KR102588787B1 - A liquid feed bowl - Google Patents

Abstract

The present invention relates to a hopper having a space for storing feed, a feed discharge pipe connected to the bottom of the hopper and discharging the feed stored in the hopper, located below the feed discharge pipe, the bottom surface of which is flat or inclined on both sides, and In a liquid feed feeder consisting of a feed tray having a storage space formed over a certain length, and a water discharge pipe that supplies water to the feed tray, the outlet of the water discharge pipe is spaced a certain distance away from the bottom surface of the feed tray. It provides a liquid feed feeder characterized in that it is positioned.

Description

Liquid feed feeder {A liquid feed bowl}

The present invention relates to a liquid feed feeder. More specifically, the water discharge pipe is positioned above the center of the bottom of a feed tray with a predetermined length and the bottom is flat or inclined in both directions, and is spaced apart at predetermined intervals. This relates to a liquid feed feeder that allows the feed supplied to the feed tray to be swept in both directions by the hydraulic pressure of water falling from the water discharge pipe to the feed tray, so that it can be spread evenly throughout the entire storage space of the feed tray.

In general, feed and water are supplied to livestock such as pigs, cows, goats, sheep, etc. (hereinafter collectively referred to as 'livestock') raised in farms or livestock barns. A wet system in which feed and water are supplied simultaneously according to the feeding method of the feed and water. There is a dry method in which feed and water are provided separately.

A representative prior art related to the wet type feeder is the Republic of Korea Intellectual Property Office Utility Model Publication No. 20-0422989 (hereinafter referred to as 'prior art 1').

The prior art 1 is a pig feed feeding device having a feed discharging means 12 below a feed storage bin and consisting of a feed stand below it, in which a water supply pipe 22 is installed on one side of the feed storage bin, and an upper part of the water supply pipe. An automatic water level control device (28) is installed, and the bottom of the water supply pipe is close to the upper surface of the feed tray so that the height is adjusted by a stopper.

However, prior art 1 has a problem in that the water supply pipe is provided on one side of the feed storage container, so not only does the feed and water not mix well, but the feed does not spread evenly throughout the entire space of the feed tray.

To solve this problem, Republic of Korea Intellectual Property Office Patent Publication No. 10-1963490 (liquid feed feeder) (hereinafter referred to as prior art 2) has been disclosed.

Prior art 2 installs a water supply means at the bottom of the rotary shaft pipe, and the water supply means is located on the upper surface of the central protrusion of the feed tray. As the rotary shaft tube rotates, the water supply means moves to the outer storage space of the feed tray. The point is to supply water evenly to the entire storage space of the feed tray by rotating along and supplying water.

Prior art 2 has the advantage that the water supply means and the feed discharge pipe are located in the center of the feed tray, so that when the feed is discharged, it can be mixed with the water and discharged into the feed tray at the same time, so that feed and water can be mixed and supplied in time.

However, prior art 2 also has a problem in that feed cannot be intentionally supplied evenly to the entire storage space of the feed tray, and furthermore, in the case where the central part of the feed tray is flat rather than a protruding shape, the feed discharged into the center of the feed tray is There is a problem in that it becomes more difficult to evenly supply the feed to the entire storage space of the feed tray.

In addition, water can be supplied evenly in a feed tray in which the water supply means and the feed discharge pipe are located in the center of the feed tray and the feed tray is long on both sides, but there is a problem in that feed cannot be supplied evenly to the entire feed tray.

The attached Figure 1 is a diagram showing the overall configuration of a conventional system liquid feed supply device.

The system liquid feed supply device as shown in Figure 1 is a method in which liquid feed is directly injected into the feed transfer pipe. In this method, a lot of feed waste accumulates inside the liquid feed transfer pipe 440 and the liquid feed distribution pipe 450, which takes time. Over time, it deteriorates and livestock have no choice but to eat the contaminated feed, endangering the health of the livestock. The inside of the liquid feed transfer pipe must be disassembled and then cleaned, but it is impossible and requires a lot of facility and after-sales service costs and a professional technician to operate it. This happens.

In addition, liquid feed with high viscosity cannot be supplied evenly to the entire space of the feed tray.

Figures 2 and 3 are diagrams showing the configuration of a general individual dry and wet food feeder.

As shown in Figure 2, individual dry and wet feed feeders provide feed and water separately, which takes a long time to consume, resulting in poor growth rates.

Additionally, it is difficult to supply food in a limited manner, so the feed tray 560 is always dirty and it is difficult to supply fresh food.

In addition, in the case of young piglets, the feed particles are soft, which causes poor feed flow in the hopper, which hinders growth.

In addition, general individual dry and wet feed feeders also have the problem of not being able to distribute feed evenly throughout the feed tray 560.

Figure 4 is a diagram showing a conventional pneumatic system liquid feed supply device.

As shown in Figure 4, a feed storage bin 310, a blower 320, a feed transfer pipe 330, at least one feed distribution pipe 340, and at least one feed stand 360 disposed in each feed distribution pipe 340. ), but is characterized in that a water distribution pipe (350) is further connected to each feed distribution pipe (340).

When the feed is distributed to the feed distribution pipe 340 through the feed transfer pipe 330 by driving the blower 320, water is supplied together from the water distribution pipe 350, so that the feed is distributed along with water to the feed tray 360. ) is a system in which feed is supplied to the feed tray 360 through air pressure.

However, there is a visual area inside the feed distribution pipe where feed waste accumulates, which requires frequent cleaning and is unhygienic. In addition, when feeding feed by air, feed dust flies, which can lead to feed loss and deteriorate the livestock environment, threatening the health of both livestock and managers.

In addition, the feed discharged through the feed distribution pipe is mixed with water and discharged into the feed tray in a viscous state, so the mixture of discharged feed and water has a limit to spreading throughout the feed tray even if air pressure is used due to its viscosity. there is.

Like the system liquid feed supply system, this can also be operated only with large facility costs, after-sales maintenance costs, and professional technicians.

Korea Intellectual Property Office Registered Utility Model Publication No. 20-0422989 Republic of Korea Intellectual Property Office Registered Patent Gazette Registration No. 10-1963490

The present invention to solve the problems described above is to place water discharge pipes at predetermined intervals above the center of the bottom of a feed tray that is formed to a predetermined length on both sides and whose bottom is flat or inclined in both directions. The purpose is to provide a liquid feed feeder that allows the feed supplied to the feed tray to be swept in both directions by the hydraulic pressure of the water falling from the water discharge pipe to the feed tray, so that it can be spread evenly throughout the entire storage space of the feed tray.

Another object of the present invention is to locate the water discharge pipe at the center of the bottom surface of the feed tray and configure the outlet of the water discharge pipe to be close to the bottom surface of the feed tray, so that the water discharged from the water discharge pipe flows into the outlet of the water discharge pipe and the feed tray. The aim is to provide a liquid feed feeder that allows the feed supplied to the feed tray to be spread evenly throughout the entire storage space of the feed tray by using the water pressure generated when it escapes between the bottom surfaces of the feed tray.

The present invention for achieving the above-described object is a hopper having a space for storing feed, a feed discharge pipe connected to the bottom of the hopper and discharging the feed stored in the hopper, and located below the feed discharge pipe and extending over a certain length on both sides. In a liquid feed feeder consisting of a feed tray having a long storage space and a water discharge pipe for supplying water to the feed tray, the outlet of the water discharge pipe is positioned at a predetermined distance above the bottom of the feed tray. It is characterized by being composed.

It is preferable that at least one hole having a smaller diameter than the flow path of the water discharge pipe is formed through the outer diameter of the outlet of the water discharge pipe.

In the space of the hopper, it is preferable to install a rotating shaft tube that rotates with the power of a drive motor and has an internal space formed in a vertical position.

The water discharge pipe is inserted into the inner space of the rotary shaft pipe, and the outlet of the water discharge pipe is exposed to the outside of the lower end of the rotary shaft pipe, and a gap of 1 mm to 300 mm is formed on the bottom surface of the inner space of the feed tray. It is desirable to configure them to be spaced apart so that they are formed.

The present invention includes a hopper having a space for storing feed, a feed discharge pipe connected to the bottom of the hopper and discharging the feed stored in the hopper, and a storage space located below the feed discharge pipe and formed at a certain length or more on both sides. In the liquid feed feeder including a feed stand and a water discharge pipe that supplies water to the feed stand, a rotating shaft pipe that rotates with the power of a drive motor and has an internal space is installed in a vertical position in the space of the hopper, , The inner space of the rotating shaft pipe is characterized in that water is supplied to the center of the inner bottom surface of the feed tray.

In the present invention, water discharge pipes are positioned at predetermined intervals above the center of the bottom of a feed tray that is formed to be long at a predetermined length on both sides and the bottom surface is formed to be flat or inclined in both directions, so that the water pressure of the water falling from the water discharge pipe to the feed tray is placed. By causing the feed supplied to the feed tray to be swept in both directions of the feed tray, the feed supplied to the feed tray is induced to spread evenly throughout the entire storage space of the feed tray through high water pressure, so that the livestock do not struggle for food. It has the effect of being able to consume liquid feed evenly.

In addition, as feed and water are mixed in the storage space of the open feed tray, fresh feed is always supplied, making it safe from disease. Since frequent cleaning is not necessary, waste of manpower can be eliminated, and feed wastage can also be reduced, helping farmers It has the effect of contributing to improving productivity.

Figure 1 is a diagram showing the overall configuration of a system liquid feed supply device according to the prior art.
Figures 2 and 3 are diagrams showing the configuration of a typical individual dry and wet feed feeder.
Figure 4 is a diagram showing the overall configuration of a liquid feed supply device of a pneumatic system according to the prior art.
Figure 5 is a diagram showing the overall configuration of a liquid feed feeder according to a preferred embodiment of the present invention.
Figure 6 is a diagram showing an excerpt of the main configuration of the liquid feed feeder shown in Figure 5.
Figure 7 is a diagram showing the water discharge pipe structure of a liquid feed feeder according to another embodiment of the present invention.
Figure 8 is a diagram showing another structure of the water discharge pipe shown in Figure 7.
Figure 9 is a diagram showing another example of a liquid feed feeder.
Figure 10 is a diagram showing another example of a water discharge pipe of a liquid feed feeder.
Figure 11 is a diagram showing another example of a water discharge pipe of a liquid feed feeder.
FIG. 12 is a view showing a configuration in which the bottom surface of the feed tray is inclined in both directions in the liquid feed feeder shown in FIG. 5.

Hereinafter, embodiments of the present invention will be described with reference to the attached drawings. In the detailed description to be described later, various embodiments of the present invention will be presented to achieve the above-described technical problem. And other embodiments that can be presented with the present invention are replaced with descriptions in the configuration of the present invention.

The present invention is intended to enable multiple livestock to feed at the same time and consume food evenly to induce rapid and even growth. There is a purpose, and in order to achieve this, the feed tray must be as long as possible. In this case, water can be sent to the entire feed tray, but feed cannot be sent, so when sending feed from the center to both sides of the feed tray, hydraulic pressure is used. There are technical features in doing so.

In addition, the present invention mixes the feed and water externally while being discharged without passing through the mixer tank and the liquid feed transfer pipe, that is, the feed and water are individually introduced into the feed tray, and then the feed and water are mixed in the feed tray. As a result, foreign substances such as feed do not accumulate and decompose in the transfer pipe, so it has a technical feature that helps livestock grow and reduces manpower waste by providing fresh liquid feed at all times.

The attached Figure 5 is a diagram showing the overall configuration of the liquid feed feeder according to a preferred embodiment of the present invention, and Figure 6 shows an excerpt of the main configuration of the liquid feed feeder shown in Figure 5. It is a drawing.

As shown in Figures 5 and 6, the liquid feed feeder of the present invention consists of a feed tray 20 containing feed, a hopper 10, and a feed discharge pipe 14.

The feed stand (20) is installed on the floor of the barn and receives the feed stored in the hopper (10) through the feed discharge pipe (14), and is supplied with water supplied from the water discharge pipe (40) so that the pigs can consume it. It is stored as liquid feed in the form of dough.

The top of the feed stand (20) is configured to be open, and a storage space (22) for storing liquid feed is provided inside. The storage space (22) must be long on both sides centered on the feed discharge pipe (14). The bottom surface (24) is made flat or inclined at both ends based on the water discharge pipe (40). That is, the entire bottom surface 24 of the feed tray 20 is configured to be flat as shown in Figure 5, or the bottom surface 24a of the feed tray 20 is angled in both directions based on the center as shown in Figure 12. It slopes downward as you go further. This equally applies to each embodiment to be configured in the present invention.

The hopper 10 is installed as a support means on the feed stand 20 at a certain distance apart. A space 12 for storing feed is formed inside the hopper 10, and a feed discharge pipe is located at the bottom of the hopper 10. (14) shall be provided.

The feed discharge pipe 14 is located between the hopper 10 and the feed stand 20, and has a cylindrical pipe shape, the upper end of which communicates with the space 12 of the hopper 10, and the lower end of the feed stand 20. It is located at a certain distance from the center of the floor surface 24 and discharges the feed stored in the space 12 of the hopper 10 into the internal storage space 22 of the feed holder 20.

Meanwhile, a feed stirring means is installed inside the hopper 10 to smoothly discharge the feed without entanglement. The feed stirring means includes a rotating shaft pipe 30 installed vertically in the inner space of the hopper 10, and a drive motor 34 connected to the tip of the rotating shaft pipe 30 and rotating the rotating shaft pipe 30. , It is coupled to the outer diameter of the rotating shaft pipe 30 and includes a brush (not shown) that prevents entanglement of feed.

A water discharge pipe 40 for supplying water to the feed tray 20 is inserted into the inner space 32 of the rotating shaft pipe 30, as shown in FIG. 6. The inlet of the water discharge pipe 40 is connected to a pump through a supply line, and a flow path 42 is formed therein to pass the water supplied according to the pumping operation of the pump (not shown).

Meanwhile, the water discharge pipe 40 is inserted into the internal space 32 of the rotating shaft pipe 30. At this time, the outlet 40b of the water discharge pipe 40 is located on the bottom surface of the storage space 22 of the feed stand 20. (24) It should be located in the center. Preferably, the outlet 40b of the water discharge pipe 40 is located close to the bottom surface 24 of the storage space 22 of the feed tray 20 while maintaining a predetermined distance, or is in contact with the bottom surface 24. Position it. The reason for locating the outlet (40b) of the water discharge pipe (40) at the center of the bottom surface (24) of the feed stand (20) is that the water supplied to the feed stand (20) is supplied by using the water pressure of the water discharged from the water discharge pipe (40). This is to encourage the feed to spread evenly throughout the entire space of the feed stand (20) by sweeping the feed to both sides of the feed stand (20). In particular, if the outlet 40b of the water discharge pipe 40 is located close to the center of the bottom surface 24 of the feed tray 20 while maintaining a predetermined distance or is brought into contact with the bottom surface 24, the water discharge pipe ( When the water discharged from 40 passes through the gap 44 between the outlet 40b of the water discharge pipe 40 and the bottom surface 24 of the feed tray 20, the flow rate is increased (i.e., the water pressure is increased). (higher) causes the feed to spread evenly throughout the storage space (22) of the feed stand (20). That is, when the outlet 40b of the water discharge pipe 40 approaches or contacts the bottom surface 24 of the feed tray 20, the outlet 40b of the water discharge pipe 40 and the bottom surface of the feed tray 20 ( 24), the gap 44 between them is bound to be smaller than the diameter of the flow path 42 of the water discharge pipe 40, and therefore, when the water passes from the wide flow path 42 through the narrow gap 44, the flow speed naturally increases. The feed that has fallen to the center of the bottom surface (24) of the feed stand (20) is swept to both sides, causing it to spread evenly throughout the storage space (22) of the feed stand (20).

In the present invention, it is preferable to install the outlet 40b of the water discharge pipe 40 close to the bottom surface 24 of the feed tray 20 while maintaining a predetermined distance. For example, the outlet of the water discharge pipe 40 ( It is desirable that the gap between 40b) and the bottom surface 24 of the feed tray 20 is maintained at 1 mm to 300 m. However, if the drop is too large (i.e., the gap between the outlet 40b and the bottom surface 24 is large), the water hits the bottom surface 24 of the feed tray 20 and splashes out of the feed tray 20. It may be difficult to distribute the feed evenly to both sides. Meanwhile, the water pressure of the water supplied to the water discharge pipe 40 is preferably maintained at 1 bar or more so that a constant amount of water can always be discharged by driving the pump.

The attached Figure 7 is a diagram showing the structure of a water discharge pipe of a liquid feed feeder according to another embodiment of the present invention.

As shown in FIG. 7, at least one hole 50 is formed on the outlet outer diameter of the water discharge pipe 40 at regular intervals along the circumferential surface, and the water supplied after passing through the flow path 42 passes through the hole 50. So that it can be discharged to the feed tray (20). In this structure, the diameter of the hole 50 is smaller than the diameter of the flow path 42, so the flow speed of water increases in the process of passing from the wide flow path through the narrow hole 50 to the bottom surface 24 of the feed tray 20. By sweeping the feed that has fallen to the center to both sides, the feed is encouraged to spread evenly throughout the storage space (22) of the feed stand (20). Meanwhile, the hole 50 may be partially opened at the bottom of the water discharge pipe 40 as shown in FIG. 8.

The attached Figure 9 is a diagram showing a liquid feed feeder according to another embodiment of the present invention.

As shown in Figure 9, unlike the above-described embodiment, the liquid feed feeder does not insert the water discharge pipe 40 into the rotating shaft pipe 30, but rather supplies water to the internal space 32 formed inside the rotating shaft pipe 30 itself. It has the function of discharging water. For this purpose, a water discharge pipe 40 is connected to the tip of the rotating shaft pipe 30 with a swing 130 in between, and the rotating shaft pipe 30 uses the power of the driving motor 34. Even if it rotates, the water discharge pipe 40 can remain fixed without rotating through the swing 130. That is, a hopper 10 having a space for storing feed, a feed discharge pipe 14 connected to the bottom of the hopper 10 and discharging the feed stored in the hopper 10, and a feed discharge pipe 14 perpendicular to the space of the hopper 10. It is installed in an erect state and rotates with the power of the drive motor 34 and supplies water through the water discharge pipe 40. It is located below the feed discharge pipe 14 and is installed on the floor of the livestock house. The feed discharged from the feed discharge pipe 14 and the water discharged from the rotary shaft pipe 30 are supplied together and stored as liquid feed in the form of dough, with a predetermined length formed on both sides based on the rotary shaft pipe 30. It includes a feed stand (20) having a storage space (22), and the outlet of the rotary shaft pipe (30) is located at the center of the bottom surface (24) of the feed stand (20) so that the water discharged from the rotary shaft pipe (30) Using water pressure, the feed supplied to the feed stand (20) is swept to both sides, causing the feed to spread evenly throughout the entire space of the feed stand (20).

In addition, the outlet of the rotating shaft tube 30 is configured to be close to or contact the bottom surface 24 of the storage space 22 of the feed tray 20, and in particular, the outlet of the rotating shaft tube 30 and the feed tray 20 ) The gap 44 between the bottom surfaces 24 is formed to be smaller than the diameter of the inner space 32 of the rotary shaft pipe 30, so that water passes through the narrow gap 44 in a wide flow path. The flow speed becomes faster and the feed that has fallen to the center of the bottom surface (24) of the feed stand (20) is swept to both sides and is evenly spread throughout the entire storage space (22) of the feed stand (20). Meanwhile, at least one or more holes may be further formed on the outlet outer diameter of the rotation shaft pipe 30, so that the water passing through the rotation shaft pipe 30 can be discharged to the feed tray 20 through the hole, Through this, the feed is encouraged to spread evenly throughout the entire storage space (22) of the feed stand (20).

Figure 10 is a diagram showing another embodiment of the water discharge pipe of a liquid feed feeder.

As shown in Figure 10, it consists of a hopper 10, a feed discharge pipe 14, and a feed stand 20 that is long and has a flat bottom surface 24 or is inclined on both sides, and the water discharge pipe 240 is connected to the hopper. It is a liquid feed feeder connected to the outside of (10).

In the liquid feed feeder of FIG. 10 above, the outlet of the water discharge pipe 240 is located between 1 mm and 300 mm from the center of the bottom surface 24 of the feed stand 20 to maintain the water pressure of the water discharged from the water discharge pipe 240. By using this, the feed supplied to the storage space (22) of the feed stand (20) is swept and the feed is spread evenly throughout the storage space (22) of the feed stand (20).

Figure 11 is a diagram showing another embodiment of the water discharge pipe of a liquid feed feeder.

As shown in Figure 11, it consists of a hopper 10, a feed discharge pipe 14, and a feed stand 20 that is long and has a flat bottom or is inclined on both sides, and a motor ( Feed is discharged by installing a screw (18) that rotates with the power of 16) or various feed discharge means. In the liquid feed feeder of this structure, the water discharge pipe (250) is separately connected to the outside of the hopper. .

In the liquid feed feeder of FIG. 11 above, the outlet of the water discharge pipe 250 is located between 1 mm and 300 mm from the center of the bottom surface 24 of the feed stand 20 to maintain the water pressure of the water discharged from the water discharge pipe 250. It is used to sweep the feed supplied to the feed stand (20) and induce the feed to spread evenly throughout the storage space (22) of the feed stand (20).

10: Hopper 14: Feed discharge pipe
20: Feed stand 22: Storage space
24, 24a: Bottom surface 30: Rotating shaft pipe
40: water discharge pipe 42: euro
44: gap

Claims (8)

A hopper (10) having a space for storing feed, a feed discharge pipe (14) connected to the bottom of the hopper (10) and discharging the feed stored in the hopper (10), and below the feed discharge pipe (14). It includes a feed stand (20) located and having a storage space (22) formed on both sides longer than a certain length, and a water discharge pipe (40) formed with a flow path (42) for supplying water to the feed stand (20), Using the hydraulic pressure of water falling from the water discharge pipe 40 to the feed stand 20, the feed is supplied to the feed stand 20 through the feed discharge pipe 14 and accumulated in the center of the bottom of the feed stand 20. In the liquid feed feeder that sweeps in both directions of the feed stand (20) to spread the feed evenly throughout the entire storage space (22) of the feed stand (20),
In the space 12 of the hopper 10, a rotating shaft tube 30 is installed vertically, which rotates with the power of the drive motor 34 and has an internal space 32 formed therein;
The outlet of the rotary shaft tube (30) is located above the center of the feed tray (20) and is positioned at a certain distance away from the bottom surface (24) of the feed tray (20);
The water discharge pipe 40 is inserted into the inner space 32 of the rotating shaft pipe 30, and the outlet 40b of the water discharge pipe 40 is in contact with the bottom surface 24 of the feed tray 20. and;
The outlet outer diameter of the water discharge pipe 40 has a smaller diameter than the flow path 42 of the water discharge pipe 40, and the bottom surface of the feed tray 20 is raised with the flow rate of water passing through the flow path 42 increased. (24) At least one hole 50 is formed through the center to discharge the accumulated feed;
A liquid feed feeder, characterized in that the bottom surface (24) of the feed stand (20) is inclined in both directions with respect to the center.
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