SU1487823A3 - Method of controlling temperature and humidity in vegetable and fruit storages - Google Patents

Abstract

A method for controlling the temperature and the humidity in storage spaces that tend to become warm and moist, in particular in vegetable and fruit warehouses. According to the method, the air in the storage space is circulated so that it passes across a cooling heat-exchange face, to which face the air delivers some of its heat. In order to keep the relative humidity of the air at its desired maximum value, in a way characteristic of the invention, the temperature of the cooling face is controlled substantially to a dewpoint temperature corresponding to the desired relative humidity, whereat any excess moisture is removed out of the air in the warehouse, but the air cannot become more dry than the desired value of humidity. The surface temperature of the heat exchanger can be brought to the said dewpoint temperature either by adjusting the surface temperature or, alternatively, by dimensioning the cooling apparatus, on the basis of empiric or experimental knowledge, in such a way relative the storage space that the heat exchanger assumes the said temperature in practice.

Description

The invention relates to methods for controlling temperature and humidity in the storage of vegetables and fruits. A method is proposed for controlling temperature and humidity in warehouses that tend to heat up and become wet, in particular in storage facilities for vegetables and vegetables.

The invention relates to the regulation of temperature and humidity in storage for vegetables, in which the heat and humidity created by stored products are removed from the air of the warehouse.

Primarily, the method is designed to control the temperature in storage facilities for vegetables, in particular for vegetables, when protective gas is used, as well as in greenhouses, where external air ventilation is undesirable, except in special cases.

fruits. The aim of the invention is to improve the quality during storage. In this method, the air in the storage room is circulated in such a way that it passes through the cooling heat exchange surface, to which the air gives off some of its heat. To maintain the relative humidity at a given maximum value, the temperature of the cooling surface is regulated mainly to the dew point temperature corresponding to the specified relative humidity, due to which excess moisture is removed from the air in the storage room, however, it is impossible for the air to become more dry than allowed humidity value. The surface temperature of the heat exchanger can be adjusted to the specified dew point temperature either by adjusting the surface temperature or by changing the area of the heat exchange surface. 5 il.

Vegetable storage, using protective gas, means a warehouse in which the composition of the air is changed so that it differs from the usual atmosphere in order to improve the storage of vegetables. Therefore, in this case, the outside air cannot be used directly for cooling. Some of the most important factors that need to be adjusted in vegetable warehouses are temperature and relative humidity, i.e. those factors that

311, .., 1487823

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increase during storage of vegetables as a result of the respiratory activity of vegetables. Typical temperature during storage of vegetables is T = 0-5 ° С, and the required relative humidity is КН = 85-95%.

The aim of the invention is to improve the quality during storage of vegetables and fruits. <10

FIG. 1 schematically shows a temperature control system; in fig. 2 - a horizontal projection of a large storage (1000 tons) for potatoes, which is divided into 10 from 15 sections of the same size; FIG. 3 shows a device for carrying out the method when the mechanized cooling does not work; in fig. 4 the same, when mechanized cooling operates; in fig. 5 - a device for the implementation, method, view in axonometry.

The regulation of temperature and humidity is achieved by cooling the internal air in the storage with the help of a heat exchanger and by regulating the heat exchanger surface of the heat exchanger to a temp. Temperatures of the dew point corresponding to 30 the required relative humidity of air in the storage. Thus, - “only excess moisture is removed from the cooling air by condensation on the heat exchange surface, 35 and when the work is carried out in accordance with this method, the air does not need to be moistened with water, because excessive drying is not observed. 40

To measure temperatures and control actuators, a microprocessor-based control device is used, which is capable of performing the necessary logic conclusions and calculations. The control device is not shown, but the detectors that are driven by this device are: detector 1 for determining the temperature of vegetables 2, detector 3 for determining the temperature of the cooling air leaving the heat exchanger 4 and passing to the vegetables 2, detector 5 for determining the temperature of the mixed air, consisting of outside air and recirculated secondary air and a heat exchanger passing on the secondary side, this detector

measures air temperature right

before it enters the heat exchanger 4. The detector 6 is designed to measure

outdoor temperature.

The temperature in the storage is maintained at a predetermined value with an accuracy of, for example, ± 0.40 °. Over 90% of the temperature control in the vegetable storage includes cooling, and cooling is successfully carried out periodically. The processor measures the temperature of the vegetables with detector 1, if the temperature rises above the permissible limit, and if it is cold enough outside, then cooling is turned on.

Cooling is carried out in such a way that the blower 7, which circulates the internal air from the storage through the side 8 of the heat exchanger for primary air, and the blower 9, which circulates the outside air through the side 30 for the secondary air, starts working. Primary and secondary air pass through the heat exchanger 4 according to the upstream principle or according to the downstream principle, and the best way is the principle upstream. The internal air is cooled when it passes through the heat exchanger 4 and is again heated in the vegetables 2. The cooling blast continues until the temperature of the vegetables decreases to the set value. Cooling capacity, i.e. the degree of cooling of the internal air in the heat exchanger 4 is determined in accordance with the required relative humidity in the storage.

The decrease in the internal air temperature in the heat exchanger 4 is controlled by controlling the flow of heat transferred from the internal to the external air. This heat flux can be controlled by changing the ratio of the number of external and internal air flows by adjusting the efficiency of the heat exchanger or by passing the mixed air together with the outside air and the recirculated secondary air to secondary circulation.

Excess moisture contained in the storage air is removed in conjunction

with cooling by condensation. If you want to adjust

relative humidity up to 90% then

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Allow the internal air to approach the surface temperature of the heat exchanger, which represents the dew point temperature corresponding to a relative humidity of 90% of the internal air. If the relative humidity of the air in the room before entering the heat exchanger 4 is above 90%, then the water from it condenses into the, θ heat exchanger 4 and when the air leaves the heat exchanger 4, then its relative humidity is 100%.

When such air becomes warm again (when passing through vegetables) 5 2) by heating to the temperature of vegetables, its theoretical relative humidity is 90%. In practice, the cooling air passing through the vegetables absorbs the new moisture from the ovaries and the theoretical value of the relative humidity, determined from the surface temperature of the heat exchanger 4, is not achieved more accurately. In each method, it is necessary to adjust the surface temperature in the heat exchanger 4 to such a value at which the correct relative humidity in the storage facility is reached.

If in the storage system in years 30 it is time (Fig. 4) to add compressor cooling, then in the design shown in Fig. 3, it is necessary to turn on the evaporator 11 and the closing flaps 12. The evaporator 11 is located on the $$ side of the secondary circulation in the heat exchanger 4 and in this case it is not connected with either the inside air or the outside air.

It is separated from the internal air 40 by a heat exchanger 4, and from the external air by valves 12, which are closed in summer. Heat is transferred from the internal air with a small difference in temperature using a cellular 45 plate heat exchanger 4 of a large area to air. The air passing through the secondary circulation consists partly of the air that passes through the evaporator 13 of the compressor, and partly of the air passing again into the secondary circuit from the front surface of the flaps 14, and the air is not cooled in the evaporator 13 of the compressor. The latter can be designed to work with a large difference in temperature between the surface of the evaporator 13 and the air passing through the evaporator, since ice in the closed air circulation in the secondary circuit can never be deposited in the evaporator 13, because after condensing the harmless water contained in secondary circuit, new water does not flow into it and condensation stops. Around ^ the evaporator 13 should not remain free space, except for the necessary, i.e. spaces for air ducts and dampers.

The relative humidity of the cooling air leaving the primary circuit of the heat exchanger 4 is controlled by controlling the surface temperature of the heat exchanger 4 by means of mixing flaps 14,

It is not necessary to measure the surface temperature of the heat exchanger 4 and the relative humidity of the air directly, since the data necessary for regulation is obtained by measuring the temperature of the air flow passing through the heat exchanger 4. For example, the surface temperature of the heat exchanger 4 is obtained by calculating the average value between the measurement results detectors 3 and 5 temperatures.

Claims (1)

Claim The method of temperature and humidity control in storage facilities for vegetables and fruits, which involves removing heat and moisture from products from the air by circulating air through a cooled heat exchange surface, characterized in that, in order to improve the quality during storage, the temperature of the heat exchange surface is adjusted to dew point temperature by changing either the heat exchange surface area or its temperature. 1487823 "Ζ“ ^ δ * '* 7'> ί? ' ¹ ". *"'Τ' * '"' -Τ. ''<Y-""'' * *" ^ SU '& • "o · **. ··· 14"% * · * * "and · G ". / 2hh <? ugo * * /. ch y * '' o * ' ⁰ /. figure 1 1487823 figl 1487823 FIG. five