KR101141747B1 - Feed fixed quantity supply apparatus - Google Patents

Abstract

PURPOSE: An apparatus for supplying fixed quantity of fodder is provided to easily adjust proper quantity of fodder while reducing load applied to a screw. CONSTITUTION: An apparatus for supplying fixed quantity of fodder comprises an inlet chute(20), a main frame(10), a weighing hopper(40), a plurality of screws(60), and a discharge gate(70). In the inlet chute, fodder is poured. The main frame is equipped with a plurality of screw housings. The weighing hopper communicates with the main frame and checks the proper quantity of fodder. A plurality of screws transfers fodder to the weighing hopper. The discharge gate is combined with the lower part of the weighing hopper and discharges proper amount of fodder.

Description

Feed metering device {FEED FIXED QUANTITY SUPPLY APPARATUS}

The present invention relates to a feed metering device, and more particularly, to a feed metering device that can easily quantitate feed while reducing the load on the screw.

So-called TMR (Total Mixed Ration) is a mixed feed that is a kind of livestock feed. It is a mixed feed made to contain nutrients such as vitamins and minerals, and forages such as rice straw, grasses and hay.

This TMR feed is quantitatively supplied to the bag by a separate device called the feed metering device. Bags fed with quantitative feed proceed to the packaging stage.

Such conventional feed quantitative feeding apparatus is well known in the Republic of Korea Patent Application No. 10-2002-0074565 and Application No. 10-2007-0042952.

However, in the conventional feed quantitative feeding apparatus, since the complete blended feed, which is mostly grass, rice straw, hay, etc., has to be pushed out with a screw, the load applied to the screw is significantly increased as the feed materials are entangled in the screw or aggregated together. Therefore, even if the operation of the screw is not smooth or the screw is operated, there is a problem in that the poor packaging often occurs because the amount of forage is not uniformly supplied to meet the quantity.

Korean Patent Office Application No. 10-2002-0074565 Korean Patent Office Application No. 10-2007-0042952

SUMMARY OF THE INVENTION An object of the present invention is to provide a feed quantitative feeding apparatus that can easily adjust the quantification of feed while reducing the load on the screw.

The object includes: a main frame having an inlet shute into which feed is fed and a plurality of screw housings disposed below the inlet chute; A weighing hopper communicating with the main frame and checking a quantity of the feed by a load cell coupled to the side; A plurality of screws formed in different sizes and disposed in the plurality of screw housings, respectively, for feeding feed fed through the inlet chute to the weighing hopper; And a discharge gate coupled to the lower portion of the weighing hopper so as to be opened and closed to discharge the quantitative feed, wherein at least one of the plurality of screw housings has a cutout portion formed at a lower end thereof, and a lower portion of the cutout portion. The area is achieved by a feed metering device, characterized in that the tray for supporting the feed is arranged.

The plurality of screws may include a large screw and a small screw having different cross-sectional area sizes, and the large screw and the small screw may be arranged in pairs.

Both the large screw and the small screw, the screw shaft rotated by the driving force of the motor; And it may include a transfer blade for spirally coupled to the outer wall of the screw shaft for transporting the feed, the screw shaft may have a wider cross-sectional area of the introduction portion than the remaining region.

It may further include a vibration feeder coupled to the tray to impart vibration to the tray.

According to the present invention, there is an effect that can easily fit the quantification of the feed while reducing the load on the screw.

1 is a front view of a feed metering device according to an embodiment of the present invention,
Fig. 2 is a plan view of Fig. 1,
3 is a left side view of FIG. 1;
4 is a right side view of FIG. 1;
5 is a structural diagram of a large screw,
6 is a structural diagram of a small screw,
7 is a perspective view of a screw housing.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

1 is a front view of the feed metering device according to an embodiment of the present invention, Figures 2 to 4 are respectively a plan view, left side view and right side view of Figure 1, Figure 5 is a structural diagram of a large screw, Figure 6 is a small The structure diagram of the screw and FIG. 7 is a perspective view of the screw housing.

Referring to these drawings, the feed metering device of the present embodiment is for supplying a complete blended feed called TMR (Total Mixed Ration) to the bag in a quantitative manner, the main frame including an inlet shute (main) 20 (main frame 10), weighing hopper 40, a plurality of screws 50, 60, and a discharge gate 70.

Briefly explaining the operation prior to the detailed structure description, the feed fed through the inlet chute 20 is pushed into the weighing hopper 40 by screws 50, 60, and then the load cell ( When the quantity is checked by the load cell 41 is discharged through the discharge gate 70 can be fed into the bag of the quantitative feed.

Looking at the detailed structure, first, the main frame 10 is a portion forming the appearance of the feed metering device of the present embodiment. Therefore, the main frame 10 is made of a rigid metal material.

The main frame 10 may be provided with an inlet chute 20 into which feed is introduced, and screw housings 31 and 32 in which screws 50 and 60 are disposed.

Of course, alternatively, the main frame 10 may form only an outer frame, and the inlet chute 20 and the screw housings 31 and 32 may be separately provided and welded or bolted to each other.

The inlet chute 20 has its entrance arranged in the upper region of the main frame 10 so that feed is fed from the top.

Inside the inlet chute 20, a leveler 21 is disposed for smooth feeding of the feed. The leveler 21 may have a rod structure in which a body is coupled to the main frame 10, and a sensing portion is disposed inside the inlet chute 20.

In the main frame 10, a plurality of screw housings 31 and 32 are formed in the lower region of the inlet chute 20.

As shown in FIG. 7, the screw housings 31 and 32 include two large screw housings 31 and two small screw housings 32 disposed on both sides of the two large screw housings 31. Include. Four screw housings 31 and 32 are arranged in a row, and screws 50 and 60 are accommodated in the screw housings 31 and 32, respectively.

The screws 50 and 60 serve to transfer the feed fed through the inlet chute 20 to the weighing hopper 40. In this embodiment, the screws 50 and 60 are large screws having different cross-sectional sizes. 50 and a small screw 60.

At this time, the large screw 50 is disposed in the two large screw housing 31, respectively, the small screw 60 is disposed in the two small screw housing 32, respectively.

As a result, in the case of the present embodiment, the large screw 50 and the small screw 60 may be provided in a double type each applied two.

Thus, the screw (50, 60) is provided in a two-stage type, while the other side is discharged feed into the bag while the other side is to be metered, and then the other side is adjusted while the other side is to be fed while the quantity is adjusted. This enables organic operation. Of course, although this is a preferred form, the scope of the present invention is not limited to this matter.

5 and 6, the large screw 50 and the small screw 60 will be described. Both the large screw 50 and the small screw 60 are rotated by the driving force of the motors 81 and 82. And shafts 51 and 61, and conveying vanes 52 and 62 that are helically coupled to the outer walls of the screw shafts 51 and 61 to feed the feed.

In this structure, the inlet regions 51a and 61a of the screw shafts 51 and 61 are formed to have a larger cross-sectional area than the remaining regions. In other words, the inlet regions 51a and 61a of the screw shafts 51 and 61 are made thicker than the other side.

By having such a structure, it is possible to reduce the amount of feed introduced from the inlet areas 51a and 61a, thereby reducing the load on the screws 50 and 60 from the feed introduction stage.

In other words, when a large amount of feed is introduced from the inlet regions 51a and 61a, the load applied to the screws 50 and 60 is inevitably increased. As shown in this embodiment, the inlet region 51a and 61a of the screw shafts 51 and 61 is increased. By making the thickness thicker than the other side, the feed amount in this area can be reduced, thereby reducing the load on the screws 50 and 60.

Referring to FIGS. 5 and 6 again, the large screw 50 and the small screw 60 are coupled to the screw shafts 51 and 61, respectively, to receive the driving force transmission unit 55 receiving the driving force from the motors 81 and 82. 65 is provided. The driving force transmission units 55 and 65 may be provided by a pulley and a belt structure or a conveyor structure with the motors 81 and 82.

In the present embodiment, the motors 81 and 82 are applied to the individual drive motors 81 and 82 corresponding to the large screws 50 and the small screws 60, respectively.

However, a large number of large screws 50 and small screws 60 may be paired and driven by using a common motor.

Meanwhile, referring to FIG. 7, a cutout 32a is formed at the lower ends of the two small screw housings 32. In the lower region of the cutout 32a, a tray 85 supporting the feed falling through the cutout 32a is disposed. The cutout 32a is not formed at all of the lower ends of the small screw housing 32, but is formed only in some sections. Therefore, the tray 85 is also coupled to the cutout 32a.

As such, the lower ends of the two small screw housings 32 are partially cut off, and the trays 85 are coupled under the cutout portions 32a to allow a portion of the feed to escape to the trays 85. The load on the load can be further reduced.

In the present embodiment, the cutout 32a is formed at the lower ends of the two small screw housings 32, but the cutout 32a may be formed in the large screw housing 31.

1 and 3, a vibration feeder 87 for vibrating the tray 85 is coupled to the tray 85. The vibrating feeder 87 vibrates the tray 85 to allow fine adjustment during quantitative adjustment.

The weighing hopper 40 communicates with the main frame 10 and is a part for checking the quantity of feed by the load cell 41 coupled to the side.

The load cells 41 may be arranged in pairs on both sides of the weighing hopper 40, in which case, the reliability of the quantitative check can be increased.

The discharge gate 70 is openly coupled to the lower portion of the weighing hopper 40 to form an outlet for discharging the quantitative feed. As shown in FIG. 1, the discharge gate 70 is opened and closed while being rotated by the actuator 71.

The operation of the feed metering device having such a configuration will be described.

First of all, the large screw 50 and the small screw 60 are operated, and the vibration feeder 87 under the tray 85 is also operated, so that all three components are operated in the first stage, through the inlet chute 20. Allow the feed to be fed into the weighing hopper 40.

For example, when 80% to 90% of the supply is made, the second stage stops the vibration of the large screw 50 and the tray 85 and only the small screw 60 is operated to feed the feeding hopper 40.

Subsequently, when approximately 95% is full, the operation of the small screw 60 is stopped in the third step, and only the tray 85 is operated so that the feed drawn out of the tray 85 when the small screw 60 is operated is vibrated feeder 87. ) Is gradually supplied to the weighing hopper 40 by vibration. By vibrating the tray 85 in the third step and gradually feeding the feed, it is easy to adjust the quantity of the feed.

After this process, if the quantity is detected by the load cell 41, the operation of the tray 85 is also stopped and the quantity is supplied. Then, the discharge gate 70 is opened and the quantity of feed is fed into the fixed food bag. It becomes possible.

When the injection is completed, the discharge gate 70 is closed again and the operation of adjusting the quantity is repeated.

As such, according to the present embodiment, it is possible to easily adjust the quantification of the feed while reducing the load on the screws 50 and 60.

As described above, the present invention is not limited to the described embodiments, and various modifications and changes can be made without departing from the spirit and scope of the present invention, which will be apparent to those skilled in the art. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

10: main frame 20: inlet chute
21: leveler 31,32: screw housing
40: weighing hopper 41: load cell
50: large screw 51: screw shaft
52: transfer blade 51a: inlet area
60: small screw 61: screw shaft
62: feed blade 61a: inlet area
70: discharge gate 81,82: motor
85 tray 87 vibration feeder

Claims (4)

A main frame having an inlet shute for feeding and a plurality of screw housings disposed under the inlet chute;
A weighing hopper communicating with the main frame and checking a quantity of the feed by a load cell coupled to the side;
A plurality of screws formed in different sizes and disposed in the plurality of screw housings, respectively, for feeding feed fed through the inlet chute to the weighing hopper; And
A discharge gate coupled to the lower portion of the weighing hopper so as to be opened and closed to discharge a fixed amount of feed;
At least one of the plurality of screw housings is formed with a cutout at the lower end,
Feeding metering device, characterized in that the tray for supporting the feed is arranged in the lower region of the cutout.
The method of claim 1,
The plurality of screws include a large screw and a small screw of different cross-sectional size,
The large screw and the small screw feed metering device, characterized in that arranged in pairs.
The method of claim 2,
Both the large screw and the small screw,
Screw shaft rotated by the driving force of the motor; And
It includes a conveying wing that is spirally coupled to the outer wall of the screw shaft for transporting the feed,
The screw shaft feed metering device, characterized in that the introduction area is formed to have a wider cross-sectional area than the remaining area.

The method of claim 1,
And a vibration feeder coupled to the tray to impart vibration to the tray.

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