JP2001261093A - Silo - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a silo wherein existing equipment can be efficiently utilized and a running cost is low and wherein a preserved material can be effectively prevented from being altered, rotted or the like. SOLUTION: The silo includes a silo body 2 for preserving the material A to be preserved comprising grain, its processed good or the like, and a ventilation means 10 for ventilating the inside of an unfilled space 3 on an upper portion of the silo body 2 where the material A is not filled, wherein the means 10 has an intake duct 11 for introducing an atmosphere into the unfilled space 3, an exhaust duct 12 for exhausting air in the space 3 to the outside a blower 13 for forming a flow of air.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a silo for storing an object to be stored, such as a grain or a processed product thereof.

[0002]

2. Description of the Related Art When an object to be stored, such as a grain or a processed product, is stored in a silo main body, if the temperature inside the silo main body is higher than the outside air temperature, dew condensation occurs on the inner wall surface of the silo main body. However, there is a problem in that the stored matter is degraded, decomposed, or fermented by the dew condensation water. Therefore, recently, cold air of 0 to 5 ° C is circulated and supplied into the silo body,
Silos configured to suppress the rise in the temperature of the material to be stored and to solve the above problem have been proposed and put into practical use. Also,
This type of silo also has the secondary effect of removing moisture when cooling the air in the silo body, thereby reducing the humidity in the silo body and preventing condensation. .

[0003]

In the case where cold air at 0 to 5 ° C. is supplied in a circulating manner, deterioration and decay of the stored material can be prevented, but the cool air is circulated into the densely packed stored material. In relation to the supply, a high-output cooling device and a blower are required, and the heat insulation structure of the silo main body becomes large. Therefore, the production cost of the silo and the running cost increase. For this reason, there is a problem in that profits cannot be obtained even if the stored materials are not high value-added materials to be stored.

[0004] It is an object of the present invention to provide a silo that can effectively use existing equipment, has low running costs, and can effectively prevent deterioration and decay of stored materials.

[0005]

The present applicant has focused on the fact that most of the alteration, decay, and fermentation of the stored material in the silo main body occur near the upper surface of the stored material, and the cause thereof is as follows. As a result of intensive studies, dew condensation occurs on the inner wall surface of the silo body facing the unfilled space above the silo body that is not filled with the storage object, and this will drop on the storage object as dew condensation water, or the silo body It was found that the property deteriorated and decayed on the upper surface by descending along the inner wall surface and permeating the object. Then, it was concluded that ventilation of the unfilled space can prevent the production cost and running of the silo and prevent the deterioration and decay of the stored material, thereby inventing the present invention.

[0006] The silo according to claim 1 comprises a silo main body for storing an article to be stored, such as a grain or a processed product thereof.
Ventilation means for ventilating the unfilled space above the silo body that is not filled with the storage material, an intake duct for introducing outside air into the unfilled space, and air in the unfilled space. It is provided with ventilation means having an exhaust duct for discharging to the outside and a blower for forming a flow of air from the intake duct to the exhaust duct through the unfilled space.

In this silo, the temperature difference between the unfilled space and the outside air is reduced by ventilating the unfilled space above the silo body and replacing it with the outside air, thereby reducing the temperature of the silo body facing the unfilled space. The occurrence of dew condensation on the wall surface is prevented. For this reason, it is possible to prevent deterioration of the stored material, decay, and fermentation due to the dew condensation water. In addition, such a ventilation means for ventilating the unfilled space above the silo body can be easily applied to an existing silo by utilizing a manhole or the like for inspection, and furthermore, can be stored. Since air is not passed through the object, the airflow resistance is low, so that a small blower having a small output can be adopted, and the production cost and running cost can be reduced and the blower can be implemented at low cost.

According to a second aspect of the present invention, the opening of the intake duct is opened at a lower part of the unfilled space, and the opening of the exhaust duct is opened at the upper part of the unfilled space. In this case, fresh outside air supplied to the unfilled space from the intake duct is efficiently supplied to the upper surface of the storage object, so that the storage object on the upper surface portion can be maintained in a dry state,
It is possible to effectively prevent deterioration and decay of the stored material. Also,
The intake duct and the exhaust duct are vertically separated from each other, and since the opening of the exhaust duct is not located on the flow path of the outside air introduced from the intake duct to the unfilled space, it flows into the unfilled space from the intake duct. It is possible to prevent the discharged outside air from flowing out of the exhaust duct in a short-circuit manner without sufficiently flowing through the entire unfilled space, and to sufficiently ventilate the unfilled space.

According to a third aspect of the present invention, in the silo, the intake duct and the exhaust duct are assembled in the same manhole, and the opening of the intake duct and the opening of the exhaust duct are spaced from each other in the height direction to form an unfilled space. It is open. When the present invention is applied to an existing silo, an intake duct and an exhaust duct are assembled by utilizing a manhole for inspection, but since the number of manholes itself is limited, two ducts are identical. It is preferable to attach a manhole. In addition, if the openings of both ducts are opened in the unfilled space at an interval in the height direction, the outside air that has flowed into the unfilled space from the intake duct will not flow through the entire unfilled space and will be short-circuited. It is possible to prevent the air from being discharged from the exhaust duct and to sufficiently ventilate the unfilled space.

According to a fourth aspect of the present invention, in the silo, one of the exhaust duct and the intake duct is disposed inside the other duct, the opening of the inner duct is opened at the lower part of the unfilled space, and the outer duct is opened. Is opened above the unfilled space. In this case, it is possible to arrange the exhaust duct and the intake duct by effectively utilizing the limited space of the manhole. Also, since the opening of the inner duct is opened at the lower part of the unfilled space and the opening of the outer duct is opened at the upper part of the unfilled space, the outside air flowing into the unfilled space from the intake duct is not It is possible to prevent short-circuiting from being exhausted from the exhaust duct without sufficiently circulating through the entire filled space, and sufficiently ventilate the unfilled space. The duct arranged inside may be either an exhaust duct or an intake duct.However, since the inner duct is opened in the lower part of the unfilled space, fresh outside air is supplied to the upper surface of the storage object. For efficient supply, it is preferable to arrange the intake duct inside and the exhaust duct outside.

According to a fifth aspect of the present invention, in the silo, the height of the opening of the duct that opens into the lower part of the unfilled space of the intake duct and the exhaust duct is adjustable. Since the height of the storage object fluctuates according to the change in the amount of the storage object input to the silo main body, for example, according to the height of the storage object, for example, the opening of the duct and the storage object are stored. It is preferable to increase the ventilation efficiency of the unfilled space by adjusting the height of the opening of the duct so that the distance between the upper surfaces of the objects is constant.

According to a sixth aspect of the present invention, the intake duct is opened so that the outside air supplied from the intake duct to the unfilled space flows along the inner wall surface of the silo body. In this case, the inside of the unfilled space is stirred by the outside air flowing from the opening of the intake duct, and the air in the entire unfilled space can be efficiently exchanged with the outside air.

According to a seventh aspect of the present invention, the output of the blower is set to an output in which the air in the unfilled space is ventilated at least once in two minutes. The output of the blower is
If the temperature is low, sufficient ventilation is not performed and dew condensation occurs. Therefore, it is preferable that the air in the unfilled space is ventilated at a rate of once or more in two minutes.

[0014]

Embodiments of the present invention will be described below with reference to the drawings. As shown in FIG. 1, the silo 1 includes a silo main body 2 that stores an article A to be stored, such as a grain or a processed product thereof, and a ventilation unit 10 that ventilates an unfilled space 3 of the silo main body 2. Have. However,
Since a plurality of silo main bodies 2 are usually arranged in parallel, a plurality of silo main bodies 2 are assigned to one ventilation means 10 and a necessary silo main body 2 is opened and closed by opening and closing a valve or the like. The outside air may be supplied sequentially.

The silo main body 2 basically includes a substantially cylindrical peripheral wall portion 4, a substantially conical conical portion (not shown) connected to the lower end of the peripheral wall portion 4 and having a diameter reduced downward, and a peripheral wall portion. And a substantially disk-shaped upper wall 5 for closing the upper end of the upper wall 4. An inlet 6 is formed substantially at the center of the upper wall 5, and a plurality of manholes 7 for inspection are formed near the outer periphery of the upper wall 5. The silo main body 2 is installed in a vertical orientation via a plurality of pillars (not shown) standing on the ground.

As shown in FIGS. 1 and 2, the ventilation means 10 has an intake duct 11 for introducing outside air into the unfilled space 3 and an exhaust duct for discharging the air in the unfilled space 3 to the outside. It has a duct 12 and a blower 13 for forming an air flow from the intake duct 11 to the exhaust duct 12 through the unfilled space 3.

The intake duct 11 and the exhaust duct 12 are assembled in the same manhole 7. Intake duct 11
Although it is possible to assemble the and the exhaust duct 12 in separate manholes, it is preferable to assemble them in the same manhole 7 so that they can be easily applied to an existing silo having a small number of manholes.

The lower end opening 14 of the intake duct 11 and the lower end opening 15 of the exhaust duct 12 are opened in the unfilled space 3 with a gap in the height direction. When the intake duct 11 and the exhaust duct 12 are separately arranged in the manholes at distant positions, the outside air flowing from the intake duct 11 is rarely short-circuited and discharged from the exhaust duct 12, but the same manhole 7 is used. When the two ducts 11 and 12 are arranged in the same space, the unfilled space 3 may not be sufficiently ventilated due to a short circuit. Therefore, the lower end opening 14 of the intake duct 11 and the lower end opening 15 of the exhaust duct 12 are at a height. It is preferable that the opening is made as far away as possible in the direction.

The lower end opening 14 of the intake duct 11 is opened in the lower part of the unfilled space 3, and the lower end opening 15 of the exhaust duct 12 is opened in the upper part of the unfilled space 3. With this configuration, fresh outside air supplied from the intake duct 11 can be supplied to the upper surface of the storage object A to prevent deterioration and decay of the storage object A, and unfilled from the intake duct 11 can be prevented. This is preferable because it is possible to prevent the outside air supplied into the space 3 from being discharged from the exhaust duct 12 in a short-circuit manner.

When these are combined, as shown in FIG.
Assemble both ducts 11 and 12 into one manhole 7,
In the most preferred embodiment, the intake duct 11 is opened in the lower part of the unfilled space 3 and the exhaust duct 12 is arranged in the upper part of the unfilled space 3.

The intake duct 11 is provided with a hood 16 for preventing intrusion of rainwater and the like, and in the middle of the intake duct 11, dust and dust, rats and insects enter the silo body 2. A filter 17 for regulating is provided, and the filter 17 is configured so that outside air is purified and introduced into the unfilled space 3.

A blower 13 is connected to the exhaust duct 12 outside the silo main body 2, and the air in the exhaust duct 12 is discharged to the outside by the blower 13 so that fresh outside air is introduced from the intake duct 11. It is configured. However, a blower fan may be provided as a blower in the intake duct 11 outside the silo main body 2 and the outside air may be sent into the intake duct 11 by the blower fan. The filling space 3 may be ventilated.

The output of the blower 13 is set in accordance with the size of the silo body 2 and the size of the unfilled space 3, but the air in the unfilled space 3 is ventilated at a rate of at least once in 2 minutes. It is preferable to select one with such an output. In addition, the blower 13 may be operated manually or automatically. If you want it to work automatically,
It may be operated periodically, or a sensor for measuring the temperature in the unfilled space 3 and the outside air temperature may be provided, and the sensor may be operated when the temperature in the unfilled space 3 is higher than the outside air temperature.

In the silo 1, the air in the unfilled space 3 is discharged to the outside through the exhaust duct 12 by the blower 13, so that the outside air is introduced from the intake duct 11 and the inside of the unfilled space 3 is ventilated. Is done. Then, since the outside air temperature is adjusted to be substantially the same as that of the unfilled space 3, the occurrence of dew condensation on the inner wall portion of the silo body 2 facing the unfilled space 3 is prevented. Corrosion can be effectively prevented.

Next, another embodiment in which the structure of the silo 1 is partially changed will be described. (1) Like the ventilation means 10A shown in FIG. 3, the intake duct 11A is arranged inside the exhaust duct 12A, the lower end opening 15A of the exhaust duct 12A is opened in the upper part of the unfilled space 3, and the intake duct 11A May be opened in the lower part of the unfilled space 3. In this case, the opening areas of both ducts 11A and 12A are preferably set to be the same, but may be set to different cross-sectional areas. Further, the intake duct 11A may be disposed at the center of the exhaust duct 12A or may be disposed at an eccentric position. Further, a partition wall may be provided inside the duct to form an exhaust duct and an intake duct. Ventilation means 1 having such a configuration
At 0A, both ducts 11A and 12A can be arranged by sufficiently utilizing the inner space of the manhole 7, so that the cross-sectional area of both ducts 11A and 12A can be set as large as possible. In addition, the intake duct 12A and the exhaust duct 12B are arranged inside and outside reversed, the lower end opening of the intake duct is opened in the upper part of the unfilled space 3, and the lower end opening of the exhaust duct is placed in the lower part of the unfilled space 3. It is possible to open it,
Since fresh outside air can be more effectively blown to the storage object A, it is preferable to configure as described above.

(2) Intake duct 11 shown in FIGS. 4 and 5
As shown in FIG. 4B, in order to increase the agitation property of the air in the unfilled space 3 and to increase the ventilation efficiency, the outside air flowing from the intake duct 11B flows in the unfilled space 3 as shown by arrows in FIG.
It is preferable to form the lower end opening 14B of the intake duct 11B so as to form a spiral. Specifically, as shown in the figure, a bent portion 20 extending in the circumferential direction of the silo main body 2 is formed at a lower end portion of the intake duct 11B, and an opening 14B is formed in the bent portion 20, or the intake duct 11B is formed. The lower ends of 11, 11A are closed to form openings on the side surfaces.

(3) The intake ducts 11, 11A, 1
1B is divided into two upper and lower parts and connected elastically, and an actuator including a cylinder and an electric motor for driving the expansion and contraction is provided. The length may be adjusted so that the opening and the lower end opening of the exhaust duct are separated as much as possible. For example, the intake duct may be expanded and contracted so that the distance between the lower end opening of the intake duct and the upper surface of the storage object is constant.
When the exhaust duct is opened at the lower part of the unfilled space 3, the exhaust duct is configured to be expandable and contractible.

[0028]

According to the first aspect of the present invention, by providing ventilation means having a simple structure to the silo body, the temperature difference between the unfilled space and the outside air is reduced, and It is possible to prevent the occurrence of dew condensation on the inner wall surface of the silo body facing, and it is possible to prevent the deterioration, decay, and fermentation of the stored material due to the dew water. In addition, the ventilation means for ventilating the unfilled space above the silo body,
It can be easily applied to existing silos by utilizing inspection manholes, etc. In addition, since air does not pass through the storage object, ventilation resistance becomes small, so blowers As a result, a small-sized one having a small output can be adopted, and the manufacturing cost and the running cost can be reduced and the cost can be reduced.

When the opening of the intake duct is opened at the lower part of the unfilled space and the opening of the exhaust duct is opened at the upper part of the unfilled space, the air is supplied from the intake duct to the unfilled space. The stored outside air can be efficiently supplied to the upper surface of the object to be stored, and deterioration and decay of the object to be stored can be prevented. In addition, the intake duct and the exhaust duct are vertically separated from each other, and the opening of the exhaust duct is not located on the flow path of the outside air introduced from the intake duct to the unfilled space. It is possible to prevent the outside air that has flowed into the space from being short-circuited and discharged from the exhaust duct, and to sufficiently ventilate the unfilled space.

When the intake duct and the exhaust duct are assembled in the same manhole, the present invention can be applied to existing silos having a small number of manholes without difficulty. Also, when the opening of the intake duct and the opening of the exhaust duct are opened in the unfilled space with a gap in the height direction, the outside air flowing into the unfilled space from the intake duct is discharged from the exhaust duct in a short-circuit manner. And the ventilation efficiency in the unfilled space can be improved.

When one of the exhaust duct and the intake duct is disposed inside the other of the exhaust duct and the intake duct, the limited space of the manhole is efficiently used to connect the exhaust duct and the intake duct. It becomes possible to arrange. Also, if the opening of the inner duct is opened at the lower part of the unfilled space and the opening of the outer duct is opened at the upper part of the unfilled space, the outside air flowing into the unfilled space from the intake duct will be short-circuited. It is possible to prevent the air from being exhausted from the exhaust duct and improve the ventilation efficiency in the unfilled space.

According to a fifth aspect of the present invention, when the height of the opening of the duct that opens into the lower part of the unfilled space of the intake duct and the exhaust duct is adjustable, the height of the storage object can be changed. Since the height position of the duct can be adjusted accordingly, the ventilation efficiency of the unfilled space can be increased.

According to a sixth aspect of the present invention, when the intake duct is opened so that the outside air supplied from the intake duct to the unfilled space flows along the inner wall surface of the silo body, the air in the entire unfilled space is efficiently used. It is possible to exchange well with the outside air.

When the ventilation capacity of the blower is set such that the air in the unfilled space is ventilated at least once in two minutes, the occurrence of dew condensation can be effectively prevented.

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram of an upper half of a silo.

FIG. 2 is a vertical cross-sectional view of the vicinity of ventilation means.

FIG. 3 is a longitudinal sectional view around a ventilation means of another configuration.

FIG. 4 is an explanatory diagram showing the flow of air in an intake duct having another configuration.

FIG. 5 is a perspective view near the lower end of the intake duct.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Silo 2 Silo main body 3 Unfilled space 4 Peripheral wall part 5 Upper wall part 6 Input port 7 Manhole 10 Ventilation means 11 Intake duct 12 Exhaust duct 13 Blower 14 Lower opening part 15 Lower opening part 16 Hood 17 Filter 10A Ventilation means 11A Intake duct 12A Exhaust duct 14A Lower end opening 15A Lower end opening 11B Intake duct 14B Lower end opening 14B Opening 20 Bent part A Stored object

 ──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Tadashi Hasegawa 2-352-9 Matsugaoka, Nagareyama-shi, Chiba Prefecture (72) Inventor Kohei Kasai 8-22-16-103 F-term (reference) 8-22-16-103, Inage-ku, Chiba-shi, Chiba 2B100 AA02 BB06 GA12 3E070 AA19 AA21 AB13 BF01 BF08 EB01 VA30 WF13 WF17 WF18

Claims (7)

[Claims] 1. A silo body for storing an object to be stored, such as a grain or a processed product thereof, and ventilation means for ventilating an unfilled space above a silo body not filled with the object to be stored. There is an intake duct for introducing outside air into the unfilled space, an exhaust duct for discharging air in the unfilled space to the outside, and air from the intake duct to the exhaust duct through the unfilled space. And a ventilation means having a blower for forming a flow of the silo. 2. The silo according to claim 1, wherein an opening of the intake duct is opened at a lower part of the unfilled space, and an opening of the exhaust duct is opened at an upper part of the unfilled space. 3. The air intake duct and the exhaust duct are assembled in the same manhole, and the opening of the intake duct and the opening of the exhaust duct are opened in the unfilled space at an interval in the height direction. The silo according to 2. 4. An exhaust duct and an intake duct, wherein the other duct is disposed inside one of the ducts, the opening of the inner duct is opened at the lower part of the unfilled space, and the opening of the outer duct is unfilled. The silo according to any one of claims 1 to 3, wherein the silo is opened in an upper part of the space. 5. The silo according to claim 1, wherein a height of an opening of the duct that opens into a lower part of the unfilled space of the intake duct and the exhaust duct is adjustable. 6. An external air supplied from the intake duct to an unfilled space flows along an inner wall surface of the silo main body.
The silo according to any one of claims 1 to 5, wherein the intake duct is opened. 7. The silo according to claim 1, wherein an output of said blower is set to an output at which air in an unfilled space is ventilated at a rate of one or more times in two minutes.