorbed the refrigerant to saturation, while the cells, their sorption layers by the action of the tension applied are depleted of refrigerant, switched off, so that in the meantime, while the other cells are kept in operation, a new recording of the refrigerant takes place. The transport of the refrigerant from the steam room to the The liquid space of the device takes place in one already described in FIG analog way.

In Figure 5, the arrangement is round and shown in plan. In the kettle-shaped container i, in the lower part of which the refrigerant z is in liquid form, z. B. four electro-osmotic cells a, b, c and d ,, which are also round, housed. The refrigerant vapor can rise in the spaces between these cells and thus reach the sorption layers. In two of the electroosmotic cells, the sorption layers 3 have been partially removed to illustrate the arrangement of the parts, so that the entry electrodes 6 are visible. The operation of the device shown in FIG. 5 can be the same as that of that in FIG. apparatus described above. The individual @electroosmotv cells can therefore be brought into effect periodically by applying an electrical voltage, so that the electrical losses are only a corresponding part. However, it is also possible to design the individual cells as shown in FIG. 1 and as already described above. are. In this case, Ida's electroo, smotic system of the cells would be permanently under voltage, for the purpose of reducing the electrical energy losses of the cross-sections of the electro-osmotic system compared to that cross-section of the sorbent through which the sorption of the refrigerant takes place, would be significantly reduced.

In the last-described training of the device for electroosmotis, chen The electrodes of the Electrically effective systems also connected in series. This will the use of a higher voltage and thus a better efficiency of the overall system @achieved.

The Fig.6 represents vain device, which in principle with the according to. Fig. Q. matches. On the for example four electroosmotic systems a, U, c "* d the sorption layer 3 lies without subdivision. The electrodes of the systems a to d can possibly be switched on periodically according to: a certain cycle, so that only a part takes up electrical energy and thus a certain section of the sorbent layer - the refrigerant loses.

Claims (3)

PATENT CLAIMS: i. Device for electro-osmotic refrigeration, in which the evaporated refrigerant sorbs through a sorbent and passes through the electroosmotic effect of two electrodes is removed from the sorbent again is, characterized in that that cross section of the sorbent which the evaporated refrigerant sorbs several times. # is larger than the cross-section of the Electrode. 2. Device for electroosmotic refrigeration according to claim i, characterized in that two or more different types of sorbent are used in such a way that the refrigerant on the way from the sorbing surface up to the exit surface first finds a sorbent that is particularly good Has sorption effect and later a sorbent, which is particularly good electroosmotic Has an effect. 3. Apparatus according to claim 2, characterized in that the various Sorptionsstofffe are arranged such that the vaporous Refrigerants first the fine-pored sorbents and then those with larger ones Finds pores. q .. Device for electroosmotic refrigeration according to claim i, in which the evaporated refrigerant by a loose, z. B. powdered sorbent sorbed and by the electroosmotic effect of two electrodes from the sorption is removed again, characterized in that the sorbent between two Walls made of porous but solid material, e.g. B. plaster of paris or porcelain is held. 5. Apparatus according to claim q., Characterized in that the loose, z. B. powdery or granular sorbent with the help of a mechanically solid substance to a solid Plate is pressed. 6. Apparatus according to claim ¢, dadurphgekisiert that the Electrodes lie between the porous walls and the sorbent. 7. Device according to claim 6, characterized in that the entry electrode near the one porous wall is arranged so that between it and the porous wall still one thin layer of active substance is present. B. Apparatus according to claim 7, characterized characterized in that the exit electrode is also arranged so that zw% shy it and the adjacent porous wall a thin layer of sorbent still exists. 9. Apparatus according to claim 7 and 8, characterized in that that the sorbent lying between an electrode and a porous wall is different from the sorbent between the electrodes. ok contraption for electro-osmotic refrigeration, in which the evaporated refrigerant passes through sorbed a sorbent and through the electroosmotic effect of two electrodes is removed from the sorbent again, characterized by a number electrically separated, electroosmotic cells that are permanently gaseous Sorb refrigerant, but only periodically for the purpose of elel- or troosmotic effect be put on tension. i i. Device according to claim i o, characterized in that that, several electroosmotic cells are electrically connected in series.