DE4315828A1 - Device for cooling - Google Patents

Abstract

The device serves for cooling and has conducting elements for a coolant which are designed as part of an arrangement for evaporation cooling. The conducting elements are arranged in an inner space for storage of ice which forms on the conducting elements. The conducting elements are connected by longitudinal ribs which bridge interspaces provided between the conducting elements. The longitudinal ribs are made of metal which at least in regions bears against the conducting elements made of metal.

Description

The invention relates to a device for cooling, which as part of an evaporative cooling facility has trained guide elements for a coolant, which in an interior for storing themselves Guiding elements forming ice are arranged.

With such ice stores the problem arises that the heat transfer increases with increasing loading time due to the ice layer that is developing gets worse. The heat to be dissipated must pass through the forming ice layer. This means that with increasing loading time the thermal resistance is constantly increasing and thus that Removing heat from the ice storage increasingly becomes more difficult.  

In particular, at the end of the loading time is through the increased thermal resistance an increased tem temperature drop required, which has the consequence that the Evaporating temperature of the refrigerant within the Guiding elements, for example as ice storage tubes or ice storage plates can be formed with increasing loading time must constantly decrease. As an catch temperature is still approx. -1.5 ° Celsius sufficient, at the end of the loading time, however, are -10 to -12 ° Celsius required.

The compressor feeding the guide elements must therefore provide an increasing cold gradient, which leads to a reduction in the cooling capacity. This also results in an effect on the suction pressure of the compressor, which is initially approximately 4 kg / cm ² and drops to a pressure of less than 3 kg / cm ² at the end of the loading process. This Druckab fall has the result that the suction gas provided with a low density, which the compressor promotes, flows through with a significantly reduced mass flow through the guide elements. With the same delivery volume, a lower refrigerant mass is thus circulated.

The decrease in mass flow has a decrease the evaporation amount and thus reduces the Cooling capacity. In the example given is one Reduction in cooling capacity by about 25% put. This results in a significant increase in Energy consumption to a given cooling capacity maintain.

The object of the present invention is therefore a pre direction of the type mentioned in the introduction  improve that the heat transfer is sufficient for one long operating period is improved.

This object is achieved in that the guide elements are connected by longitudinal ribs that gaps provided between the guide elements bridge and that the longitudinal ribs made of metal forms are that on the metal formed Leit elements.

This combination of features becomes a rib height realized that far from the thickness of the usual ice pan protrudes. Due to the metallic formation of the Longitudinal ribs provide thermal conductivity represents the thermal conductivity of ice far exceeds. In particular, the use of Aluminum or steel intended for high quality Training from copper is also a requirement or silver conceivable.

A simple additional use of lateral distances the guide elements to a housing can thereby take place that the longitudinal ribs at least in some areas protrude laterally beyond the gaps.

A device to be manufactured is thereby prepared represents that the guide elements as evaporator coils are formed with sheet-like longitudinal ribs are provided.

A good heat transfer between the guide elements and the longitudinal ribs is realized in that the longitudinal ribs with a pushing them against the guide elements elastic bias are provided.  

To implement a device with evaporation he plates is proposed that the guide elements as Evaporator plates are formed between those with a fold provided longitudinal ribs are arranged.

Simple manufacture and good heat transfer in an operation, this enables the Fold has elastic resilient properties.

To fix and improve the heat transfer ganges even when manufacturing problems occur satchel is suggested that the longitudinal ribs at least welded to the guide elements in some areas are.

Existing devices can be retrofitted thereby facilitated that the longitudinal ribs at least in some areas of a clamping element in the area of Guide elements are fixed.

When using evaporation is also thought that the longitudinal ribs at least area are glued to the guide elements.

Appropriate manufacture of new devices follows from the fact that sheet-like longitudinal ribs braid ten-like formed by the guide elements Extend rows.

This will retrofit existing devices relieved that sheet-like longitudinal ribs tang tial ent on rows spanned by the guide elements stretch long.

Exemplary embodiments of the invention are shown in the drawing shown schematically. Show it:  

Fig. 1 is a horizontal section through an evaporator coil package with sheet-like longitudinal ribs,

Fig. 2 is a horizontal section through evaporator he plates, which are connected together by longitudinal ribs with an elastic fold,

Fig. 3 is a schematic view of a central Be eisungszustandes of a smooth tube evaporator, which is screwed retrofitted with longitudinal ribs,

FIG. 4 shows the device according to FIG. 1 with icing areas shown; FIG.

FIG. 5 shows the device according to FIG. 2 with icing areas and

Fig. 6 shows the device of FIG. 2 with L-shaped longitudinal ribs.

As shown in FIG. 1, the cooling device consists of guide elements ( 1 ) which are designed as part of an evaporator coil package. In spaces ( 2 ) extending between the Leitele elements ( 1 ), longitudinal ribs ( 3 ) are arranged. In the embodiment according to FIG. 1, the longitudinal ribs ( 3 ) are designed as rib plates ( 4 ) which are braided between the guide elements ( 1 ). This creates a series of interconnected arrangements. Such a design is particularly expedient if a combination of the guide elements ( 1 ) with the longitudinal ribs ( 3 ) takes place during initial assembly and the longitudinal ribs ( 3 ) can be pushed between the guide elements ( 1 ).

In the embodiment according to FIG. 2, the Leitele elements ( 1 ) are designed as evaporation plates, each of which is connected by longitudinal ribs ( 3 ). The longitudinal ribs (3) have elastic folds ( 4 ) which, on the one hand, enlarge the effective surface of the longitudinal ribs ( 3 ) and, on the other hand, can take a resilient clamping of the longitudinal ribs ( 3 ) between the guide elements ( 1 ). A contact between the longitudinal ribs ( 3 ) and the guide elements ( 1 ) is in this case supported by Fußele elements ( 5 ), in the area of which the longitudinal ribs ( 3 ) have a stronger design than in the remaining area of their extension.

In the embodiment according to FIG. 3, the longitudinal ribs ( 3 ) are plate-shaped and in each case facing sides are placed on the guide elements ( 1 ). The longitudinal ribs ( 3 ) are braced with the aid of tensioning elements ( 6 ) which, for example, can be designed as screw bolts. From the representation in Fig. 3 can also be seen as being deposited in the region of the guide elements (1) and the longitudinal ribs (3)-forming ice (7). Due to the deposition in the area of the longitudinal ribs ( 3 ), the ice ( 7 ) extends through the intermediate spaces ( 2 ) and an interior space ( 8 ) of the device can be used intensively.

For the device according to FIG. 1 and FIG. 2 4 and 5, the corresponding arrangement of the ice (7) is shown in FIGS..

The dimensioning of the longitudinal ribs ( 3 ) ensures that these protrude far from the usual expansion of the ice ( 7 ), which separates in a prior art design of the device. This ensures good heat transfer during a long period of operation. The longitudinal ribs ( 3 ) are provided with good thermal conductivity, in particular the use of aluminum or steel is intended. Such training has a considerable price advantage over a conceivable realization of copper or silver. In the embodiment according to FIG. 1 and FIG. 3, the longitudinal ribs ( 3 ) can be manufactured from unprocessed and thus inexpensive sheet metal. It is also desirable, but not absolutely necessary, that the longitudinal ribs ( 3 ) rest on all guide elements ( 1 ). By choosing an appropriate manufacturing quality, it can thus be influenced which efficiency improvement is to be achieved at what cost. With a fixation of the longitudinal ribs ( 3 ) in the area of the Leitele elements ( 1 ) with the help of welding points, with a corresponding conductivity, gaps between the guide elements ( 1 ) and the longitudinal ribs ( 3 ) can be partially bridged by the welding points, thereby ensuring adequate heat conduction will. An appropriate dimensioning of sheet-like longitudinal ribs ( 3 ) is given with a thickness of 2-4 millimeters. When using aluminum sheet, a thickness of 1-1.5 millimeters is generally sufficient.

The embodiment according to FIG. 1 can be manufactured by first pushing a sheet-like longitudinal rib ( 3 ) between the guide elements ( 1 ) and in this positioning every second guide element is arranged in a raised position. After the longitudinal ribs ( 3 ) are pushed in, the raised guide elements ( 1 ) are lowered and this results in a plastic or elastic deformation of the longitudinal ribs ( 3 ). Due to the resulting residual tension, the longitudinal ribs ( 3 ) rest firmly against the guide elements ( 1 ).

In addition, the use of longitudinal ribs ( 3 ) made of aluminum has the advantage that the guide elements ( 1 ), which are usually made of iron or iron alloys, are provided with cathodic corrosion protection. This eliminates the need for expensive galvanizing.

When using evaporator plates according to the embodiment in FIG. 2, an adhesive bond between the guide elements ( 1 ) and the longitudinal ribs ( 3 ) is also conceivable if sufficient heat transfer is achieved. The use of the longitudinal ribs ( 3 ) makes it possible to provide a spacing between the guide elements ( 1 ) which is approximately three to five times the planned ice thickness in the region of the guide elements ( 1 ) and thus both a sufficient flow of water and to ensure optimal use of the spaces ( 2 ). A good compromise between an optimal volume utilization and a provision of sufficient flow cross sections for the amount of circulating water is thus realized.

By combining the guide elements ( 1 ) with the longitudinal ribs ( 3 ), it is either possible to utilize an existing volume of the interior ( 8 ) with higher intensity, or the goal can be to construct a more compact arrangement with the same performance , which would lead to a reduction in the device price. It is assumed that the area formed by the Leitele elements ( 1 ) evaporator surface is far more expensive than the area formed by the longitudinal ribs ( 3 ) per unit area. A corresponding compact embodiment is particularly useful in systems with low annual operating hours.

In Fig. 6 L-shaped longitudinal ribs (3) are each arranged with a distance to each other. In all embodiments, cross ribs are also conceivable.

When dimensioning, it is useful to Ver Ratio of tube diameter to ice thickness of about 3: 4 to provide. The distance between the pipe centers should be about five times the pipe diameter wear. As a horizontal pipe distance, that's about Appropriately ten times the pipe diameter.

Claims (11)

1. A device for cooling, as part of a device for evaporative cooling Leit elements for a coolant, which are arranged in an interior for storing elements forming at the Leitele ice, characterized in that the guide elements ( 1 ) by longitudinal ribs (3) are connected, the bridge between the guide elements (1) provided intermediate spaces (2) and that the longitudinal ribs (3) are formed of metal that is applied to the metal ausgebil Deten vanes (1) at least in regions. 2. Device according to claim 1, characterized in that the longitudinal ribs ( 3 ) project at least partially laterally beyond the spaces ( 2 ). 3. Apparatus according to claim 1 or 2, characterized in that the guide elements ( 1 ) are formed as serpentine evaporators, which are provided with sheet-like longitudinal ribs ( 3 ). 4. Device according to one of claims 1 to 3, characterized in that the longitudinal ribs ( 3 ) with an against the guide elements ( 1 ) pressing elastic bias are provided. 5. The device 1 or 2, characterized in that the guide elements (1) are designed as evaporator plates forms, between which are arranged with a fold (4) provided with longitudinal ribs (3). 6. The device according to claim 5, characterized in that the fold ( 4 ) has elastically resilient properties. 7. Device according to one of claims 1 to 6, characterized in that the longitudinal ribs ( 3 ) are at least partially welded to the guide elements ( 1 ) in some areas. 8. Device according to one of claims 1 to 7, characterized in that the longitudinal ribs ( 3 ) min least in some areas by a clamping element ( 6 ) in the region of the guide elements ( 1 ) are fixed. 9. Device according to one of claims 1 to 8, characterized in that the longitudinal ribs ( 3 ) min at least partially glued to the guide elements ( 1 ). 10. Device according to one of claims 1 to 4, characterized in that sheet-like longitudinal ribs ( 3 ) braid-like elements formed by the Leitele ( 1 ) extend through rows. 11. Device according to one of claims 1 to 9, characterized in that sheet-like longitudinal ribs ( 3 ) extend tangentially along rows spanned by the guide elements ( 1 ).