FI81904B - Heat pump of the multiple regeneration and multiple absorption type - Google Patents

Description

81904

Multiple regeneration and multiple absorption type heat pump.

The present invention relates to an absorption-type heat pump as set out in the preamble of claim 1, with which the liquid to be heated can be heated by a combination of a coolant and an absorbent liquid.

The amount of temperature rise that can be achieved with respect to the liquid to be heated by the absorption-type heat pump cannot exceed the equilibrium temperature difference of 10 between the refrigerant and the absorbing liquid at the same pressure. For example, in a conventional heat pump using water and lithium bromide as a combination of coolant and absorbent, respectively, a temperature rise of at most 50 ° C can be achieved. As such, a heat pump consisting of a water-lithium bromide system has been proposed in order to achieve a higher heat rise. , which has a multi-stage absorber, but the introduction of multiple absorption-2Q stages causes the problem that the thermal efficiency is significantly reduced.

Heat pumps based on multiple absorption and multiple regeneration are also known in the art. These have been presented e.g. U.S. Pat. Nos. 3,483,710, 3,742,728, 3,831,397, 3,928,983, 3,990,263 and 4,337,625. However, the applications disclosed therein relate to cooling systems which are not suitable for heating or stepwise temperature rise on at least 30 regeneration sides. In them, the latent heat of the refrigerant is wasted.

Accordingly, it is an object of the present invention to provide a heat pump which is capable of heating a liquid to be heated over a wide temperature range and which nevertheless has a good heat efficiency. The invention is characterized by the features defined in the characterizing part of claim 1.

ϊ 2 81904 To this end, the invention provides a multiple regeneration and a multiple absorption type heat pump having a multiple absorption apparatus and a multiple regeneration apparatus, adapted to circulate a coolant and an absorbent between said two plants, and to heat the liquid to be heated therethrough. : said multiple absorption device consists of an evaporator which evaporates the refrigerant with heat from an external low temperature heat source, at least one absorption / evaporation unit which allows the absorber to absorb the absorber and absorbs the cooling steam from said evaporator or a similar evaporator absorbent cooling vapor from either the absorber or the preceding absorption / evaporation unit, and heat heat absorption of the liquid to be heated; said multiple regeneration apparatus consists of a regenerator which evaporates the coolant contained in the absorbent with heat from an external high temperature heat source and thus compacts the absorbent, at least one sealing regenerator A condenser that heats the liquid to be heated by the latent heat of cooling steam from this or a previous similar sealing / regeneration unit.

According to the above arrangement, the process of evaporating and absorbing the refrigerant is repeated numerous times. the high temperature heat source is used in several stages for the regeneration of the absorbent, and in addition the heat available in the last stage of the multiple regenerative 3 81904 thiol is also used to heat the gas to be heated. Therefore, it is possible to heat the low temperature heat source and the liquid to be heated over a large temperature range and a high heat efficiency.

These and other features and advantages of the invention will become apparent from the following description of the implemented devices, with reference to the accompanying drawings, in which:

Figure 1 is a schematic diagram showing a heat pump according to various embodiments of the invention.

Figure 2 is a graph showing the temperature-pressure cycle in the heat pump.

Figure 3 is a schematic diagram showing a heat pump according to a second embodiment of the invention.

Figure 4 is a graph showing the temperature-pressure cycle of the heat pump of Figure 3.

The heat pump of Figure 1 generally consists of a multiple absorber 1 and a multiple regenerator 2. The multiple absorber comprises an evaporator 3 having an evaporation region E1, a first and a second absorber / evaporator 4, 5 having absorption regions 4, respectively. ; L, A2 and evaporation regions E2, E3, absorber β having an absorption region A3. The multiple regeneration device comprises a regenerator 7 having a regeneration region R1, a first and second compactor / regenerator 8, 9, respectively, having sealing regions C1, C2 and regeneration regions R2, R3, and a seal 10 having a sealing region C3. A stream 12 of coolant, e.g. water, is circulated between the multiple absorption device 1 and the multiple regeneration device 2, and the chamfer 13 of the absorbent, e.g. lithium bromide, is also circulated between them via the heat exchanger 11. An external is passed to the evaporator 3 and the regenerator 7

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mätplahLatemperatlAän ^ iThermal heat liquid and external high temperature heat source liquid b, respectively. The liquid to be heated is flowed in parallel into the absorber 6 and the seal 10, respectively.

According to the above arrangement, the evaporator 3 is heated by the heat of the vapor coolant 12 from a liquid coming from an external low temperature source α. The first absorber / evaporator 4 allows the vapor of the coolant formed in the evaporator 3 to be absorbed into the absorbent 13 introduced from the second absorber / evaporator 5 into the absorption region A1, and the higher temperature. with a higher temperature and higher pressure. The second absorber / evaporator 5 allows the cooling gas from the first absorber / evaporator to be absorbed into the absorber 13 introduced from the absorber 6 into the absorption zone A2, and the high temperature heat generated in this process is used to evaporate the coolant 12 in the evaporation zone E3. temperature and higher pressure. The absorber 6 allows the cooling steam from the second absorber / evaporator to be absorbed into the absorbent coming from the multiple regenerator 2 through the heat exchanger 11, and the heat to be heated c is heated by the higher temperature heat generated in this process.

; The absorbent which has become diluted as a result of the cooling gas it absorbs is transferred from the absorption zone from the first absorber / evaporator 4 to regenerate; to the market 7 through the heat exchanger 11. In the regenerator 7, the coolant is evaporated from the absorbent 13 by the heat obtained from the liquid b of the external high temperature heat source, whereby the absorbent 13 condenses. The first seal / re-generator 8 allows the cooling gas formed by the regenerator 7 to condense in the sealing area C1. The absorbent 13 introduced from the regenerator 7 to the compactor / regenerator 8 is further compacted by the latent heat of the cooling gas in the regeneration zone R2. The cooling heat generated in the regeneration zone R2 of the first compactor / regenerator $ is compacted in the sealing zone C2 of the second compactor / regenerator 9. In the regeneration zone R3, the absorbent 13 from the first compactor / regenerator 8 is compacted

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81904 adds cooling gas by latent heat. The condenser C3 heats the liquid to be heated c with the latent heat of the cooling gas generated in the second condenser / regenerator 9, and the cooling gas condenses in this process. The condensed absorbent 13 is again passed to the absorber 6 through the heat exchanger 11. The coolant 12, which has been condensed by the first and second condensers / regenerators 8, 9 and the condenser 9, is fed to the evaporator 3, as well as to the absorber / evaporators 4,5.

Figure 2 shows the temperature-pressure period in the case where water and aqueous lithium bromide solution are used as coolant 12 and absorbent 13, respectively, in the apparatus of Figure 1. As can be seen from the figure, in the process of the multiple absorber, the temperature of the absorber 13 rises as the stepwise absorption of the cooling steam proceeds, and the temperature of the absorber 13 rises to about 120 ° C in the absorber 6 in the absorption region A3 where the heated gas c is heated. At the same time, the multiple regeneration device 2 uses high heat obtained by external high temperature heat; from the main source liquid b, to the stepwise step evaporation of the coolant 12 from the absorbent 13, i.e. to the stepwise compaction of the absorbent, wherein: the cooling gas; the heat state decreases as the% idling process proceeds, i.e. in series C1 - C2 - C3. However, the cooling gas introduced into the seal 10 (sealing area C3) has a temperature as high as about 120 ° C. Thus, by passing the liquid to be heated c, for example water through both the absorber 6 and the condenser 10, it is possible to heat it to temperatures as high as 80 to 120 ° C, i.e. to generate low-pressure steam.

The apparatus shown in Fig. 3 differs from that shown in Fig. 1 only in that the absorbent 13 is recirculated in its order in the order of heat exchanger 11, first absorber / evaporator 4, second absorber / evaporator 5, absorber 6, heat exchanger 11, second seal / regenerator. 6 81 904 Nerator 9, first compactor / regenerator 8, regenerator 7.

Figure 4 shows the temperature-pressure period in the case where water and aqueous lithium bromide solution are used as coolant 12 and absorbent 13, respectively, in the apparatus of Figure 3. The beneficial effects of the arrangement, which are similar to those of Figure 2, can be seen from the curve.

It should also be noted that, for simplicity, only one heat exchanger 11 is shown in Figures 1 and 3, but to improve system efficiency, a plurality of heat exchangers may be added to the multiple absorber 1 and the multiple regenerator 2 to exchange heat between the coolant 12 and the absorber 13. It is also possible to arrange the liquid c to be heated to flow through the absorber 6 and the seal 10 in series.

As the external low temperature heat source a, 0 to 60 ° C heat from an ambient source (air or chilled water) t.ai low temperature waste heat can be used, and as the external high temperature heat source b, heat which; is above 250 ° C, such as steam high temperature waste heat *: or pa?> amiS heat. When using such heat, the heated liquid can be heated up to 140UC, maximum.

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Claims (9)

A heat pump equipped with multiple regeneration and multiple absorption comprising a multiple absorption plant (1) and a multiple regeneration plant (2), between which a extendable liquid refrigerant (12) and a liquid absorbent (13) are circulated, the multiple absorption plant comprises: an evaporator (3) to extend the refrigerant coming from said multiple regeneration plant (2) through the heat exterior low temperature source (a), one or more absorption / evaporation units (4,5) with an absorption zone (Α 2, A 2) and an evaporation zone (E 2, E 2) in heat conduction connection with said absorption zone (A 2, A 2), wherein said absorption zone (A 2, A 2) is arranged to allow the absorbent zone (A ^ tionsmedbdbi ·. (13) absorbing the steam of the coolant from said evaporator (3) or from a previous absorption-evaporation unit (4) evaporation zone (2) 1 wherein said evaporation zone (Ejf 3) is arranged to evaporate the refrigerant (12). from said multi-faceted ... regeneration plant (2) with the absorption heat formed in said 2q absorption zone (Α ^, A2), and an absorber (6j 'to allow the absorbent (13) to absorb the coolant in this from the evaporation zone (E ^) of its or one preceding absorption Zav evaporation unit (4, 5), and wherein the multiple regeneration plant (2) comprises: a regenerator (7) for concentrating it in this introduced absorbent (13) by evaporation of the absorbed refrigerant · - through the heat of an external high temperature source (b), one or more condensation / regeneration units (8, 9) with a condensation zone (C regeneration zone (R2 »Rg) soin is in thermal conductive connection to said condensing zone (C 2, C 2), wherein said condensing zone (C 2, C 2) condenses the branch of said regenerator (7) or from a previous condensation / regeneration unit J8) 'regeneration zone (r coming coolant while said regeneration zone (Rj, Rg) concentrates the absorbed agent (13) introduced into it by evaporation of the absorbent coolant by means of the condensation heat formed in said condensation zone (C and a condenser (10) for condensing the refrigerant vapor coming from a pre-existing condensation / regeneration unit (} 8, 9), characterized in that the multiple absorption plant (1) and the plurality of regeneration plant (1). 2) arranged so that the residual heat from the last absorber (6) and the last condenser (10) has been collected in the heat-receiving liquid (C), which is arranged to at least partially flow through the absorber (6) and the condenser (10) by heating in them, where the plurality of absorption plant (1) and the plurality of regeneration plant (2) are arranged so that the temperature of the absorber (6) is substantially the same as the temperature of the condenser (10). A heat pump according to claim 1, characterized in that it further comprises a heat exchanger, through which the absorbent medium (13) flows in its route from said multiple / absorption plant (1) to said multiple regeneration plant (2). and vice versa. A heat pump according to claim 1, characterized in that said heat receiving liquid (c) is divided into a first flow passing through said absorber (6) and a second flow passing through said condenser (10), said first and other currents flow together into a single current passed through said absorber (6) and analogously through said condenser (10). 4. A heat pump according to claim 1, characterized in that said abscirbator. (6) receives the absorbent (13) from the regeneration zone (R3) of the condensation / regeneration unit (9) 13 81 904, and said regenerator (7) receives the absorbent radiator (7) 13) from the absorption / evaporation unit (4) of the absorption / evaporation unit (4) immediately after said evaporator (3). 5. A heat pump according to claim 1, characterized in that it immediately receives the absorbent means (13) from said regenerator (7) immediately after said evaporator (3), the absorption / evaporation unit (4) of said absorbent (13) from said regenerator (7). The condensation / regeneration unit (9) located immediately above said condenser (10) receives the absorbent means (13) from said absorber (6). Heat pump according to claim 1, characterized in that said coolant (12) is water, and that said absorbent is a solution of lithium bromide in water. 7. A heat pump according to claim 1, characterized in that said low temperature source (a) has a temperature of 0 - 60 ° Cocb said high temperature source (b) has a temperature: of at least 20 ° 0 ° b. 8. A heat pump according to Claim 7, characterized in that said low temperature source (a) is air or water in ambient or low temperature waste. 9. A heat pump according to claim 7, characterized in that said high temperature source (b) is meadow or high temperature waste combustion heat. i i