KR102180822B1 - Grain storage - Google Patents

Abstract

A grain storage facility according to the present invention comprises: a wall portion constituting a wall of a storage warehouse for storing grains such as rice; a support member for supporting the wall portion; a ceiling portion constituting the ceiling of the storage warehouse; an opening and closing door installed on the wall portion; a temperature control device for controlling a temperature inside the storage warehouse; and a lighting member installed on the ceiling portion. The wall portion includes: a lower wall portion buried in the ground; and an upper wall portion installed on an upper portion of the lower wall portion. The lower wall portion is formed of stone or concrete to be buried into the ground at a predetermined depth. The upper wall portion includes a pair of surface members disposed facing each other and a heat insulating member disposed between the surface members. The support member has an upper wall portion protection member protruding from the support member toward the interior, and the surface member disposed in the interior side of the upper wall portion has a concave portion and a convex portion formed therein. A bonding force with the ground is increased, so that durability against earthquakes and vibrations is increased, the degree of deformation due to drafts is reduced, insulation efficiency is increased to increase cooling and heating energy efficiency, and the invasion of harmful animals such as rats is prevented.

Description

Grain storage facility {GRAIN STORAGE}

The present invention relates to a grain storage facility, and in more detail, heat insulation efficiency is increased, cooling and heating energy efficiency is increased, and durability against earthquakes and vibrations is increased by increasing cohesion with the ground, and invasion of harmful animals such as rats. The invention relates to a grain storage facility configured to prevent.

In general, the harvesting period for agricultural crops in Korea is limited to autumn, and grains such as rice harvested in autumn are peeled through threshing, punggu, and milling, and then dried in a bag and stored in a grain storage facility. It is stored for a certain period before harvest the following year.

On the other hand, it is relatively easy to store and manage grain in winter when the temperature is low, but when the temperature of the grain storage facility rises in spring and summer, the respiration of the grain itself increases and the increased respiration causes fever, so the temperature and moisture of the grain As the content increases, the grains are spoiled or spoiled due to physical and chemical changes in the grains.

In addition, in the process of packing the grain bag, the larvae or eggs of insects are mixed into the inside of the bag. As the temperature of the grain storage facility increases, the propagation of pests becomes active, so the propagation of the insects in the grain storage facility is prevented. Cold storage methods are used to prevent and supply high-quality grain to consumers.

Low temperature storage is a method of storing and storing grains by lowering the temperature inside the grain storage facility to a low temperature of about 14℃. It suppresses the respiration of grains to prevent the consumption of ingredients contained in the grains, and the growth of perishable bacteria. And, by preventing the physical and chemical changes of the grain, it is possible to maintain the quality of the grain in the harvest season at high quality.

However, in the conventional grain storage facility, when the outside temperature rises above a certain temperature, heat is transferred through the walls and bottom of the grain storage facility, so that the temperature of the upper and lower layers of the grain storage facility rapidly rises, and cold air is supplied. Even if a blower for this is installed, there is a problem in that cold air is not circulated evenly in the grain storage facility, so that grains receiving cold air are subcooled, and grain quality is deteriorated.

On the other hand, in the grain storage facility, there is a lot of loss of grain due to rats.Since the number of populations increases exponentially within a short time due to the excellent reproductive power of rats, it is most important to prevent the invasion of rats into the grain storage facility, but to prevent the invasion of rats. The conventional technique is to use a trap, such as a mouse trap, which attracts rats and traps them in a confined space, and the application of the above technique is inappropriate in a grain storage facility, which is a large facility.

Accordingly, there is a need for a grain storage facility capable of increasing insulation efficiency, securing seismic performance in case of an earthquake, and preventing damage caused by invasion of rats.

The present invention has been conceived to solve the above-described problems, and an object of the present invention is to provide a grain storage facility configured to increase the strength of the wall and improve the insulation performance.

Another object of the present invention is to provide a grain storage facility configured to increase the insulation effect and prevent the invasion of pests and mice by forming a ground contact portion at the lower end of the opening door, blocking the space between the opening door and the floor surface Is to do.

Another object of the present invention is that by forming concave portions extending in the horizontal direction in the portion buried in the ground of the lower wall portion, the coupling force between the lower wall portion and the ground is increased, thereby increasing durability against earthquakes and vibrations. It is to provide grain storage facilities.

Another object of the present invention is to prevent the buckling of the support member by being installed coupled to the support member in the form of a grid-shaped upper wall, and when the grain bags loaded and stored in the central part of the grain storage facility are inverted toward the upper wall part. In addition, it is to provide a grain storage facility that is configured to reduce damage from damage to the upper wall.

Another object of the present invention is to circulate by symmetrically supplying cold or warm air from the top and bottom of the grain storage facility by symmetrically installing a ventilation member on the ceiling and the bottom based on the center of the grain storage facility. It is to provide a grain storage facility configured to prevent degradation of grain quality by reducing the temperature deviation of the upper and lower layers of the grain storage facility.

Another object of the present invention is to provide a grain storage facility configured to prevent condensation caused by a temperature difference between the inside and the outside of the grain storage facility.

The grain storage facility according to the present invention for achieving the above object comprises a wall part constituting a wall of a storage warehouse for storing grains such as rice, a support member for supporting the wall part, and a ceiling of the storage warehouse. A ceiling and an opening and closing door installed on the wall, a temperature control device for controlling a temperature inside the storage warehouse, and a lighting member installed on the ceiling, wherein the wall part includes a lower wall part and the lower wall embedded in the ground. It includes an upper wall part installed on the upper part of the part, the lower wall part is formed of stone or concrete to be buried in a predetermined depth underground, and the upper wall part is between a pair of surface members disposed facing each other and the surface members It is formed including a heat insulating member disposed on the support member, the upper wall protection member is installed protruding from the support member to the indoor side, and the surface member disposed on the indoor side from the upper wall portion has a concave portion and a convex portion It is characterized in that it is formed.

Preferably, the opening and closing door includes a first door configured to slide in a horizontal direction along a rail and a second door configured to move in a vertical direction, and a ground contact portion is formed at a lower end of the second door.

Here, the first door is formed of a metal material, a ground contact portion is formed at a lower end facing the rail, and the second door is formed of a synthetic resin material.

In addition, a concave portion and a convex portion are formed on a surface facing the heat insulating member in the surface member disposed on the outdoor side of the upper wall portion.

In addition, a concave portion and a convex portion are formed on a surface facing the heat insulating member in a surface member disposed indoors in the upper wall portion.

In addition, a contact preventing protrusion may be formed on a surface of the upper wall portion facing the heat insulating member.

In addition, horizontal concave portions are formed in a portion of the lower wall portion buried in the ground, and concave portions are formed in a vertical direction in a portion protruding to the ground.

Here, a grid-shaped recessed portion may be formed in a portion of the lower wall portion buried in the ground.

In addition, spaces having a cylindrical shape or a hexagonal cross section may be formed in a portion of the lower wall portion buried in the ground.

On the other hand, it further includes a rat intrusion prevention member disposed under the opening door, wherein the rat intrusion prevention member prevents lateral movement formed at predetermined intervals on the base portion and the inclined surface member formed inclined from the base portion and the inclined surface member Including absence.

Here, the base portion is formed protruding from the lateral movement preventing member by a predetermined width.

Meanwhile, a third door made of a synthetic resin material may be installed opposite the second door with respect to the first door, and the third door may be configured to move in a vertical direction.

In addition, the temperature control device includes an outdoor unit and a blowing member for blowing cold air or hot air transmitted from the outdoor unit into the storage facility, and the blowing member includes a ceiling and a bottom part based on the center of the storage facility. Are installed symmetrically to each other.

In addition, an air passage in the form of a concave portion may be formed at the bottom of the storage facility.

Here, the air flow path is formed as a grid-shaped recess.

Meanwhile, the support member is formed of an H-beam, and the upper wall portion protection member is formed in a grid shape using a steel pipe, and is installed on the H-beam.

Here, the upper wall protection member is installed on the H-beam via an elastic member.

In addition, the elastic member includes an elastic member on the support member side located on the H-beam side and the frame side elastic member located on the upper wall protection member side, and the surface of the elastic member on the support member side has a concave-convex shape. A portion and a convex portion may be formed, and a concave portion and a convex portion having a concave-convex shape may be formed on a surface of the frame-side elastic member to engage the concave portion and the convex portion of the supporting member-side elastic member.

In addition, the lighting members are installed at the center and the edge of the ceiling, and the number per unit area of the lighting members installed at the edge is larger than the number per unit area of the lighting members installed at the center.

Meanwhile, a second door receiving portion for accommodating the second door may be formed with a predetermined depth on the surface facing the second door.

In addition, a rat intrusion prevention panel is installed in a portion of the upper wall portion through which a pipe connecting the outdoor unit and the blowing member passes, and a convex portion is formed on the surface facing the upper wall portion in the rat intrusion prevention panel. It occludes with the wall part.

According to the present invention, the strength of the wall portion is increased and the heat insulation performance is improved, so that energy required for operation of a grain storage facility can be reduced.

In addition, a ground contact portion is formed at the lower end of the opening and closing door to block the space between the opening and closing door and the floor, thereby increasing the insulating effect and preventing the invasion of pests and mice, thereby preventing loss of grain.

In addition, by forming concave portions extending in the horizontal direction in a portion buried in the ground of the lower wall portion, the coupling force between the lower wall portion and the ground is increased, so that durability against earthquakes and vibrations can be increased.

In addition, the grid-shaped upper wall protection member is coupled to the support member to prevent buckling of the support member, and even when the grain bags loaded and stored in the central part of the grain storage facility are transferred to the upper wall part, the upper wall part is damaged. Can be prevented.

In addition, the ventilation members are symmetrically installed on the ceiling and the bottom based on the center of the grain storage facility, thereby symmetrically supplying cold or warm air from the top and bottom of the grain storage facility to facilitate circulation, and to store grain. By reducing the temperature difference between the upper and lower layers of the facility, it is possible to prevent the degradation of grain quality.

In addition, by preventing condensation caused by a temperature difference between the inside and outside of the grain storage facility, damage caused by moisture can be prevented.

The accompanying drawings are for understanding the technical idea of the present invention together with the detailed description of the present invention, and the present invention should not be construed limited to the matters shown in the drawings.
1 is an overall view for explaining a grain storage facility according to a preferred embodiment of the present invention,
2 is a perspective view of the first door included in the opening and closing door installed in the grain storage facility,
3 is a front view of the vertical opening and closing door included in the opening and closing door,
4 is a perspective view showing a state in which the door receiving portion is formed on the ground facing the vertical opening and closing door,
5 is a plan view of the opening and closing door,
6 is an exploded perspective view of an upper wall part included in a wall part installed in the grain storage facility,
7 is an exploded perspective view of the upper wall portion according to another embodiment,
8 is a perspective view of a lower wall part included in the wall part,
9 is a perspective view of a lower wall body according to another embodiment of the present invention,
10 is a perspective view (a) and a side view (b) of the rodent intrusion prevention member included in the grain storage facility,
11 is a side cross-sectional view of the grain storage facility,
12 is a plan view of the floor included in the grain storage facility,
13 is a plan view of the grain storage facility,
14 is a perspective view of an upper wall protection member coupled with a support member installed in the grain storage facility,
15 is a plan view showing a state in which the support member and the upper wall protection member are connected and coupled,
16 is an exploded view showing the coupling method of the support member and the upper wall protection member,
17 is a perspective view of a rat intrusion prevention panel included in the grain storage facility.

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings.

Prior to this, terms used in the present specification and claims should not be construed as limited in a dictionary meaning, and based on the principle that the inventor can appropriately define the concept of terms in order to describe his invention in the best way. , It should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

Accordingly, the embodiments described in the present specification and the configurations shown in the drawings are only preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, and various equivalents that can replace them at the time of the present application It should be understood that water and variations may exist.

1 is an overall view for explaining a grain storage facility according to a preferred embodiment of the present invention, FIG. 2 is a perspective view of a first door included in an opening and closing door installed in the grain storage facility, and FIG. 3 is the opening and closing door It is a front view of the vertical opening and closing door included in

4 is a perspective view showing a state in which a door receiving part is formed on the ground facing the vertical opening and closing door, FIG. 5 is a plan view of the opening and closing door, and FIG. 6 is an upper part included in the wall installed in the grain storage facility An exploded perspective view of a wall part, FIG. 7 is an exploded perspective view of the upper wall part according to another embodiment, FIG. 8 is a perspective view of a lower wall part included in the wall part, and FIG. 9 is a lower wall according to another embodiment of the present invention. A perspective view of the lower part, FIG. 10 is a perspective view (a) and a side view (b) of a rat intrusion prevention member included in the grain storage facility, FIG. 11 is a side cross-sectional view of the grain storage facility, and FIG. 12 is the grain storage facility 13 is a plan view of the grain storage facility, FIG. 14 is a perspective view of an upper wall protection member coupled with a support member installed in the grain storage facility, and FIG. 15 is a view showing the support member and the It is a plan view showing a state in which the upper wall protection member is connected and coupled, FIG. 16 is an exploded view showing the coupling method of the support member and the upper wall protection member, and FIG. 17 is a rat intrusion prevention panel included in the grain storage facility Is a perspective view of.

1 and 6, the grain storage facility according to the present invention includes a wall portion 10 constituting a wall of a storage warehouse for storing grains such as rice and a support member for supporting the wall portion 10 (20) And the ceiling part 30 constituting the ceiling of the storage warehouse, the opening and closing door 40 installed in the wall part 10, and a temperature control device 50 for controlling the temperature inside the storage warehouse, and the Including a lighting member 60 installed on the ceiling 30, the wall portion 10 is a lower wall portion 12 buried in the ground and an upper wall portion 16 installed above the lower wall portion 12 ), and the lower wall part 12 is formed of stone or concrete to be buried in the ground at a predetermined depth, and the upper wall part 16 is a pair of surface members 162 and 164 disposed facing each other. ) And a heat insulating member 166 disposed therebetween, and the support member 20 has an upper wall part protection member 70 protruding from the support member 20 toward the interior, and the upper wall body In the portion 16, the surface member 162 disposed on the indoor side has a concave portion and a convex portion.

As shown in Fig. 1, in the grain storage facility for low-temperature storage of grain and prevention of rat invasion, a support member 20 is installed in a vertical direction along the inner surface of the wall part 10 of the grain storage facility. 10 is supported, and a wall portion 10 is coupled to one side (outer surface) of the support member 20, and an upper wall protection member 70 is installed on the other side (inner surface).

The support member 20 may preferably be formed of an H-beam having a "H" shape in cross section.

In addition, at the upper end of the support member 20 installed in the vertical direction, the support member 20 is connected and installed along the inner surface of the ceiling 30 in a horizontal direction, so that the wall portion 10 and the ceiling 30 are supported by the It is supported by member 20.

In addition, the grain storage facility includes a temperature control device 50 for controlling the internal temperature, and the temperature control device 50 includes, for example, an outdoor unit 55 and the outdoor unit for generating cold or warm air. It may include a blowing member 53 for sending cold air or warmth transmitted from the device 55 to the inside of the grain storage facility.

The blowing member 53 is configured to include a blowing fan, and is configured to blow cold air or warm air by supplied power.

Here, the outdoor unit 55 and the indoor blowing member 53 are connected by a pipe 59, so that cold air or warmth is transmitted from the outdoor unit 55 to the indoor air blowing member 53 through the pipe 59. By being supplied to, it is possible to control the temperature of the grain storage facility.

In addition, an opening and closing door 40 is installed in the wall portion 10 of the grain storage facility so that a worker or vehicle can enter and exit.

The opening/closing door 40 is formed as a triple door, and the opening/closing door 40 includes a first door 42 configured to slide in a horizontal direction along a rail, and the first door 42 It includes a pair of vertical opening and closing doors 45 arranged in the front and rear.

Here, the vertical opening/closing door 45 includes a second door 44 installed on the indoor side from the first door 42, and a third door 46 installed on the outdoor side from the first door 42. ).

The first door 42 may preferably be formed of a metal material, and as shown in FIG. 2, the first door 42 moves in the horizontal direction on the bottom surface facing the lower surface of the first door 42 A rail 420 is installed along for guiding it.

In addition, the first door 42 is coupled to slide along the rail 420 while the wheel 421 is installed on the bottom surface of the first door 42, so that the first door 42 may slide in a horizontal direction.

In addition, a ground contact portion 422 is formed at the lower end of the first door 42 to prevent the inflow of outdoor air, thereby improving the insulation effect, and also preventing the inflow of pests.

In addition, it is possible to prevent rats from entering and exiting through the space between the first door 42 and the floor surface by the ground contact portion 422.

The vertical direction opening and closing door 45 is preferably formed of a synthetic resin material, and as shown in FIG. 3, the vertical direction opening and closing door 45 is connected to the driving unit 444 installed on the upper side by a wire 446, etc. As a result, it can be operated in a manner that opens and closes in a vertical direction.

In addition, since the ground contact portion 442 is also formed at the lower end of the vertical opening and closing door 45, it is possible to prevent the inflow of outdoor air to increase the insulation effect, and to prevent entry of pests and mice.

In addition, as shown in FIG. 4, a door receiving portion 204 capable of accommodating the vertical opening and closing door 45 may be formed at a predetermined depth on the surface facing the vertical opening and closing door 45. have.

Thus, by inserting the lower portion of the vertical opening and closing door 45 into the door receiving portion 204, the heat insulating effect through the vertical opening and closing door 45 is increased, and the rat is prevented from the vertical opening and closing door 45 It is possible to prevent intrusion into the grain storage facility through the space between the lower part and the ground.

The opening and closing door 45 is formed of a triple door including a first door 42 made of a relatively heavy metal material and a second door 44 and a third door 46 made of a light synthetic resin material.

Here, the first door 42 is configured to slide in a horizontal direction by human attraction, and the second door 44 and the third door 46 are driven vertically by a motor by power supply. .

Thus, the first door 42 secures strength as a structure, and at the same time, an air layer is formed between the doors 42, 44, and 46, thereby enhancing thermal insulation performance.

In addition, it is configured to increase the insulation performance through the ground contact portions 422 and 442 formed at the lower ends of the doors and more completely prevent the invasion of pests and mice.

In addition, the first door 42 is opened in a horizontal direction and the second door 44 and the third door 46 are opened and closed in a vertical direction, so that the first door 42 is opened. In a state in which the vertical opening and closing doors 44 and 46 are opened or closed, the first door 42 may be opened and closed while the vertical opening and closing doors 44 and 46 are open.

Accordingly, it is possible to select and drive the door to be opened or closed according to the operator, vehicle, or season entering and leaving the opening/closing door 40.

On the other hand, the wall portion 10 constituting the wall of the grain storage facility includes an upper wall portion 16 and a lower wall portion 12, and the upper wall portion 16 is formed of the lower wall portion 12. It is installed on the top.

As shown in Fig. 6, the upper wall portion 16 includes an outer surface member 164 and an inner surface member 162, and a heat insulating member 166 disposed therebetween.

The outer surface member 164 and the inner surface member 162 include a plurality of recesses (1642, 1622) and protrusions (1644, 1624) extending in the height direction of the upper wall part (16). It is formed alternately along the horizontal direction of (16).

And, the heat insulating member 166 is disposed between the outer surface member 164 and the inner surface member 162, so that the outer surface member 164 and the inner surface member 162 on the heat insulating member 166 The concave portions 1642 and 1622 are configured to be in contact with each other.

Thus, the concave portions 1622 and 1642 formed in the surface members 162 and 164 are in contact with the heat insulating member 166, so that the heat insulating member is compared with the case where the surface members 162 and 164 are simply formed in a flat plate shape. The contact area between the 166 and the surface members 162 and 164 may be significantly reduced.

In addition, an air layer is formed on the convex portions of the surface members 162 and 164 to serve as an insulating layer, so that a heat transfer rate between indoor and outdoor air can be reduced.

In addition, the concave portions 1622 and 1642 and the convex portions 1624 and 1644 of the surface members 162 and 164 serve as a kind of corrugation, thereby increasing the support strength of the surface members 162 and 164, As a result, the support strength of the upper wall portion 16 is improved.

The upper wall portion 16 of another embodiment of the present invention, as shown in Figure 7, the surface members (162, 164) of the upper wall portion 16, a plurality of contact preventing protrusions ( 165 may be formed toward the heat insulating member 166.

The contact prevention protrusion 165 may be formed of, for example, a metal rod or a square cross-section pipe, and the contact area between the surface member 162 and the heat insulating member 166 may be reduced.

In addition, by forming an air layer between the surface members 162 and 164 and the heat insulating member 166, the insulating effect and support strength of the upper wall portion 16 may be increased.

The lower wall part 12 is preferably formed of concrete, and includes a lower wall upper part 124 which is a part protruding to the ground and a lower wall lower part 122 which is a part buried in the ground.

As shown in FIG. 8, a plurality of concave portions 1242 formed in the height direction are formed along the horizontal direction on the outer surface of the lower wall upper portion 124.

In addition, a plurality of concave portions 1221 and convex portions 1222 formed in a horizontal direction are formed in the lower wall portion 122.

The lower wall upper portion 124 protruding to the ground is formed with a concave portion 1242 in the vertical direction on the outer wall surface, thereby preventing rats from climbing up the wall portion 10 and entering the grain storage facility. have.

In addition, the convex portions 1243 formed on the lower wall upper portion 124 may serve as reinforcing ribs, thereby increasing the support strength of the lower wall upper portion 124.

Widths w1 and w2 of the concave portion 1242 and the convex portion 1243 formed in the upper portion of the lower wall 124 are formed in a range of about 3 cm to 5 cm.

Thus, the concave portion 1242 and the convex portion 1243 formed in the lower wall upper portion 124 formed in a relatively narrow range are configured so that it is difficult to hit the surfaces of the concave portions 1243 and climb upwards.

In addition, the concave portion 1221 and the convex portion 1222 formed in the lower wall portion 122 increase the bonding force with the ground, and an effect of buffering vibration may be exhibited.

In addition, since the soil of the ground is filled inside the horizontal concave portion 1221 of the lower wall lower portion 122, the contact area between the lower wall load portion 122 and the ground is increased.

Thus, when a strong external force such as a typhoon is applied, the external force or vibration applied from the upper wall portion 16 is dissipated as thermal energy due to the frictional action between the lower wall portion 122 and the ground, thus supporting the external force. Strength can be increased.

In addition, since vibration energy transmitted from an earthquake or the like may be dissipated as heat energy due to a frictional action between the lower wall body 122 and the ground, damage caused by an earthquake may be reduced.

In the lower wall portion 122 according to another embodiment of the present invention, as shown in FIG. 9(a), a grid-shaped concave portion 1223 and a convex portion 1224 are formed along the longitudinal and transverse directions. It is formed alternately to form a matrix.

Thus, by the concave portion 1223 and the convex portion 1224, the support force that the wall portion 10 receives from the ground is increased, and the vibration generated in the wall portion 10 due to drafts and earthquakes is reduced. I can.

In the lower wall portion 122 of another embodiment, as shown in FIG. 9(b), a plurality of cylindrical spaces 1226 are formed on the outer wall surface of the lower wall body 122, and the cylinder By filling the inside of the shaped space 1226 with soil, the supporting force and vibration reduction effect of the wall portion 10 may be improved.

On the other hand, the honeycomb structure is a stable structure that is strong against bending or compression, and as shown in FIG. 9(c), a plurality of hexagonal-shaped spaces 1228 on the outer wall surface of the lower wall body 122 are formed in a honeycomb structure. By forming with, it is possible to form a stable structure while significantly reducing the amount of concrete for forming the lower wall (122).

In addition, since the soil of the ground is accommodated in the hexagonal space, the vibration reduction effect can be increased while the lower wall load part 122 is stably coupled to the ground.

Meanwhile, as shown in FIG. 10, a rat intrusion prevention member 80 may be disposed under the second door 44, and the rat intrusion prevention member 80 includes a base portion 81 and the base portion. It includes an inclined surface member 82 formed to be inclined from 81 and a lateral movement preventing member 84 formed on the inclined surface member 82 at predetermined intervals.

As shown in Figure 10 (b), the base portion 81 included in the rat intrusion preventing member 80 is formed to protrude forward by a predetermined width than the lateral movement preventing member 84, 2 When the door 44 is closed, the base portion 81 is formed to be inserted between the lower end of the second door 44 and the ground.

Thus, the portion of the lateral movement preventing member 84 comes into contact with the front portion of the second door, and the base portion 81 is configured to fill the gap at the lower end of the second door 44.

The width of the lateral movement preventing member 84 may be slightly larger than the width of the second door 44.

In addition, the inclined surface member 82 is formed to be inclined toward the second door 44, and thus is configured to prevent a rat from climbing along the inclined surface member 82.

In addition, the lateral movement preventing member 84 is installed inside the inclined surface member 82 at predetermined intervals, so that the rat can be prevented from moving in the transverse direction along the interior of the inclined surface member 82.

Thus, when the second door 44 is closed, the rat intrusion preventing member 80 is disposed on the front side of the second door 44, so that the rat can be moved through the space between the lower end of the second door 44 and the ground. It can prevent intrusion into grain storage facilities.

On the other hand, the temperature control device 50 is the outdoor unit device 55 and a pipe 59 for transmitting cold air or hot air from the outdoor unit device 55 to the blowing member 53, and from the outdoor unit device 55 It includes a blower member 53 for blowing transmitted cold air or warmth into the storage facility.

Here, the blowing member 53 included in the temperature saving device 50 may be installed at a mutually symmetrical position in the ceiling 30 and the bottom 2 with respect to the center C of the grain storage facility. have.

For example, based on FIG. 11, which is a side view of a grain storage facility, a ceiling blowing member 51 is installed on the right side of the ceiling 30, a bottom blowing member 52 is installed on the left side of the floor, and By being configured to blow air facing each other in a state in which the air blowing member 51 of the ceiling is installed on the upper side and the floor blowing member 52 is installed on the lower side based on FIG. 13 which is a plan view of the grain storage facility, With respect to the central portion (C) of the grain storage facility can be supplied to circulate cold or warm in a counterclockwise direction.

Thus, by increasing the circulation efficiency of the cold or hot air flowing by the blowing member 53 to reduce the temperature difference between the upper and lower layers of the grain storage facility, the quality of the grain is prevented from deteriorating, and the grain storage It can improve the cooling and heating efficiency of the facility.

On the other hand, in a general grain storage facility, grain sacks are loaded in the loading area (a) at the center of the bottom part (2) shown in FIG. 12, and the outside of the loading area (a) serves as a passage for people. It becomes a passage area (b).

However, among the grain sacks loaded in the loading area (a), the grain sacks arranged in the center thereof are surrounded by other grain sacks in all directions, so that the cold air from the blowing member 53 cannot be sufficiently supplied. there is a problem.

Accordingly, in the present invention, by forming the concave portions 202 having a depth of approximately 1 cm to 3 cm in the bottom portion 2 in a grid shape, the concave portions 202 are configured to serve as air channels.

Thus, the cold air discharged from the blowing member 53 is evenly supplied to the entire bottom portion 2 along the air flow path, so that the cold air can reach the grain bag located at the center of the loading area (a).

And, when the grain bag is loaded high in the loading area (a), the light irradiated from the lighting member 60 installed in the ceiling 30 is interfered by the grain bag loaded in the loading area (a), the There is a problem that it is not sufficiently transmitted to the passage area (b).

In addition, there is a problem in that the heat generated from the lighting member 60 installed in the ceiling 30 is transferred to the grain bags loaded in the loading area (a), thereby increasing the temperature of the grain.

In order to solve this problem, in the present invention, as shown in FIG. 13, the edge portion of the ceiling portion 30 is more than the number per unit area of the lighting member 60 installed in the center of the ceiling portion 30. It is configured to have a large number per unit area of the lighting member 60 to be installed.

That is, the lighting member 60 is installed more closely at the edge of the ceiling 30 than at the center thereof.

Thus, it is configured to reduce the heat energy received by the grain bag in the loading area (a) and improve visibility in the passage area (b) to secure a worker's view and prevent safety accidents.

On the other hand, in order to prevent the wall part 10 from being damaged when the grain bag that is loaded high in the loading area (a) is inverted toward the wall part 10, the grid-shaped upper wall protecting member 70 Is coupled to the inner surface of the support member 20.

The support member 20 may be formed of an H-beam, and is supported on the outer surface of the support member 20 in a state in which the wall portion 10 is in contact, and a steel pipe is provided on the inner surface of the opposite side of the support member 20. The upper wall protection member 70 formed in a grid shape is combined and installed using the.

In the upper wall protection member 70, as shown in FIG. 14, a plurality of frame members 72 are disposed in a longitudinal direction and a transverse direction to form a lattice shape, and are cross-coupled.

In addition, the frame member 72 and the support member 20 are cross-coupled to each other by a connection member 74, the end of the connection member 74 coupled to the support member 20, a coupling panel 75 is formed.

In addition, an elastic member 77 is disposed between the coupling panel 75 and the support member 20.

Thus, the upper wall protection member 70 is installed on the H-beam via the elastic member 77, and the elastic member 77, as shown in Fig. 15, the frame-side elastic member ( 76) and the support member side elastic member 78 may be included.

And, as shown in Figure 16, the frame-side elastic member 76 and the support member-side elastic member 78 are in contact with each other, a grid-shaped concave portions and convex portions alternate along the longitudinal and transverse directions. Is formed by

In this state, the frame-side elastic member 76 and the support member-side elastic member 78 are arranged to face each other, so that the concave portion of the frame-side elastic member 76 and the support member-side elastic member 78 The convex portions of the frame-side elastic member 76 and the convex portions of the support member-side elastic member 78 are configured to engage each other, and the elastic members are coupled.

And, in a state in which the frame-side elastic member 76 and the support member-side elastic member 78 are mutually engaged, one side of the coupling panel 75 and the H-beam by a coupling means 79 such as a bolt and a nut By additionally fixedly coupled, the upper wall protection member 70 is installed in a state in which the frame-side elastic member 76 and the support member-side elastic member 78 are interposed.

By installing the upper wall protection member 70 on the support member 20, even when the grain bags loaded in the loading area (a) are overturned, damage to the wall unit 10 can be prevented. have.

In addition, the impact force received by the wall portion 10 may be minimized through a buffering action of the elastic member 77.

In addition, since the concave portion on one side of the elastic member 77 and the convex portion on the other side are coupled in a mated state, even when vibration is applied to the support member 20 due to earthquake or draft, the support member 20 By being buffered by the elastic members 77 coupled to, vibration applied to the support member 20 may be reduced.

In addition, the upper wall protection member 70 cross-linked in the form of a grid is connected and coupled across a plurality of the support members 20, so that the support force of the support member 20 structure coupled with the upper wall protection member 70 Can be augmented.

Thus, it is possible to prevent the support member 20 from being buckled or deformed in case of an earthquake.

On the other hand, as shown in Fig. 17, on the outer wall surface of the upper wall portion 16, the opening 1647 portion where the pipe 59 connecting the outdoor unit 55 and the blowing member 53 is coupled Rat intrusion prevention panel 592 may be installed.

The portion of the opening 1647 in the upper wall portion 16 to which the pipe 59 is coupled may be damaged by corrosion and vibration over time and thus increase in size.

In order to prevent rats from entering through the widened opening 1647 as described above, a rat intrusion prevention panel 592 is installed in the opening 1647.

In the rat intrusion prevention panel 592, a convex portion 5922 is formed on the surface facing the outer surface member 164 of the upper wall portion, and the concave portion 1642 on the surface of the outer surface member 164 of the upper wall portion and By being installed in an occlusal state, the rat intrusion prevention panel 592 is configured not to be separated and separated from the surface member 164 even after a long period of time.

In the above, although the present invention has been described by the limited embodiments and drawings, the technical idea of the present invention is not limited to these, and by those of ordinary skill in the art to which the present invention pertains, the technical idea of the present invention and Various modifications and variations will be possible within the scope of the following claims.

10: wall part
20: support member
30: Heavenly Government
40: opening door
50: thermostat
60: lighting member
70: upper wall protection member

Claims (21)

A wall part constituting a wall of a storage warehouse for storing grains such as rice;
A support member for supporting the wall portion;
A ceiling portion constituting a ceiling of the storage warehouse;
An opening and closing door installed on the wall;
A temperature control device for controlling a temperature inside the storage warehouse;
Including a lighting member installed on the ceiling,
The wall portion and a lower wall portion buried in the ground;
Including an upper wall portion installed above the lower wall portion,
The lower wall portion is formed of stone or concrete to be buried into the ground at a predetermined depth,
The upper wall portion is formed to include a pair of surface members disposed facing each other and a heat insulating member disposed between the surface members,
The support member is provided with an upper wall protection member protruding from the support member toward the interior,
A concave portion and a convex portion are formed in the surface member disposed on the indoor side of the upper wall portion,
An air flow path in the form of a concave portion is formed at the bottom of the storage facility,
The air flow path is formed as a grid-shaped recess,
The support member is formed of an H-beam, and the upper wall portion protection member is formed in a grid shape using a steel pipe, and is installed in the H-beam. The method of claim 1,
The opening and closing door includes a first door configured to slide in a horizontal direction along a rail;
It includes a second door configured to move in the vertical direction,
Grain storage facility, characterized in that the ground contact portion is formed at the lower end of the second door. The method of claim 2,
The first door is formed of a metal material, and a ground contact portion is formed at a lower end facing the rail,
Grain storage facility, characterized in that the second door is formed of a synthetic resin material. The method of claim 1,
A grain storage facility, characterized in that a concave portion and a convex portion are formed on a surface facing the heat insulating member in the surface member disposed on the outdoor side of the upper wall portion. The method of claim 1,
A grain storage facility, characterized in that a concave portion and a convex portion are formed on a surface facing the heat insulating member in a surface member disposed indoors in the upper wall portion. The method of claim 1,
A grain storage facility, characterized in that a contact preventing protrusion is formed on a surface of the upper wall portion facing the heat insulating member. The method of claim 1,
A grain storage facility, characterized in that horizontal concave portions are formed in a portion buried in the ground in the lower wall portion, and concave portions are formed in a vertical direction in a portion protruding to the ground. The method of claim 7,
Grain storage facility, characterized in that a grid-shaped recessed portion is formed in a portion of the lower wall portion buried in the ground. The method of claim 7,
A grain storage facility, characterized in that spaces having a cylindrical or hexagonal cross-section are formed in a portion of the lower wall portion buried in the ground. The method of claim 1,
It additionally includes a rat intrusion prevention member disposed under the opening and closing door,
The rat intrusion prevention member includes a base portion;
An inclined surface member formed to be inclined from the base portion;
Grain storage facility, characterized in that it comprises a lateral movement preventing member formed at predetermined intervals on the inclined member. The method of claim 10,
Grain storage facility, characterized in that the base portion is formed to protrude by a predetermined width than the lateral movement preventing member. The method of claim 3,
A third door made of a synthetic resin material is installed opposite the second door based on the first door,
The third door is a grain storage facility, characterized in that configured to move in the vertical direction. The method of claim 1,
The temperature control device includes an outdoor unit;
And a blowing member for blowing cold air or warmth transmitted from the outdoor unit into the storage facility,
The ventilation member is a grain storage facility, characterized in that installed symmetrically to each other on the ceiling and the bottom with respect to the center of the storage facility. The method of claim 1,
The upper wall protection member is a grain storage facility, characterized in that installed in the H-beam via an elastic member. The method of claim 14,
The elastic member includes an elastic member on the support member side located on the H-beam side;
And the frame-side elastic member located on the upper wall protection member side,
A concave portion and a convex portion are formed on the surface of the supporting member side elastic member,
Grain storage facility, characterized in that the concave and convex portions in the shape of a concave-convex shape that engage with the concave portion and the convex portion of the support member-side elastic member are formed on the surface of the frame-side elastic member. The method of claim 1,
The lighting member is installed at the center and the edge of the ceiling,
A grain storage facility, characterized in that the number per unit area of the lighting members installed at the edge is larger than the number per unit area of the lighting members installed in the center. The method of claim 3,
A grain storage facility, characterized in that a second door receiving portion for accommodating the second door is formed at a predetermined depth on the ground facing the second door. The method of claim 13,
A rat intrusion prevention panel is installed in a portion through which a pipe connecting the outdoor unit device and the blowing member passes in the upper wall portion,
Grain storage facility, characterized in that the convex portion is formed on the surface facing the upper wall portion of the rat intrusion prevention panel to be engaged with the upper wall portion. delete delete delete

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