DE10325933A1 - Diffusion absorption system has pressure system with at least two adjacent, independent, hermetically sealed individual pressure systems, each with stack with absorber, evaporator and condenser - Google Patents

Abstract

The system has a pair of working materials formed by a coolant, e.g. ammonia, and a solvent, e.g. water, and a pressure equalizing auxiliary gas, e.g. helium or hydrogen, in a pressure system. The pressure system consists of at least two adjacent, independent, hermetically sealed individual pressure systems (1-3), each with an independent absorber (7,..), evaporator (5,..) and condenser (4,..) arranged in series at least essentially in the vertical direction.

Description

The Invention relates to a diffusion absorption system accordingly the preamble of claim 1.

Diffusion absorption systems are known, inter alia, as refrigeration systems for use in refrigerators. However, with a corresponding design, they can also be used as heat pumps for heating or cooling purposes. In known systems, ammonia (NH ₃ ) is generally used as the refrigerant and water as the solvent or absorbent substance, that is to say ammonia-water as the working substance pair. An auxiliary or inert gas, for example hydrogen or helium, is also used to equalize the pressure. The heat is supplied in a cooker. By boiling, steam bubbles are expelled from the ammonia-rich solution, thereby creating a solution cycle and an ammonia cycle. The water fraction in the steam stream formed by the steam bubbles is separated in a rectifier, so that then almost pure ammonia steam flows to the condenser of the plant. The ammonia vapor condenses in the condenser and releases the heat of condensation to the environment or, for example, to the heating water of a heater via a condenser heat exchanger. The liquid ammonia then flows downward from the condenser arranged at a higher level into an evaporator, in which the ammonia in the atmosphere present there evaporates from the auxiliary gas and ammonia, with the absorption of heat from the environment or with useful cooling power. The gas mixture of ammonia gas and auxiliary gas then passes through a gas heat exchanger into the absorber, where the gaseous ammonia is absorbed by the ammonia-water solution containing only a small amount of ammonia and thus returned to the solution cycle. The heat of absorption is released via an absorption heat exchanger, for example back to the water of a heater. The ammonia-water solution enriched with ammonia flows back to the stove via a flow.

It is known to realize such diffusion absorption systems also for larger outputs, for example in the range of several kilowatts of heating output, by dividing the respective liquid streams in the evaporator and absorber into partial streams and distributing them to achieve the large internal surfaces necessary for the mass and heat transfer smaller evaporator and absorber heat exchangers are routed ( CH 678 103 ). In this way, the water-ammonia solution can in principle be distributed over a total absorber area of more than one square meter, so that with a typical specific surface load of about 0.15 watts / cm ² more than three kilowatts of total absorber power are quite possible. In the same way, the liquid ammonia can also be distributed over a similarly large total area in the evaporator in order to obtain evaporator outputs in the kilowatt range.

adversely but here u. a. that the liquids preferably exactly according to the respective surfaces of the smaller heat exchangers must be distributed in the evaporator or absorber. For example, there is the entire evaporator from four smaller evaporators of the same size or Partial evaporators, it is necessary to determine the amount of liquid ammonia preferably exactly evenly distribute these four partial evaporators. This is because of the minor Volume flow of, for example, 0.8 grams of ammonia per second at about a kilowatt of evaporator power and because of that in diffusion absorption systems potential low pressure differences technically very complex and only limited control or controllable.

at an uneven distribution of the liquid Ammoniaks on the partial evaporators will not achieve the desired evaporator output reached. Because namely for example, a partial evaporator supplied with too much liquid ammonia occurs this from the partial evaporator again without completely evaporating to be. Conversely, another vaporizer may be too small because of it Liquid supply Ammonia does not provide sufficient evaporator power. In the same An uneven distribution is wise the water-ammonia solution for example of the same size Partial absorbers also negatively affect the total absorber performance. In both cases reduce the overall performance and / or the efficiency of the Aggregates. An uneven distribution of liquids on the individual partial evaporators in this known absorption system especially from an inclined position result, i.e. result from the fact that the diffusion absorption system in question is not is arranged or aligned exactly perpendicular. In many applications is such an alignment not made or z. B. with mobile systems at all not possible.

A disadvantage of the known diffusion absorption systems for higher outputs (outputs in the range of several kilowatt heating output) is that the internal volume of the unit increases approximately proportionally with the internal surfaces of the absorber and evaporator. For example, with an absorber surface of one square meter, there is already an internal volume of at least ten liters. This volume is then available for diffusion absorption systems for example operated with ammonia as the refrigerant, under a high internal pressure, for example under an internal pressure of 20 to 25 bar. This exceeds the intrinsically safe pressure vessel values from the internal pressure multiplied by the internal volume.

adversely is in known diffusion absorption systems for higher performances in the range of several kilowatts further that at the filling quantity of these systems of ammonia is 1.5 kilograms or more. This then also the for intrinsically safe devices permitted filling quantities exceeded for ammonia, so that then no longer intrinsically safe devices usually in accordance with the standards and legal regulations periodically checked at the installation site have to, what additional Costs.

task the invention is to show a diffusion absorption system, which avoids these disadvantages and still has high heating outputs in the range of several kilowatts. To solve this The task is a diffusion absorption system according to the claim 1 trained.

The diffusion absorption system according to the invention consists of at least two, preferably structurally identical and hermetic against each other and to the outside closed single printing systems. Each individual printing system contains independently all for the operation of a diffusion absorption system necessary components. Such components of the individual printing systems, the (components) a larger volume have, such as absorbers, evaporators and condensers are arranged essentially one above the other in each system. This points each individual printing system has a small footprint so that the total footprint of the Diffusion absorption system consisting of at least two individual pressure systems can also be kept small in size. With typical heights the diffusion absorption system from 1200 to 1900 mm become compact Overall system dimensions achieved, with advantages u. a. in the production, transport and installation of the diffusion absorption system.

On Another essential advantage of the diffusion absorption system according to the invention consists in their low sensitivity to inclination. This is also due to the fact that diffusion absorption systems according to the invention in at least two Single printing systems is divided into all the necessary components and with it all heat exchangers each have separately, so that these components in each individual printing system the invention, especially in the horizontal direction, small dimensions have or the distribution of the liquid ammonia in the evaporator as well as the distribution of the water ammonia solution in the absorber in each Single printing system takes place on a relatively small horizontal width. This reduces the risk of an uneven distribution of the liquids on the respective components during the Operating with a slight inclination. The performance and the efficiency is hereby through an inclination less strong or at all unaffected.

Diffusion absorption plants with higher performances, i.e. with power in the range of several kilowatts often have to Part load range are operated. This is usually done by a reduced heat input in the stove. In this part-load operation, however, the results are comparatively high Losses, i.a. for example in gas operation unfavorable Combustion, but also in general through internal losses, in particular out too big inert gas streams result. The inert gas flow of a diffusion absorption system namely exclusively through natural Convection causes and is caused by the loss of flow pressure within the upper limit of the diffusion absorption system. This pressure loss is constructively given by the line cross sections and on the maximum performance of the diffusion absorption system and can thus during of the company cannot be adapted to the respective performance. The training according to the invention allows it, with a lower power requirement of the diffusion absorption system every single printing system, which has its own stove, independently from the other single printing system on or off or on regulate. This means, for example, that one consists of three individual printing systems Diffusion absorption system only by switching individual on and off Single printing systems can output 100%, 66% and 33%. In any of these cases the single pressure systems in operation work under full load, i.e. with an optimal efficiency, so that the overall efficiency the diffusion absorption system is optimal and disproportionately high losses, for example in the stove heating or through the inert gas flow are avoided.

The design according to the invention also has considerable advantages in manufacture, transport and assembly compared to conventional diffusion absorption systems for high performance. If, as is generally the case, ammonia is used as the refrigerant, this means operating pressures of 20 to 25 bar and, as a result, sufficiently large wall thicknesses, for example at least in a range of 1.5 to 3 mm for the elements of the system. Is the Diffusi in question onsabsorptionsanlage, as is also common practice, made of steel and the components, but especially the heat transfer surfaces, are large according to the high performance, so a diffusion absorption system of high performance and in the usual design results in high weight, for example from 100 to 180 kg without additional components such as housings etc. These high weights have to be handled during manufacture, transport and assembly, which is not possible without mechanical auxiliary devices. The design according to the invention results in smaller dimensions for each individual printing system or its components and thus also a reduced total weight of the respective individual printing system, for example in the order of approximately 30 to 40 kilograms. This makes it possible to handle the individual printing systems individually manually and without mechanical aids, ie in particular to lift, transport and / or move them. By simplifying handling during manufacture, the costs for production systems and thus the direct production costs are also reduced. The same applies to assembly.

The In the following, the invention is illustrated by the figures using exemplary embodiments explained in more detail. It demonstrate:

1 and 2 each in a simplified schematic representation and in two views rotated by 90 ° a possible embodiment of the diffusion absorption system according to the invention;

3 and 4 similar in representations 1 and 2 another possible embodiment.

The in the 1 and 2 The diffusion absorption system shown consists of three identical single pressure systems 1 . 2 and 3 , Each of these single-pressure systems has all the components necessary for its function independently, as a closed system, both with respect to the other single-pressure systems and with the environment, each consisting of a capacitor 4 . 4 ' respectively. 4 '' , from an evaporator 5 . 5 ' . 5 '' , from a gas heat exchanger 6 . 6 ' . 6 '' and an absorber 7 . 7 ' and 7 '' , The above components are in the 1 illustrated embodiment arranged within each system in the vertical direction one above the other. The cooker 8th . 8th' . 8th'' is next to the absorber 6 . 6 ' . 6 '' intended.

The in the 3 and 4 The diffusion absorption system shown in turn consists of three identical single-pressure systems 1a . 2a and 3a , ie each of these individual printing systems has all the components necessary for the function independently and is closed to the outside as an independent single printing system with respect to the other systems. The individual printing systems show in detail 1a . 2a and 3a again the capacitor 4 . 4 ' . 4 '' , the heat exchanger 6 . 6 ' . 6 '' and the absorber 7 . 7 ' . 7 '' which are arranged one above the other in the vertical direction. The cooker 8th . 8th' . 8th'' is on the side next to the absorber 6 . 6 ' . 6 '' arranged. The evaporator 8th . 8th' . 8th'' is in this embodiment opposite the capacitor 4 . 4 ' . 4 '' , the gas heat exchanger 6 . 6 ' . 6 '' and the absorber 7 . 7 ' . 7 '' laterally offset.

The The invention has been described above using exemplary embodiments. It is understood that numerous further changes as well as modifications possible are without this leave the inventive idea underlying the invention becomes.

Claims (11)

Diffusion absorption system with a working medium pair formed by a cooling medium, for example ammonia and a solvent, for example water, and with a pressure-compensating auxiliary gas, for. B. helium or hydrogen, in a pressure system, characterized in that the pressure system of the diffusion absorption system consists of at least two independent, each hermetically sealed individual pressure systems, each of which has an independent absorber, evaporator and condenser arranged one above the other in the vertical direction or essentially in the vertical direction and which are arranged side by side. Diffusion absorption system according to claim 1, characterized characterized that the at least two individual printing systems are constructed identically. Diffusion absorption system according to claim 1 or 2, characterized in that absorber, Cooker and condenser are arranged substantially vertically one above the other. Diffusion absorption system according to one of the preceding Expectations, characterized in that at every single pressure system absorber, rectifier and condenser vertical or essentially vertically one above the other are arranged. Diffusion absorption system according to one of the preceding Expectations, characterized in that each Single printing system has an individually controllable stove. Diffusion absorption system according to one of the preceding claims, characterized net that the absorber of each individual printing system consists of a tube wound into a spiral with a substantially vertical axis, and that essential parts of the cooker are arranged within this spiral. Diffusion absorption system according to one of the preceding Expectations, characterized in that the Absorbers and / or condensers of each individual pressure system are circular or has an oval or substantially circular or oval base. Diffusion absorption system according to one of the preceding Expectations, characterized in that the Evaporator opposite the absorber and the capacitor is laterally offset and with this forms a plane, the individual, preferably identical Single printing systems essentially perpendicular to this level are arranged. Diffusion absorption system according to one of the preceding Expectations, characterized in that between the evaporators and the other components the diffusion absorption system a vertical or essentially vertically insulating layer is arranged. Diffusion absorption system according to one of the preceding Expectations, characterized by their training as a cooling unit, which for example at least partially in a cold room wall is integrated, the evaporator in the refrigerator or in one with the refrigerator related space are arranged. Diffusion absorption system according to one of the preceding Expectations, characterized by their training as a heat pump, the system for example partly in a building wall is integrated and the evaporator outside or essentially outside the building wall are arranged.