KR200436019Y1 - Total Mixed Ration self-feeder - Google Patents

Abstract

The present invention relates to an automatic feeder of TMR feed, and more specifically, having two screws on the upper and lower portions, the lower screw serves to discharge the feed, and the upper screw feeds the feed raised by the lower screw to the lower portion. It acts to lower the cavities in the lower part after a certain amount of feed is initially supplied, to control both the upper and lower screws with a single drive motor and does not require a separate discharge arm. Due to the simple structure, the manufacturing cost can be reduced, and the size of the outlet can be adjusted by having an outlet structure cut out so that the user can easily adjust the amount of feed supplied.

TMR feed, automatic feeder, upper and lower screws, discharging structure

Description

THM feed automatic feeder {Total Mixed Ration self-feeder}

1 is a perspective view and a configuration diagram of a conventional TML feeder

2 is a front view of the present invention TEMAL feed automatic feeder

Figure 3 is a side view of the subject TIMAL feed automatic feeder

Figure 4 is a plan view of the subject TIMAL feed automatic feeder

Figure 5 is the mobility of the feed in the present invention TEMAL feed automatic feeder

※ Explanation of code for main part of drawing

100. Feed Feeder 110. Hopper

111. Upper Shaft 112. Lower Shaft

113. First upper screw 114. Second upper screw

115. First lower screw 116. Second lower screw

120. Rail 130. Wheel

140. Outlet 141. Supply section

150. Drive unit 151. Drive motor

152. Belt 161. First Control Box

162. Second control box 170. Discharge structure section

171.Adjustment door 172.Screw

181. Movement direction of feed by lower screw

182. Direction of movement of feed by upper screw

The present invention relates to an automatic feeder of TMR feed.

In general, TMR feeds (total mixed rations) supplied to livestock are summarized as mentioned in the prior art.TMR feeds include all the nutritional components (hay + corn + cotton + grains) required by individual livestock. It is a fermented mixture of other nutrients, and the feed of the animal is mixed in the same concentration. Therefore, it is possible to prevent the livestock from eating or leaving the feed, keeping the MDI maximum, and maintaining the diet according to the feed design.採食, and can be fed according to the nutritional needs, to control the nutrition of the feed, to eat fiber on average, to maintain homeostasis in the lumen, to facilitate the operation of lumen fermentation, Feed efficiency is improved by easy feeding, and low-cost organic by-products such as starch meal, sweet corn residue and fresh feed pulp that can be formulated Can be used as a feed resource use highly self-feed, it is possible to design a low-cost feed such that contribute to the reduction of salaries and labor, can use the low palatability of feed, which will contribute to the specification of the scientific management of modern cattle.

Conventional TMR feed production equipment includes a trailer-type TMR feed production device that installs a feed mixer on a trailer chassis and is connected to a tractor to drive and move, and a planted TMR feed production line. Since a homogeneous mixing is made by driving for a certain time and then the feed is discharged at a time, a storage and feeding device is needed to temporarily store the TMR feed in a TMR feed production line and supply it as necessary.

However, the conventional TMR feed production line has a problem that the storage and supply device for temporarily storing and gradually feeding the feed TMR feed received intermittently is not installed.

The reason for this is due to the physical properties of the TMR feed expressed by viscosity, moisture content, entanglement of fibrous materials, etc., when the TMR feed is stored in a 1 to 6 ton storage container and the feed is discharged little by little through the outlet, ), The amount of TMR feed filled in the container is not consistently subsided and the feed is not quantitatively fed.

In order to solve the above problems, as shown in FIG. 1, a configuration of the inclined wall 13 is formed on both sides of the bottom of the storage container, and a pair of discharge screws. (11) a and b are installed close to the storage container bottom plate 14 and the inclined wall 13, and the feed direction of the screw shaft 15 is transferred from the bottom 14 to the inclined wall 13 above. Symmetrically install the discharge screw pins 16a, 16b on both screws a, b to collect feed centrally from both ends of the reservoir, and correspond to the outlets 17 at the bottom of the center of the reservoir. It is comprised by installing the discharge arm 20 so that it may have the discharge angle 19 in the center.

However, although the above-described prior art is more advanced than the prior art, the discharge screw pins 16a and 16b are symmetrically installed so that the pair of discharge screws 11 a and b collect the feed from both ends of the storage container to the center. Since the TMR feed at the bottom of the container is discharged through the outlet by a predetermined amount, there is a problem in that the TMR feed existing in the center and the top of the container has a hollow phenomenon.

The reason is that the feed is collected in the center of the container by the pair of discharge screws 11 a, b and the discharge screw pins 16a, 16b, and the feed cannot be discharged to the discharge port by the discharge arm. Since the feed up to the top of the container and the feed up to the top of the container is a humid TMR feed, there is a limit to the downward flow. Therefore, after a certain amount of the feed in the bottom of the container is discharged, There was a problem that (tunnel) phenomenon occurred, and a plurality of discharge arms 20 must be separately provided in the center of the shaft 15 to facilitate the discharge, and a pair of discharge screws 11 a, b Since each drive motor 21 must be provided to rotate in different directions, there is a problem that the manufacturing cost increases.

In addition, the prior art has a problem that can not control the amount of feed supplied because the size of the outlet is fixed.

The present invention is to solve the above problems, provided with two screws in the upper and lower, the lower screw serves to discharge the feed and the upper screw serves to lower the feed raised by the lower screw to the lower portion Therefore, the purpose is to prevent the cavitation occurring at the bottom after a certain amount of feed is initially supplied.

The present invention has another object to provide a configuration that can control the upper and lower screws with a single drive motor, and can reduce the manufacturing cost with a simple structure because it does not require a separate discharge arm.

The present invention has yet another object to provide an outlet structure so that the user can easily control the amount of feed supplied.

The present invention is to achieve the above object, a detailed description will be described with reference to the accompanying drawings.

FIG. 2 is a front view of the present invention TEM feed automatic feeder, FIG. 3 is a side view of the TH invention feed automatic feeder, FIG. 4 is a plan view of the TH invention feed automatic feeder, and FIG. Feed mobility in the autofeeder.

2, 4, 5, the present invention is provided with a moving wheel 130 to move along the rail 120 at the bottom of the hopper 110 of the TMR feed automatic feeder 100, hopper One side of the 110 is provided with a drive unit 150 having a drive motor 151, the lower center of the hopper 110 is provided with a discharge port 140 to discharge the feed.

In the lower shaft 112 provided in the lower part of the hopper 100, the first lower screw 115 and the second lower screw 116 twisted in opposite directions to each other are formed in the center of the lower shaft, that is, the feed outlet 114. The first upper screw 113 is provided integrally with the lower shaft 112 in a state that is not connected to the discharge portion to the upper shaft 111 provided in the upper portion of the hopper 100 and twisted in opposite directions to each other. ) And the second upper screw 114 is provided integrally with the upper shaft 111 in a state in which it is not connected to the center portion.

The first upper screw 113, the second upper screw 114, the first lower screw 115, and the second lower screw 116 connected to the upper and lower shafts 111 and 112 are opposite to each other on each axis. Of course, the screw is provided in the direction, the first upper screw 113 and the first lower screw 115 are provided twisted in the opposite direction facing each other, the second upper screw 114 and the second lower screw. 116 is also provided to be twisted in the opposite direction facing each other.

That is, the upper screws 113 and 114 and the lower screws 115 and 116 are provided in opposite directions.

The upper and lower shafts 111 and 112 provided in the hopper 110 are connected to one driving motor 151 and the belt 152 of the driving unit 150. When driving the driving motor 151, the belt ( The upper and lower shafts 111 and 112 are rotated in the same direction by the 152, and the first and second lower screws 115 and 116 are twisted in opposite directions to the lower shaft 112. Feed is collected toward the outlet 140 provided in the lower center of the hopper 110 is discharged through the outlet 140, and at the same time moved upward by the first lower screw 115 and the second lower screw 116 The feed is moved to the outside and bottom from the center of the hopper by the first upper screw 113 and the second upper screw 114 twisted in opposite directions on the upper shaft 111, the feed is lowered again The feed is formed in the lower center of the hopper 110 by the first lower screw 115 and the second lower screw 116 of the lower shaft 112. Are gathered toward the discharge port 140 is discharged through the discharge port 140. The

In the above description, the driving motor 151 of the driving unit 150 and the upper and lower shafts 111 and 112 are connected by the belt 152 to be driven. Instead of the belt 152, the driving is performed using a chain or a gear. It's important to note that the way you do it is optional.

As in the above configuration, the present invention is a configuration capable of reliably preventing the cavitation occurring after discharging a predetermined amount of feed at the time of discharging the TMR feed containing a lot of moisture.

In addition, the outer top side of the hopper 110 is provided with a first controller 161 to control the TMR feeder of the present invention.

The present invention, as shown in Figure 3, the outlet 140 is provided with a supply unit 141 for actually feeding the feed feed to the livestock of the livestock, the discharge structure section that can adjust the size of the outlet 140 ( 170 is provided, the configuration is a screw 172 is connected to the second controller 162 linked to the first controller, the screw 172 is a control door 171 that can cover the outlet 140 is provided Is connected, the control door 171 is provided to be raised or lowered from the outside of the outlet 140.

That is, when the control door 171 is raised by the second controller 162 and the screw 172, the outlet 140 is opened, on the contrary, when the control door 171 is lowered, the outlet 140 is closed. The user can easily adjust the size of the outlet.

Here, the control door 171 should be provided according to the size and shape of the outlet 140, the reason is that if the size of the control door 171 is smaller than the outlet 140, the feed is leaked into the gap so that the feed amount of the feed Since it is difficult to adjust, it should be provided with a slightly larger control door 171 than the outlet 140.

According to the prior art in which a predetermined amount of feed is supplied to an outlet having a fixed size according to the moving speed of the hopper 110 moving along the rail 120, there is no method of controlling the amount of feed other than the moving speed of the hopper 110. In addition, since there is a problem that the manufacturing cost is increased because a sophisticated mechanical configuration is required to adjust the moving speed, it is proposed to improve the discharge structure section 170 of the present invention, the hopper moving along the rail 120 ( The moving speed of the 110 may be constant and the size of the outlet 140 may be adjusted by adjusting the size of the outlet 140, and the size of the outlet 140 may be simultaneously adjusted while controlling the moving speed of the hopper 110. Feeding while adjusting can make it easier to control the feeding rate.

Although the screw 172 is adopted as the structure which raises and lowers the control door 171 in the above, it turns out that it is selectable to adopt a structure, such as a hydraulic / pneumatic cylinder.

The present invention has two screws at the top and bottom, as seen in the above configuration, the lower screw serves to discharge the feed and the upper screw serves to lower the feed raised by the lower screw to the lower portion. It has the effect of preventing the cavitation occurring at the bottom after a certain amount of feed is supplied to the feed. It is possible to control both the upper and lower screws with one driving motor and does not require a separate discharge arm. The manufacturing cost can be reduced and the size of the outlet can be adjusted by providing an outlet structure section, so that the user can easily adjust the amount of feed supplied.

Claims (3)

The lower portion of the hopper 110 containing the TMR feed is provided with a moving wheel 130 moving along the rail 120, and a screw provided in the hopper is driven by the driving motor 151 in the lower center of the hopper. In the automatic feeder of the TMR feed for automatically supplying feed to the provided outlet 140, The first lower screw 115 and the second lower screw 116 twisted in opposite directions to the lower shaft 112 provided in the lower portion of the hopper 100 are not connected at the center of the lower shaft. It is provided integrally with the sub-shaft 112 to collect the feed in the center and discharged to the discharge port 140, twisted in the opposite direction to each other in the upper shaft 111 provided in the upper portion of the hopper 100 in the opposite direction to the lower axis The first upper screw 113 and the second upper screw 114 is provided in the center portion is not connected to the upper shaft 111 is integrally provided with a configuration that lowers the feed raised from the lower screw Egg feeder. According to claim 1, TEM feed feeder characterized in that the discharge structure section 170 is provided with a screw 172 and the control door 171 to adjust the size of the outlet 140 of the hopper (110). The feed automatic feeder of claim 2, characterized in that it has a cylinder instead of a screw (172).

Images