RU2723327C1 - Method for storage of grain in container - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to the agriculture. Method of storage of grain in reservoir envisages use of sealed container, in which grain is stored, with means of evacuation. Container is made double-layer from external heat-insulating layer and inner layer, between which heating element is installed, fixed on heating plate with insulating rods, which are fixed to outer walls of inner layer. Inside between walls of outer heat-insulating layer and inner layer, additionally providing warm air blowing by means of low-power fan.

EFFECT: invention provides increased efficiency of storage of grain in reservoir due to provision of uniform movement of heated warm air in closed cavity between two layers of reservoir and reduced risk of condensate formation on walls and bottom of reservoir.

4 cl, 1 dwg

Description

The invention relates to agriculture, in particular for the storage of grain and can be used for storage of wheat, rye, buckwheat groats, oats, peas, corn, rice and other food products.

Improving the quality of stored grain by passing air through the grain mass by suction (negative pressure) or by pushing it out (overpressure). To achieve cooling as uniformly and quickly as possible, the design of the aeration system must ensure that the air distribution in the grain mass is as uniform as possible.

Even with the best aeration systems, however, problems still manifest themselves to increase the shelf life of dried grain, as well as the quality of the grain with pests. Such problems develop and worsen with the storage time of the grain, where the grain is stored in a sealed metal case, which is placed in a closed room in the winter. The air temperature space in it changes, the outside of the wall of the metal (galvanized) grain storage cools down, and heat forms inside, resulting in a difference in temperature, which means that condensate forms inside the tank’s body, i.e. there is no heat exchange surface or it is not sufficiently insulated, in particular in the winter period with sharp changes in subzero temperatures, and also when the grain is stored for a long time in a closed case. Inside, condensation forms in the form of droplets that wet the dried grain near the walls and bottom, i.e. condensate builds up from the metal (galvanized) walls of the granary enclosure. Along with these indicators for farms, value, reliability and ease of maintenance are of particular importance, and in winter, a large production area for storage.

A granary is known, which is used for mass acceptance of grain (wheat, rye) and made of reinforced concrete (Patent RU No. 2027341, A01F 12/60, A01F 25/08 from 01/27/1995).

Its loading is carried out by elevators, or periodic grain ventilation should be performed, which is very time-consuming and inefficient, as it absorbs from atmospheric air with variable relative humidity, which is why long-term storage of grain (more than one year) in elevator granaries, as the most modern and advanced , it is impossible and frequent cases when the grain sprouts, due to the presence of excessive moisture and oxygen (air) in it, and, when germinating, it heats up and deteriorates.

Known grain storage containing a sealed container of a vacuum-strong construction, connected with a means of vacuum (L. A. Trisnyatsky and others. “Storage and technology of agricultural products”, ed-3, revised and expanded. M .: Kolos, p. 169- 171, 1983).

The disadvantage of this technical solution is the complexity of the work to ensure vacuum within this design, which requires deepening the storehouse into the ground and additional workloads associated with this.

It is known that periods of constant drying speed are determined by the dynamics of humidity of the processed material depending on the drying and storage times, where time is expressed as W = f (T) (Lykov A.V. Drying theory / A.V. - M .: Energy , 1968, - 471 p.), However, this method cannot be carried out when drying bulk solids in a vacuum drying unit, since measuring the moisture of a material under vacuum is problematic.

For an analog, a known method of automatic control of the drying process can be cited, including controlling the drying process in a three-zone dryer, containing temperature and heating grain sensors in each of the drying zones, a grain moisture meter at the dryer inlet and a grain moisture meter at the dryer grain outlet, and the coolant temperature can be further controlled in each zone and control the exposure of drying by the temperature of the grain at the exit of the zones, and the temperature in each zone is controlled by the amount of moisture removal (Author's certificate SU No. 1483218, F26B 25/22 of 05/30/1989).

The disadvantage of this method is that the control process is carried out only partially at the final stage during unloading after drying. It is also impossible to use this method in vacuum drying plants.

A granary has been taken as a prototype from patent materials, since it coincides with the claimed technical solution for most of the essential features, including a sealed container of vacuum structures connected to vacuum devices, and the container is formed from a closed cone mounted on top of the cylinder supports, with nozzles , with gates and a metal-woven adsorber, while the walls of the cylinder and cones are made of light three-layer pre-cut and glued panels of the vacuum design, and the vacuum tools are made in the form of an electric vacuum pump mounted on the upper cone of the tank and connected to a wind generator, or photoelectric batteries that process radiation into electric current, as well as a vacuum pipe with a gate for receiving grain and a vacuum gauge (Patent RU No. 2122313, A01F 25/08, A01F 12/60, A01F 25/16 from 11/27/1998).

The disadvantage of the analogue (prototype) is the decrease in the quality of storage of dried grain due to the lack of the possibility of high-quality heating of the outer surface of the container mounted on the support by ventilation with warm air inside the cavity between the outer layer of the panel and the inner layer of the panel where the fire-resistant material is located. In addition, when the middle layer is made of a porous material, i.e. the case consists of a multilayer material, which means a large overspending of the material and the complexity of manufacturing. Another disadvantage is the decrease in the drying quality due to the inability to control the preservation of grain flow depending on the parameters of humidity and the environment, and to control the temperature of heating the walls and bottom of the structure to optimize drying (beginning and end of grain storage)) and increases the risk at the bottom moisture accumulation due to the absence of air heat blasting during its passage in the closed cavity of the multilayer material, i.e. unventilated cavity complicates the maintenance of dried grain and, as a result, different in time of the entire period of its storage,

As an example, it should be mentioned that when studying the possibility of applying the method for determining the drying and storage period of grain in vacuum drying plants with a heating temperature inside, the grain should not have an elevated temperature above 50 ° C, since this leads to a decrease in the quality of the finished material. In this regard, the regulation inside the cavity of the multilayer material and the combination of its storage with the temperature regulation inside the cavity to heat the inner layer of the panel evenly, given the thickness of its walls, for the given parameters of the granular material inside the dryer body, it is necessary to take into account this connection, but it is possible only knowing moments of the onset of condensation from the metal walls inside the housing. Therefore, in order to overcome this undesirable natural effect, it is necessary to remove the obtained free moisture during storage of the finished grain (period of dried grain, falling drying speed). Thus, uniform heating of the inner walls of the grain storage case of a given layer height is required. A low-power fan that blows walls with warm air inside the cavity of the heat-insulating layer is a heating element connected to the input of the control unit and to a personal computer for transmitting temperature and humidity indicators, and this connection. These values can be set based on laboratory tests, depending on the temperature of the grain in the tank when installing a temperature and humidity sensor. Thus, this leads to an increase in the efficiency of the method of storing grain in the installation.

Thus, in order to obtain high-quality ready-made preserved material and to reduce the excess moisture associated with this from the walls of the case, timely information on the dynamics of the grain storage process during drying is necessary. And this means that we need a new way of storing grain, which will allow us to fix the moment of the beginning of condensation formation on the walls and the bottom of the granary body (free moisture) and adjust the temperature storage parameters of dried grain in time.

The technical task of the invention is to maintain the normalized energy intensity of the process in a closed cavity of a two-layer tank under the changing temperature conditions of the air atmosphere, i.e. when storing grain at low temperatures in rooms, increasing the reliability and safety of grain storage.

The technical result is achieved by the fact that in the method of storing grain in a container, providing for the use of a sealed container in which grain is stored, with evacuation means, according to the invention, the container is double-layer of an external heat-insulating layer and an inner layer, between which a heating element is mounted on a plate heating with insulating rods, which are fixed to the outer walls of the inner layer, and inside between the walls of the outer insulating layer and the inner layer additionally provide blowing with warm air through a low-power fan.

In addition, a predetermined temperature regime in the cavity between the two-layer walls of the tank is supported by a temperature controller located at the entrance to the control unit, the output of which is connected to the heating element.

In addition, a temperature and humidity sensor is installed in the cavity of the drying tank, the output of which is connected to the control unit.

In addition, the control unit can be connected to a personal computer to transmit temperature and humidity readings.

The novelty of the claimed technical solution lies in the fact that the supply of the cavity between the two layers of the tank intensifies the process with an additionally equipped heating element and an air fan connected to the temperature controller integrated in the control unit, and this makes it possible to evenly fill the cavity with warm, ventilated air in an enclosed space, which will lead to an increase the device’s operating efficiency, in addition, a temperature and humidity sensor of grain material is installed directly in the vacuum drying container of the casing, which allows continuous monitoring of the change in these values in the granular material and is connected by the output to the input of the control unit, the output of which is connected to the heating element with a fan blower, and the control unit connected to a personal computer to transmit temperature and humidity, and associated with the temperature of the heating element on the heating plate.

Industrial applicability is due to the fact that the method of storing grain in the tank is efficient and it can be used in the drying and storage of grain in the tank.

The invention is illustrated in the drawing. A diagram illustrating the method of storing grain in a tank is given.

Programmable thermostat for heating with a liquid crystal screen (the control unit is not shown with disclosing symbols explaining on it - for example, program mode, event indicator, installation temperature, and other buttons).

To implement the method of storing grain in the tank, they are made in the form of a prefabricated cylindrical tank 1, formed from the mounted cones 3 and 4, from the bottom and top of the closed cones 3 and 4; 9,

an electric vacuum pump 10, a vacuum wire 11, a loading hopper 12. At the cone 3 place the lower pipe 5 with the gate b.

The sealed container 1 is made of metal, galvanized iron, etc. The capacity is made of an external heat-insulating layer 13 and an inner layer 14, between which a heating plate 16 with a heating element 17 is fixed with insulated rods 15. In addition, the heating element 17 is provided with a fan (not shown, like a desktop heater) with a blowing of the heating plate 16 and connected with the inputs of the control unit 18 with a temperature controller and with temperature control inside the cavity between the two layers 13 and 14. Also, the container 1 inside is equipped with a temperature and humidity meter 19, as a control sensor, and connected to the input of the grain temperature and humidity control unit 18 and signal personal computer 20. Thus, there is no assumption of condensation (moisture) of the walls and the bottom of the cone of the tank 1 during storage and drying of grain.

The control panel unit in the form of a programmable temperature regulator for a heating element 17 with a liquid crystal screen (not shown) is based on a programmable temperature regulator for heating systems with a liquid crystal screen and includes: anti-freezing mode, program mode, manual mode, event indicator, time (temperature settings), current tamper, day of the week, heating on, menu button lock, Up / Plus button, air temperature sensor, Down / minus button, ON / OFF button. Technical characteristics of control unit 18: voltage ~ 220 V (possibly 110 V ~ 14 V); power consumption 2 W; temperature range 50 ° С-90 ° С; differential switch 0.5 ° C; mounting temperature 5 ° C; housing protection level LP20; case material - non-combustible plastopolymer. The sensor 19 temperature and humidity of the grain is connected through a wire. Control function: manual mode - all program settings do not work, the thermostat constantly maintains the set temperature; programmable mode - the day is divided into six periods and the thermostat works automatically according to the set temperature and time. In addition, there is a comfortable mode where the temperature can be temporarily changed for the current period of the day. When the next period sets in, the thermostat will independently return from the comfortable mode to the programmed one.

Standard thermostats are recommended for controlling electric and water heating systems. The weekly programming function makes it possible to divide the day into six periods and automatically the temperature in each period, i.e. You can select "manual" or "comfortable" mode.

In this case, the control unit 18 is connected via a communication line with a personal computer 20 in the online mode. At a signal from the computer 20, the control unit 18 is turned on or off via a communication line, while in a container 1 with grain material with dried grain, for example, dry seed grain, with a predetermined humidity of 13-14%, they are held up to a predetermined vacuum value set by the automation system known in advance of this grain material (for example, wheat) from the predicted respiration rate of this grain during the entire storage period, entered into the personal computer program 20 for the maximum permissible concentration of grain storage in a controlled gas environment, and this in turn is also associated with warm heating air blowing by a fan (not shown) of the heating plate 16 by the heater element 17, which are connected to the input of the temperature control unit 18 inside the closed cavity between the two layers 13 and 14 of the tank body 1.

Thus, a signal is sent from the computer 20 to the control unit 18, as a result of which the heating element 17 and the fan (not shown) are turned on or off.

To obtain information about the storage of dried grain and preserve its high-quality finished grain (material) and reduce energy costs, timely information on the dynamics of the storage and drying process is necessary. The proposed method will allow you to record the start and stop of the appearance of condensate on the walls and the bottom of the housing of the inner layer 14 of the tank, and the beginning of the possible removal of the evaporation of moisture associated with this accumulation by the vacuum pump, and adjust the temperature parameters of drying in a vacuum drying device (installation). So, it will be possible to build a graph of the dependence of changes in the electrical connection to the heating element 17, fixed to the heating plate 16, which is blown by a fan (not shown), the resulting warm air in the cavity between the two heat-insulated layers 13 and 14 in a closed circuit to allow overheating of granular material.

The method is as follows.

Initially, when filling grain into the granary in the form of a tank 1 through a hopper 12 or a vacuum wire 11, close the gate 6, after filling close the gate 8 and turn on the electric vacuum pump 10 and turn off the electric vacuum pump (vacuum generation is checked by a vacuum gauge - not shown).

The operation of the granary is ensured according to the quality and correct operation of the control unit 18, connected both with the heating element 17 with the heating plate 16 and with a fan (not shown), and with a personal computer 20, as well as maintenance in accordance with the rules of the instruction manual for the programmed thermostat in block 18 for heating systems with a liquid crystal screen, in compliance with safety standards.

In this regard, it is necessary to be able to heat the heating plate 16 with a heater 17, then blowing a fan (not shown), warm air that circulates in a closed cavity between the walls of the external heat-insulating layer 13 and the inner layer 14. The temperature regulator in the control unit 18 maintains a predetermined temperature the regime for heating air between layers 13 and 14. Throughout the whole process, a closed cavity between layers 13 and 14 provides for the heating of circulating air from the operation of the blowing fan in the cold season when storing grain material in closed warehouses, for which a heating element 17 mounted on the heating plate 16 with a fan (not shown), which is associated with work, also with the control unit 18 and with a personal computer 20, taking into account the readings of the meter 19 for temperature and humidity of the grain material, as a control sensor.

Even in dry grain, placed in the air of the tank, there is a certain amount of water vapor, in order to take into account the relative humidity of a few percent. Thus, it is necessary to take into account the condensation of water vapor from the air, even in grams in a certain volume of grain, which is stored for a long time, respectively, this varies from the methods of its storage and for conditions, which in this case can be in real concrete cases. In this case, the contacts of the heating elements through a wire are connected to the control unit 18 and the connection with the computer 20, and the contacts of the heating elements themselves are isolated from the walls of the layers 13 and 14, since the heating element 17 with the heating plate 16 is isolated, suspended (fixed) to the insulated rods 15 .

To achieve a positive effect (the absence of condensate inside the grain material) during storage of crops by the proposed method, it is important that the composition of the gas mixture in the tank is quickly monitored. This is possible when using technically generated heated air by devices in the cavity between the layers 13 and 14 of the container bodies using the sensor of the temperature and humidity meter 19, the algorithms of which are entered into a personal computer 20, i.e. the process is automated and easy to manage. Thus, having received the inner walls of the layer 14 heat, and the condensate forming inside the tank 1 turns into warm steam, and rises up, where the temperature and humidity sensor 19 is installed, the latter is triggered and transmits a signal with its output to the input of the control unit 18, and it is connected additionally with a computer 20. Thus, the grain in the container is monitored by a sensor 19. The drying container itself, after the grain material has completely dried, is also checked by a vacuum gauge (not shown). The optimal moisture content of the grain, which should not exceed 13-14% and is maintained for the time required for a given relative grain moisture to a predetermined value. It should be borne in mind that the cycle can be repeated and depends on the control unit 18 and communication with the computer 20 (or manually) in the work system of being in the storage room. Over time, drying and storage can be obtained data on the formation of condensate in the grain space, controlled by a temperature and humidity sensor 19. It is possible to control the processes of not only drying, but also storage of grain, which is especially important not only for feed production, but also for planting material i.e. to improve the quality of seed (material) to the level of class 1 on germination, allowing the introduction into production.

The proposed invention will eliminate the formation of condensate in the cold season in storage facilities. The capacity is performed by a two-layer sheathing of the body, in the cavity between which a heating plate is suspended (fixed) on insulated rods with a heating element, with their blowing using an air fan, i.e. ventilated warm air inside a closed cavity between the layers 13 and 14 of the tank. And this, in turn, increases the efficiency of the drying tank with heat-insulating multilayer layers inside with heating elements; eliminating the condensation of the walls of the container body. And this eliminates the loss of grain from mold during storage and is used both in fodder production and for sowing, selling, etc., and preserving the set grain moisture preserves it for a given storage period. The risk of moisture condensation inside the container is reduced due to the heat air screen inside between the layers of the container’s body, while maintaining the discharged atmosphere inside the container, moisture condensation conditions change, the atmospheric pressure decreases the _dew point P, and the amount of air entering the container does not great, since heating elements are used with blowing by their fan - creating an annular (closed) movement of warm air.

Using the proposed method of storing grain in a container in any warehouse in the form of a series of modules is easily implemented. This combination of all elements eliminates the effect of condensate in the grain material, provides almost complete automation of the processes and improves the working conditions of staff on the storage of grain material in comparison with the prototype.

The originality of the invention consists in maintaining the circulation inside the heated air layers in a closed state and normalized energy consumption for heating the ventilated air under conditions of changing temperature effects of the environment, by maintaining a predetermined humidity in the container’s grain material from a shielding heating plate with a heating element and blowing them with a fan. The method can be widely used in agriculture to maintain its high quality.

Claims (4)

1. A method of storing grain in a container, providing for the use of a sealed container in which the grain is stored, with evacuation means, characterized in that the container is double-layer of an external heat-insulating layer and an inner layer, between which a heating element is mounted, mounted on a heating plate with insulating rods which are fixed to the outer walls of the inner layer, and inside between the walls of the outer heat insulating layer and the inner layer, additionally provide blowing with warm air through a low power fan. 2. The method according to p. 1, characterized in that the specified temperature in the cavity between the two-layer walls of the tank is supported by a temperature controller located at the entrance to the control unit, the output of which is connected to the heating element. 3. The method according to p. 1, characterized in that in the cavity of the drying container, a temperature and humidity sensor is installed, the output of which is connected to the control unit. 4. The method according to p. 2 or 3, characterized in that the control unit can be connected to a personal computer to transmit temperature and humidity.

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