NO339882B1 - Cooling Device - Google Patents

Abstract

The invention relates to a cooling unit installable into the air-conditioning systems of buildings for cooling/heating the indoor air thereof, the indoor spaces being cooled/heated by the supply air and liquid coolant-circulating cooling elements (7), The invention is implemented by way of complementing the intake air cooling/heating function of the cooling unit with a liquid-coolant cooler coupled to the same main circuit and passing the coolant to liquid-coolant circulating cooling devices (7) serving to cool the indoor spaces,

Description

The present invention relates to a cooling unit that can be installed in air conditioning systems in buildings for cooling/heating the indoor air therein. The indoor rooms are cooled/heated by supplied air and coolant circulating in the cooling element.

At present, the implementation of cooling function in air conditioning systems in buildings is generally based on cooling indoor spaces using both a flow of cooled supply air as well as cooling devices such as cooling coils mounted in the indoor space. A cooling medium such as water circulates in the cooling coil. To this end, a water chiller produces chilled water which is circulated via the cooling coil to the air intake unit and cooling devices at the indoor space. In addition to the water cooler, a separate roof-mounted evaporator/condenser is required to transfer heat extracted from the indoor space to the outdoor air. Thus, a simultaneous A/C system requires three different units: an air intake cooling unit, a circulating refrigerant cooling unit, and a roof mounted evaporator/condenser.

From US-A-4446703, a cooling unit for air conditioning systems is known which comprises an air intake for the supply of air and liquid-cooled cooling elements, where, in addition to the intake air cooling function, the cooling unit comprises a cooler which is connected to the liquid circuit of the cooling elements.

It is a purpose of the present invention to provide a new type of cooling unit that can be installed in an air conditioning system in buildings where the cooling unit is able to solve the problems with previously known systems and simplify the system structure in a significant way. The cooling unit according to the invention is characterized in that the cooling unit comprises two compressors and two heat exchangers which act to cool the coolant circulating cooling elements to the indoor rooms, and that the coolant circulating line is connected to another line which, with the help of a pump, circulates coolant via the intake air cooling battery to thereby achieve cooling of supplied air,

A preferred embodiment of the cooling unit according to the invention is characterized in that the cooling unit includes an integrated function for heating supplied air.

Another preferred embodiment of the invention is characterized by the fact that a low temperature of the indoor air is used to cool the liquid coolant that circulates in the indoor cooling elements.

Another preferred embodiment of the invention is characterized in that the liquid refrigerant is returned to the refrigerant circulating indoor cooling elements and is led via a valve to an inlet air cooling coil to the cooling unit where the liquid refrigerant is cooled, after which the refrigerant is led to an evaporator for further cooling.

The cooling unit according to the invention is mounted as a unified functional section in the air conditioning system. Complimenting the heating of the intake air, the cooling unit incorporates a touch of condensation evaporated (circulating refrigerant unit) connected to the same main circuit that is connected to the cooling circuit of the cooling coils. This arrangement allows a simple factory-fitted unit to handle the entire cooling needs of a building. In normal applications the water cooler can be removed and a separate roof mounted evaporator/condenser unit is also redundant.

The invention is further described in more detail by means of preferred embodiments with reference to the attached drawings where

Figure 1 shows a circuit design of the preferred embodiment according to the invention; Figure 2 shows a circuit design of a second preferred embodiment according to the invention; Figure 3 shows a circuit design of a third preferred embodiment according to the invention; Figure 4 shows a circuit design of a fourth preferred embodiment according to the invention.

With reference to Figure 1, where a circuit configuration of a cooling unit is shown where a compressor 1 cools the intake air with the help of a heat exchanger 3. The compressors 2 act to cool with the help of refrigerant/coolant heat exchangers 4 the liquid coolant that circulates in the pipe network of the the indoor A/C devices 7. A pump 6 circulates the cooled liquid coolant in the indoor A/C devices 7 which performs cooling of the indoor air. Heat flowing out from the compressors is transferred to an evaporator/condenser 5 of the cooling unit where heat released from the cooling process is transferred via the cooling unit to the outlet air that passes out of the A/C system. The power output of the compressors 1,2 can be controlled in stages and distributed beyond so that a desired cooling effect is optionally delivered to any point that needs cooling while at the same time the outlet air temperature is prevented from rising very high.

Figure 2 shows a circuit configuration of a second embodiment of the invention. This design is mainly similar to that in Figure 1, while this design has two compressors instead of three in the design described above, where the compressor 1 here via the refrigerant/coolant heat exchangers 4 cools the refrigerant that circulates in the pipe network 8. The pump 9 circulates the cooled refrigerant in the intake air cooling battery which works to cool supplied air. The pump 6 circulates cooled liquid refrigerants in the indoor A/C devices 7 which perform the cooling of the indoor air. Heat flowing out from the compressors is passed to an evaporator/condenser coil 3 of the cooling unit.

Under certain outdoor air temperature conditions, the intake air must be heated even when the indoor air in a building requires cooling. Figure 3 shows a circuit configuration according to another embodiment of the invention which provides the possibility of using the intake air cooling battery alternatively to heat the intake air while water circulates as coolant in the pipe network 8 which acts to cool the indoor A/C devices. The integration of the heating function into the cooling unit has the advantage of allowing the removal of a separate intake air heating coil from the A/C system. In the same case, the pressure figure in the intake air heating coil is removed and the intake power of the ventilators is reduced. Removing the heating coil also reduces the space required for the A/C equipment length in the engine room on the roof by around 700mm which is a significant advantage.

With reference again in more detail to Figure 3, the circuit diagram of the following embodiment works as follows: compressors 1 cool via heat exchangers 4 the refrigerant which circulates in the pipe network 8. The pump 6 circulates the cooled refrigerant in the indoor A/C devices 7 which perform cooling of the indoor the air. The indoor mounted pump 9 circulates the refrigerant to the same pipe network system via the supply air heat exchanger 3 (liquid refrigerant/air heat exchanger). This cooling circuit 12 is diverted away from the liquid refrigerant circulation to the indoor cooling devices by a valve 11. The thermal energy required to heat supplied air is introduced into the additional circuit 12 via a liquid/liquid heat exchanger 10.1 by virtue of having circuits 8, 12 running separately from each other is it possible to operate these two circuits at different temperature levels. Thus, the indoor air conditioning cooling devices can be supplied with a liquid refrigerant cooled in the evaporator 4 and at the same time hot water can be supplied to the intake air heat exchanger 3 while at the same time the intake air is heated to the desired

set temperature for supplied air.

The invention also makes it possible to implement the application of a low temperature to the outdoor air to cool the liquid refrigerant circulating in the indoor A/C devices whereby this "free circulation" runs while the compressors are stopped. Since the water coolant that circulates in the pipe network in the indoor A/C devices also passes through an intake air cooling coil to the cooling unit, it becomes possible to use this "free circulation" cooling system when the building needs cooling and the outdoor air is sufficiently low, i.e. around 10-15 ° C to achieve a cool effect. Cooling by "free circulation" also allows the cooling effect offered by passing cold outdoor air through the intake air cooling coil and is transferred to the pipe network in the indoor A/C devices and from there to a desired indoor room. Cooling by means of "free circulation" allows the electrical energy consumption of a building to be significantly reduced.

Furthermore, the "free circulation" discussed above will be explained in more detail with reference to

Figure 4. The liquid coolant that returns from the cooling devices 7 is led via a valve 11 to the intake air cooling coil 3 of the cooling unit. At this time, the cooling temperature is around 19 °C. The liquid coolant is cooled in the intake air cooling coil to a temperature of e.g. 17 °C. The cooled coolant passes forward to the evaporator 4 in the cooling unit, which is evaporated so that the liquid coolant is finally cooled down to a temperature of e.g. 15 °C required to operate the pipe network of the indoor A/C devices. Cooling of the liquid medium in the intake air cooling coil becomes possible when the outside air temperature is below 19 °C.

For a person with knowledge of the technique, it is obvious that the invention is not limited by the above described embodiments but rather can be varied within the inventive spirit and scope of the appended claims. The refrigerant of the liquid-refrigerant-circulating indoor A/C devices can be any type of liquid used in this type of application as required to comply with local restrictions. Furthermore, the number of compressors and heat exchangers mentioned in the requirements and the description above are by definition exemplary and can be varied as desired.

Claims (4)

1. Cooling unit mountable in air conditioning systems in buildings to cool/heat indoor air in these, where the indoor rooms are cooled/heated by supplied air and liquid refrigerant circulating cooling elements (7), where, in addition to the cooling/heating function of the intake air, the cooling unit comprises a with the same main circuit connected refrigerant circulating cooling device which is connected to the refrigerant circulating cooling elements (7) to cool the indoor air, characterized in that the cooling unit comprises two compressors (1) and two heat exchangers (4) which act to cool the refrigerant circulating cooling elements (7) to the indoor spaces, and that a coolant circulating line is connected to another line which, by means of a pump (9), circulates the coolant via the cooling elements (7) in order to achieve cooling of supplied air. 2. Cooling unit according to claim 1, characterized in that the cooling unit incorporates an integrated function to heat supplied air. 3. Boiler unit according to claim 1, characterized in that a low temperature of the indoor air is used to cool the liquid coolant that circulates in the indoor cooling elements (7). 4. Cooling unit according to claim 3, characterized in that the liquid refrigerant is returned to the refrigerant-circulating indoor cooling elements (7) and is led via a valve (11) to an inlet air cooling coil (3) of the cooling unit where the liquid refrigerant is cooled, after which the refrigerant is led to an evaporator (4) for further cooling.