NL8900352A - Air moisture control for fruit ripening arrangement - incorporates moisture-heat exchanger unit for air control - Google Patents

Abstract

Fruit e.g. bananas ripening arrangement, ensures that air temp. is increased until a predetermined moisture level is reached. Fruit ripening arrangement of large capacity includes a moisture and heat exchange appts. (100) in which a number of adjacent positioned ventilators (40) with motors (44) provide the required air circulation. The moisture/heat exchanger unit includes a section (1) of curved walls from which through pipe (2) water via nozzle (3) is sprayed. Below section (1) is a gas inlet (6) below which a trough has an outlet (5) and higher positioned overflow (4).

Description

Method and device for bringing air to a certain temperature and certain relative humidity.

The invention relates to a method for bringing air to a certain temperature and a certain relative humidity, wherein the air is brought into contact with a free surface of water of low temperature, which gives the air a very high relative humidity and a device for application of this method.

This course of action, in which the air to be treated comes into direct contact with water, has the important advantage of a direct heat and water vapor transfer between the water and the air, so that heat losses are small and a high relative humidity can be achieved.

In various applications, however, it is desirable to be able to control the relative humidity. This is the case, for example, when ripening cheese, sausages or bananas. However, other cases may also arise in which it is important to obtain cool air with a relative humidity lower than the relative humidity of 95% to 98% and even more obtainable by the known method.

Heretofore, this problem has been addressed by mixing the air with less humid, opening ventilation hatches and the like. The first difficulty here is that there is often no air available which, after a temperature drop to the temperature customary in maturing processes, does not become supersaturated.

A second difficulty is that it is particularly difficult to obtain a sufficiently precise adjustment of the relative humidity in this way. For this reason, complex air conditioning systems were often used, which lacked the important advantage of direct contact between water and air.

A further difficulty is that the air usually consists, at least in large part, of recirculation air. Now air in a ripening room usually gets very high humidity. This leads to air having a very high relative humidity after cooling by means of direct contact with water.

The invention now provides a solution which requires relatively little equipment, gives a high degree of reliability of the relative humidity to be obtained and, partly because the direct heat and water vapor transfer between water and the air can be used, it is often energetically attractive.

This is achieved according to the invention by providing that the temperature of the air is then raised until the determined relative humidity is reached.

The invention is advantageous not only in setting a constant relative humidity at a constant temperature, but also in cases where temperature and humidity must vary. When storing various foods, it is undesirable, for example, if a sudden excessive cooling occurs.

On the other hand, it may also be undesirable when the cold air is supplied to warm goods, so that a relatively low relative humidity will prevail in the air layer adjacent to the objects due to the local heating of the air. This may lead to excessive dehydration.

By applying the invention it is now possible to also vary the temperature and humidity of the air, in a controlled and reliable manner. Accordingly, according to a further aspect of the invention, it is provided that the temperature increase as a function of the air temperature after contact with the free water surface, the temperature and / or relative humidity of the air after use in a room to which the air is supplied , and / or the water temperature and / or the time is set.

The invention also includes an apparatus for applying the method. This is based on a heat and moisture exchange section, which comprises a water supply, means for distributing water supplied by the supply over a large area, a water discharge, an air supply, an air cooling and humidification part, where the air comes into contact with the large water surface , and has an exhaust air.

3 Such devices are widely used, where the heat and moisture exchange section may consist of an exchange block of repeatedly curved walls, for example of PVC or the so-called Celdeck material, both marketed by Munters from Sweden, but it is also possible spraying or dripping water from top to bottom and obtaining a very large surface by bursting the drops. Of course, a misting or fine spraying is also possible.

According to the invention it is now provided that an air heating device is arranged in the air discharge.

An energetically attractive embodiment of the invention, in which it comprises a cooling device with cold and hot side, the cold side of which is introduced into the water supply in heat exchange relationship with the water, characterized in that means are present for at least part of the heat supplying heat released on the side of the cooling device to the air heating device.

The invention is further elucidated hereinbelow with reference to the drawing, in which: Fig. 1 shows a diagram of a device for applying the invention; Fig. 2 shows a side view, partly in section, of a heat and moisture exchange device according to the and Fig. 3 shows a front view, partly in section, of the exchange device according to Fig. 2.

In the drawing, 100 denotes the heat and moisture exchange device, which has a heat and moisture exchange section 1, for example of multiple curved walls, onto which water from a pipe 2 is sprayed via a nozzle 3. Of course, any other known liquid-gas contacting agent can be used.

Below the circuit 1 is the gas inlet 6, under which there is a basin with an outlet 5 and an overflow 4 located higher.

Above the sprinkler 3, a heat exchange device 9, for example in the form of a radiator, is provided, which can be supplied with hot water from a hot water vessel 26 via the pipe 23, the pump 24 and the return pipe 25, with an adjustable short-circuit connection 27 parallel to the radiator 9 is connected. As can be seen more particularly from Fig. 1, a cooling device is provided with a condenser 10, a pressure reduction stage 14, an evaporator 11, a pump 12 and a cooler 13. In this circuit a medium is pumped around, which at the high pressure condensation temperature of 45 ° C.

The gas, which after compression from the evaporator 11 enters the heat exchanger 13, has a considerably higher temperature and can heat water, which is supplied from the hot water vessel via line 20 and a pump 21 and is discharged via line 22. A short-circuit line 28 contains a control valve 29, which is controlled by a temperature probe 30, which records the temperature in the hot water vessel 26.

The evaporator 11 is located in a cold water tank 15, which can be fed via an overflow 4 of the heat and moisture exchange device 100 and then fed via a pump 31 to a three-way valve 17, which is controlled by an adjusting device 32 . The three-way valve 17 can assume a position in which the line 5 is connected to the pump 18 and, via a number of intermediate positions, another position in which the line 16 is connected to the pump 18, which feeds the nozzles 3 via the line 19. The three-way valve 17 is controlled via the adjusting device 32 under the control of a control unit 33, to which, for example, the dry and wet bulb temperatures are supplied via probes 34 and 35, which together determine the relative humidity, and a probe 36, which measures the air temperature when leaving the device 100.

The hot water tank 26 is connected via the pipe 23 and the pump 24 to the heat exchanger 9, which is, for example, a radiator, and from there the pipe 25 returns to the hot water tank 26. In order to control the amount of water that passes through the heat exchanger 9, a short circuit 27 applied with a control valve 37, which is also under the control of the control unit 33.

A level sensor 38 controls an inlet valve 39 to replenish the water in the circuit when it has disappeared by evaporation or otherwise.

Of course, the control unit 33 can not only be set to obtain a certain humidity and temperature of the air exiting from the device 100, but it can also contain possibilities to control the temperature and the humidity of this air depending on other factors, for instance a timetable. for adjustment to goods in a storage room or to control the humidity of air drawn back from the storage room to device 100.

When the heat supplied by the heat exchanger 13 and possibly the condenser 10 is insufficient to maintain the temperature of the radiator 9, an additional heating unit can be provided.

The device shown has proven to be particularly useful for the ripening of foodstuffs for which a certain temperature and humidity level, possibly as a function of the temperature, have been prescribed, and also has the possibility of adapting the temperature and humidity of the air to objects, if these have been placed in a storage room at a temperature that deviates from the storage temperature.

As Fig. 3 in particular shows, the device is suitable for a large capacity, by giving the moisture and heat exchange device 100 a large width, wherein a number of juxtaposed fans 40 with motors 41 provides the necessary air circulation. The device 100 can be arranged in a storage or ripening space, but it is also possible to connect it to such a space via pipes.

Claims (5)

Method for bringing air to a certain temperature and a certain relative humidity, wherein the air is brought into contact with a free surface of water of low temperature, which gives the air a very high relative humidity, characterized in that the temperature of the air is then increased until the determined relative humidity is reached. Method according to claim 1, characterized in that the temperature increase as a function of the air temperature after contact with the free water surface, the temperature and / or relative humidity of the air after use in a room to which the air is supplied, and / whether the water temperature and / or the time is set. Device for applying the method according to claim 1 or 2, provided with a heat and moisture exchange section, which comprises a water supply, means for distributing water supplied by the supply over a large area, a water discharge, an air supply, a air-cooling humidifying part, where the air comes into contact with the large water surface, and has an air outlet, characterized in that an air heating device (9) is arranged in the air outlet (8). Device as claimed in claim 3, provided with a cooling device with a cold and a warm side, the cold side of which is brought into the water supply in heat exchange with the water, characterized in that means (13,20,21,22 23, 24, 25, 26) are present to supply at least a part of the heat released on the hot side of the cooling device to the air heating device (9). Device according to claim 4, characterized by a circuit (18,19,2,3,5,17) containing the water inlet and outlet, a parallel circuit thereof (18,19,2,3,4,15, 16), which includes a cold water tank (15), which is in heat exchange with the cold side (11) of the cooling device, an air heating circuit (26,23,24,9f25,27) containing a hot water tank (26) and a controllable short circuit connection (27) and a water heating circuit, which contains the hot water vessel (26) and is heat exchanged with at least a portion (13) of the hot side of the cooling device.