JPH05260846A - Method for cooling storage silo and device therefor - Google Patents

Abstract

PURPOSE:To simply prevent the rise of the temperature in a storage silo by spraying water so that the water flows down from the upper part of the silo along its side wall. CONSTITUTION:When heat invades into a silo, water is sprayed so that at least one side wall 1a of the silo is wetted and that the water flows down from the upper part of the silo along the side wall. The spaying is performed by pumping up the water in a tank 2 with a pump 4 and subsequently spraying the water through a spraying pipe 8 to cool the silo.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cold storage method for a storage silo capable of suppressing a rise in the temperature of the grain in a storage silo for storing grains and storing it for a long period of time.

[0002]

2. Description of the Related Art Conventionally, when the grains in a storage silo are stored for a long period without degrading the quality, cooling air from a cooling device is supplied into the storage silo to cool the grains to a predetermined temperature. The method of storing in the state is known (actual fairness 1
-43005). This method has a problem in that a large-capacity cooling device is required to cool a large amount of grain and the storage silo needs to have a heat insulating structure, which increases construction costs and operating costs.

Therefore, as disclosed in Japanese Examined Patent Publication No. 60-45887, a ground silo and an underground silo are provided, and when the monthly average temperature is less than 15 degrees Celsius, the ground silo is stored and the underground silo is cooled naturally or naturally. Cool with cold water. Then, when the monthly average temperature is 15 degrees Celsius or higher, a method is known in which grains in the above-ground silo are transferred to the underground silo and stored.

[0004]

However, even with such a conventional method, the ground silo and the underground silo must be provided separately, and the ground must be dug deep to provide the underground silo. .. Moreover,
Since the ground must be dug widely so as to secure a space between the ground and the underground silo, there is a problem that a large installation space is required and the construction is difficult and the construction cost is high.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a storage silo cooling method and a storage silo control device which can easily suppress the temperature rise in the storage silo.

[0006]

In order to achieve the above object, the present invention takes the following methods to solve the problems.
That is, when there is heat intrusion into the grain storage silo, at least the side wall of the silo wets the side wall and water is sprayed so that water flows down from the upper side. That is it.

In order to achieve the above object, the present invention has the following constitution in order to solve the problems. That is, the grain storage silo is provided with a sprinkling pipe for sprinkling water on at least the side wall, a pump for supplying water to the sprinkling pipe, and a tank for storing water pumped by the pump, the side wall being wet and traveling along the side wall. That is the structure of a cooler for a storage silo, which is characterized by allowing water to flow down from above.

[0008]

In the cold storage method of the storage silo, when heat enters the silo, water is sprayed on at least the side wall of the silo. When there is no heat penetration, let it cool naturally. For watering, the side wall of the silo travels along the wet side wall so that water flows down from above. Although it is affected by sensible heat, latent heat, wind around the silo, etc., at least the side wall may be always wet.

In the cold storage device of the storage silo having the above-mentioned structure, the tank stores water, the pump pumps up the water and supplies it to the water spray pipe, and the water spray pipe sprays at least the side wall of the silo to wet the side wall. Water flows down from the top along the side wall.

[0010]

Embodiments of the present invention will now be described in detail with reference to the drawings. 1 and 2 are a schematic front view and a top view of a cold storage device for a storage silo that implements a cold storage method for a storage silo according to an embodiment of the present invention. Reference numeral 1 is a silo, and in this embodiment, 10 silos 1 are arranged closely in two rows of 5 silos. Even if the silo 1 is made of concrete,
It may be made of steel.

Next to the silo 1, a tank 2 for storing water is formed by digging down the ground. A pump 4 is arranged in the tank 2, and a main water supply pipe 6 is provided along the side wall 1 a of the silo 1 along the side wall 1 from the pump 4.
It is piped to the upper part of a. Furthermore, this main water supply pipe 6
Along the upper wall 1b of the silo 1 along the upper wall 1 of each silo 1.
It is piped in a loop shape so as to pass through b.

A plurality of arc-shaped sprinkler pipes 8 are arranged on all the silos 1 along the outer periphery of the side wall 1a above the side wall 1a of the silo 1. All of the sprinkler pipes 8 and the main water supply pipe 6 are connected to each other via an electromagnetic opening / closing valve 10. A large number of nozzle holes (not shown) are bored in the water spray pipe 8 toward the side wall 1a of the silo 1.

Further, a branch pipe 12 extending toward the center of the upper wall 1b of each silo 1 is connected to the main water supply pipe 6, and the other end of the branch pipe 12 is lowered at the center of the upper wall 1b. It is open toward. The branch pipe 12 has a solenoid opening / closing valve 1
4 is installed. On top of each silo 1 is a top wall 1b
A gutter (not shown) for collecting water flowing out from the gutter is provided. The gutter is connected to a vertical gutter 16 provided along the side wall 1a, and the other end of the vertical gutter 16 is arranged to open in the tank 2. ing.

On the other hand, a drain groove 18 is formed on the ground around the silo 1 so as to surround the plurality of silos 1. The drain groove 18 is connected to the tank 2. The electromagnetic on-off valves 10 and 14 and the pump 4 are connected to a control device 20, and the control device 20 is a well-known CPU 2
2. ROM that stores control programs and data in advance
24, a readable / writable RAM 26 is mainly configured as a logical operation circuit, and an input / output circuit 28 is connected to each other via a common bus 30 to perform input / output with the outside.

Then, the CPU 22 inputs data from the pyranometer 32 and the outside air temperature meter 34 via the input / output circuit 28, and based on these signals, the programs and data in the ROM 24, RAM 26, etc. The control signal is output to the pump 4 and the electromagnetic on-off valves 10 and 14 via the input / output circuit 28.

The pyranometer 32 measures the amount of solar radiation (cal / cm ² · min) which is the amount of heat passing through a unit area per unit time. This pyranometer 32 is installed at a position where it does not become a shadow. The outside air temperature meter 34 measures the outside air temperature outside the silo 1.

Next, a sprinkling control process for carrying out the cold storage method of the storage silo of this embodiment will be described with reference to the flow chart of FIG. As shown in FIG. 4, the temperature of the grain in the silo 1 rises with the passage of time, and the temperature is different between the outer periphery and the center of the silo 1. When the grain is paddy, it is preferable to store it at a temperature of 15 ° C or lower.

Therefore, the watering operation is started from around the beginning of April when the grain temperature rises to 15 ° C. and the temperature difference between the outer periphery and the center of the silo 1 widens. Then, the amount of solar radiation from the pyranometer 32 is read (step 10
0), the outside air temperature is read from the outside air temperature meter 34 (step 110).

Then, it is judged whether or not the amount of solar radiation exceeds 0.4 cal / cm ² · min (step 120), and when the amount of solar radiation does not exceed this, whether the outside air temperature exceeds 20 ° C. It is determined (step 130). When the outside air temperature does not exceed, it is determined whether or not the amount of solar radiation is 0.1 cal / cm ² · min or more (step 140).

The outside temperature is 20 ° C. or lower, and the amount of solar radiation is 0.
When the pressure is less than 1 cal / cm ² · min, the pump 4 is not operated and the electromagnetic opening / closing valves 10 and 14 are closed (step 150). That is, when the sun does not appear at night or the like, it is determined that heat does not enter the silo 1 from the outside, and the pump 4 is not operated. Rather, the outside temperature is lower than the temperature inside the silo 1, and the silo 1 is cooled by natural wind or the like.

Then, as the sun rises and the amount of solar radiation increases,
When it is determined by the process of step 140 that the temperature is 0.1 cal / cm ² · min or more, it is next determined whether the outside air temperature is 15 ° C. or more (step 160). When the outside air temperature is less than 15 ° C, the pump 4 is not operated, and when the outside air temperature is 15 ° C or more, it is determined that heat is invading the silo 1 from the outside, and the pump 4 is kept at regular intervals. The operation / stop is repeated to open / close the electromagnetic on-off valves 10 and 14 at regular time intervals (step 170).

When the pump 4 is operated, the water in the tank 2 passes through the main water supply pipe 6 and is pumped up to the upper part of the silo 1, and the side wall of the silo 1 through the electromagnetic opening / closing valve 10 and the sprinkler pipe 8. Water is sprinkled on top of 1a. The amount of water sprayed is such that the side wall 1a forms a wet wall through which water flows down along the wet side wall 1a. In the case of concrete, a wet wall is formed by sprinkling water in an amount of 900 kg / hr per 1 m in width.

The sprinkled water flows down along the side wall 1a, and the remaining evaporated water flows into the drain groove 18. Then, it flows through the drain groove 18 and flows into the tank 2. Then, it is pumped again by the pump 4 through the main water supply pipe 6 to the upper part of the silo 1. Water is also sprayed on the upper wall 1b of the silo 1 via the electromagnetic opening / closing valve 14 and the branch pipe 12. The water on the upper wall 1a is collected in a gutter (not shown), and is collected in the tank 2 via the gutter 16. Then, it is again pumped by the pump 4 through the water supply pipe 6 to the upper portion of the silo 1.

Further, every time a certain period of time elapses, the operation and stop of the pump 4 and the opening and closing of the electromagnetic on-off valves 10 and 14 are repeated, so that watering is intermittently performed. In addition, the amount of water stored in the tank 2 should be such that the water pumped up by the pump does not become empty before the water returns to the tank 2 through the drain groove 18 and the vertical gutter 16. Good.

[0025] Thus, the present sprinkler control process is repeatedly executed, 0.4cal / cm ² · in the amount of solar radiation 0.1cal / cm ² · min or more
Intermittent watering is performed in the morning, evening, or spring when the temperature is less than min and the outside temperature is 15 ° C or higher. On the other hand, the position of the sun is high, the amount of solar radiation is increased, such as in the day and during summer the outside air temperature is high, the amount of solar radiation is 0.4cal / cm ² · mi
n (step 120) or outside temperature is 20 ° C
When it exceeds, it is judged that heat is invading from the outside into the silo 1 (step 130), the pump 4 is continuously operated, and the electromagnetic opening / closing valve 10 is kept open (step 18).
0).

Then, in the same manner as described above, the water in the tank 2 is pumped up, and the side wall 1a is wet on the upper part of the side wall 1a of the silo 1 through the sprinkler 8 and the water flows down along the side wall 1a. Sprinkled to form a wall. This water is
It is collected in the tank 2 through the drainage ditch 18 and again pump 4
Is pumped up and sprinkled on the upper part of the silo 1.

Further, the electromagnetic opening / closing valve 14 is repeatedly opened and closed at regular time intervals in the same manner as described above, and intermittent water sprinkling is performed on the upper wall 1b. In addition, in the case where there is a building on the upper wall 1b of the silo 1, it is possible to prevent heat from entering from the outside through the upper wall 1b. ..

In this way, by executing the processing of steps 170 and 180, water is sprinkled and the side wall 1a becomes a wet wall, so that the heat from the sun is consumed as the temperature rise of the water or the heat of evaporation of the water. Consumed as. Therefore, the invasion of heat into the silo 1 is suppressed. Then, as shown in FIG. 4, the increase in grain temperature in the silo 1 after April is suppressed to about 15 ° C. or less regardless of the outer circumference and the center of the silo 1.

The amount of solar radiation at night is 0.1 cal / cm ² · mi
When it is less than n or the outside air temperature is less than 15 ° C, it is judged that the heat is radiated from the inside of the silo 1 rather than the heat entering from the outside, and the operation of the pump is stopped to cool the silo 1 naturally. The water in the tank 2 is also naturally cooled. In this way, the cooled water is repeatedly used for the sprinkling control process, and is used when the processes of steps 170 and 180 are executed.

Therefore, when there is heat intrusion, water is sprinkled so as to form a wet wall, and when there is no heat intrusion, the silo 1 is naturally cooled, so that heat can be easily introduced into the silo 1. Can be suppressed. In addition, in the above-described embodiment, the pyranometer 32 and the outside air temperature meter 34 are used to determine the intrusion of heat, but instead of this, a once-through calorimeter is used to execute the watering control process. This will be described with reference to the flowchart of FIG.

The once-through calorimeter uses a thermopile or the like,
The amount of heat passing through the unit area of the side wall 1a of the silo 1 per unit time is measured. This once-through calorimeter is provided on the side wall 1a of the silo 1. Then, similarly to the above-described embodiment, the operation is started from around the beginning of April to execute the sprinkling control process, and the once-through heat quantity of the once-through calorimeter is read (step 20
0), when the amount of heat of flow is less than ²⁰ Kcal / m ² · hr (step 210) and the amount of heat of flow is 0 or less (step 220), the sprinkling is stopped as in the process of step 150 (step). 230).

When the amount of heat flowing through becomes 0 or more (step 220), as in step 170,
Water is intermittently sprinkled (step 240). On the other hand, when the amount of heat flowing through exceeds ²⁰ Kcal / m ² · hr, the above step 180
Similarly, water is sprinkled on the side wall 1a continuously.

Even in this case, as described above, it is possible to suppress heat from entering the silo 1 by a simple method, and it is possible to accurately measure the amount of heat entering the silo 1. The present invention is not limited to the embodiments as described above, and can be implemented in various modes without departing from the gist of the present invention.

[0034]

As described above in detail, according to the cold storage method and apparatus for a storage silo of the present invention, it is possible to easily suppress heat from entering the silo and store grains for a long period of time. Play.

[Brief description of drawings]

FIG. 1 is a schematic front view of a cold storage device for a storage silo that implements a cold storage method for a storage silo according to an embodiment of the present invention.

FIG. 2 is a schematic top view of the cold storage device for the storage silo of this embodiment.

FIG. 3 is a flowchart showing an example of a sprinkling control process executed in the control device of the present embodiment.

FIG. 4 is a graph showing temperature changes of grains in a storage silo.

FIG. 5 is a flowchart showing an example of sprinkling control processing executed in the control device of the second embodiment.

[Explanation of symbols]

1 ... silo 1a ... side wall
1b ... upper wall 2 ... tank 4 ... pump
8 ... Sprinkler pipe 10, 14 ... Electromagnetic on-off valve 18 ... Drain groove
20 ... Control device

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Masakazu Sakano 1-1, Sanbonmatsucho, Atsuta-ku, Nagoya, Aichi Japan Vehicle Manufacturing Co., Ltd. (72) Seiwa Miwa 1-68 Nishiyanagihara-cho, Tsushima-shi, Aichi (72) Inventor Kiyokazu Goto 127, Saitama, Saitama, Gifu City, Gifu Prefecture 6 (72) Inventor Yoshio Terabe 52, Nakakaido, Sakurai-cho, Anjo City, Aichi Prefecture

Claims (2)

[Claims] 1. A storage silo characterized in that, when heat is introduced into a grain storage silo, at least a side wall of the silo is wetted and water is sprinkled so that water flows down from the upper side. Cooling method. 2. A sprinkler for sprinkling water on at least a side wall of a grain storage silo, and a pump for supplying water to the sprinkler.
A cold storage device for a storage silo, comprising: a tank for storing water pumped by the pump, wherein the side wall is wet and the water flows down from the upper part along the side wall.