KR102233426B1 - feed feeder using feed quantitative feed device - Google Patents

Abstract

Disclosed is a feed supplier using a feed quantitative supplying device. According to an embodiment of the present invention, the feed supplier comprises: a storage container (110) with a predetermined storage space to store feed therein; a housing (120) disposed on a lower portion of the storage container (110) and having an accommodation space formed therein; a feed quantitative supplying device installed in the housing (120) and configured to quantitatively supply feed supplied from the storage container (110); a spraying unit (180) configured to spray feed which is quantitatively metered by the feed quantitative supplying device (130); and a control unit (190) electrically connected to the feed quantitative supplying device (130) and the spraying unit (180) to control the operations of the same. According to the present invention, the feed supplier can automatically supply feed.

Description

Feed feeder using feed quantitative feed device

The present invention relates to a feed feeder for automatically supplying feed to aquaculture fish in fish farms, and more particularly, feed feed using a feed quantitative feed device capable of spraying a fixed amount of feed using a feed feed feed device. It is about selfishness.

In general, fish farms are artificially supplying feed to farmed fish. For the smooth growth of aquaculture fish, such feed must be provided at a fixed time and quantity, and most fish farms now rely on manual labor by workers. In other words, feed is supplied by a method in which an operator carries a container containing feed directly and sprays feed into the farm using a hand or a simple tool.

However, feeding feed by hand as described above takes a lot of time and manpower, and is not preferable in terms of productivity or efficiency. In particular, as the scale of fish farms is becoming larger today, the supply of feed by hand by workers is facing a limit in terms of productivity and the like.

In addition, feeding by hand has an undesirable aspect for the smooth growth of farmed fish. Aquaculture fish can grow more smoothly only when a small amount of feed is frequently supplied at regular time intervals. Feeding by hand makes it difficult to supply such a small amount of frequent feed due to time or manpower limitations.

Therefore, in most cases, a larger amount of feed is supplied at a time than a predetermined amount of feed, which inhibits the smooth growth of farmed fish. In addition, the feed supply of more than this amount may cause the problem of water pollution due to waste of feed and settled feed, as the excess feed sinks to the bottom of the farm without processing the feed supplied by the farmed fish.

On the other hand, feed supply by hand also has a problem in that feed cannot be widely spread throughout the farm. In other words, due to the limitation of manual labor, feed is concentrated in some areas of the farm, and in this case, feed may not be supplied evenly to the entire farmed fish.

In addition, since a large number of farmed fish are concentrated in a narrow area to consume feed, the healthy growth of farmed fish is adversely affected by food competition or stress due to the dense space. It goes without saying that this may eventually lead to a decline in the marketability of farmed fish.

In view of the above problems, some devices for automatically supplying feed in conventional fish farms have been proposed. For example, Korean Laid-Open Patent Publication No. 10-2013-0000145 (Patent Document 1) discloses a feed supply device capable of automatically supplying feed by scattering by centrifugal force or air pressure. In addition, the present applicant has proposed a feed supply device having an impeller and capable of mixing and discharging the feed stored in the hopper through the previously applied Korean Patent Publication No. 10-2016-0016208 (Patent Document 2).

However, the feed supply device of the above patent documents is evaluated to have some limitations in the quantitative control or supply range of feed. In other words, in the case of Patent Document 1, the feed can be automatically discharged, but the quantitative control of the feed is made in a semi-automatic manner that requires the user's manipulation, and since it is a method of dispersing the feed by a certain centrifugal force or air pressure, the range in which feed can be supplied. (Distance) will also be limited. In Patent Document 2, since feed is also supplied to a certain position through a feed supply pipe, the supply range is limited.

In addition, in the case of the above-described conventional patent documents, feed can be simply supplied in large quantities, and although it is semi-automatic, there is an advantage of being able to supply feed by scattering, but it is somewhat insufficient to supply a constant amount of feed. In addition, it was not easy to accurately supply feed to a wide range, even if feed is supplied in a quantity.

Accordingly, the applicant of the present invention has been registered by applying for a feed supply device for a farm in the Republic of Korea Patent No. 10-2117279. Looking at this, as shown in FIG. 1, a housing 10 having an inner space divided into an upper space 17 and a lower space 18 by an intermediate blocking plate 13, and the upper space 17 It is formed in a part of the upper plate 11 of the housing 10 to cover the supply port 11a for supplying the feed 82 to the upper space 17, and the upper space is formed in the intermediate blocking plate 13 A drop hole 13a, which is a passage through which the feed 82 falls from 17 to the lower space 18, and a part of the lower plate 15 of the housing 10 forming the bottom of the lower space 18 It is formed in the outlet 15a for discharging the feed 82 from the lower space 18, and the feed 82 that is connected to the outlet 15a and discharged from the outlet 15a to the outside by high-speed air. The discharging device 60 for blowing and the feed 82 installed in the upper space 17 and supplied from the supply port 11a are rotated in a state filled in the space between the wings to the falling hole 13a. The upper impeller 30 for discharging and the feed 82 installed in the lower space 18 and falling from the dropping hole 13a are rotated in a state accommodated in the space between the blades to the discharge port 15a. The lower impeller 40 for discharging, and a rotary shaft rod 53 that integrally rotates with each other by forming a central axis of the upper impeller 30 and the lower impeller 40, and rotationally driving the rotary shaft rod 53 Including an electric motor 51, wherein the falling hole 13a is out of the supply port 11a and the discharge port 15a when viewed from the upper side to the lower side of the position of the circumference of the rotary shaft bar 53 A feed supply device for a farm, characterized in that it is installed at the location, was proposed.

For this reason, it is possible to supply a certain amount of feed over a wide range. However, the feed supply device of the conventional registration patent No. 10-2117279 described above has a disadvantage that feed is caught in the gap between the upper and lower impellers rotating with respect to the middle plate and the lower plate, respectively, in order to supply a quantity of feed, As a result, there was a drawback that excessive force was applied to the motor. In addition, the conventional feed supply device has a disadvantage in that the above-described intermediate plate and lower plate are deformed by the fastening force of the bolt when the housing is coupled with a bolt.

The present invention is a feed feeder using a feed quantitative feed device that has improved the conventional problems as described above.

According to an embodiment of the present invention, a feed feeding device using a feed quantitative feeding device capable of rapidly and accurately supplying feed in a quantitative manner using a feed quantitative feeding device and spreading the feed over a wide range is provided. I want to provide.

The present invention discloses a feed feeder using a feed quantitative feed device. The feed feeder according to an embodiment of the present invention includes a storage passage provided with a predetermined storage space to store feed therein, a housing located under the storage container and having an accommodation space therein, and installed in the housing and the A feed quantitative supply device capable of supplying the feed supplied from the reservoir in a quantitative amount, a spraying unit capable of spraying the feed measured by the feed quantitatively by the feed quantitative supply device, the feed quantitative supplying device and the spraying unit It is electrically connected to and provides a feed feeder using a feed quantitative feed device including a control unit capable of controlling the drive.

The feed feeder using the feed quantitative feed device according to an embodiment of the present invention can supply a quantity of feed as if it is a millstone method, and also, the feed supplied in a quantity can be widely distributed and supplied using a blower.

In addition, since a large amount of feed is stored in a storage container and then automatically sprayed through a spraying unit, it is possible to automate the feed supply of fish farms, which were conventionally dependent on manual labor. This has many advantages in terms of work efficiency and productivity.

In addition, the advantages described above enable the supply of feed in a fixed amount at a predetermined time, thereby preventing the problem of water pollution due to waste of feed or excess feed. In addition, since the amount of feed is spread more evenly throughout the farm, it is possible to promote healthy growth of farmed fish and contribute to the improvement of marketability.

1 is a view schematically showing a conventional feed feeder.
2 is a view schematically showing a feed feeder using a feed quantitative feed device according to an embodiment of the present invention.
3 is an exploded perspective view of FIG. 2.
4 is a cross-sectional view of FIG. 2.
5 is a schematic view showing a feed quantitative supply device used in an embodiment of the present invention.
6 is an exploded perspective view of FIG. 5.
7 is a cross-sectional view of a feed quantitative feed device used in an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the following embodiments are provided to aid understanding of the present invention, and it should be noted that the scope of the present invention is not limited to the following embodiments. In addition, the following embodiments are provided to more completely describe the present invention to those with average knowledge in the art, and a detailed description of a known configuration determined to unnecessarily obscure the technical subject matter of the present invention. Will be omitted.

2 to 4 are views schematically showing a feed feeder using a feed quantitative feed device according to an embodiment of the present invention.

2 to 4, the feed feeder using the feed quantitative supply device according to an embodiment of the present invention includes a storage container 110 provided with a predetermined storage space to store feed therein, and the storage container 110. ), and a housing 120 with an accommodation space formed therein, and a feed quantitative supply device 130 installed in the housing 120 and capable of supplying the feed supplied from the reservoir 110 in a quantitative manner. Wow, a spraying unit 180 capable of spraying the feed quantitatively measured by the feed quantitative feeding device 130, and the feed quantitative feeding device 130 and the spraying unit 180 are electrically connected to A controller 190 may be included to control driving.

Specifically, the storage container 110 has a predetermined storage space therein, and feed can be stored in the storage space. The shape of the storage container 110 is not limited as long as it has a shape in which a predetermined storage space can be secured. That is, it is not particularly limited to the appearance. However, in this embodiment, for convenience of explanation, the storage container 110 is formed in a cylindrical shape, the upper part is formed to be open, and a funnel-shaped hopper part 114 is formed in the lower part to provide a storage space in the storage container 110. To allow the feed stored in the container to be discharged.

A lid 112 may be provided on the opened upper portion of the storage container 110. That is, the lid 112 can be opened and the open upper part can be sealed, such as supplying and storing feed into the storage space inside the storage container 110.

The housing 120 is located under the storage container 110. The storage container 110 has an accommodation space therein, and may be formed in a rectangular housing shape. At this time, as shown in the drawing, the housing 120 is formed with an opening formed in the upper portion so that the feed supplied to the reservoir 110 can be introduced, and spraying of the spraying unit 180 to be described later on one side of the side The pipe 184 is positioned to pass through, and a spraying port 120b is formed so that the feed supplied in a fixed amount can be sprayed to the outside.

In addition, a vibrating sound may be generated in the sprinkling port 120b when blowing from the blower of the sprinkling unit 180 to be described later. Accordingly, an elastic support member 121 is installed to stably support the sprinkling pipe 184 and provide an elastic restoring force to minimize the vibration sound. That is, the wind and feed flow from the blower, and at this time, a vibrating sound is generated inside the spray pipe 184. Accordingly, the elastic support member 121 provides an elastic restoring force and at the same time suppresses the vibration sound.

Meanwhile, the feed quantitative supply device 130 is installed in the receiving space in the housing 120 to quantitatively measure the feed supplied from the reservoir 110. Referring to FIGS. 5 to 7, feed A body 140 having an inlet 140a to allow the inflow and an outlet 140b to discharge the introduced feed in a quantitative manner, and a body 140 located within the body 140 so that the feed can be measured in a quantitative manner. The valve unit 150, a transfer unit 160 capable of transferring the feed measured by the valve unit 150 to the outlet 140b so that the feed measured by the valve unit 150 can be discharged to the outside of the body 140, and the valve unit ( 150) and by providing power to the transfer unit 160 so that it can rotate, it may include a drive motor 170 capable of measuring and transferring feed.

Specifically, the body 140 is formed in a cylindrical shape and has a lower case 142 having an outlet 140b formed on one side of the bottom plate 142a, and is coupled to the upper side of the lower case 142, and is coupled to one side of the bottom plate 144a. An upper case 144 having a through hole 145 formed therein, a plate 146 formed to cover the upper portion of the upper case 144 and having an inlet 140a formed to allow feed to be introduced into one side thereof, and the The metering membrane 147 and the lower case 142 and the upper case are positioned to penetrate the upper and lower portions of the plate 146 and to allow the lower part through the plate 146 to contact the surface of the valve unit 150. Each of the bottom plates 142a and 144a of the 144 and a plurality of bolts 148 that penetrate and fix the plate 146 may be included.

Here, the lower case 142 and the upper case 144 are formed in the same shape, and have a diameter smaller than the diameters of the bottom plates 142a and 144a formed in a circular plate shape, and the bottom plates 142a and 144a. Consisting of side walls (142b, 144b) protruding upward to have, a plurality of bolts 148 are bolt holes (140c) formed in the bottom plates (142a, 144a) located outside the side walls (142b, 144b) It is installed to penetrate through the bottom plates 142a and 144a.

At this time, a pair of reinforcing ribs 140d are formed to protrude on both sides of the bolt holes 140c formed in each of the bottom plates 142a, 144a, so that the bottom plates 142a, 144a are applied to the pressing force when the bolts 148 are combined. ) And the shape of the plate 146 is prevented from being deformed. That is, the reinforcing ribs 140d support the lower portions of the bottom plates 142a, 144a and the plate 146, so that the bottom plates 142a, 144a and the plate 146 are twisted by the coupling force of the bolts and nuts. Can be prevented.

In addition, the outlet 140b formed in the lower case 142 is characterized in that the diameter is larger than that of the through hole 145 formed in the upper case 144. That is, when the feed is discharged from the upper case 144 to the lower case 142 through the through hole 145 later, the feed in the lower case 142 is to be smoothly discharged to the spraying unit 180.

In addition, the valve unit 150 is rotatably installed in the upper case 144 formed in a cylindrical shape, and the transfer unit 160 is rotatably installed in the lower case 142. The valve unit 150 and the transfer unit 160 may be rotatably installed with respect to the body 140 by a rotation shaft 143 connected to the driving motor 170. At this time, the rotation shaft 143 is formed in a square column shape, and the coupling hole between the valve unit 150 and the transfer unit 160 to which the rotation shaft 143 is coupled is also formed in a rectangular shape, so that when the rotation shaft 143 is rotated The valve unit 150 and the transfer unit 160 may be rotated together with the rotation shaft 143.

Meanwhile, the valve unit 150 and the transfer unit 160 are formed to have a plurality of partition walls 152 and 162 in a serrated shape, and feed may be filled between the partition walls 152 and 162. In this case, the partition walls 152 and 162 are configured to have eight partition walls 152 and 162 in an embodiment of the present invention, but may be applied in various ways such as six or five depending on the case.

In addition, the valve unit 150 and the transfer unit 160, as shown in Figure 5, by forming a feed jam prevention protrusions (152a, 162a) under each of the partition walls (152, 162) to protrude the valve unit ( 150) and the bottom plate 144a of the upper case 144, and between the transfer unit 160 and the bottom plate 142a of the lower case 142 can be prevented from getting caught.

That is, when feed is inserted between the bottom plates 142a and 144a and the valve unit 150 and the transfer unit 160, the valve unit 150 and the transfer unit 160 do not rotate smoothly. A problem of damage may occur due to an excessive force applied to the drive motor 170 rotating the valve unit 150 and the transfer unit 160. Accordingly, in an embodiment of the present invention, feed jamming prevention protrusions 152a and 162a are formed on the barrier ribs 152 and 162 of the valve unit 150 and the transfer unit 160, respectively, to minimize feed jamming.

In addition, as shown in the drawing, the valve unit 150 has a tapered upper edge, that is, when feed is introduced through the inlet 140a of the body 140, the valve unit 150 Feed is filled between the tapered upper surface and the partition wall 152. At this time, the valve unit 150 is in a state in which the lower portion of the metering membrane 147 coupled to the above-described plate 146 is in contact with the tapered upper surface. Feed can be measured quantitatively while rotating, and since the upper portion of the valve unit 150 is formed to be tapered, it can rotate smoothly when the valve unit 150 rotates within the upper case 144, In addition, the conventional feed supply device has a disadvantage in that feed is crushed into a powder form as feed is caught between the plate 146 and the partition walls 152 and 162 of the valve unit 150, but one embodiment of the present invention As described above, the feed quantitative supply device 130 according to the example forms a tapered upper portion of the valve unit 150, and is in contact with it to flatten the feed so that it can be quantified. 147) was used to prevent the feed from being pinched to prevent the feed from being crushed.

Here, the metering membrane 147 is rigid, and the bottom surface is formed to have a predetermined inclination angle to correspond to the tapered partition wall 152 of the valve unit 150, and the upper side of the valve unit 150 In a state in which the metering membrane 147 is in contact, the valve unit 150 can be rotated. In addition, the metering membrane 147 has a through hole 149 formed in the plate 146 so that the metering membrane 147 can be replaced during continuous use, and the metering membrane 147 is attached and detached in the through hole 149. can do.

That is, the metering membrane 147 is constantly rubbed against the valve unit 150 and abraded, so that the feed cannot be accurately metered after a long period of use. To this end, in an embodiment of the present invention, the metering membrane 147 is detachable so that it can be used interchangeably. That is, the metering membrane 147 is positioned to be inserted into the upper case 144 through the through hole 149, and at the end, a locking end 147a extending along the rim is formed to protrude, so that the through hole ( 149).

Meanwhile, the feed measured by the valve unit 150 and the metering membrane 147 flows into the lower case 142 through the through hole 145 formed in the bottom plate 144a of the upper case 144, at this time A transfer unit 160 is installed in the lower case 142, and a quantity of feed is filled between the partition walls 162 of the transfer unit 160 through the through hole 145, and the filled feed is transferred to the transfer unit. As the 160 rotates, it is discharged through the discharge port 140b formed in the bottom plate 142a of the lower case 142.

In addition, the drive motor 170 is positioned so that the rotation shaft 143 passes through the body 140, and the valve unit 150 and the transfer unit 160 are fixedly coupled to the rotation shaft 143 to the rotation shaft ( When 143 is rotated, the valve unit 150 and the transfer unit 160 rotate in the same direction as the rotation shaft 143.

That is, the valve unit 150 and the transfer unit 160 rotate within the body 140 by the rotation of the driving motor 170, and the valve unit 150 and the transfer unit 160 It is a structure that improves the feed flowing into the case 144 and the lower case 142 in a quantitative manner so that the feed is discharged through the through hole 145 and the outlet 140b.

At this time, the inlet 140a formed in the plate 146 of the body 140, the through hole 145 formed in the upper casing, and the outlet 140b formed in the lower casing are arranged in a zigzag shape. Accordingly, the feed introduced into the upper case 144 through the inlet 140a is formed in the through hole 145 in the bottom plate 144a of the upper case 144 opposite the inlet 140a by the rotation of the valve unit 150 The feed is allowed to fall into the lower case 142 through the through hole 145, and the feed flowing into the lower case 142 through the through hole 145 is rotated by the transfer unit 160 to the bottom of the lower case 142 opposite to the through hole 145 To be discharged to the outside of the body 140 through the outlet (140b) formed in.

On the other hand, the feed quantitatively improved in the feed quantitative supply device 130 is discharged through the outlet 140b, and the discharged feed is moved to the spraying unit 180.

The spraying unit 180 is a blower 182 capable of supplying air according to the application of power, and " ㅗ" shape, one side in the horizontal direction is connected to the blower 182, the upper side is formed to receive the feed discharged from the outlet (140b), the other side in the horizontal direction is the feed supplied from the outlet (140b) It may include a spray pipe 184 formed to be sprayed.

That is, when feed is introduced into the upper side connected to the outlet 140b, air is supplied from the blower 182 so that the feed can be sprayed.

Therefore, in the feed feeder using the quantitative feeding device according to an embodiment of the present invention, the driving motor 170 is driven when the feed stored in the storage container 110 is supplied into the feed quantitative feed device 130 through the hopper unit 114. As a result, the valve unit 150 and the transfer unit 160 are rotated. At this time, the feed stored in the storage container 110 is introduced into the body 140 through the inlet 140a of the feed quantitative supply device 130 by its own weight, and the introduced feed is the valve unit 150 located in the upper case 144 It is distributed between the partition walls 152 of the valve unit 150 as the valve unit 150 rotates, and the feed is filled and metered into the valve unit 150 by the size of the space between the partition wall 152 and the partition wall 152 by the metering membrane 147. .

Thereafter, the feed measured by the valve unit 150 is transferred into the lower case 142 through the through hole 145 formed in the bottom plate 144a of the upper case 144 while the valve unit 150 rotates. In this case, a transfer unit 160 is provided in the lower case 142 and has a structure that rotates in the same manner as the valve unit 150. In addition, since the transfer unit 160 has a wider space between the partition wall 162 and the partition wall 162 than the valve unit 150, smooth inflow is possible.

That is, in the case of the valve unit 150, the upper side of the partition wall 152 is formed to be tapered, whereas the transfer unit 160 does not have a tapered portion, so the transfer unit 160 has a relatively large amount compared to the valve unit 150. It is a structure that can be filled with feed.

Meanwhile, the feed filled between the bulkheads 162 of the transfer unit 160 is rotated by the transfer unit 160 and the body 140 through the outlet 140b formed in the lower case 142 and the bottom plate 142a. The measured feed is discharged to the outside, that is, to the outside of the feed quantitative supply device 130.

That is, the feed quantitative supply device 130 is capable of discharging the feed in a quantitative manner by measuring and transporting the feed in a millstone method.

After that, the feed discharged from the feed quantitative supply device 130 is sprayed by the spraying unit 180 and supplied to the fish.

At this time, in an embodiment of the present invention, the blower 182 is used as the spraying unit 180, and the structure of the valve unit 150 and the transfer unit 160 in the form of a multi-stage stacked structure used in the present invention It is possible to prevent the feed from flowing back into the body 140 of the feed quantitative supply device 130 by the city wind, and the feed may be sprayed only in a desired direction.

On the other hand, the control unit 190 is located in the receiving unit 122 formed in the housing 120 and the drive motor 170 of the feed quantity supply device 130 and the blower 182 of the spraying unit 180 It is connected electrically so that it can be controlled electrically.

In addition, the receiving unit 122 in which the control unit 190 is located is formed to be in communication with the outside so that it can be replaced or repaired when an abnormality occurs in the control unit 190. That is, after forming the receiving part 122 in the housing 120, forming an opening to communicate with the receiving part 122, and installing a cover 124 to seal the opening, the receiving part ( 122) allows the control unit 190 to be selectively withdrawn.

Therefore, it is possible to quickly and accurately measure and supply feed in a quantitative manner by the feed quantitative supply device 130 described above.

The spirit of the present invention is limited to the described embodiments and should not be defined, and all those having equivalent or equivalent modifications to the claims as well as the claims to be described later belong to the scope of the inventive concept.

110: storage bin 112: lid
114: hopper part 120: housing
122: storage unit 124: cover
130: feed quantitative supply device
140: body 140a: inlet
140b: outlet 140c: bolt hole
140d: rib 142: lower case
142a: base plate 142b: side wall
143: rotating shaft 144: upper case
144a: base plate 144b: side wall
145: through hole 146: plate
147: dividing membrane 148: bolt
150: valve unit 152: bulkhead
152a: feed snag prevention protrusion 160: transfer unit
162: bulkhead 162a: feed trapping prevention protrusion
170: drive motor 180: spray unit
182: blower 184: spray pipe
190: control unit

Claims (9)

A storage bin 110 provided with a predetermined storage space to store feed therein,
A housing 120 located below the storage container 110 and having an accommodation space formed therein,
A feed quantitative feed device 130 installed in the housing 120 and capable of supplying feed supplied from the reservoir 110 in a quantitative manner,
A spraying unit 180 capable of spraying the feed measured in a quantity by the feed quantitative supply device 130,
It includes a control unit 190 that is electrically connected to the feed quantitative supply device 130 and the spraying unit 180 to control the driving,
The feed quantitative supply device 130
A body 140 having an inlet 140a for introducing feed and an outlet 140b for discharging the introduced feed in a quantitative manner,
A valve unit 150 located within the body 140 and having a plurality of partition walls 152 in a serrated shape to measure feed in a quantitative manner,
The feed measured by the valve unit 150 can be transferred to the outlet 140b so that the feed measured by the valve unit 150 can be discharged to the outside of the body 140, and a transfer unit having a plurality of partition walls 162 in a serrated shape ( 160), and
By providing power to the valve unit 150 and the transfer unit 160 so that it can rotate, it consists of a drive motor 170 that enables the metering and transfer of feed,
The upper edge of the partition wall 152 of the valve unit 150 is formed to be tapered, and a metering membrane having a predetermined inclination angle is provided at the lower part to contact the upper surface of the tapered partition wall. Feed feeder using feed quantitative feed device that can be quantitatively measured. delete The method according to claim 1, wherein the body (140) is
A lower case 142 formed in a cylindrical shape and having an outlet 140b on one side of the bottom plate 142a,
An upper case 144 coupled to the upper side of the lower case 142 and having a through hole 145 formed at one side of the bottom plate 144a,
A plate 146 formed to cover an upper portion of the upper case 144 and having an inlet 140a formed to allow feed to be introduced into one side thereof,
A metering membrane 147 positioned to penetrate the upper and lower portions of the plate 146 and having a lower portion passing through the plate 146 in contact with the surface of the valve unit 150, and
Feed feeder using a feed quantity feeding device consisting of a plurality of bolts 148 that penetrate and fix each of the bottom plates 142a and 144a and the plate 146 of the lower case 142 and the upper case 144. The bolt according to claim 3, wherein a pair of reinforcing ribs (140d) are formed to protrude on both sides of the bolt holes (140c) formed in each of the bottom plates (142a, 144a) so that the plurality of bolts (148) are coupled to each other. Feed feeder using a feed quantity supply device that minimizes deformation of the shape by preventing twisting of the bottom plates 142a and 144a and the plate 146 due to the pressing force when the 148 is combined. delete The method according to claim 3, wherein each of the partition walls 152 and 162 of the valve unit 150 and the transfer unit 160 includes a bottom plate 144a of the valve unit 150 and the upper case 144 when rotating, and the Feed quantitative supply device, characterized in that the feed trapping protrusions 152a and 162a are formed to protrude to prevent feed from being trapped between the transfer unit 160 and the bottom plate 142a of the lower case 142 Feeding machine using. The method according to claim 1, wherein a spray opening (120b) is formed so that the spray pipe of the spraying unit can be positioned to pass through at one side of the housing, and the spraying pipe of the spraying unit is elastically supported at the spraying hole (120b) when blowing. Feed feeder using a feed quantitative feed device, characterized in that the elastic support member is installed so as to suppress the vibration sound of the air and feed flowing into the spreading pipe. delete The method according to claim 1, wherein the control unit 190 is located in the receiving unit 122 formed in the housing 120, the drive motor 170 of the feed quantity supply device 130 and the blower of the spraying unit 180 It is electrically connected to 182 so that it can be electrically controlled, and the receiving unit 122 in which the control unit 190 is located is formed to be in communication with the outside, so that when an abnormality occurs in the control unit 190, it is replaced or repaired. The housing 120 is formed in the housing 120 so that the housing 120 is formed, and an opening 120b is formed on one side of the housing 120 to communicate with the housing 120, and then the opening 120b is sealed. Feed feeder using a feed quantitative feeder, characterized in that a cover 124 is installed so that the control unit 190 can be selectively withdrawn from the receiving unit 122.

Images