KR950008136Y1 - Apparatus for storing agricultural - Google Patents

Abstract

No content.

Description

Grain storage device

1 is a system diagram showing a conventional grain storage device.

Figure 2 is a system diagram showing the configuration of the grain storage device of the present invention.

Figure 3 is a schematic diagram showing another embodiment of the grain storage device of the present invention.

* Explanation of symbols for main parts of the drawings

1a, 1b: storage silo 2: packing silo

3: blower 4a, 4b: air purifier

5: burner 7a: cyclone

9a, 9b, 9c: branch valve 11a: water tank

12a: electromagnet valve 13: band nozzle

14: inert gas storage tank 20a, 20b, 20e, 20f, 20g: piping

The present invention is a hermetic silo that stores and manages grains in a silo by a gas transportation device to dry grains contained in a storage silo by using hot dry air to move grains to storage silos, and to store the pressure inside the storage silo. It relates to a grain storage device that can be kept constant at all times.

Conventionally, in order to store and manage a large amount of grain, grains were placed in bales, and the bales were stacked and stored or managed.

However, this storage method takes a lot of labor in the storage and management of grains, the grains are easily deteriorated by moisture contained in the atmosphere, and it is difficult to extract from the long-stored bales when the grains are taken out.

In addition, the conventional storage method has a defect that can not protect the stored grains when the loss of the storage grains caused by the rats, insects, etc., and the fire in the storage warehouse.

Patent application of December 14, 1991 to solve the problems of the past to prevent the alteration of grain, to take out the grain in the order of storage, and to manage the grain storage management method and device that can safely store the grain from disasters and insects, etc. No. 91-22994 proposed by the applicant.

The grain storage device is connected to the cyclone installed on the upper part of the storage silo and the bottom of the storage silo with a pipe material, and the other side of the pipe is connected to a water tank containing water by connecting one side of the other pipe to the upper part of the storage silo. In the water tank, an operating water level switch that opens and closes according to the water level is installed, and the water level switch is electrically connected to an electromagnet valve that controls the supply of an inert gas into the storage silo so that the hot dry air passing through the cyclone is stored in the storage silo. It moves from the bottom to the top to dry the grain contained in the storage silo, and the water level of the water tank changes according to the change of the internal pressure of the storage silo to open and close the water level switch, which causes the electronic valve to open and close the storage silo. By controlling the inert gas, the storage silo maintains a constant internal pressure. It was to do it.

The conventional problems have been greatly improved by the grain storage device. However, as a result of careful investigation, the grain position in the silo is unchanged once the grain is stored in the storage silo. There were still problems such as the lack of dryness and the inability to easily grasp the abnormal condition of the current grain dryness.

The present invention circulates the grains in the storage silo with hot dry air to uniformly dry the grains, and makes it easy to grasp the dry state of the grains by sampling the circulating grains. Was omitted, and a separate grain circulation pipe was installed.

Figure 2 of the accompanying drawings is a schematic diagram showing the structure of the present invention grain storage device, Figure 3 is a schematic diagram showing another embodiment of the subject innovation according to the accompanying drawings in detail the embodiment of the subject innovation as follows.

The upper part of the storage silo 1a for storing grain is connected with a branch valve 9b and a pipe material, and the branch valve 9b is connected to a pipe 20a, which is an air transfer passage, and a pipe 20f for circulating grain. The other side of the pipe 20f is connected to the pipe 20b through the branch valve 9c.

The pipe 20a is connected to the other branch valve 9a for controlling the flow direction of air, and then connected to the dehumidifiers 6a and 6b via the other valves 10c and 10d, respectively. The hopper 1c for supplying the gas into the pipe 20a.

Then, a rotary feeder 8a is provided between the hopper 1c and the pipe 20a.

The dehumidifiers 6a and 6b are connected to a blower 3 which gives a transfer force to the transfer air transferred through the pipe 20a via the other valves 10a and 10b, and the blower 3 is connected to the transfer unit. It is connected to the burner (5) for drying the air at high temperature, the burner (5) is connected to the air cleaner (4a) for filtering the air transported through the pipe (20a) clean.

The lower portion of the silo 1a is connected to an electronic valve 12a for controlling the movement of the inert gas, and the electronic valve 12a is an inert gas storage tank 14 for diluting the air in the storage silo 1a. ) And the pipe 20b and the lower portion of the storage silo 1a are connected to the hot air transfer pipe (20g).

The upper end of the storage silo 1a is connected to one end of another pipe 20c through which the internal air of the storage silo 1a is transferred, and the other end of the pipe 20e is filled with water in an open state. The exhaust port 13a is provided in the pipe 20e so as to be located in the water of 11a.

The water level switch 17a is installed in the water tank 11a to open and close according to the water level of the water tank 11a so that the electromagnet valve 12a is opened and closed by the water level switch 17a.

The branch valve 9a is connected to a pipe 20a which is a passage for air for transferring grains supplied through the hopper 1c to the storage silo 1a and at the same time to the outside through the lower end of the storage silo 1a. It is also connected to the pipe (20b) that is the passage of air for transferring the discharged grain to the packaging silo (2).

Then, the pipe 20b is connected to the rotary feeder 8d installed at the lower end of the storage silo 1a, and one end of the pipe 20b is connected to the cyclone 7c installed at the top of the packing silo 2. .

The storage silo 1a is formed in a conical shape with a lower end portion, and an inner surface 25 of a conical shape in which a plurality of holes are drilled is installed on an inner surface of the lower portion so that an inert gas in the storage tank 14 passes through the inner plate 25. The storage silo 1a is uniformly supplied and a vent nozzle 13 is installed at the lower end of the silo 1a.

In addition, the packing silo 2 is equipped with a scale 15b for measuring the amount of grain discharged, and the free joints in the cyclone 7c and the packing silo 2 are positioned so that the packing silo 2 is freely positioned. (16e) to (16f).

In addition, the storage silo 1a may be provided with a window for looking into the internal state from the outside, and a scale may be installed on the inner circumferential surface of the storage silo 1a so that the amount of grain stored from the outside may be known and a thermometer may be installed. To know the temperature of the storage silo (1a) and the altered state of the grain.

The storage silos may be provided with a plurality of storage silos in series to increase grain storage capacity as necessary.

Grain drying action and effects of the present invention grain storage device as described above are as follows.

The air is filtered cleanly through the air cleaner 4a and then heated by the heat from the burner 5 and then compressed in the blower 3 to be transferred to the dehumidifiers 6a and 6b, and to the dehumidifiers 6a and 6b. After passing through the pipe (20a) and the grain supplied from the hopper (1c) is transported through the branch valve (9b) to the silo (1a).

Grain entering the silo 1a is stored in the storage silo 1a, and the air carrying the grain moves to the lower part of the upper silo of the silo 1a while drying the grain stored in the storage silo 1a and vent nozzles. It exits to the atmosphere through (13).

After the transportation and storage of the grains, the moisture content of the air exhausted from the vent nozzle 13 is checked. If the moisture content is high, the grains are heated together with the high-temperature dry air through the valve 8d-pipe 20d. The valve 9c, the pipe 20f, and the valve 9b are stored in the silo 1a again through the circulation line leading to the valve 9b, and the hot dry air absorbs the moisture of the grains and is discharged to the vent nozzle 13.

Such circulation drying operation of the grain is repeated until the moisture content of the exhaust air discharged to the vent nozzle 13 falls below the reference value.

After drying, the vent nozzle 13, the branch valve 9b, and the nozzle 13a are blocked, and the storage tank 14 of the inert gas is opened to allow the inert gas to flow into the storage silo 1a through the electronic valve 12a. Supplied.

As described above, when the inert gas continues to be supplied into the storage silo 1a, pressure is applied to the silo 1a and the pipe 20e, and the pressure is the water contained in the water tank 11a through the open end of the pipe 20e. It acts on the water level to change.

At this time, when the water level is changed, the water level switch 17a operates accordingly to close the electromagnet valve 12a, and the air delivered to the water through the pipe 20e is drawn out of the water, thereby storing the silo 1a. The internal pressure of the does not rise above a certain pressure value.

In addition, the internal pressure may be measured by comparing the difference in water surface between the inner surface of the pipe 20e and the surface of the water tank 11a.

In other words, if the difference in water level is x cm and the specific gravity of water is rw, the internal pressure of the silo becomes a water column of x X rw cm.

And by adjusting the amount of water contained in the water tank (11a) to limit the maximum level of water contained in the water tank (11a), thereby limiting the difference between the water level of the pipe (20e) and the water level of the water tank water This will limit the maximum pressure inside the silo.

In the process of storing and storing the grain in the storage silo 1a as described above, when the outside temperature drops or discharges the stored grain, the negative pressure is applied to the internal pressure of the storage silo 1a. The internal pressure of the storage silo 1a is adjusted as follows.

That is, when the air temperature in winter decreases, the internal temperature of the storage silo 1a also decreases, thereby causing the gas inside the storage silo 1a to change its specific volume, and the internal pressure is changed by the specific volume. It falls under Boyle-Charrel's Law.

According to the experiment, when the internal temperature of the silo 1a is lowered by 27 ° C, the internal pressure is lowered by about 10% (approximately) to absolute pressure.

When negative pressure is applied to the internal pressure as described above, the water in the water tank 11a is sucked into the pipe 20e, the water level of the water tank 11a is changed, and the water level switch 17a is operated by the change of the water level, thereby operating the electronic valve. 12a is opened, and water is supplied from the storage tank 14 of the inert gas into the storage silo 1a to adjust the internal pressure.

When the grain is removed from the storage silo during the storage of the grain, the grain falls to the pipe 20b through the rotary feeder 8d and then by air supplied into the pipe 20b through the branch valve 9a. The grain is transferred to the cyclone 7c and the packing silo 2.

At this time, when the grain is discharged from the storage silo 1a, a negative pressure is generated inside the storage silo 1a, and the adjustment of the negative pressure is performed in the same manner as the negative pressure control process according to the temperature change from the above.

When it is necessary to store grain for a long time and then dry the grain again, hot air is pumped into the silo 1a through the pipe 20b-pipe 20g, and the air containing the moisture after preheating the grain is silo. (1a) If the moisture of the grain is large, the air is vented out through the vent nozzle (13), if the moisture of the grain is discharged out through the vent nozzle (13a) to the silo (1a) Dry the grain in).

At this time, the amount of air entering the silo 1a through the pipe 20g is determined by the opening and closing degree of the valve 10g.

3 is a configuration in which the grain circulation pipe 20f is additionally installed between the pipe 20a and the pipe 20b in a conventional configuration as another embodiment of the present invention.

In this embodiment, the grain or air passage path is the same as in the case of storing the grain, but the hot drying air passes through the path of 9a-20b-20f-9b-7a-20c-25-1a-20e when drying the stored grain. 13a), the grain is stored in the storage silo (1a) again via the path of 1a-8d-9c-20f-9b-7a-8b.

Of course, such a circular drying process of the grain is repeated until the moisture content of the exhaust air discharged to the exhaust port (13a) falls below the reference value.

As such, the present invention circulates and stores the grain stored inside the storage silo with high temperature dry air, thereby preventing the alteration of the grain by deteriorating the humidity and oxygen conditions among the three components of humidity, humidity, temperature, and oxygen. Of course, by changing the location of the grain in the silo, uniform drying is possible, and in the process of circulating simply by sampling can check the state of the grain, as well as the cost of the facility is effective.

Claims (1)

One end of the pipe 20e connected to the storage silo 1a is formed as an open end and placed in a water tank 11a containing water, and the water tank 11a is operated according to the water level of the water tank 11a. A switch 17a is provided, and an electromagnet valve 12a for controlling the movement of the inert gas is formed in the pipe connected from the inert gas storage tank 14 so that the electromagnet valve 12a is electrically connected to the water level switch 17a. In the grain and dry storage device to circulate air and grains, characterized in that the connection between the rotary feeder (8d) of the lower storage silo (1a) connected to the grain circulation pipe (20f), storage silo (1a) Vent vent (13) is installed at the lower end of the) and the grain storage device, characterized in that the grain stored in the silo (1a) is circulated with the hot dry air to the grain circulation pipe (20f) to dry.