DE20005951U1 - Cooling device based on the absorber principle - Google Patents

Description

Bernhard Gau
Pulpit wall 5
72622 Nuertingen

Cooling system based on the absorber principle

Cooling device according to the absorber principle, in which a fluid as a heat or cold transport medium is set in flow and kept in motion by a conveying device in a circuit, wherein the fluid, starting from the conveying device, flows through further, various devices integrated in the circuit in order to be sucked in again by the conveying device and passed on again into the circuit and during the circuit, depending on the respective further device - changes the state of aggregation and flows out of the respective further device in liquid and/or gaseous form, wherein one of the further devices is a heating device.

Cooling devices of the type mentioned are well known in refrigerators, air conditioning systems and the like and are designed to extract heat from specific locations and reduce the prevailing temperature. To do this, one uses the physical law that the boiling point of a liquid, i.e. the temperature at which this liquid evaporates, depends on its ambient pressure. For example, water turns into steam at a pressure of 1013 mbar at 100° ^C . However, if this ambient pressure is reduced from 1013 mbar to 101.3 mbar, this change in the state of matter from liquid to vapor already occurs at 46° ^C . Conversely, this means that water vapor at, for example, 50°C and 101.3 mbar can easily be liquefied again by increasing the pressure, for example to 1013 mbar.

Furthermore, the law is used that every liquid absorbs heat when changing from one state to another, e.g. from a liquid to a vaporous state, and releases the same heat when changing from a vaporous state to a liquid state. If a liquid is used in a cooling device whose boiling point under normal conditions is

&phgr;&phgr;&phgr;&phgr; φ ?·??? φ φ φ

• φ φ φ φ · φ

If the ambient pressure, i.e. 1013 mbar, is below the lower temperature to be generated, this liquid evaporates at the lower temperature and absorbs heat that it extracts from the surroundings. If this vapor is then brought to high pressure, its boiling point is higher. When it cools to the ambient temperature, the vapor changes its state of aggregation and liquefies, releasing heat as condensation heat. If this liquid is released back to the lower pressure, the state of aggregation changes again from liquid to vapor.

The fluids chosen for changing these states of aggregation in cooling systems under given pressure and temperature conditions are, for example, ammonia, ethyl chloride, etc.

The exemplary structure of a cooling device can be as follows: the fluid is water with a high ammonia content, which is set into flow by a conveying device. Starting from the conveying device, the fluid initially flows through a heat exchanger as the first device in a fluid circuit, then a heating device, then a condenser and passes through a throttle device into an evaporator. From here, the

Fluid is fed to an absorber, from where the fluid is then sucked back into the conveying device through the suction connection.

In the heating device, the water, which contains a high amount of ammonia, is heated so that the ammonia evaporates from the water and water remains. This evaporation continues continuously. As a result, the pressure of the evaporated ammonia increases until the pressure is high enough to condense the ammonia vapor again in the condenser. A throttle device is arranged downstream of the condenser, through which the pressurized liquid ammonia now flows. After it leaves the throttle device, the pressure relaxes and the liquid ammonia evaporates in the evaporator. This evaporation process removes heat from the area around the evaporator. It goes without saying that the evaporator is assigned to the place that is to experience a temperature drop.

The water that has not evaporated in the heating system and only contains a small amount of ammonia is returned from the heating system via a heat exchanger, where it releases a large part of its excess heat and flows from the heat exchanger into an absorber. Here the water now absorbs the pure ammonia.

· a··

The ammonia vapor that flows from the evaporator into the absorber is heated up again to its saturation level. This ammonia-water solution is fed to the heat exchanger via the conveyor, where it absorbs the heat of the low-ammonia water that previously flowed back from the heating device, and then flows back into the heating device, already preheated, where the process begins again.

The heating device is heated in a conventional manner, either electrically or by gas. In mobile cooling devices, such as in air conditioning systems in motor vehicles or in refrigerated trucks, the electrical heating is partly taken from the general on-board network or from an on-board network that is specially designed for this application.

In other designs, e.g. in caravans, a dual heating option is used, on the one hand in which the heating can be carried out electrically, and on the other hand, e.g. by switching, the integrated heating device can be heated with gas, e.g. propane gas, in order to operate an absorption cooling device.

These options have the disadvantage that additional energy or energy sources are required for heating, which can cause considerable acquisition and follow-up costs. With gas heating, there is also an additional, special safety requirement.

The object of this invention is to propose a cooling device based on the absorber principle, which requires low acquisition and maintenance costs, as well as the lowest possible operating costs.

This object is achieved in the generic cooling device according to this invention in that the heating device is assigned to a heating energy converter unit, and the heating device is heated by the loss or waste heat of the heating energy converter unit.

The heating device is assigned to the energy converter unit. This unit can be, for example, a fuel or propellant combustion unit. Such energy converter units generate a high proportion of waste heat during their energy conversion process, which reduces the efficiency of this unit.

gregates. According to the invention, this lost or waste heat is fed to the heating device of the proposed cooling device in order to stimulate and maintain the evaporation process of the fluid required for cooling using this amount of heat. Since this lost or waste heat is generated anyway and is additionally used due to this invention, the overall efficiency increases if the energy converter unit and the cooling device according to the invention are assigned to a common device group. This is the case, for example, in a motor vehicle, where a fuel or fuel combustion unit, the engine, generates correspondingly high lost or waste heat, which is used, for example, to supply an air conditioning system based on the absorber principle with the necessary heat energy in order to cool the air inside the vehicle to a correspondingly lower level than the outside temperature.

The energy converter unit can not only be a fuel or fuel combustion unit, but also an electrical one, e.g. in an electrically operated vehicle. Here too, the energy converter unit, in this case an electric motor, heats up during driving and must also be cooled against overheating. The waste heat can be used to

Use the heating system of the cooling unit without incurring additional costs for additional energy consumption of the cooling system.

The waste heat released during chemical reactions can also be used for the heating process described. Such a chemical process occurs, for example, when charging a vehicle battery used for propulsion.

The design of the heating device for the use of waste heat depends on how the waste heat is dissipated from the heating unit. If this unit is liquid-cooled, for example, the heated cooling liquid is used to heat the heating device before it is fed back into a cooler of the energy converter unit after passing through the heating device. If an energy converter unit is air-cooled, however, the air heated by the waste heat from the unit is used to heat the heating device.

Further details can be found in subclaims.

The cooling system is described as an example using the drawing.

Figure 1 shows schematically a cooling device in its entirety,
Figure 2 shows the heating device in more detail.

The cooling device 1 has a first circuit 14 through which a heated coolant 11, 11.1, 11.2 flows. The coolant 11 is heated by an energy converter unit 10, which can be the combustion engine of a motor vehicle, for example, to dissipate heat from the energy converter unit and flows as heated coolant 11.1 through a heat exchanger chamber 5.2 of a heating device 5, from where it is fed back to the energy converter unit as cooled coolant 11.2, cooled further, via a cooler 15.

Furthermore, the cooling device 1 has a second circuit 4 through which a fluid 2 flows, which serves as a coolant for the cooling device. This fluid 2 can be, for example, an almost saturated ammonia-water solution, with ammonia dissolved in the water. Such a fluid has two different boiling points, one is the boiling point of ammonia, the other is the boiling point of the water.

on the other hand, the boiling point of water. The boiling point of ammonia is considerably lower than that of water. This physical behavior is used to evaporate the ammonia from the water. During a cooling process, the fluid 2 passes through the liquid and gaseous states. The liquid fluid 2.1 is set in flow and maintained by a conveyor device 3 and, starting from the conveyor device 3, flows through a heat exchanger 13 in which the liquid fluid 2.1 is preheated. This preheated fluid reaches the evaporator chamber 5.1 of the heating device 5 and is heated here to a temperature that is higher than the boiling point of the ammonia dissolved in the fluid. Since the fluid 2.1 continuously flows into the evaporator chamber 5.1, the ammonia portion dissolved in the fluid 2.1 also continuously evaporates, so that the gas pressure of the dissolved ammonia portion increases steadily up to a predetermined maximum value. This gaseous ammonia portion is referred to below as gaseous fluid 2.2. After the gaseous fluid 2.2 has left the evaporator chamber 5.1, it first flows through a so-called condenser 6, in which the gaseous fluid 2.2 liquefies and is, as liquid fluid 2.4, under the vapor pressure of the gaseous fluid 2.2. The liquid fluid 2.4 then flows through a throttle device 7 before

·

·

the fluid 2.4 is passed through an evaporator 8. After the throttling device 7, the fluid 2.4 is relieved of pressure so much by a suitable design of the evaporator 8 that it evaporates within the evaporator 8 and extracts heat from the environment 8.1 of the evaporator so that the environment 8.1 cools down rapidly. The previously liquid fluid 2.4 thus leaves the evaporator again as a gaseous fluid 2.2 and flows into an absorber 9.

The water portion 2.3 of the fluid 2.1 that has not evaporated in the evaporator chamber 5.1 first flows through the heat exchanger 13, which is thereby heated, and reaches the absorber 9 as cooled water. Here, the water is now enriched with the vaporous ammonia, ie with the gaseous fluid 2.2.
in order to be sucked from here as liquid fluid 2.1, i.e. as an ammonia-water solution, by the conveying device in order to go through the previously described process again.

In Figure 2, the heating device 5 is shown in more detail, and its function will be explained again below. The fluid 11.1 heated by the energy converter unit flows through the inlet 5.2.1 into the heat exchanger chamber 5.2. This

The heat exchanger chamber 5.2 is hermetically sealed from the evaporator chamber 5.1 by a heating plate 5.3 that separates the chambers. The heating plate 5.3 has surface enlargements 5.3.2.1, e.g. in the form of ribs, etc., on the heating surface 5.3.2 facing the heat exchanger chamber 5.2. As the fluid flows through the heat exchanger chamber 5.2, heat is extracted from the heated fluid 11.1, which lowers its temperature. The fluid 11.2 cooled in the heat exchanger chamber 5.2 leaves the heat exchanger chamber 5.2 via the drain connection 5.2.3.

The liquid fluid 2.1, i.e. the ammonia-water solution, is introduced into the evaporator chamber 5.1, close to the evaporator surface 5.3.1, via an inlet connection 5.10. Due to the corresponding surface temperature of the evaporator surface 5.3.1, the ammonia contained in the fluid 2.1 evaporates and exits again as a gaseous fluid 2.2 through the outlet connection 5.11 to be fed to the condenser 6 in Figure 1.

The advantages of this cooling device according to the invention lie primarily in the fact that by using the waste heat of a heating energy converter unit, the operation of the cooling unit can be achieved without additional heating energy being supplied.

This saves considerable operating costs and also has an advantageous effect on the aim of saving energy resources.

Claims (7)

1. Cooling device ( 1 ) according to the absorber principle, in which a fluid ( 2 ) as a heat or cold transport medium is set in flow and kept in motion by a conveyor device ( 3 ) in a circuit ( 4 ), wherein the fluid ( 2 ), starting from the conveyor device ( 3 ), flows through further, various devices ( 13 , 5 , 6 , 7 , 8 , 9 ) integrated in the circuit ( 4 ) in order to be sucked in again by the conveyor device and passed on again into the circuit and during this circuit - depending on the respective further device - changes the state of aggregation and flows out of the respective further device in liquid and/or gaseous form, wherein one of the further devices is a heating device ( 5 ), characterized in that the heating device ( 5 ) is assigned to a heating energy converter unit ( 10 ) and the heating device ( 5 ) is heated by the loss or Waste heat from the heating energy converter unit is heated. 2. Cooling device according to claim (1), characterized in that the heating device ( 5 ) has a heat exchanger chamber ( 5.2 ) through which heated coolant ( 11 , 11.1 ) of the heating energy converter unit ( 10 ) flows or against, and whereby the fluid ( 2.3 ) is heated. 3. Cooling device according to claim 1, characterized in that the heating device ( 5 ) is flowed through or against by cooling air heated by the energy converter unit ( 10 ), and whereby the fluid ( 2.3 ) is heated. 4. Cooling device according to claim 1, characterized in that the heating device ( 5 ) is flowed through or against by exhaust gas heat emitted by the energy converter unit ( 10 ), and whereby the fluid ( 2.3 ) is heated. 5. Cooling device according to one of the preceding claims, characterized in that the energy converter unit ( 10 ) is a fuel or fuel combustion unit. 6. Cooling device according to one of claims 1-4, characterized in that the energy converter unit ( 10 ) is an electrical unit. 7. Cooling device according to one of the preceding claims, characterized in that the energy converter unit ( 10 ) is a chemically reacting unit which releases waste heat under chemical reaction.