DE10255833A1 - A method for increasing the rate of cooling in an adsorption refrigerator when the temperature is high has a second independent rapid cooling system - Google Patents

Abstract

The enclosure (2) is normally held at low temperature by an adsorption system (3) with an evaporator (5). Under start conditions or a rise in temperature a valve (12) connects an independent adsorption system (4) to a second evaporator (6) to boost the cooling.

Description

The present invention relates to a cooling device after Preamble of claim 1.

Refrigerators can do it all generally differentiated according to two different working principles become, namely on the one hand in absorption cooling units and compressor cooling units. Absorption cooling devices are generally known and described for example in WO 01/2723 A1. With such cooling devices a working fluid, usually ammonia, which is in a solvent, mostly water, soluble is circulated. This cycle includes an expeller, also known as a stove or pump, a condenser, an evaporator and an absorber. In the expeller the working fluid is made from the solvent enriched with working fluid under feed external energy driven out by a heater, for example. In the gaseous State, the working medium is transferred from the expeller to the capacitor in which the working medium heat releases to the environment, cools and finally condensed. The condensed working fluid is transferred from the condenser to the Evaporator transferred where it absorbing heat at a low level, for example in the evaporator of a refrigerator, evaporated and in vapor form Condition is transferred to the absorber. The working fluid is emitted into the absorber, giving off heat solvent absorbed and then in the solvent in dissolved Form returned to the expeller, whereby the described working fluid cycle is closed.

Such cooling devices have generally been used for a large number well proven by applications. Indeed exists with these cooling devices Disadvantage that they react somewhat sluggishly to temperature fluctuations and especially at the beginning of the cooling process only a limited one cooling capacity to disposal put, causing the cooling process takes a certain amount of time.

It is therefore the task of the present Invention, a generic absorption refrigerator in the Way to improve that especially at the beginning of the cooling process a faster cooling allows and that on the other hand the cooling device temperature fluctuations can compensate better. At the same time, however, a simple structure is intended and ensures easy operation of the refrigerator his.

This task is solved by a cooling device with the Features of claim 1 and a method for operating the refrigerator with the Features of claim 9. Advantageous refinements are the subject the dependent Expectations.

Basis of the present invention is the idea that you want Characteristics of the cooling device can be achieved that an additional Cooling stage, a so-called booster is provided. This additional Cooling stage, which in particular completely independently from the first cooling device, in particular an absorption cooling device, can be operated, can then generally to reinforce the cooling capacity or used to compensate for temperature fluctuations for all known cooling devices become. It is therefore no longer necessary, for example, for the first cooling device to provide a complex control, but it is for example possible, a first cooling device relative in a refrigerator operate constantly while a second, additional Cooling device, the so-called additional Cooling level, at Demand is switched on. Offers in particular with the above-mentioned absorption cooling devices this for the reasons mentioned above a special advantage.

Since the second cooling device thus peaks in performance intercept, it is appropriate that the second additional cooling device has a range of services that respond quickly to temperature changes allows. Thus, in particular, a quick cooling characteristic should be ensured by the second additional cooling device guaranteed his.

In the preferred application of the second, additional cooling device, i.e. the additional cooling stage in an absorption cooling device, it has proven to be particularly expedient to design the second cooling device as a so-called adsorption cooler, in particular in the form of a zeolite cooling device, in which the adsorber material is produced by zeolites is formed. This type of cooling device is characterized in that very rapid cooling is made possible when the cooling process is started. The general disadvantage of adsorption coolers, namely the need for regeneration after a certain time, does not matter when used as an additional second cooling stage, since the second cooling stage is not designed for continuous operation. This means that the adsorption cooler can regenerate at times when it is not necessary to operate it. Adsorption coolers are also generally known and for example in the DE 195 07 768 A1 described. In the simplest form, adsorption coolers have an adsorber container in which the adsorber material to which the working medium adsorbs is arranged, and a combined evaporator-condenser container in which the working medium alternately evaporates with heat absorption or condenses with heat emission. The working fluid evaporates in the evaporator during the cooling process and is adsorbed on the adsorber material, while the Ar is regenerated Beitsmittel is now condensed in the evaporator or condenser and expelled from the adsorber material, usually by supplying heat.

Since in the regeneration phase of the adsorption type warm water vapor is passed into the evaporator or condenser of the adsorption cooler and the evaporator is arranged to achieve the cooling effect in or on the cold room it must be appropriate to Water vapor before entering the evaporator or condenser already cool down a bit and / or condense to excessive temperature stress of the refrigerator to avoid when regenerating the adsorption cooler. To this Purpose it is advantageous to use a heat exchanger outside of the refrigerator to provide through which the expelled from the adsorber material guided is going to initially already a certain amount of heat leave. Alternatively, it can also be useful to use the evaporator or to arrange the condenser so that the evaporator or Condenser at the times when it was used as an evaporator is in or on the refrigerator is arranged while outside when it is used as a capacitor of the refrigerator is arranged.

A control is expediently also provided, the operation of the two cooling devices, especially the absorption cooling device and the adsorption cooler, controls.

Here, the control according to another Aspect of the invention preferably designed so that the two cooling equipment when the refrigerator is switched on and / or when the temperature in the refrigerator rises above a predetermined threshold operate simultaneously while after the temperature in the refrigerator drops below the predetermined Threshold the second cooling device is switched off and / or regenerated. In the case of an adsorption cooling device as additional cooling stage this means in particular that after reaching the predetermined threshold the second cooling device, so the additional Cooling stage, is regenerated and then kept in the standby position, to be operated again when the temperature rises.

Around the second cooling device in standby position to be able to hold it is advisable to shut off for either the evaporator-condenser container, for the Connection line between adsorber tank and evaporator-condenser tank and / or the adsorber tank to provide the condensed working fluid, especially water, for the Keep evaporation ready.

Other advantages, characteristics and Features of the present invention will become apparent in the following detailed description of an embodiment clearly. The attached Drawing shows a functional diagram in a purely schematic manner of a cooling device according to the invention.

The cooling device shown in the figure 1 has a cold room 2 on which is to hold the goods or objects to be cooled. There are two cooling devices on the cooling device 3 and 4 provided that the refrigerator is completely self-sufficient 2 can cool.

The cooling device 3 is formed by a known absorption cooling device, only the evaporator in the schematic drawing 5 inside the refrigerator 2 is shown, while the rest of the absorption cooling circuit schematically as a ball with the reference numeral 7 is taken into account.

The second cooling device 4 , also referred to as an additional cooling stage, is designed as a so-called adsorption cooling device, in the preferred exemplary embodiment presented here as a zeolite cooler. The zeolite cooler 4 also has an evaporator 6 on that in the cold room 2 is arranged. The evaporator 6 however, as described in more detail below, also serves as a condenser, so that it is used here as an evaporator-condenser container 6 referred to as. The evaporator-condenser container 6 is via a connecting line 11 with the adsorber tank 8th connected, in which the adsorber material, here zeolites, is added.

In the connecting line 11 is also a valve 12 provided, which enables the connecting line 11 complete. The valve 12 can be of any known type, in particular a mechanical or an electromechanical valve.

The connecting line also leads 11 through a heat exchanger 10 who is outside the refrigerator 2 is arranged. In the schematic representation of the attached figure, the connecting line runs 11 through the heat exchanger in a straight line and thus over the shortest distance. Of course, in a real embodiment, the connecting line 11 , for example in turns through the heat exchanger 10 led to provide the largest possible area for the heat exchanger.

Near the adsorber tank 8th is also a heater 9 provided, which can also be realized by any known and suitable design.

The cooling device shown now works in such a way that when the cooling device is switched on 1 , i.e. when the absorption cooling device is started 3 at the same time the valve 12 in the connecting line 11 between the adsorber tank 8th and the evaporator-condenser tank 6 is opened. In this way, the working fluid, for example water, which is initially in the evaporator-condenser container 6 located in the adsorber tank 8th reach. That in the adsorber tank 8th absorbed material takes up the water vapor itself in the working space of the adsorption device 4 , i.e. the evaporator-condenser container 6 , the connecting line 11 and the adsorber tank 8th located on, so that further evaporation of the water in the evaporator-condenser container 6 is excited. Through the evaporation of the working fluid or water in the evaporator-condenser container 6 becomes the cold room 2 Deprived of heat, leaving the refrigerator 2 is cooled.

At the same time, through the operation of the absorption cooling circuit 3 due to the evaporation of the working fluid, e.g. ammonia, in the absorption cooling circuit 3 the cold room 2 also removes heat, so that the cooling effect is enhanced. However, the performance and effectiveness of the adsorption cooling device 4 is higher at the beginning of the cooling process, so that the cooling device initially 4 contributed most of the cooling capacity.

After a certain time, the adsorber material, i.e. the zeolites, is in the adsorber container 8th saturated with water and the evaporation of the water in the evaporator-condenser container 6 comes to a standstill. However, at this point the cold room is 2 already largely cooled and the absorption cooling device 3 has reached your optimum performance. At this point, the adsorption cooling device 4 regenerated by the heater 9 is operated and the working fluid contained in the adsorber material, i.e. the water, is expelled from it by the heat. The warm water vapor passes through the connecting line 11 and thus via the heat exchanger 10 , which contributes to a first cooling and / or condensation of the water vapor, into the evaporator-condenser container 6 , in which condensation of the water vapor now takes place. When almost all of the water or the proportion of water that can be expelled at reasonable expense evaporates from the adsorber material and into your evaporator-condenser container 6 is condensed, the valve 12 closed, so that the water or water vapor no longer in the adsorber 8th can reach. The adsorption cooling device is now in place 4 available for another cooling task. This can consist, for example, of the adsorption cooling device increasing when the temperature in the cooling space rises above a certain threshold value 4 is switched on by means of a control, not shown.

Through the additional cooling stage in the form of the additionally provided adsorption device 4 in addition to the absorption cooling device 3 Thus, an improvement of the absorption cooling device is brought about in such a way that, on the one hand, a faster cooling of the cooling space becomes possible and, on the other hand, it is possible to react better to temperature fluctuations. Although an adsorption cooling device has been described as an additional cooling stage in the preferred exemplary embodiment shown, it is of course conceivable to also provide another suitable cooling device or to combine different cooling devices with one another in the manner shown.

As an alternative additional cooling stage, an additional absorption device can also be used instead of the adsorption device 4 be provided if it has a faster cooling characteristic than the first cooling device. An absorption cooling device, for example a system with ammonia and salt, is particularly suitable here. In general, any type of sorption cooling device that has a faster cooling characteristic than the first cooling device can thus be used as the second cooling device.

Claims (10)

Cooling device with a cold room ( 2 ) for receiving the objects to be cooled and a first cooling device ( 3 ) in the form of an absorption cooling device, the evaporator ( 5 ) for cooling the cold room in or on the cold room ( 2 ) is arranged, characterized in that on or in the cooling space a second, in particular from the first cooling device ( 3 ) independently operable cooling device ( 4 ) is provided, which the cold room ( 2 ) alternatively and / or additionally cools. Cooling device according to claim 1, characterized in that the second cooling device ( 4 ) faster cooling characteristics than the first cooling device ( 3 ) to start the refrigerator ( 1 ) to achieve rapid cooling. Cooling device according to claim 1 or 2, characterized in that the second cooling device ( 4 ) is an absorption cooler, in particular with a working solvent pair of ammonia / salt solution. Cooling device according to claim 1 or 2, characterized in that the second cooling device ( 4 ) is an adsorption cooler, in particular in the form of a zeolite cooling device, which has an adsorber container ( 8th ) for the absorption of the adsorber, in particular zeolite, and one in or on the cold room ( 2 ) arranged evaporator-condenser container ( 6 ) for alternating condensation and evaporation of the working medium and its working medium, which adsorbs and evaporates on the zeolite, is preferably water. Cooling device according to claim 4, characterized in that the second cooling device ( 4 ) a connecting line ( 11 ) from the adsorber tank ( 8th ) to the evaporator-condenser container ( 6 ), which is at least partially, in particular outside of the cold room, in a heat exchanger ( 10 ) is arranged in particular for cooling the working medium expelled by the adsorber. Cooling device according to claim 4 or S, characterized in that the adsorber container ( 8th ), the evaporator-condenser container ( 6 ) and / or the connecting line ( 11 ) from the adsorber tank ( 8th ) to the evaporator-condenser container ( 6 ) Shut-off means ( 12 ) exhibit. Cooling device according to one of claims 4 to 6, characterized in that the evaporator-condenser container ( 6 ) is arranged so that it is in or on the cold room ( 2 ) can be moved and removed again, in particular in accordance with the operating mode of the adsorption cooling device. Cooling device after one of the preceding claims, characterized in that the cooling device is a controller for controlling of the operation of the first and / or second cooling device. Method for operating a cooling device ( 1 ) according to one of the preceding claims, characterized in that when the cooling device is switched on and / or when the temperature in the cooling chamber rises ( 2 ) the first and second cooling device () above a predetermined threshold value 3 . 4 ) are operated in parallel in cooling mode, while after the temperature in the refrigerator 2 ) below the predetermined threshold, the second cooling device ( 4 ) is switched off and / or regenerated. A method according to claim 9, characterized in that when the cooling device ( 1 ) the first cooling device ( 3 ) (Absorption cooling device) and second cooling device ( 4 ) (Adsorption cooling device) can be started, in particular in the case of the adsorption cooling device in the evaporator-condenser container ( 6 ) working medium is enabled, in the adsorber tank ( 8th ) to arrive and adsorb on the adsorber material.