KR101635733B1 - Apparatus for Maintaining Freshness in Feed Bin - Google Patents

Abstract

Disclosed is a feed storage device for maintaining internal freshness.
The present invention relates to a feed storage device for maintaining the freshness of an inside of a feed storage device to control the operation of the air injection module in order to maintain the freshness of stored feeds.

Description

[0001] The present invention relates to a feed storage device for maintaining fresh freshness,

The present embodiment relates to a feed storage device for maintaining an internal freshness.

The contents described in this section merely provide background information on the present embodiment and do not constitute the prior art.

In general, feed storage (eg feed beans, feed tanks, etc.) is used to store feed for breeding livestock. If the feed is stored for a long time in a closed feed storage device in a hot and humid season, the feed may be clogged on the inner wall of the feed storage device or the nutrients contained in the feed (eg, vitamins, proteins, carbohydrates) Is damaged or destroyed.

More specifically, due to the temperature difference between the inside and the outside of the feed storage device, moisture condensation phenomenon occurs on the inner wall of the feed storage device, and the environment where fungi and harmful microorganisms grow becomes a good environment, And a loading phenomenon occurs.

In the case of summer, there may be differences in temperature and humidity depending on the amount of sunshine in each region, but the temperature inside the feed storage device may rise to about 40 to 70 ° C. When the internal temperature of the feed storage device is above 60 ° C, protein denaturation due to heat and vitamin destruction, which is added much in the summer season, occur. Some feed storage devices may be equipped with air conditioning or air supply motors on the top cover, but they can not supply air evenly inside the feed storage device, may fail due to heat in summer, There is a problem that the entire upper cover portion needs to be replaced.

Therefore, there is a need for a feed management system that maintains the freshness of the feedstably in a stable and efficient manner while minimizing the influence of temperature and humidity in an external feed storage device.

The main object of the present invention is to provide a feed storage device having an air injection module inside the feed storage device and maintaining the freshness of the operation of the air injection module to maintain the freshness of the stored feed.

According to an aspect of the present embodiment, there is provided an animal feeder comprising: a cylindrical body capable of storing feed; A cover for protecting an upper portion of the main body; A plurality of module fixing portions provided on an inner surface of the main body; An air pipe for injecting air generated from the outside of the main body into the inside; And an air injection module fixed at a position adjacent to the lid by the module fixing part and injecting the air supplied from one side of the air pipe into the inside of the main body. Device.

As described above, according to the present embodiment, there is an effect of minimizing the influence of temperature, humidity, etc. on the feed stored in the feed storage device, and it is possible to prevent the feed stored in the feed storage device from being damaged It is effective.

In addition, the air spraying device provided in the feed storage device can provide the cooling air or the circulating air uniformly inside.

In addition, a module for supplying air to the feed storage device is separately provided to reduce faults, and the air spraying device installed therein can be attached and detached, thereby improving the convenience of replacement, repair, and cleaning.

1 is a perspective view schematically showing an air injection module included in a feed storage device according to the present embodiment.
2 is a cross-sectional view of the air injection module according to the present embodiment.
3A and 3B are views schematically showing a feed storage apparatus according to the present embodiment.
4A and 4B are views showing an installation structure of the air injection module in the feed storage device according to the present embodiment.
FIG. 5 is an exemplary diagram showing an operation of performing multi-control to maintain internal freshness by interlocking a plurality of feed storage devices according to the present embodiment.
6 is an exemplary view for explaining an operation of cleaning the inside of the feed storage apparatus according to the present embodiment.
7 is a block diagram schematically showing a control module included in the feed storage device according to the present embodiment.

Hereinafter, the present embodiment will be described in detail with reference to the accompanying drawings.

The feed storage device 100 according to the present embodiment stores feeds and includes an air injection module 110 having a ring structure inside to maintain the freshness of feed stored therein, The feed storage device for maintaining freshness will be described. Here, the feed storage device 100 is described as storing only feed, but not limited thereto, and any storage such as grain, liquid storage, chemical storage, etc. that requires freshness can be replaced with any storage Do.

1 is a perspective view schematically showing an air injection module included in a feed storage device according to the present embodiment.

The air injection module 110 is installed inside the feed storage device 100 in a ring structure and injects air from the outside of the feed storage device 100 into the inside of the feed storage device 100.

The air injection module 110 is implemented in a form having a predetermined thickness and receives external air through the air inlet 114 and injects the supplied air into the inside of the feed storage device 100.

The air injection module 110 has a structure capable of being separated and coupled to at least two stages in the feed storage device 100 for efficient installation. The air injection module 110 has a structure in which a groove for air flow is formed on the inner circumferential surface, one side of the upper and lower portions is closed, and the other side is open, air is blown to the open portion.

Hereinafter, the structure of the air injection module 110 will be described.

The air injection module 110 includes a first uneven portion 112 and an air inlet 114.

The first concavo-convex portion 112 means a body portion of a ring-shaped structure of the air injection module 110, and a groove for airflow is formed on the inner circumferential surface to uniformly inject the air introduced from the air inlet 114 . Here, the concave portion may be realized as a right angle shape of '?', But may be implemented as a curved shape of '?', That is, a curved shape, to further smooth the flow of air.

The air inlet 114 is made of one of metal, plastic, and rubber, and is provided in the first concavity and convexity 112. The air injection port 114 is provided on one side wall of the outer circumferential surface of the first concavo-convex part 112, which is in contact with the inner surface of the main body 130 of the air injection module 110, . Here, the air inlet 114 is supplied with the air conveyed via the air pipe 140.

Although only one air inlet 114 is shown in the first concave and convex portion 112 in FIG. 1, the present invention is not limited thereto and a plurality of air inlet holes 114 may be provided. For example, when there are a plurality of air pipes 140 connected to the inside of the air injection module 110, a plurality of air injection holes 114 may be formed in the first concave- 112 may be provided on one side wall of the outer circumferential surface of the air injection module 110 that is in contact with the inner side surface of the main body 130. The plurality of air inlets 114 are provided in pairs on the outer circumferential surface of the first concavo-convex portion 112 at positions facing each other on one side wall surface of the air injection module 110 that contacts the inner side surface of the main body 130, So that the air flows uniformly on the inner peripheral surface of the concave and convex portion 112.

The air injection module 110 may include a second concave-convex portion 116 for guiding the flow of air to the inner circumferential surface of the first concave-convex portion 112.

The second concavo-convex portion 116 is coupled to the outer circumferential surface of the first concavo-convex portion 112 at a position perpendicular to one side wall surface of the air injection module 110 which is in contact with the inner surface of the main body 130. The second concavo-convex portion 116 is implemented in a ring-like structure.

The second concave-convex portion 116 is vertically coupled to one side wall of the first concave-convex portion 112 and is formed to be adjacent to the other side wall face of the first concave-convex portion 112 opposed to the one side wall face. The second concave-convex portion 116 is formed in a ring-like structure from a portion in contact with one wall surface of the first concavo-convex portion 112 to a portion adjacent to the other wall surface with reference to the center of the width of the concave portion of the first concavo- do. The second concave-convex portion 116 is shown in Figs. 2 (b) and 2 (d).

2 is a cross-sectional view of the air injection module according to the present embodiment.

2 (a) is a sectional view of the air injection module 110 including the first concave-convex portion 112 and the air inlet 114 according to the present embodiment. 2 (a), the first concavo-convex part 112 is formed in a right angle shape of '?', And the air injection module 110 is formed in an air- .

2B is a sectional view of the air injection module 110 including the first concave-convex portion 112, the air inlet 114 and the second concave-convex portion 116 according to another embodiment. 2, the first concavo-convex part 112 is formed in a right angle shape of '┌┐', and the inner surface of the main body 130 of the air injection module 110 in the outer circumferential surface of the first concavo- And the second concavo-convex portion 116 is coupled to a position perpendicular to one side wall surface contacting the first concavo- The second concavo-convex part 116 is vertically coupled to one side wall of the first concavo-convex part 112 and is adjacent to the other side wall of the first concavo-convex part 112 facing the one side wall, The air bag 110 injects air in the open direction (downward direction in FIG. 2 (b)) between the first concave-convex portion 112 and the second concave-convex portion 116. Here, the second concave-convex portion 116 is formed on one side wall of the first concave-convex portion 112 with an 'A' reference line (a reference line passing through the center of the groove width perpendicular to the paper surface) And is formed between the wall surfaces.

2C is a cross-sectional view of the air injection module 110 including the first concave-convex portion 112 and the air inlet 114 according to another embodiment. 2 (c), the first irregular portion 112 is formed in a curved shape of '∩', that is, a curved shape, and the air injection module 110 is formed in the open direction of the recessed portion ).

2D is a sectional view of the air injection module 110 including the first concave-convex portion 112, the air inlet 114, and the second concave-convex portion 116 according to another embodiment. 2 (d), the first concavo-convex part 112 is formed to have a curved shape, that is, a curved shape of '∩', and the main body 130 of the air injection module 110, The second concavo-convex portion 116 is coupled to a position perpendicular to one side wall surface that contacts the inner side surface of the second concavo-convex portion. The second concavo-convex part 116 is vertically coupled to one side wall of the first concavo-convex part 112 and is adjacent to the other side wall of the first concavo-convex part 112 facing the one side wall, The air bag 110 injects air in the open direction (lower diagonal direction of FIG. 2 (d)) between the first concave-convex portion 112 and the second concave-convex portion 116. Here, the second concave-convex portion 116 is formed on one side wall of the first concave-convex portion 112 with an 'A' reference line (a reference line passing through the center of the groove width perpendicular to the paper surface) And is formed between the wall surfaces.

The air injection module 110 shown in FIG. 2 (d) is configured such that the inner circumferential surface of the first concavo-convex portion 112 is curved so as to inject air into the inner wall of the feed storage device 100, It is possible to remove feed that solidifies on the wall surface of the storage device 100 and effectively circulate the internal air of the feed storage device 100.

3A and 3B are views schematically showing a feed storage apparatus according to the present embodiment.

FIG. 3A is a view showing the feed storage device 100 according to the present embodiment, and FIG. 3B is a view showing the air injection module 110 and the module fixing part 120 provided in the feed storage device 100. FIG.

3A, the feed storage device 100 includes an air injection module 110, a module fixing part 120, a main body 130, a cover 132, an air pipe 140, an air pump 150, And a control module 160. The feed storage device 100 shown in FIG. 3A is according to one embodiment, and not all of the components shown in FIG. 3A are required components, and in some embodiments, some components May be added, changed or deleted.

The feed storage device 100 is configured by supplying outside air to the inside, and separating the air pump 150 and the air injection module 110 for supplying air. Here, the feed storage device 100 may be provided with an air injection module 110 as a removable structure, and may be installed in a structure capable of vertical spraying.

The air injection module 110 is implemented in a form having a predetermined thickness and receives external air through the air inlet 114 and injects the supplied air into the inside of the feed storage device 100. A detailed description of the air injection module 110 is shown in FIG.

The module fixing portion 120 is provided on the inner surface of the main body 130 to fix the air injection module 110. The module fixing portion 120 includes a groove formed in the inner surface of the main body 130 and a protrusion which is fastened to all or a part of the groove portion. The module fixing portion 120 can be attached and detached, and the height of the air injection module can be changed according to the height of the protrusion.

The module fixing part 120 includes a first protrusion that is fastened to all or a part of a plurality of grooves located on a straight line parallel to the upper surface of the air injection module 110 and a second protrusion that is parallel to the lower surface of the air injection module 110 And a second protrusion which is fastened to all or a part of the plurality of grooves located in the recesses. Here, the first protrusions are paired at the opposite positions on the inner surface of the main body 130 and are fixed at the upper side of the air injection module 110, and the second protrusions are disposed at the opposite positions at the inner side of the main body 130 And is supported on the lower side of the air injection module 110.

The main body 130 is a cylindrical structure capable of storing feedstuffs and the cover 132 protects the upper portion of the main body 130 and removes and removes the air injection module 110 and the module fixing portion 120 It is implemented in a possible form.

The air pipe 140 connects the air injection module 110 and the air pump 150 and introduces the cooled or circulated air generated by the air pump 150 into the air injection module 110. One side of the air pipe 140 is connected to the air injection module 110, and the other side is connected to the air pump 150. Here, the air pipes 140 are implemented in the same number as the number of the air injection modules 110, and are connected to the respective air injection modules 110.

The air pump 150 generates cooling air or circulating air based on the control signal input from the control module 160. Here, the air pump 150 is provided outside the main body 130, and is connected to the other side of the air pipe.

The control module 160 acquires internal state information from a sensor (not shown) installed in the main body 130 and generates a control signal for controlling the air pump 150 based on the internal state information.

Hereinafter, the operation of maintaining freshness in the feed storage device 100 will be described in order.

(1) Measurement of the internal temperature and humidity of the feed storage device 100 (using the air injection module 110 or a temperature / humidity sensor installed in the upper part of the main body 130)

(2) Measurement of the amount of feed stored in the feed storage device 100. (Distance between the feed and the air injection module 110 using the distance sensor installed inside the main body 130)

(3) Air supply control of the air pump 150 according to the internal state based on the control signal of the control module 160 located outside the feed storage device 100. (The internal temperature of the feed storage device 100 is adjusted to a predetermined temperature Or more, it generates and supplies cooling or circulating air instead of natural air)

(4) Repeating the operation of controlling the air supply based on the temperature and humidity data of the feed storage device 100 fed back.

3 (b), the air injection module 110 is fixed using the module fixing part 120 provided inside the main body 130, the fixed height can be adjusted, and a plurality of air The injection module 110 can be installed.

The module fixing portion 120 includes a groove formed in the inner surface of the main body 130 and a protrusion which is fastened to all or a part of the groove portion. Here, the protrusion can be attached and detached, and the height of the air injection module 110 can be changed according to the height of the protrusion.

The module fixing portion 120 includes first protrusions 122 and 123 fastened to all or a part of a plurality of grooves positioned on a straight line parallel to the upper surface of the air injection module 110, And second projections 124 and 125 fastened to all or a part of the plurality of grooves positioned in a straight line parallel to the first projections 124 and 125. The first projections 122 and 123 are paired at opposite positions on the inner surface of the main body 130 and are fixed on the upper side of the first air injection module 110a and the second projections 124 and 125 are fixed on the upper side of the first air injection module 110a. And is supported at the lower side of the first air injection module 110a by being paired at the opposite positions on the inner surface of the main body 130. [ The module fixing portion 120 of the second air injection module 110b is the same as the module fixing portion 120 of the first air injection module 110a and the description of its structure is omitted.

4A and 4B are views showing an installation structure of the air injection module in the feed storage device according to the present embodiment.

FIG. 4A shows an installation structure of the air injection module 110 for spraying air downward into the feed storage device 100, FIG. 4B shows an air injection module for spraying air in the feed storage device 100 in both directions 110).

One or more air injection modules 110 provided in the feed storage device 100 according to the present embodiment may be installed. For example, as shown in FIG. 4A, when one air injection module 110 is installed, the air injection module 110 injects air in a lower direction of the feed storage device 100 to feed the feed storage device 100, It is possible to circulate the inside air of the air-

4B, when the two air injection modules 110a and 110b are installed, the first air injection module 110a is installed to spray air in the lower direction of the feed storage device 100, 2 air injection module 110b is installed to inject air in the upper direction of the feed storage device 100. [ Here, the second air injection module 110b injects the cooling air in the upward direction, thereby transferring the cooling air to the lower side and moving the warmer air upward than the cooling air to increase the cooling and air circulation efficiency. The feed storage device 100 can change the installation structure of the plurality of air injection modules 110a and 110b in accordance with the modification of the module fixing part 120. The plurality of air injection modules 110a and 110b It is preferable that air is supplied from a separate air pipe 140 from the outside.

FIG. 5 is an exemplary diagram showing an operation of performing multi-control to maintain internal freshness by interlocking a plurality of feed storage devices according to the present embodiment.

When there are a plurality of feed storage devices 110, it is possible to perform supply of outside air in a group form. Here, each of the plurality of feed storage devices 110 performs an operation of maintaining the freshness of the same structure as that of one feed storage device 110. [ Each of the plurality of feed storage devices 110 can maintain the same temperature and humidity using automatic valve control.

5, when the first feed storage device 101, the second feed storage device 102, ..., and the nth feed storage device 103 exist, the first feed storage device 101 The second feed storage device 102 receives air from the second air pipe 144 and the nth feed storage device 103 receives the air from the nth air pipe 142, And the air is supplied from the air blower 146. Here, the first air pipe 142, the second air pipe 144, and the nth air pipe 146 are connected to the interlocking air pipe 141, and air control valves 510, 520, 530 ).

In other words, the first air control valve 510 is provided at a portion where the first air pipe 142 and the interlocking air pipe 141 are connected, and the second air pipe 144 and the interlocking air pipe 141 are connected And an nth air control valve 530 is provided at a portion where the nth air pipe 146 and the interlocking air pipe 141 are connected to each other.

The first air control valve 510, the second air control valve 520 and the nth air control valve 530 perform an opening or closing operation according to the control signal of the control module 160, 101, the second feed storage device 102, ..., and the nth feed storage device 103 are kept at the same temperature and humidity.

6 is an exemplary view for explaining an operation of cleaning the inside of the feed storage apparatus according to the present embodiment.

6 (a), when the difference in height between the feed existing in the inner wall of the feed storage device 100 and the feed present in the center of the main body 130 occurs, the air injection module 110, The air is sprayed in the direction of the inner surface of the main body 130.

The feed storage device 100 has a height 610 of the feed existing on the inner wall measured using a pre-installed remaining amount measuring sensor (not shown) and a height 610 of the feed 620 existing in the center of the main body 130 When the difference 630 is equal to or greater than a preset threshold value, air is injected from the air injection module 110 in the direction of the inner side of the main body 130 to prevent the feed from solidifying and sticking to the inner side.

6 (a), when the inside of the main body 130 is cleaned, the feed storage device 100 removes air from the air injection module 110 at a high pressure to the inside surface of the main body 130 So that the internal cleaning can be performed. 6A shows cleaning of the feed storage device 100 by using only the ring-shaped air injection module 110. However, the present invention is not limited thereto, and the air injection module 110 may be removed (Not shown) to the air pipe 140 to perform internal cleaning.

7 is a block diagram schematically showing a control module included in the feed storage device according to the present embodiment.

The control module 160 for controlling the operation of the feed storage device 100 according to the present embodiment includes a sensor unit 710, a control unit 720, and an output unit 730.

The sensor unit 710 measures internal state information using a sensor provided in the feed storage device 100. Here, the sensor unit 710 measures the internal state information of the inside and outside of the feed storage device 100 with respect to the temperature and humidity, the remaining amount of feed stored in the feed storage device 100, and the like.

The control unit 720 controls the air pump 150 based on the measured internal state information. For example, when acquiring the internal state information including the temperature and humidity information from the temperature and humidity sensor, the control unit 720 generates a control signal for controlling the supply of the cooling air when the internal temperature is equal to or higher than a predetermined temperature based on the temperature and humidity information So that the cooling air is jetted from the air injection module 110.

In addition, when acquiring the internal state information including the remaining amount measurement information from the remaining amount measurement sensor, when the storage height of the stored contents exceeds a predetermined threshold value based on the remaining amount measurement information, So that the circulated air is injected from the air injection module 110. [0050]

The output unit 730 transmits a control signal to the air pump 150 to perform an operation of injecting the air from the air injection module 110 and outputs the result of the operation and the current state information of the feed storage device 100.

The foregoing description is merely illustrative of the technical idea of the present embodiment, and various modifications and changes may be made to those skilled in the art without departing from the essential characteristics of the embodiments. Therefore, the present embodiments are to be construed as illustrative rather than restrictive, and the scope of the technical idea of the present embodiment is not limited by these embodiments. The scope of protection of the present embodiment should be construed according to the following claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

100: Feed storage
110: air injection module 112: first irregular portion
114: air inlet 116: second concave /
120: module fixing part 130: main body
132: cover 140: air pipe
150: air pump 160: control module

Claims (11)

delete A cylindrical body capable of storing feed;
A cover for protecting an upper portion of the main body;
A plurality of module fixing portions provided on an inner surface of the main body;
An air pipe for injecting air generated from the outside of the main body into the inside; And
And an air injection module fixed to the cover at a position adjacent to the cover by the module fixing part and configured to inject the air supplied from one side of the air pipe into the interior of the main body,
The module fixing unit includes:
And a projection formed on an inner surface of the body and a protrusion that is fastened to the whole or a part of the groove, wherein the protrusion is detachable and the height of the air injection module is changed according to a height of the protrusion. Storage device. 3. The method of claim 2,
The module fixing unit includes:
A first protrusion which is fastened to all or a part of a plurality of grooves located on a straight line parallel to an upper surface of the air injection module; And
And a second projection which is fastened to all or a part of a plurality of grooves located on a straight line parallel to a lower surface of the air injection module,
Wherein the first projections are paired at opposite positions on an inner surface of the main body and are fixed on the upper side of the air injection module and the second projections are formed in pairs at opposite positions on an inner surface of the main body, Wherein the feed module is supported on the lower side of the injection module. A cylindrical body capable of storing feed;
A cover for protecting an upper portion of the main body;
A plurality of module fixing portions provided on an inner surface of the main body;
An air pipe for injecting air generated from the outside of the main body into the inside; And
And an air injection module fixed to the cover at a position adjacent to the cover by the module fixing part and configured to inject the air supplied from one side of the air pipe into the interior of the main body,
The air injection module includes:
A first concavo-convex structure of a ring-shaped structure having a groove for air flow formed on an inner circumferential surface thereof to uniformly inject the air into the main body; And
And an air inlet port provided on one side wall surface of the outer circumferential surface of the first concavo-convex portion which is in contact with an inner surface of the main body,
Wherein the feed storage device comprises: 5. The method of claim 4,
The air-
Wherein a plurality of air pipes are provided on one side of the outer circumferential surface of the first concavo-convex part, the first concavo-convex part being in contact with an inner surface of the main body, corresponding to each of the plurality of air pipes. 6. The method of claim 5,
Wherein the plurality of air inlets
Wherein a pair of the outer circumferential surfaces of the first concavo-convex portions are provided at positions opposed to one side wall surface contacting the inner side surface of the main body, so that air flows uniformly to the inner circumferential surface. 5. The method of claim 4,
The air injection module includes:
Further comprising a second concave-convex portion of a ring-shaped structure which is coupled to the inner circumferential surface of the first concavo-convex portion at a position perpendicular to one side wall surface of the outer circumferential surface of the first concavo-
Wherein the second concavo-convex portion is adjacent to the one side wall surface of the first concavo-convex portion and is opposed to the one side wall surface with respect to the center of the width of the concave portion. 5. The method of claim 4,
The first concave-
Wherein the inner circumferential surface includes the concave portion having a curved shape. 3. The method of claim 2,
An air pump provided outside the feed storage device and connected to the other side of the air pipe to generate cooling air or circulating air according to an input control signal; And
A control module for obtaining internal state information from a sensor provided in the feed storage device and generating the control signal for controlling the air pump based on the internal state information,
Further comprising a feeder for feeding the feed. 10. The method of claim 9,
The control module includes:
Wherein the controller generates the control signal for controlling the cooling air to be supplied when the internal temperature is equal to or higher than a predetermined temperature based on the internal state information including the temperature and humidity information from the sensor including the temperature and humidity sensor, So that air is jetted. 10. The method of claim 9,
The control module includes:
When the storage height of the stored contents is greater than a predetermined threshold value based on the internal state information including the remaining amount measurement information from the sensor including the remaining amount measuring sensor, And the circulation air is sprayed from the air injection module.

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