KR102117640B1 - feed transportation system using blower - Google Patents

Abstract

The present invention relates to a blower type feed transport system, which comprises: a main feed storage tank which is installed to discharge feed through a main outlet at the lower portion; a rotary valve which receives the feed introduced through an upper inlet disposed to communicate with the main outlet by the rotation of a plurality of distribution wings through the intervals between the distribution wings before discharging the same through a lower outlet disposed at the lower portion of the housing; a rotary driving unit which rotationally operates a rotary shaft of the rotary valve; a main transport pipe which has a main transport inlet performing communication with the lower outlet of the rotary valve and extends to have a main transport flow path to transport the introduced feed by blowing force; a blower which is coupled to one side of the main transport pipe to generate the blowing force for transporting the feed falling through the main transport inlet by means of the main transport flow path; a plurality of sub-transport pipes which are coupled to mutually communicate with the main transport pipe; a terminal storage tank which is installed to store the feed introduced through the sub-transport pipes; a plurality of flow path control valves which are installed over the main transport pipe and the sub-transport pipes and are installed to control a transport path such that the feed introduced through the main transport inlet may be transported to one among the sub-transport pipes; and a control unit which controls the opening and closing of the flow path control valves, the rotary driving unit and the blower. Therefore, the feed can be supplied to remote farms.

Description

Feed transportation system using blower

The present invention relates to a blower-type feed transport system, and more particularly, to a blower-type feed transport system constructed to be able to transport feed to remote farms by in-pipe blowing power.

In pig farms, cattle farms, and poultry farms, where large-scale livestock are kept, devices that can automatically supply feed are installed and operated.

The automatic pay machine has been variously disclosed, such as Korean Utility Model No. 20-2010-0005041.

In addition, the method of supplying feed to be stored in the hopper of the automatic feeding machine is applied to a method of supplying at a short distance using a feed transport vehicle or a transfer screw or conveyor.

However, this method of feeding is built on its own on a farm-by-farm basis, which is inconvenient to perform feed storage and feeding on its own.

Therefore, there is a need for a system for easily supplying feed through a transport pipe to remote farms for raising livestock.

The present invention has been created to solve the above-described requirements, and has an object to provide a blower-type feed transport system capable of supplying feed to long-distance livestock farms through a feed pipe to which a blowing force is applied.

In order to achieve the above object, the blower-type feed transport system according to the present invention includes a main feed storage tank installed to discharge feed through a main outlet at the bottom; It is provided on the lower part of the housing by receiving feed introduced through the upper inlet port provided in communication with the main discharge port by rotation of a plurality of distribution blades extending radially on the rotation axis in the housing and spaced apart from each other along the circumferential direction. A rotary valve discharging through the lower outlet; A rotation driving unit for rotationally driving the rotation shaft of the rotary valve; A main conveying pipe having a main conveying inlet communicating with a lower outlet of the rotary valve and extending with a main conveying passage for conveying the introduced feed by blowing force; A blower coupled to one side of the main conveying pipe to generate a blowing force conveyed through the main conveying passage to feed falling through the main conveying inlet; A plurality of sub-transfer pipes coupled to each other in communication with the main transfer pipes; A terminal storage tank installed to store feed introduced through the sub-transfer pipe; A plurality of flow path control valves installed on the main transfer pipe and the sub transfer pipe to control feed paths such that feed fed through the main transfer inlet is transferred to any one of the sub transfer pipes; And a control unit that controls opening and closing of the flow path control valves and controlling the rotary drive unit and the blower.

Preferably, in the process of ascending after passing through the lower outlet, the upper inlet and the upper portion so that the wind pressure generated by inflow of a part of the blower flow generated from the blower between the distribution vanes can be reduced before reaching the upper inlet. It is further provided; a pressure-reducing tube connected in communication between the main feed reservoir and the housing on the rising position of the distribution blade between the lower outlets.

In addition, on the inner surface of the main feed reservoir to which the upper end of the pressure reducing pipe is connected, a drop promoting guide plate mounted to change the path of the air flow discharged through the pressure reducing pipe downward by interference to facilitate dropping of the feed; It is preferable to further include.

According to one aspect of the present invention, the width along the circumferential direction of the upper inlet is formed smaller than the width between the inner wall of the adjacent dispensing wings and the opposite end.

According to the blower type feed transport system according to the present invention, feed can be transported to remote farms, and the wind pressure applied between the distribution vanes along the rotational direction after discharging the feed of the rotary valve is attenuated so as not to affect the drop of the feed. It also provides the advantage of improving feed efficiency.

1 is a view showing a blower method feed transport system according to the present invention,
2 is an enlarged cross-sectional view of the rotary valve installation portion of FIG. 1.

Hereinafter, with reference to the accompanying drawings will be described in more detail the blower feed system according to a preferred embodiment of the present invention.

1 is a view showing a blower type feed transport system according to the present invention, and FIG. 2 is an enlarged cross-sectional view of the rotary valve installation part of FIG. 1.

1 and 2, the blower-type feed transport system 100 according to the present invention includes a main feed storage tank 110, a rotary valve 130, a rotary driving unit 147, a main transport pipe 150, and a blower ( 155), a sub-transfer pipe 160, a terminal storage tank 170, a flow path control valve 181a, 181b and a control unit 190 are provided.

The main feed storage tank 110 has a storage space 111 for accommodating feed therein, and is installed to discharge the feed through the main outlet 112 at the bottom.

The main feed storage tank 110 is capable of receiving feed through a relay supply tank 128 that is capable of receiving feed through a feed supply pipe 125 from a plurality of feed supply tanks 121. The feed supply pipe 125 is connected to receive feed falling from each feed supply tank 121, and the feed feed pipe is rotated by a driving motor 126 therein to transfer it to the main feed storage tank 110. The transfer screw 127 is built-in. Each feed supply tank 121 and relay supply tank 123 are provided with supply valves 123 for controlling feed supply to the feed supply pipe 125 and feed supply to the main feed storage tank 110. The supply valve 123 is controlled to be opened and closed by a control unit 195 to be described later. Unlike this, the supply valve 123 may be of course manually applied.

Unlike the illustrated example, the feed falling from each of the feed supply tanks 121 is collected into the main feed storage tank 110, such as a method of collecting the feed falling in a free-falling manner and supplying it to the relay supply tank 128 and the main feed storage tank 110. Various methods can be applied as the method of supplying. In addition, the relay supply tank 128 is omitted and the main feed storage tank 110 may be connected to receive feed supplied from the relay supply tank 128, of course.

The rotary valve 130 and the main feed storage tank 110 to control supply or supply cutoff of feed discharged through the main outlet 112 of the main feed storage tank 110 to the main transport pipe 150 to be described later. It is installed between the main transfer pipe 150.

The rotary valve 130 has a structure having a housing 132, a rotating shaft 136, and a distribution blade 135.

The housing 132 is coupled to the main feed storage tank 110 at the top of the cylindrical portion 132a and the cylindrical portion 132a having a cylindrical receiving space so that the end of the distribution blade 137 can be rotated in close contact. It has a structure having an upper coupling portion 132b and a lower coupling portion 132c coupled to the main transfer pipe 150 at the lower portion of the cylindrical portion 132a.

An upper inlet 133 communicating with the main outlet 112 of the main feed storage tank 110 is formed at an upper portion of the cylindrical portion 132a, and a lower outlet 134 communicating with the main transfer pipe 150 is formed at the lower portion. Is formed.

The distribution blades 137 are radially extended to the rotation shaft 136 extending along the longitudinal direction in the center of the cylindrical portion 132a of the housing 132, and a plurality of distribution wings are spaced apart from each other along the circumferential direction. In the illustrated example, six distribution blades 137 applied to the rotary valve 130 are applied, and of course, four to five or seven distribution blades 137 may be applied.

The distribution wing 137 receives the feed introduced through the upper inlet 133 provided to communicate with the main outlet 112 by rotation into the receiving compartment 137a between the distribution wings 137, and the housing 132 It discharges through the lower outlet 134 provided in the lower portion.

The pressure reducing pipe 140 is generated by inflow of a part of the blower flow generated from the blower 155, which will be described later, into the partition receiving space 137a between the distribution blades 137 in the process of rising after passing through the lower outlet 134 The cylindrical portion 132a and the main part of the housing 132 on the rising position of the distribution blade 137 between the upper inlet 133 and the lower outlet 134, so that the air pressure to be reduced can be reduced before reaching the upper inlet 133. It is connected in communication between the feed storage tanks 110.

Here, the width (d) along the circumferential direction of the upper inlet 136 of the cylindrical portion 132a of the housing 132 to improve the decompression effect is the cylindrical portion 132a of the housing 132 of the adjacent distribution wings 137 ) It is formed smaller than the width (W) between the inner wall and the opposite end.

In the illustrated example, when the commercially used rotary valve is made of the same width (W) between the inner wall of the cylindrical portion (132a) and the opposite end, and the width of the upper inlet, a shield 145 that closes a part of the upper inlet It is constructed to satisfy the conditions described above by applying.

 In addition, the position where the lower end of the pressure reducing pipe 140 is connected is a partition receiving space 137a between a distribution blade 137 rotated between the upper inlet 133 and the lower outlet 134 to communicate with the upper inlet 133. The position before being applied is applied as low as possible. Preferably, the position where the lower end of the pressure-reducing tube 140 is connected is between the horizontal reference position among the upper areas in the upward direction of the rotary blades based on the horizontal reference position extending horizontally while traversing the rotation axis 136. The angle is applied to a position in the range of 5 to 15 degrees. In this case, since the partition receiving space 137a between the distribution wings 137 is disposed to be shielded from the lower outlet 134, communication with the decompression pipe 140 of the partition receiving space 137a can be quickly achieved in an ascending process. Thereby, the desired decompression can be sufficiently achieved before the divided receiving space 137a between the distribution wings 137 reaches the upper inlet 133.

On the other hand, the inner side of the main feed storage tank 110 to which the upper end of the decompression tube 140 is connected is changed to downward through the interference by changing the path of the airflow discharged through the decompression tube 140 so as to facilitate the dropping of the feed. The acceleration guide plate 148 is mounted.

The fall promotion guide plate 148 is provided at the lower end of the inclined portion 148a and the lower portion of the inclined portion 148a, which extends inclined downward from the inner side of the upper portion than the connected upper end of the pressure reducing tube 140 of the main feed storage tank 110. It has a vertical portion (148b) extending vertically, and the space between the inner surface of the main feed storage tank (110) from the inclined portion (148a) to the end of the vertical portion (148b) is lower and the pressure reducing tube (140). Only the communication part is opened, and the rest part is formed in a closed structure.

According to this structure, the air flow discharged through the upper end of the pressure reducing tube 140 is in contact with the drop promoting guide plate 148, and then the path changes to the open downward direction, thereby facilitating the dropping of feed.

The rotation driving unit 147 controls the rotation shaft 136 of the rotary valve 130 to be controlled by the control unit 195 and rotates. The rotation driving unit 147 may be constructed as a power relay element that relays the rotational force generated by the motor (not shown) and the motor to the rotating shaft 136 through power relay means such as gears, belts, and chains.

The main transfer pipe 150 is extended to have the main transfer flow path 152 and is piped to a length capable of transferring feed to the terminal storage tank 170 described below, and communicates with the lower outlet 134 of the rotary valve 130 The main transfer inlet 154 is connected to the lower coupling portion 132c of the rotary valve 130 so as to communicate with the main flow path 152.

The main transfer pipe 150 transfers the feed introduced from the lower outlet 134 through the main transfer inlet 154 by the blowing force.

The blower 155 is coupled to one side of the main transport pipe 150 to generate a blowing force that is fed through the main transport flow path 152 to feed the food falling through the main transport inlet 154. The blower 155 is controlled in operation by the control unit 195.

The sub conveying pipe 160 is branched from the main conveying pipe 150 but is coupled to the main conveying pipe 150 in communication with each other.

The sub transfer pipes 160 may be provided to correspond to the number and location of the terminal storage tanks 170 applied.

The terminal storage tank 170 is installed at the end of each sub-transfer pipe 160 to store feed introduced through the sub-transfer pipe 160.

The flow path control valves 181a and 181b are installed on the main transfer pipe 150 and the sub transfer pipe 160 so that feed fed through the main transfer inlet 154 is transferred to one of the sub transfer pipes 160. It is installed to control the transfer path. For reference, reference numeral 181a is installed on the main transfer pipe 150, and reference numeral 181b is installed on the sub transfer pipe 160.

Here, the flow path control valve 181b installed on the sub-transfer pipe 160 is preferably applied with a pinch valve that opens and closes the flow path by elastic deformation to suppress clogging and failure due to feed attachment.

Similarly, a pinch valve may be applied to the flow path control valve 181a installed on the main transfer pipe 150.

The flow path opening and closing structure of the pinch valve is variously disclosed, such as Korean Patent No. 10-0886871, and the method of opening and closing the sleeve through which the feed is transferred is controlled by the control unit 195, thereby controlling various types of actuators to press the sleeve. Just apply it.

The control unit 190 controls opening and closing of the flow path control valves 181a and 181b, and the rotary drive unit 147 and the blower 155.

The control unit 190 includes an operation unit 191, a display unit 193, and a control unit 195.

The operation unit 191 is configured to set supported functions. As an example, the operation unit 191 may be constructed to select the terminal storage tank and the amount of feed to be fed by using the unique identification information provided to each terminal storage tank 170.

In this case, the control unit 195 processes the feed transport path information set by the operation unit 191 to be displayed on the display unit 193, and provides flow control valves 181a and 181b so that feed can be transferred to the selected feed transport path. By controlling and operating the rotary drive unit 147 and the blower 155, the feed stored in the main feed storage tank 110 is transferred to the corresponding terminal storage tank 170 along the selected feed transport path by rotation of the rotary valve 130. Control.

For example, the flow control valve 181a installed in the first sub-transfer pipe 160 when it is set to transfer the feed to the first terminal storage tank 170 disposed along the extension direction of the main transfer pipe 150 in FIG. 1. Is opened, the flow path control valve 181a installed in the main transfer pipe 150 between the first sub transfer pipe 160 and the second sub transfer pipe 160 is closed and blown by the blower 155, and the rotary valve The rotation driving unit 147 may be controlled to rotate 130.

Meanwhile, the control unit 195 controls the supply valve 123 of the feed supply tank 121 in which the feed to be transported is stored, and controls the driving motor 126 to control the feed to feed the feed. It is controlled to be supplied to the storage tank (110).

During the feed transfer process, the feed received in the partition receiving space 137a between the distribution blades 137 passing through the lower outlet 134 of the rotary valve 130 falls and is applied to the blowing force through the main transfer pipe 150. The airflow of the blowing pressure applied to the divided receiving space 137a in the process of being transferred by the lower outlet 134 and ascending is ejected into the main feed storage tank 110 through the pressure reducing tube 140 and resolved. In addition, the air flow discharged to the main feed storage tank 110 through the pressure reducing tube 140 is changed by the air flow downward by the fall facilitation guide plate 148, thereby facilitating dropping of the stored feed to improve feed transport efficiency. Order.

Such a blower-type feed transport system can support remote feed transport by arranging the main transport pipe to reach livestock farms at a distance. In particular, the present system provides an advantage of improving the feed supply efficiency by attenuating the wind pressure applied between the distribution vanes along the rotational direction after the discharge of the feed of the rotary valve so as not to affect the drop of the feed.

110: main feed storage tank 130: rotary valve
147: rotating drive unit 150: main transfer pipe
155: blower 160: sub transfer pipe
170: terminal storage tank 181a, 181b: flow path control valve
190: control unit

Claims (5)

delete delete A main feed storage tank installed to be able to discharge the feed through the main outlet at the bottom;
It is provided on the lower part of the housing by receiving feed introduced through the upper inlet port provided in communication with the main discharge port by rotation of a plurality of distribution blades extending radially on the rotation axis in the housing and spaced apart from each other along the circumferential direction. A rotary valve discharging through the lower outlet;
A rotation driving unit for rotationally driving the rotation shaft of the rotary valve;
A main conveying pipe having a main conveying inlet communicating with a lower outlet of the rotary valve and extending with a main conveying passage for conveying the introduced feed by blowing force;
A blower coupled to one side of the main conveying pipe to generate a blowing force conveyed through the main conveying passage to feed falling through the main conveying inlet;
A plurality of sub-transfer pipes coupled to each other in communication with the main transfer pipes;
A terminal storage tank installed to store feed introduced through the sub-transfer pipe;
A plurality of flow path control valves installed on the main transfer pipe and the sub transfer pipe to control feed paths such that feed fed through the main transfer inlet is transferred to any one of the sub transfer pipes;
A control unit for controlling opening and closing of the flow path control valves, and controlling the rotary drive unit and the blower;
Between the upper inlet and the lower outlet so that the wind pressure generated by inflow of a part of the blower flow generated from the blower between the distribution vanes in the process of ascending after passing through the lower outlet can be reduced before reaching the upper inlet. A pressure-reducing tube connected in communication between the main feed storage tank and the housing on the rising position of the distribution blade;
On the inner surface of the main feed reservoir to which the upper end of the pressure reducing pipe is connected, a drop promoting guide plate mounted to facilitate the dropping of the feed by changing the path of the air flow discharged through the pressure reducing pipe downward by interference; Blower method feed transport system, characterized in that. [4] The blower feed system according to claim 3, wherein the width along the circumferential direction of the upper inlet is formed smaller than the width between the inner wall of the adjacent dispensing wings and the opposite end. According to claim 4, The flow control valve installed on the sub-transfer pipe is a blower feed system, characterized in that a pinch valve is applied.

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