KR102754108B1 - feed dispenser - Google Patents

Abstract

The present invention discloses a feed dispenser. According to one embodiment of the present invention, a main body (110) having an internal receiving space (100a) formed therein, an inlet (112) that is connected to the receiving space (100a) and allows feed to be introduced, and at least two or more outlets (114) that are connected to the receiving space (100a) and allows the introduced feed to be discharged, a branch plate (120) positioned within the receiving space (100a) and selectively allowing feed to be discharged through one of the two or more outlets (114), a driving motor (130) connected to the branch plate (120) on the outside of the main body (110) so as to rotate the branch plate (120), and a driving motor (130) installed between the main body (110) and the driving motor (130) and positioned at a predetermined distance from the main body (110) so that vibration due to the driving of the driving motor (130) is reduced. A feed dispenser is provided that includes a vibration absorption unit (140) that can minimize transmission to the main body (110).

Description

Feed dispenser

The present invention relates to a feed distributor, and more specifically, to a feed distributor that distributes feed when supplying feed to fish raised in a fish farm so that the feed can be distributed and supplied to a plurality of breeding rooms.

In general, feed is artificially supplied to farmed fish in fish farms, etc. In order for the farmed fish to grow smoothly, this type of feed supply must be done at a set time and amount, but most fish farms currently rely on the manual work of workers. In other words, workers carry containers containing feed and use their hands or simple tools to spread the feed in the farm.

However, the manual feeding as described above takes a lot of time and manpower, and is not desirable in terms of productivity or efficiency. In particular, as the size of fish farms is gradually increasing, the manual feeding by workers is reaching its limits in terms of productivity, etc.

In addition, manual feeding has an undesirable aspect for the smooth growth of farmed fish. Farmed fish need to be fed small amounts of feed frequently at regular time intervals to grow more smoothly, but manual feeding makes it difficult to provide such small amounts of feed frequently due to time and manpower constraints.

Therefore, in most cases, more than the prescribed amount of feed is supplied at once, which hinders the smooth growth of farmed fish. In addition, supplying more than the prescribed amount of feed can cause the farmed fish to not be able to process the supplied feed and the excess feed to sink to the bottom of the farm, which can cause waste of feed and water pollution due to the settled feed.

On the other hand, there is also the problem that manual feeding cannot spread the feed widely across the entire farm. In other words, due to the limitations of manual feeding, feed is concentrated in some areas of the farm, and in this case, feed may not be supplied evenly to all farmed fish.

In addition, since many farmed fish are crowded together in a small area and consume feed, the healthy growth of farmed fish is adversely affected by competition for food and stress due to the crowded space. It goes without saying that this can ultimately lead to a decline in the marketability of farmed fish.

That is, in the past, feed was supplied by having workers personally transport and scatter feed to each fish raised in multiple breeding rooms, which not only made it impossible to supply an appropriate amount of feed, but also took a long time to supply the feed.

Accordingly, the applicant of the present invention has devised a feed distributor capable of solving various conventional problems as described above.

European Patent Publication EP2482643 (November 12, 2014) Publication of Patent Publication No. 10-2006-0029838 (April 7, 2006)

According to one embodiment of the present invention, it is an object to provide a feed dispenser that enables easy and convenient feeding of feed to fish in a fish farm and stably supplies an appropriate amount of feed by automatically supplying feed to a breeding room where feed is to be sprayed.

The present invention discloses a feed dispenser. According to one embodiment of the present invention, a feed dispenser is provided, including a main body having an accommodation space formed therein, an inlet communicated with the accommodation space and allowing feed to be introduced, and at least two or more outlets communicated with the accommodation space so that the introduced feed can be discharged, a branch plate positioned within the accommodation space and allowing feed to be selectively discharged through one of the two or more outlets, a driving motor connected to the branch plate on the outside of the main body so as to rotate the branch plate, and a vibration absorbing unit installed between the main body and the driving motor and positioning the driving motor a predetermined distance from the main body so as to minimize vibration transmitted to the main body due to the operation of the driving motor.

The feed distributor according to the present invention supplies feed into a breeding room through a pipe by wind pressure provided from a blower, and automatically distributes feed to a desired breeding room by using a valve that is opened and closed by driving a motor.

Figure 1 is a schematic drawing showing a feed distributor installed according to one embodiment of the present invention.
FIG. 2 is a drawing illustrating a feed distributor according to one embodiment of the present invention.
FIG. 3 is a drawing schematically illustrating the internal appearance of a feed dispenser according to one embodiment of the present invention.
FIG. 4 is a drawing schematically illustrating a spraying unit used in a feed distributor according to one embodiment of the present invention.
Figure 5 is a cross-sectional view and an exploded view of Figure 4.

Hereinafter, the present invention will be described in more detail with reference to the attached drawings.

Prior to this, terms or words used in this specification and claims should not be interpreted as limited to their usual or dictionary meanings, and should be interpreted as meanings and concepts that conform to the technical idea of the present invention based on the principle that the inventor can appropriately define the concept of the term in order to explain his or her own invention in the best way.

Accordingly, the embodiments described in this specification and the configurations illustrated in the drawings are only the most preferred embodiments of the present invention and do not represent all of the technical ideas of the present invention. Therefore, it should be understood that there may be various equivalents and modified examples that can be replaced with them at the time of filing this application.

Referring to FIG. 1, a feed distributor (100) according to one embodiment of the present invention is installed in a fish farm where aquaculture fish are raised, and is characterized by being installed on a pipe (30) so that feed can be supplied to feed storage containers (20) of each breeding room (10) divided into multiple sections, thereby distributing the supplied feed.

To this end, a feed dispenser (100) according to one embodiment of the present invention, as shown in FIGS. 2 and 3, comprises: a main body (110) having an interior space (100a) formed therein, an inlet (112) that is connected to the interior space (100a) and allows feed to be introduced, and at least two outlets (114) that are connected to the interior space (100a) and allows the introduced feed to be discharged; a branch plate (120) positioned within the interior space (100a) and allowing feed to be selectively discharged through one of the two or more outlets (114); a driving motor (130) connected to the branch plate (120) on the outside of the main body (110) so as to rotate the branch plate (120); and a driving motor (130) that is installed between the main body (110) and the driving motor (130) and moves the driving motor (130) relative to the main body (110) at a predetermined distance. It may include a vibration absorption unit (140) positioned so as to minimize vibration transmitted to the main body (110) due to the operation of the driving motor (130).

Specifically, referring to FIG. 3, the main body (110) is formed as a pair that can be mutually connected, is formed in a square block shape, and a rectangular parallelepiped-shaped receiving space (100a) can be formed inside.

At this time, the above-mentioned receiving space (100a) can be installed so as to be connected to an inlet (112) formed on one side of the main body (110) and an outlet (114) formed on the other side of the inlet (112) by a flow path.

Here, at least two or more of the above discharge ports (114) can be formed, and a branch plate (120) can be installed to guide the feed supplied to one of the receiving space (100a) and two or more discharge ports (114).

For example, in one embodiment of the present invention, an inlet (112) is formed on one side to communicate with the receiving space (100a) in the main body (110), a first outlet (114a) is formed in a direction facing the inlet (112), and a second outlet (114b) is formed below the receiving space (100a) so that a Y-shaped flow path is formed.

That is, by forming one inlet (112) and two outlets (114), feed introduced through the inlet (112) can be selectively discharged through the first outlet (114a) or the second outlet (114b).

The above branch plate (120) is selectively rotated to determine the discharge direction of the feed flowing in through the inlet (112).

That is, it serves to guide the feed so that the feed can be moved to one of the two discharge ports (114a, 114b) according to the rotation of the branch plate (120).

The above branch plate (120) is formed so as to completely seal the discharge port (114) and may be formed in a shape corresponding to the rectangular receiving space (100a) formed inside the main body (110). That is, it may be formed in a rectangular plate shape similar to the receiving space (100a).

In addition, the branch plate (120) is formed so that one side can rotate by the main body (110) and the rotary pin, and the edge portion except for the side where the rotary shaft is coupled is formed to be tapered so that when one side comes into contact with the inner surface of the receiving space (100a) of the main body (110), a step is not generated, thereby preventing the feed from being stagnated or crushed by a step that may be generated by the branch plate (120) that adheres to the inner surface of the main body (110).

In addition, a catch (100b) that can support the branch plate (120) can be formed on the lower part where the rotated branch plate (120) is positioned, that is, on the inner wall surface of the receiving space (100a). That is, the branch plate (120) can be supported so as to limit the rotation of the branch plate (120) due to the pressure of the feed moving into the flow path and receiving space (100a).

Meanwhile, a driving motor (130) may be provided on the outside of the main body (110). The driving motor (130) provides power to rotate the branch plate (120) and is connected to a rotary pin that rotatably supports the branch plate (120).

That is, by allowing the driving motor (130) to rotate forward or reverse depending on the power supplied from the outside to rotate the branch plate (120), the discharge port (114) through which the feed is discharged can be selected.

Here, the branch plate (120) is fixedly connected to the rotation shaft of the driving motor (130), so that the branch plate (120) can rotate when the rotation shaft rotates.

Additionally, a vibration absorption unit (140) may be included between the main body (110) and the driving motor (130).

The above vibration absorption unit (140) serves to minimize the transmission of vibration that may occur when the driving motor (130) is driven to the main body (110), thereby preventing irregular feeding of feed due to vibration.

Specifically, the vibration absorption unit (140) may include a plurality of pillar members (142) that are fixedly connected to the outer surface of the main body (110) at one end, and a vibration absorption plate (144) that is fixedly connected to the upper end of the pillar members (142).

The above plurality of pillar members (142) are positioned so as to be vertically positioned with respect to the outer surface of the main body (110) but are positioned so as to be spaced apart from each other by a predetermined distance, and the vibration absorbing plate (144) can be fixedly connected to the other end of the plurality of pillar members (142) that are positioned so as to be vertically positioned with respect to the main body (110).

The above vibration absorbing plate (144) is made of synthetic resin and is formed to have a predetermined elastic restoring force so as to support the driving motor (130).

That is, the driving motor (130) is fixed to the vibration absorbing plate (144) of the vibration absorbing unit (140), and the rotational shaft of the driving motor (130) penetrates the vibration absorbing plate (114) and is fixedly connected to the rotational pin of the branch plate (120), so that the rotational pin rotates according to the rotation of the rotational shaft, and the branch plate (120) selectively blocks the first discharge port (114a) or the second discharge port (114b) to guide the movement of the feed.

Meanwhile, a feed distributor (100) according to one embodiment of the present invention may be connected to a separate feed storage container (20) through a pipe (30) to supply and store a certain amount of feed to each breeding room (10), and in some cases, feed may be sprayed directly into the breeding room (10).

In this case, each pipe (30) connected to the first outlet (114a) and the second outlet (114b) may be positioned at the upper center of each breeding room (10), and then a spraying unit (150) capable of spraying feed into the breeding room (10) may be installed.

At this time, the pipe (30) is installed with the end facing downwards toward the upper center of the breeding room (10), and a spraying unit is installed so that the feed discharged through the end can be sprayed so that it expands into the breeding room (10), thereby allowing the fish to consume it stably.

Specifically, the above-described spraying unit (150), as illustrated in FIG. 4, is configured to disperse feed discharged from the pipe (30) over a wide range, and may be composed of a support (151) formed in a “ㄷ” shape, a fastening means (152) coupled to an upper end of the support (151) and allowing the support (151) to be detachably attached to the pipe, a rotating dispersion body (153) rotatably installed on a lower end of the support (151) so as to disperse and spray feed supplied from the pipe (30) evenly within the breeding room, and a rotating support means (154) installed between the support (151) and the rotating dispersion body (153) so as to enable stable rotation of the rotating dispersion body (153).

Referring to the drawing, the support (151) is formed in a “ㄷ” shape and serves to support the rotating disperser (153) at a certain distance from the pipe (30). That is, the support (151) is formed in a “ㄷ” shape, and the rotating disperser (153) can be connected to one end located at the bottom so that it can rotate horizontally.

In addition, the fastening means (152) is fixedly connected to one end provided on the upper side of the support (151) so that the support (151) can be fixedly installed on the pipe (30). To this end, in one embodiment of the present invention, it is composed of a band member that can wrap around the outer circumference of the pipe (30) and a tightening screw that tightens the band member so that the band member can be fixed to the pipe.

In addition, a rotary disperser (153) that is rotatably coupled to one end provided on the lower side of the support (151) is freely coupled to an end of the support (151) that is formed to be bent upwards. That is, the rotary disperser (153) can be freely coupled to the support (151) by a rotary support means (154).

The rotating disperser (153) is formed in a disk shape, but is formed in a cone shape with the center of the upper surface protruding upward. That is, the upper surface formed as a disk protrudes upward by a certain height and is formed to slope downward from the center to the outside, and a plurality of rotating blades (153a) are formed to protrude upward along the circumferential direction on the downwardly inclined upper surface.

The above-mentioned rotary blades (153a) serve to guide the feed falling from the pipe (30), and can be formed so that at least five or more are protruding from the rotary disperser (153). That is, the number of the rotary blades (153a) can be designed in various ways, and there is no limitation on the number of rotary blades (153a) as long as the structure can stably and evenly distribute the falling feed.

In addition, the rotary blade (153a) is formed to have a crescent-shaped curve, but is formed in a form that is laid down at a predetermined angle toward the rear as it faces upward, so that when the rotary disperser (153) is rotated and the feed falls, the feed is spread along the surface of the rotary blade (153a) that is formed to be laid down, so that the feed can be evenly distributed and sprayed.

That is, the rotary blade (153a) is formed to be tilted at an angle of about 60° toward the rear in the direction of rotation with respect to the rotary disperser (153), but is formed in a rounded crescent shape so that the feed can be sprayed by sliding along the surface of the rotary blade by centrifugal force when the rotary disperser (153) rotates.

Here, the rotary blade (153a) may be formed orthogonally at a 90° angle to the rotary disperser (153), and may be formed to be laid down at various angles of less than 60° toward the rear, depending on the case. That is, the laying angle of the rotary blade (153a) may be formed in various ways depending on the feed diffusion range.

Meanwhile, the rotation support means (154) for stably coupling and rotating the rotational disperser (153) to the support (151) is, as shown in FIG. 5, a rotational protector (154a) that is coupled to a fitting hole (153b) formed on the lower surface of the rotational disperser (153) and has a groove formed in a cone-shaped depression at the lower end, a rotational fixing shaft (154b) that is formed on the upper end with a protrusion having a shape corresponding to the cone-shaped groove of the rotational protector (154a) inserted into the fitting hole (153b) so that it can be rotatably inserted, and is fixedly coupled to the support (151) at the lower end, and a rotational fixing shaft (154b) that surrounds the outer circumference of the rotational fixing shaft (154b) so that the rotational fixing shaft (154b) inserted into the fitting hole (153b) does not separate from the fitting hole (153b). It can be formed of a rotation support ring (154c) that is forcibly fitted into a fitting hole (153b).

That is, the rotation protection member (154a) is fitted and fixed inside the fitting hole (153b) of the rotation dispersion member (153), and the rotation fixing shaft (154b) is fitted and connected inside the fitting hole (153b) so that the upper end of the rotation fixing shaft (154b) comes into contact with the rotation protection member (154a). At this time, the rotation dispersion member (153) is a structure that can rotate about the rotation fixing shaft (154b), and the rotation protection member (154a) is fixedly connected to the rotation dispersion member (153).

In addition, the rotation support ring (154c) supports the rotational disperser (153) so that it can rotate smoothly about the rotational fixed shaft (154b) and prevents the rotational fixed shaft (154b) from separating from the fitting hole (153b) of the rotational disperser (153). The outer surface is fixed by force-fitting into the fitting hole (153b), and the inner surface is penetrated so that the rotational fixed shaft (154b) can rotate.

At this time, the above-mentioned rotation protection member (154a) is formed of a metal material, and the above-mentioned rotation fixing shaft (154b) that comes into contact with the above-mentioned rotation protection member (154a) is formed of a plastic material so as to prevent fusion due to friction of the same material when the above-mentioned rotation dispersion body (153) rotates and to increase the rotational power.

The rotation support means (154) having such a configuration is coupled so that the lower part of the rotation fixed shaft (154b) is fixedly connected to the support (151) and the upper part of the rotation fixed shaft (154b) is inserted into the fitting hole (153b) of the rotation disperser (153). At this time, a rotation protection member (154a) is fixedly connected by fitting inside the fitting hole (153b) of the rotation disperser (153), and the upper end of the rotation fixed shaft (154b) is positioned to contact the rotation protection member (154a). At this time, the rotation disperser (153) is coupled so as to be rotatable with respect to the rotation fixed shaft (154b), and the rotation support ring (154c) prevents the rotation fixed shaft (154b) from being separated from the rotation disperser (153).

Accordingly, when feed is supplied from the upper side of the rotary disperser (153), the rotary disperser (153) that is coupled to be able to rotate freely about the fixed rotation shaft (154b) is rotated by the falling air and feed, and the feed is moved along the surface of the rotating blade by the centrifugal force generated by the rotation of the rotary disperser (153) and is spread and distributed around the fish farm.

Accordingly, the feed distributor (100) according to one embodiment of the present invention can easily and conveniently automatically supply and store feed in a separate feed storage container (20) provided in each breeding room (10), and in some cases, feed can be sprayed to each breeding room (10) using a spraying unit (150).

Above, the idea of the present invention should not be limited to the described embodiments, and not only the claims described below, but also all things that are equivalent or equivalent to the claims are included in the scope of the idea of the present invention.

10: Breeding room 20: Feed storage bin
30 : Piping 100 : Feed Distributor
100a: Accommodation space 110: Main body
112 : Inlet 114 : Outlet
114a: 1st outlet 114b: 2nd outlet
120 : Branch plate 130 : Drive motor
140: Vibration absorbing unit 142: Column member
144: Vibration absorbing plate 150: Spraying unit
151: Support 152: Fastening means
153: Rotating dispersion body 154: Rotating support means
154a: Rotating guard 154b: Rotating fixed shaft
154c : Rotating support ring

Claims (7)

A main body (110) having an internally formed receiving space (100a), an inlet (112) that is connected to the receiving space (100a) and allows feed to be introduced, and at least two or more outlets (114) that are connected to the receiving space (100a) and allow the introduced feed to be discharged;
A branch plate (120) positioned within the above-mentioned receiving space (100a) so that feed can be selectively discharged to one of the two or more discharge ports (114),
A driving motor (130) connected to the branch plate (120) on the outside of the main body (110) so as to rotate the branch plate (120),
A vibration absorption unit (140) is installed between the main body (110) and the driving motor (130) and is positioned at a predetermined distance from the main body (110) so as to minimize vibration transmitted to the main body (110) due to the driving of the driving motor (130).
The above main body is formed in a square block shape that can be mutually connected as a pair, and has a rectangular parallelepiped-shaped receiving space (100a) formed inside, and the receiving space (100a) has an inlet (112) formed on one side of the main body (110) and two outlets (114) formed in a Y shape on the other side of the inlet (112) and formed to be connected by a flow path, and a feed distributor characterized in that a branch plate (120) formed in a rectangular plate shape that can guide feed supplied to either of the two outlets (114) is rotatably installed inside the receiving space (100a). delete In claim 1, the feed dispenser is characterized in that the branch plate (120) is formed so that one side can rotate by the main body (110) and the rotary pin, and the edge portion except for the side where the rotary pin is coupled is formed to be tapered so that a step does not occur when one side comes into contact with the inner surface of the receiving space (100a) of the main body (110), and a catch (100b) capable of supporting the branch plate (120) is formed on the lower part where the branch plate (120) is located, that is, the inner wall surface of the receiving space (100a). In claim 1, the vibration absorption unit (140) includes a plurality of pillar members (142) that are fixedly connected to the outer surface of the main body (110) at one end, and a vibration absorption plate (144) that is fixedly connected to the upper end of the pillar members (142).
A feed dispenser characterized in that each of the plurality of pillar members is positioned so that one end thereof is erected relative to the outer surface of the main body (110), but is positioned so as to be spaced apart from each other by a predetermined distance, and the vibration absorbing plate (144) is fixedly connected to the ends of the plurality of pillar members (142) positioned so as to be erected relative to the main body (110). A feed distributor according to claim 1, characterized in that it may further include a spreading unit (150) that can spread the feed discharged from the pipe (30) over a wide area. In claim 5, the spraying unit (150) is characterized by a feed dispenser that is configured with a support (151) formed in a “ㄷ” shape so that the feed discharged from the pipe (30) can be dispersed over a wide range, a fastening means (152) that is connected to the upper end of the support (151) and allows the support (151) to be detachably attached to the pipe, a rotating dispersion body (153) that is rotatably installed on the lower end of the support (151) so that the feed supplied from the pipe (30) can be dispersed and sprayed evenly within the breeding room, and a rotating support means (154) that is installed between the support (151) and the rotating dispersion body (153) so that the stable rotation of the rotating dispersion body (153) can be achieved. In claim 6, the feed dispenser characterized in that the rotary disperser (153) is formed in a disk shape, but is formed in a cone shape in which the center of the upper surface protrudes upward, and the upper surface protrudes upward by a certain height and is formed to slope downward from the center in an outward direction, and a plurality of rotary blades (153a) are formed to protrude upward along the circumferential direction on the downwardly inclined upper surface, and at least five or more are formed to protrude, and the protruding rotary blades (153a) are formed to have a crescent shape and to have a curve, but are formed to be inclined at an angle of 60° toward the rear as they face upward, so that the feed can be distributed by sliding along the surface of the rotary blades (153a) by centrifugal force during rotation.

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