HU228723B1 - Device for producing cold water for the purpose of cooling rooms - Google Patents

Description

EQUIPMENT FOR THE PRODUCTION OF COLD VLZ FOR COLD COOLING

BACKGROUND OF THE INVENTION The present invention relates to an apparatus for producing cold water for room cooling comprising a cooling surface and a condenser in the building structure, in particular a cooling ceiling with a refrigerator and an evaporator condenser connected thereto through which coolant and air flow.

It is known that cooling water for a cooling surface is produced by a refrigerator. It is also known that the condenser or liquidiser of the refrigerator is cooled in a water cycle in which a heat exchanger is arranged and air flows through the heat exchanger. It is also known that the heat exchanger is self-primed with water to improve heat transfer (wet cooling tower),

It is an object of the present invention to improve the cooling capacity of the apparatus mentioned in the introduction and to provide a corresponding apparatus whereby both installation costs and installation work are reduced.

According to the present invention, the object is solved by contacting the evaporator air stream with water to be cooled through a heat exchanger. The liquid to be cooled is supplied either directly to the heat exchanger and condenser, or to an intermediate storage, or directly to the user, the cooling surface. Further, an air condenser is coupled in front of the condenser and the air condenser is arranged in the horse guide of the evaporator cooler.

Impacting the heat exchanger with water on the air side results in a more efficient and cheaper cooling capacity. This is especially advantageous when you need higher cooling capacities, such as summer cooling. The heat97.338-7983 We / mí φ ·> * φ * ♦ Φ * Φ φ φ ♦ φ ** φ + Μ φ φφφ

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- 2 Λ ése replacing your replacements with water and thereby cooling the air will result in condensation hd at a lower temperature level. A refrigerator operating at a lower condensation temperature results in a correspondingly better performance.

Preferably, the evaporator condenser is a polypropylene sheet heat exchanger.

Since water is used in the heat exchanger of the evaporator cooler, the heat exchanger material of the sheet is very important. Polypropylene avoids the use of a material that does not have a solid deposit when using water.

It is particularly advantageous to have a heat exchanger in the refrigerator cooling circuit in front of the expansion valve through which water is passed through rather than injecting water into the air stream of the evaporator cooler.

Further improvement in cooling performance can be achieved with the air condenser in front of the water condenser, preferably located in the drain channel or outlet of the evaporator cooler.

A further advantage is the increase in the outlet temperature and the resulting reduction in relative humidity. This reduces the risk of condensation in the drainage duct. The evaporation of the aerosols in the evaporator cooler outlet evaporates the living conditions of the bacteria that may be present, such as the legions, pneumophils. It is particularly advantageous if the air condenser is located in the evaporator cooling drainage atom,

A further advantage of the device according to the invention is its compactness. This eliminates the heat loss from the flow between the parts because the unit is assembled into one unit,

DETAILED DESCRIPTION OF THE INVENTION The present invention will be described in detail with reference to the drawings, in which it is illustrated

Figure 1 shows an embodiment of the apparatus according to the invention, a

Figure 2 illustrates another embodiment.

The apparatus shown in FIG. 1 has a refrigerator having a cooling circuit 1 and a compressor 2 arranged therein. Downstream of this compressor 2 is a condenser 3 which is cooled by a second fluid circuit 4. This is described in detail below for these coolers. From the condenser, the refrigerant is sent to the evaporator 6 via an expansion valve S to which a third circuit 7 is connected.

By means of the evaporator roof 6, the cooling power released in the cycle 7 is transmitted by means of a pump 8 to an intermediate storage 9, The cooling power from the intermediate storage 9 is transferred to the cooling surface 11 via a distribution system 12 via a fourth cycle 10. In the second fluid coupled to the condenser 3, it is led via a pump 13 to an evaporator cooler 14, which is designed as a fluid exchanger and is resistant to corrosion and dirt. The evaporator cooler 14, i.e. the sheet heat exchanger, is fed with food, which is introduced through the inlets 15 between the sheets and 16 out.

- is released into the environment through 4 missions. This flow is created by a fan 17.

Between the inlet 15 and the evaporator cooling plates 14, water is introduced into the air stream through a valve system 18, in particular by spraying, whereby the cooling capacity of the air in the heat exchanger is increased by evaporation. A pump 19 is provided to supply the water to the water pipe.

When using a power control chiller, the intermediate storage 9 may be omitted. The cycle 7 is then connected directly to the valve system 12.

In the cooling circuit of the refrigerator, a heat exchanger 25 may be provided in front of the expansion valve 5, through which water is passed, which is then fed to the distribution system 18. This results in further cooling performance improvements.

In addition, a heat exchanger 28 may be installed in the refrigerator circuit of the refrigerator, in front of the condenser 3, through which air from the evaporator cooler 14 will flow. This increased heat dissipation increases the overall performance of the unit.

The apparatus is preferably operated in three different stages:

1) The air is cold enough, it is not necessary for the refrigerator to work and the contact of the sheet heat exchanger with water may be lost. The liquid to be cooled is passed through conduit 21 to heat exchanger 23. It flows back into conduit 22 and through the steaming plant 6 to the intermediate reservoir S.

2) If the air temperature is so high that free cooling is no longer sufficient, the cooling capacity can be increased by contacting the evaporator 14 with water.

- 5 «

3} If the air temperature continues to rise, or if a larger cooling demand is required, the refrigerator must be switched on. The heat exchanger 25 is contacted with water, thereby reducing the condensation temperature, which results in increased refrigerator performance and reduced power consumption. The total power of the system is increased by the heat exchanger 26.

All parts of the apparatus, i.e. the refrigerator, the evaporator cooler 14 and all the controls, as well as all the liquid and other conductive conduits are housed in a compact housing. The house itself can consist of several units that are easy to transport.

In an alternative embodiment, the capacitor 3 is provided with a bypass 28 by which the second fluid circuit 4 flows when the valve 27, which is formed as a three-way valve, is opened. This results in condensation in the heat exchanger 26. In addition, the compressor 2 operates in several stages. This has the advantage that the liquid 4 is not thermally loaded and thus the energy consumption of the entire system is reduced.

Claims (6)

Apparatus for the production of cold water for cooling water having a cooling surface and a cooler in the building structure, in particular an evaporator cooler connected to a refrigerator through which the liquid and air to be cooled flow through, - the air stream to be cooled by the evaporator cooler (14) can be contacted with water, the coolant (4) is supplied to the heat exchanger (23) and condenser (3) either directly to an intermediate storage (9) or directly to the user, - an air condenser (26) is connected in front of the condenser (3), - the air condenser (28) is arranged in the air outlet of the evaporator cooler (14). Apparatus according to claim 1, characterized in that the evaporator condenser (14) is a polypropylene sheet heat exchanger. Apparatus according to claim 1 or 2, characterized in that in the cooling circuit (1) of the refrigerator a flow-through heat exchanger (25) is arranged in front of the expansion valve (5). 4, 1-3. Apparatus according to any one of claims 1 to 4, characterized in that the refrigerator and the evaporator cooler and all the control / control parts are arranged within a housing (2). 5, Az 1-4. Device according to any one of claims 1 to 5, characterized in that the housing consists of several transportable parts, 6, 1-5. Device according to any one of claims 1 to 3, characterized in that a bypass valve {28} which can be activated by a valve * '♦ # ** (27) bypassing the refrigerator condenser (3) is provided.