DE2153175C3 - System for temperature control and dehumidification of an air flow for air conditioning of rooms - Google Patents

Description

The invention relates to a system for tempering and dehumidifying an air stream with only one single chiller for indirect temperature control and dehumidification. Such a system is for air conditioning of rooms where the air conditions »cooling«, »heating« and dehumidifying «are components of the Climates are subjected to processing, but preferably for large-volume, accessible test chambers applicable.

A variety of test chambers are available for such purposes. So it has already been suggested several times for the temperature control and dehumidification of the air in a test chamber the evaporator of a refrigeration machine in To be used in conjunction with an electric reheater. In other known test chambers was used for the temperature control of the evaporator of a refrigeration machine and a heater and for dehumidification the evaporator of another refrigeration machine is used. The humidification should be done by a separate device take place. The cost of such a facility is certainly low, at least in the first case, but it is the achievable control quality is also very low and does not meet many requirements. That is in mainly due to the excessive temperature difference between the air circulated in the test chamber and the evaporator surface. Every time a cooling process is required, the Moisture balance of such test chambers strongly influenced, whereby a precise regulation and thus also a increasingly demanded program operation cannot be implemented in this way. Also suggested means to influence the evaporation temperature or to dose the amount flowing through the evaporator Air volume does not eliminate the fundamental disadvantages, nor do the subdivision of the evaporator surface and the cooling capacity. This can be remedied by indirect temperature control with a liquid, e.g. B. Sole, if - as is known - by appropriate dimensioning of the heat exchanger surfaces and the Flow ensures that the temperature difference between the circulated air and during the cooling process Cooler surface remains smaller than about 1 to 2 degrees. Then you can cool in the usual humidity range, without influencing the moisture balance at the same time. This then only happens in to a small extent at very high relative humidity and can easily be compensated with a humidifier.

A known climatic test chamber with only one refrigeration machine has indirect temperature control for small temperature differences, but the air is dehumidified on a surface of the evaporator, which is always kept at low temperatures. The temperature difference is therefore great and too great Dehumidification effects can only be prevented by a carefully selected dosage of the from the Usable space or the environment by means of a fan conveyed air flow. For small usable space volumes Such a method is still justifiable, as is the expenditure of energy that is necessary for the brine bath Alternating climate operation constantly towards the brine temperature necessary for the target temperature to be controlled cool or heat. Incidentally, this also applies to many other well-known climatic test chambers. Furthermore must it must be ensured that at the inlet or outlet of the dry or moist partial air flow, there is no excessive air flow local influence on the climatic condition occurs. At evaporation temperatures below 273 K, the becomes The surface used for dehumidification should be frosted relatively quickly. Finally, the flow rate is the temperature control brine not constant due to the type of dosage.

Climatic disturbances on the part of the test item or the environment are not always compensated equally well can be. In many known climatic test cabinets or chambers, at least the dehumidification, mostly also the humidification, in some cases even the temperature control of the test room air outside the test room performed. That is why they are isolated and at least when using a humidity control too temperature-controlled air lines necessary. The space requirement increases, especially with larger usable space volumes therefore larger, fans and automatic valves are required, and costs increase.

In some known climatic test cabinets or chambers, the climatic conditions are of high quality aimed at in the test room with very high effort. B. in one case two separate ones Chillers, two pumps for brine or water, a blower, many control devices such as solenoid valves, thermostatic Injection valves, engine valves and three evaporators, two condensers and additional heat exchangers in one plant.

For the sake of completeness, a number of well-known climatic chambers should be mentioned, those for larger ones Dehumidification services are designed. In principle, there is a liquid-loaded heat exchanger in these chambers arranged, the temperature of which is influenced by the humidity controller and thus the dew point the air adjusts. In order to obtain the desired air temperature, electrical post-heating is usually carried out. at At low humidity, the energy requirement for this is considerable. This also applies if the dehumidification rate is relatively small because the dew point is at least on part of the surface of the liquid Heat exchanger, but mostly on the total area, must be reached or fallen below and one corresponding cooling of the air is unavoidable.

The aim of the invention is to reduce or eliminate the deficiencies shown and thus To create systems with a higher practical value.

The invention is based on the complex task of using a system for temperature control and dehumidification an air flow for air conditioning of rooms, a high quality of the air temperature and humidity control to achieve, d. H. for these large only very small deviations compared to the preselected Allow setpoints. However, there should only be low demands on the control equipment be asked. On the other hand, however, when compensating for climatic disturbances on the part of the Test item or the environment a high stability can be achieved. The air treatment should be related to the Temperature control, humidification and dehumidification take place as far as possible within the room to be air-conditioned. Cooling and dehumidifying processes should take place with the smallest possible temperature difference, and the temperature difference should automatically adapt to the upcoming cooling or dehumidifying performance. The conception must be suitable for program control for versatile climatic tests. Short-term should a high cooling rate may be possible without a large installed capacity. Even with frequent setpoint jumps operating costs should be low. The system should have a high level of functional reliability, and after all, a clear, compact structure with only one refrigeration machine should be guaranteed, insulated and temperature-controlled air lines, blowers for them and accessories should be avoided, total volume, Space requirements and manufacturing costs should be minimal.

According to the invention, this object is reproduced in the characterizing part of the main claim Features solved With little equipment and machinery, this circuit is used A high control quality achieved The actuators operated by the controllers allow - in contrast to Refrigerant compressors - a high switching frequency, i.e. the deviations from the respective setpoint can thus be kept small! in the cycles

ίο is the flow rate of the heat transfer medium also at Normal operation almost constant and roughly equal to the maximum flow rate, since it is sufficient to switch to the or adjustable actuators to specify a low pressure drop.

This leads to high heat transfer coefficients in the heat exchangers and in connection with the high Water value of the temperature control medium for a stable temperature control of the air flow. In addition the large-area heat exchanger also contributes to the temperature control. The dehumidification heat exchanger receives a smaller surface, which requires a low expenditure of energy. The bypass effect in the Heat release in the container for the heat carrier leads to gradual, adjustable or controllable Actuators can be influenced, but temperature changes that take effect immediately when a signal is given by the controller in the circuits, which also contributes to increasing the control quality. It also needs the temperature of the heat transfer medium in the container does not match the respective

jo temperature setpoints of the air flow accordingly to be followed, but it can be kept at a sufficiently low temperature level.

The heat transfer medium stands for rapid temperature change

J5 the air flow is always in sufficient quantity Available, and energy is also saved in the mode of operation described above.

According to a further embodiment of the invention, two actuators connected in parallel are in a circuit provided, wherein an actuated by the associated controller actuator, z. B. a solenoid valve in Is connected in series or instead of these simple actuators motor-operated, continuously in cross section changeable multi-way actuators provided

4 ¹ ) are. This also serves to improve the control quality, especially when large work areas have to be mastered. The temperature controller, as well as the actuator located in the circuit of the heat exchanger responsible for temperature control

^r ) ii also actuates the heater, is preferably equipped with two sensors, one of which is located in the air flow and the other at the inlet of the heat carrier in the heat exchanger. This provides a sufficiently large signal for the temperature controller in good time

κ is formed and thus also improves the control quality. In further training, the humidity controller is in addition to the actuator of the dehumidifying effect Circuit is still connected to the humidifier. The refrigerant compressor expediently has a

bü thermostatic circuit, the sensor preferably is built into the container for the heat transfer medium. In addition, to achieve lower temperatures an evaporator can be used for direct cooling in the air stream.

b5 The invention is to be based on an exemplary embodiment explained.

In the drawing, 1 is a test chamber with insulated walls 2, a fan 3, a

Heat exchanger 4 for dehumidification, a droplet separator 5 and a heat exchanger 6 for denotes the temperature control of the circulated air. The direction of flow of the air is indicated by arrows indicated. An evaporator 7, which may be built-in for lower temperatures, is for direct cooling Drawn in dashed lines, as well as its connecting lines with the refrigeration machine. On the representation the necessary refrigeration fittings for connecting the evaporator 7 to the refrigerant circuit for indirect temperature control, consisting of refrigerant compressor 8, condenser 9, solenoid valve 10, thermostatic injection valve 11 and evaporator 12 have been omitted for the sake of clarity.

The circuit of the heat transfer medium for dehumidification also includes the heat exchanger 4 mentioned a conveyor 13 and an adjustable actuator 14. This circuit is through 2 lines with an insulated container 15 for the heat transfer medium, e.g. B. Sole, connected, one of the lines in one of a humidity sensor 16, a humidity regulator 17 via switching elements 18 actuated actuator 19, a solenoid valve, is built in. From the humidity regulator 17 is over the switching elements 18 also actuates a humidifier 20.

In addition to the heat exchanger 6, the circuit of the heat transfer medium for temperature control includes a Conveyor 21 and an adjustable actuator 22. This circuit is also provided with two lines the container 15 connected. In one of these lines, an actuator 23, a solenoid valve, is installed, which is controlled by a temperature sensor 24 at the inlet of the heat carrier in the heat exchanger 6, another Temperature sensor 25 in the test chamber, a temperature controller 26 actuated via switching elements 27 will. The temperature control medium is constantly circulated in the circuits described. Through this result in high heat transfer coefficients at the heat exchangers and in connection with the high Water value of the temperature control medium ensures stable temperature control of the usable space air. Through the commanding sensor 16 or 25 is controlled by 17 or 26 and switching elements 18 or 27, which the Actuate actuators 19 or 23, one for changing a climatic condition or one for compensation Disturbance required during normal operation

ίο Temperature reduction on one of the heat exchangers initiated. The actuators 14 and 22 are throttled so that a pressure difference is established at them. If the actuators 19 or 23 are now opened, the pressure difference will correspond to the size of the pressure difference renz, a defined amount of the cold temperature control medium taken from the common container 15 men and added to the relevant circuit. The mixture temperature is thereby gradually, however without any time delay, lowered until the new setpoint is reached and the relevant actuator 19 or 23 is closed again. At 28 is another adjustable actuator and in series with this one also operated by the temperature controller 26 steep member 29, a solenoid valve, shown in dashed lines This indicates a further possibility, as there Control behavior can be further refined. Also the one in the temperature control circuit and somi indirectly acting heater 30 is operated by the temperature regulator 26. At 31 there is a thermostatic regulator and its sensor is denoted by 32. Both act via switching elements 33 on the refrigerant compressor 8, det depending on the temperature range for the heat preselected on the thermostatic controller 31 carrier temperature in container 15 in "on-off" mode is switched. A compensation tank for the heat transfer medium is designated by 34

1 sheet of drawings

Claims (6)

Claims: 20 25 1. System for tempering and dehumidifying an air flow for air conditioning rooms with only a single chiller for indirect temperature control and dehumidification, preferably for large-volume accessible test chambers, characterized in that that both for temperature control and for dehumidification each one from another largely independent circuit for a uniform heat transfer medium is available and each circuit has a heat exchanger (4,6) arranged in the air flow, a conveying device (13, 21) and an adjustable or controllable actuator (14, 22), the circuit for temperature control is also has a heater (38) installed in front of the conveyor device (21) and both circuits through each two lines with a common container (15) and associated compensation tank (34) for the Heat transfer media are connected, and in each case a line from the temperature controller (26) or Humidity controller (17) via switching elements (18, 27) actuated actuator (19, 23) and also in common Container (15) the evaporator (12) of the refrigeration machine is installed. 2. System for tempering and dehumidifying an air stream according to claim 1, characterized in that that instead of a single actuator (14, 22) connected in parallel in a circuit of the heat transfer medium adjustable actuators (22, 28) are installed, the same or different cross-sections have and of which an actuator (28) with an actuator actuated by the associated controller (2S) (29) e.g. B. a solenoid valve is connected in series or instead of these simple actuators (14,22,28) J5 Motor-operated, continuously variable cross-section controlled by the assigned controller Multi-way actuators are provided. 3. System for tempering and dehumidifying an air stream according to claim 1. characterized marked ίο net that the actuators (23, 29) and the heater (30) via switching elements (27) with the temperature controller (26) are connected, which is preferably equipped with two sensors (24, 25), one of which is in the Air flow and the other is located at the inlet of the heat carrier in the heat exchanger (6). 4. System for tempering and dehumidifying an air stream according to claim 1 and 3, characterized characterized in that the actuator (19) and a humidifier (20) via switching elements (18) with the w Humidity controller (17) and its sensor (16) are connected. 5. System for tempering and dehumidifying an air stream according to claim 1, 3 and 4, characterized characterized in that the refrigerant compressor (8) has a thermostatic circuit (31, 33) and the associated sensor (32) is preferably arranged in the container (15). 6. System for tempering and dehumidifying an air stream according to claim 1, 3 to 5, characterized by w) characterized in that an evaporator (7) is additionally arranged in the air stream.