KR20210156943A - Fodder manufacture system - Google Patents

Abstract

The present invention relates to a soldier fly-applied feed manufacturing system, with which soldier fly drying and processing and quantitative packaging can be performed. The present invention includes: a soldier fly feed supply unit where a soldier fly feed is put in after grinding by a grinder such that the input soldier fly feed is continuously discharged with time; a first transport conveyor connected to the soldier fly feed supply unit and transporting the soldier fly feed discharged from the soldier fly feed supply unit; a first hopper provided with a weight measurement sensor for weight measurement attached to a first door and the first door formed on a lower end side such that the soldier fly feed transported by the first transport conveyor is discharged quantitatively corresponding to a set weight; a second transport conveyor positioned below the first hopper and transporting the quantitative soldier fly feed supplied from the first hopper; a packaging unit packaging the quantitative soldier fly feed from the second transport conveyor; a control unit controlling the first door to open when the weight measured by the weight measurement sensor is equal to the set weight; and an odor reduction device installed at one end of the first hopper for odor collection and combustion.

Description

Feed manufacturing system applying Dongae, etc. {FODDER MANUFACTURE SYSTEM}

The present invention relates to a feed manufacturing system to which Dongae etc. is applied, and more particularly, to a feed manufacturing system to which Dongae etc. is applied, characterized in that it can be packaged in a quantitative manner by drying and processing the Dongae etc.

Organic wastes currently discharged from homes, livestock farms, and cafeterias can cause serious environmental problems in soil and rivers if they are discharged without treatment.

According to the conventional method, a method of recycling organic waste as feed or compost of livestock through a specific treatment process, a method of landfilling in a certain area, or a method of dumping in the sea have been mainly used.

However, in this case, there is a problem of low economic feasibility in terms of installation cost and maintenance cost of the treatment device. In addition, when the waste is used as feed, side effects such as lump formation are large, and in the case of composting, there are problems such as reheating and inefficiency imbalance.

Accordingly, recently, an organic waste treatment system has been developed using organisms such as earthworms and housefly larvae.

In this case, the discharged fecal soil has excellent inefficiency, so it can be usefully used for cultivation of agricultural land, horticulture, orchards, etc. It is known that it plays a role in increasing plant growth and yield of products.

In particular, the growing period from egg to adult is 37-41 days for larvae, and the period of larvae acting as a decomposer is about 14 days. More than 80% of the decomposed food waste was reduced in volume by 42% and weight by about 70% compared to before the larvae were introduced.

It is much more effective to breed and use Dongae larvae, as the period for decomposing organic waste is longer than that of other seeds.

For this reason, the development of a technology for mass-proliferating larvae in Dongae, etc. using organic waste has been steadily made.

In this regard, Korean Patent Application Laid-Open No. 10-2009-0121774 discloses that, in the process of mass breeding Dongae, etc., the degree of fermentation of organic waste used to grow the larvae of Dongae, etc. and the degree of odor generated thereby is controlled. Although a difficult problem is disclosed, a solution related thereto has not yet been disclosed.

In addition, in the feed using dongae, etc., a large amount of feed supply device is not provided, and thus there is a problem in that the supply of the dongae, etc. feed is not smooth.

Prior art literature

Patent Literature

(Patent Document 0001) 1 Korea Patent Publication No. 10-2009-0121774

An object of the present invention is to provide a manufacturing apparatus that manufactures and packs feed using Dongae, etc., but is equipped with a weighing sensor to pack the feed in Dongae, etc. by a set weight.

As a means for achieving the above object,

The present invention comprises: a feed supply unit to the dongae, etc., which is fed to the dongae crushed in the grinder, and continuously discharges the feed to the put dongae, etc. over time; a first conveying conveyor connected to the feed supply unit to the Dongae, etc. and transferring the feed to the Dongae etc. discharged from the feed supply unit to the Dongae etc.; A first door formed on the lower end side to discharge the feed to the Dongae, etc. of the quantity corresponding to the set weight, and a weight sensor attached to the first door to measure the weight. a first hopper provided; a second transfer conveyor positioned under the first hopper to transfer feed to the amount of dongae supplied from the first hopper; a packaging unit for packaging the feed in the amount of Dongae transferred from the second transfer conveyor; a control unit controlling the first door to be opened when the weight measured by the weight sensor matches the set weight; It is installed at one end of the first hopper, and it is characterized in that it comprises an odor reduction device for collecting and burning odors.

In addition, the odor reduction device 2000 includes an air input tube 2100 into which air is introduced by external power in the form of a cylindrical pipe or a polygonal tubular pipe; a pump device 2200 connected to one end of the air input tube 2100 to transfer air by external electric power; a case 2400 for a tornado-type air circulation device to which the air input tube is connected to the upper part to receive air; a tornado-type air circulation device 2300 installed inside the case for the tornado-type air circulation device to rotate and compress the air to heat the air; an air output pipe 2500 installed on the bottom surface of the case for the tornado-type air circulation device to output air; a container-shaped diffusion chamber 2600 installed in the lower portion of the air output tube 500 and configured to spread air that has passed through the air output tube while splashing in all directions in the inner space; a motor input tube 2700 connected to the air input tube to input polluted external air; a final output line (2800) installed on the output side of the diffusion chamber; The air input tube 2100, a first structure connecting body 21800 is installed at the lower portion, the end of the first structure connecting body 2180, the both sides of the protrusion for merging (2180a) inclined on both sides is installed 1 structure 2100A; and a second structure (2100B) for connecting to the first structure; The second structure (2100B), the first assembly structure (2110) installed in the outermost and; A second structure for merging is installed spaced apart from the first structure for merging by a predetermined distance to form a space so that the protrusion for merging enters the space, and a groove for merging is formed at one end so that the protrusion for merging is inserted and fixed. (2120) and; a first repulsion means 2130 installed between the first merging structure and the second merging structure; Installed at the front end of the first repulsion means, when the coalescence protrusion of the first uniting structure enters, it retreats to press the first repulsion means, and when the coalescing protrusion is inserted into the coalescing groove of the second uniting structure, the first The first repulsion means flowing part 2150 which is advanced by the repulsion of the repulsion means and is located on the upper part of the protrusion for coalescence; a second repulsion means 2140 installed at the rear end of the first repulsion means flow part and having a repulsion function; a second repulsion means flow part 2160 for driving the second repulsion means while retreating backward as a cylindrical structure installed outside the second repulsion means to drive the second repulsion means; It is characterized in that it is installed at the rear end of the second repulsion means to include a second repulsion means support portion 2170 for supporting the movement of the second repulsion means.

In addition, the tornado-type air circulation device 2300 is made of a polygonal panel-shaped upper plate 2310 having a cylindrical pressure control cap 2311 with a closed upper portion installed thereon, and a polygonal panel-shaped air in the lower portion. Installed between the lower plate 2320 having the discharge hole 2321 and the upper plate 2310 and the lower plate 2320, the upper plate and the lower plate coupling part are inserted and coupled in a spiral form from the edge to the center direction, and the flowing air is rotated and compressed. It is characterized by comprising at least two tornado-type panels 2330 to output.

In addition, it is characterized in that a plurality of air circulation holes 2312 are further formed on the side surface of the pressure control cap 2311 .

As described above, the present invention has the effect of providing a manufacturing apparatus for manufacturing and packaging feed using Dongae, etc., but having a weight sensor to pack the feed in Dongae, etc. by a set weight.

1 is a perspective view showing a feed manufacturing system according to an embodiment of the present invention.
Figure 2 is a cross-sectional view showing a cross section of the first hopper.
3 is an exploded view showing in detail the first and second filter plates shown in FIG.
4 is an overall configuration diagram of a whirlwind type odor reduction device of the present invention.
5 is a perspective view of a tornado-type air circulation device of the present invention.
Figure 6 is an exploded perspective view of the tornado-type air circulation device of the present invention.
Figure 7 is a state diagram inserted into the case of the tornado-type air circulation device of the present invention.
8 is a cross-sectional view showing the concept of operation of a tornado-type air circulation device of the present invention.
9 is a plan view showing the concept of operation of the tornado-type air circulation device of the present invention.
10 is a conceptual diagram of the operation of the diffusion chamber of the present invention.
Figure 11 is an embodiment of the first structure and the second structure combined structure of the present invention.
12 is a first operation diagram of a first structure and a second structure combined according to the present invention.
13 is a second operation diagram of the first structure and the second structure combined according to the present invention.

Hereinafter, the principle of operation of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. However, the drawings shown below and the description to be given below relate to a preferred implementation method among various methods for effectively explaining the characteristics of the present invention, and the present invention is not limited only to the following drawings and description.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. And the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the content throughout the present invention.

In addition, preferred embodiments of the present invention implemented below are already provided in each system functional configuration in order to efficiently describe the technical components constituting the present invention, or system functions normally provided in the technical field to which the present invention belongs The configuration is omitted as much as possible, and the functional configuration to be additionally provided for the present invention will be mainly described.

If a person of ordinary skill in the art to which the present invention pertains, will be able to easily understand the functions of the components already used in the prior art among the functional configurations omitted without being shown below, and the configuration omitted as described above Relationships between elements and components added for purposes of the present invention will also be clearly understood.

In addition, the following examples will be used with appropriate modifications of terms so that those of ordinary skill in the art to which the present invention pertains can clearly understand in order to effectively describe the key technical features of the present invention, thereby It is never limited.

As a result, the technical spirit of the present invention is determined by the claims, and the following examples are one means for efficiently explaining the technical spirit of the present invention to those of ordinary skill in the art to which the present invention belongs. it's just

Moreover, it is to be understood that all detailed description reciting specific embodiments, as well as principles, aspects, and embodiments of the invention, are intended to include structural and functional equivalents of such matters. It should also be understood that such equivalents include not only currently known equivalents, but also equivalents developed in the future, i.e., all devices invented to perform the same function, regardless of structure.

Thus, for example, the block diagrams herein are to be understood as representing conceptual views of illustrative circuitry embodying the principles of the present invention. Similarly, all flowcharts, state transition diagrams, pseudo code, etc. may be tangibly embodied on computer-readable media and be understood to represent various processes performed by a computer or processor, whether or not a computer or processor is explicitly shown. should be

The functions of the various elements shown in the drawings including a processor or functional blocks represented by similar concepts may be provided by the use of dedicated hardware as well as hardware having the ability to execute software in association with appropriate software. When provided by a processor, the functionality may be provided by a single dedicated processor, a single shared processor, or a plurality of separate processors, some of which may be shared.

In addition, the clear use of terms presented as processor, control, or similar concepts should not be construed as exclusively referring to hardware having the ability to execute software, and without limitation, digital signal processor (DSP) hardware, ROM for storing software. It should be understood to implicitly include (ROM), RAM (RAM) and non-volatile memory. Other common hardware may also be included.

In the claims of the present specification, a component expressed as a means for performing the function described in the detailed description includes, for example, a combination of circuit elements that perform the function or software in any form including firmware/microcode, etc. It is intended to include all methods of performing the functions of the device, coupled with suitable circuitry for executing the software to perform the functions. Since the present invention defined by these claims is combined with the functions provided by the various enumerated means and in a manner required by the claims, any means capable of providing the functions are equivalent to those contemplated from the present specification. should be understood as

The above objects, features and advantages will become more apparent through the following detailed description in relation to the accompanying drawings, and accordingly, those of ordinary skill in the art to which the present invention pertains can easily implement the technical idea of the present invention. There will be. In addition, in the description of the present invention, if it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

Before describing various embodiments of the present invention in detail, it will be understood that the application is not limited to the details of the construction and arrangement of components described in the following detailed description or shown in the drawings. The invention is capable of being embodied and practiced in other embodiments and of being carried out in various ways. Also, device or element orientation (eg, “front”, “back”, “up”, “down”, “top”, “bottom”) The expressions and predicates used herein with respect to terms such as ", "left," "right," "lateral," etc. are used merely to simplify the description of the invention, and the associated apparatus Or it will be appreciated that it does not simply indicate or imply that an element must have a particular orientation.

1 is a perspective view showing a feed manufacturing system according to an embodiment of the present invention.

Figure 2 is a cross-sectional view showing a cross section of the first hopper.

3 is an exploded view showing in detail the first and second filter plates shown in FIG.

4 is an overall configuration diagram of a whirlwind type odor reduction device of the present invention.

5 is a perspective view of a tornado-type air circulation device of the present invention.

Figure 6 is an exploded perspective view of the tornado-type air circulation device of the present invention.

Figure 7 is a state diagram inserted into the case of the tornado-type air circulation device of the present invention.

8 is a cross-sectional view showing the concept of operation of a tornado-type air circulation device of the present invention.

9 is a plan view showing the concept of operation of the tornado-type air circulation device of the present invention.

10 is a conceptual diagram of the operation of the diffusion chamber of the present invention.

Figure 11 is an embodiment of the first structure and the second structure combined structure of the present invention.

12 is a first operation diagram of a first structure and a second structure combined according to the present invention.

13 is a second operation diagram of the first structure and the second structure combination of the present invention,

1 to 2, the feed manufacturing system according to an embodiment of the present invention is a feed supply unit 100, a first transfer conveyor 200, a first hopper 300, a second hopper 400, It may include a second transfer conveyor 500 , a packaging unit 600 , and a control unit 380 .

Specifically, the feed supply unit 100 to the Dongae etc. supplies the feed to the Dongae etc. to the first transport conveyor 200 . The feed supply unit 100 to Dongae etc. may be provided with a transfer screw 210 therein so as to continuously supply feed to the put Dongae etc. to the first transfer conveyor 200 according to time.

The transfer screw 210 may include a rotating shaft connected to a power unit such as a motor and a screw blade formed in one direction on an outer peripheral surface of the rotating shaft. The transfer screw 210 is driven by a motor and rotates in one direction to continuously discharge the feed to the Dongae etc. supplied to the inside of the feed supply unit 100 through the screw blade to the first conveying conveyor 200 .

The first conveying conveyor 200 moves at a constant speed, and provides feed to the first hopper 300 for dongae supplied from the conveying screw 210 .

The first hopper 300 discharges the feed to the dongae, etc. of a quantity corresponding to the set weight of the dongae, etc. transported by the first transfer conveyor 200 . To this end, the first hopper 300 may include a weight sensor such as a scale and an openable and closed first door. The first hopper 300 automatically opens the first door and lowers the feed to the fixed amount of Dongae, etc. when the feed is accumulated on the first door at the weight set by the weighing sensor.

As shown in FIGS. 2 and 3 , the first hopper 300 includes a body 310 , a first filter plate 320 , a second filter plate 330 , a first driving means 370 , and a first door. It may include a 340 and a weight measurement sensor 350 .

Specifically, the body 310 is provided with an input unit in which the feed is input to the Dongae, etc. in the first transfer conveyor 200 and an outlet through which the feed is discharged to the input Dongae, etc. The inlet and outlet are vertically arranged. At this time, the body 310 may be formed in a reverse trapezoidal cross section so that the feed can be easily discharged to the input Dongae.

The lower side of the body 310 is formed in a cylindrical shape, and the first and second filter plates 320 and 330 may be installed in the cylindrical portion.

The first filter plate 320 is formed in the shape of a disk, and as shown in FIGS. 2 and 3 , the central portion is formed to protrude. The first filter plate 320 is formed to be in close contact with the body 310 . The first filter plate 320 may be provided with at least one first opening 325 so as to selectively supply feed to the first door 340 , such as Dongae. As shown in FIG. 3 , four first openings 325 are formed as an example, but the present invention is not limited thereto.

The first opening 325 may be formed in a sector shape from the center of the first filter plate 320 to the outside. Since the first filter plate 320 is circular, when it has a fan shape from the center to the outside, feed can be effectively supplied to the dongae and the like through the first door 340 .

As shown in FIG. 2 , the first door 340 is formed at the end of the lower body 310 of the first filter plate 320 . The first door 340 is formed with two rotating protrusions protruding from the outer circumferential surface, and any one of the two rotating protrusions passes through the body 310 and is connected to the first driving means 370 . The first door 340 may be rotated in one direction through the first driving means 370 to discharge the feed to the outside of the first hopper 300 . At this time, the weight sensor 350 is coupled to the first door 340 to measure the weight of the feed on the dongae, etc. accumulated on the first door 340 .

Here, the controller 380 controls the first and second driving means 370 and 360 so that the second filter plate 330 and the first door 340 operate. For example, the control unit 380 rotates the second filter plate 330 when the feed is put into the first hopper 300 , such as dongae, so that the first opening 325 and the second opening 335 are all or part of it. to overlap. At this time, the control unit 380 controls the first door 340 to be closed. When the first opening 325 and the second opening 335 overlap, the feed begins to accumulate on the first door 340, and the control unit 380 periodically calculates the weight of the feed from the weighing sensor 350 to the Dongae, etc. receive as The control unit 380 compares the set weight and the feed weight received from the weighing sensor 350 and, if the same, rotates the second filter plate 330 to close the first opening 325 . At the same time, the first door 340 is operated to discharge the feed to the outside of the first hopper 300 .

The feed in the amount of Dongae discharged from the first hopper 300 may be seated on the second transfer conveyor 500 and transferred to the packaging unit 600 . In this case, the second hopper 400 may be provided under the first hopper 300 .

The second hopper 400 may supply feed to the second transfer conveyor 500 for the amount of dongae supplied from the first hopper 300 . When the distance between the first hopper 300 and the second transfer conveyor 500 is high, the second hopper 400 is installed to prevent the scattering of feed in the amount of dongae descending from the first hopper 300. . The second hopper 400 may include a second door that is an openable and closeable door like the first hopper 300 , and is driven according to a control signal from the control unit 380 and includes a third driving means for opening and closing the second door. can be Here, the third driving means may be constituted by a motor or the like as the first driving means.

The control unit 380 may control the opening and closing of the second door, preferably before the first door 340 is opened, the second door is controlled to be closed, and the second door is controlled to be opened when the food is accumulated on the second door. can do.

Although not shown in FIGS. 1 to 3, the weight measurement sensor shown in FIG. 2 may be provided on the second door as well, and the weight measurement sensor installed on the second door is not used as a sensor for quantification, but rather on the second door. It can be used for the purpose of detecting the presence or absence of feed.

The second transfer conveyor 500 supplies feed to the packaging unit 600 in a quantity of dongae, etc. to the packaging unit 600 .

The packaging unit 600 vacuum-packs the feed in a quantity of dongae supplied through the second transfer conveyor 500 and discharges it to the outside.

As described above, the feed manufacturing system according to an embodiment of the present invention can automatically package the feed by separating a predetermined amount of feed in the Dong-Aed, thereby saving time and supplying the user with a precise weight.

As an embodiment of the odor reduction device of the present invention, the air input pipe 2100, the air input pump device 2200, the tornado type air circulation device 2300, and the tornado type air circulation device case 2400 and an air output tube 2500 , a diffusion chamber 2600 , a motor input line 2700 , and a final output line 2800 .

The air input pipe 2100 is a pipe erected in a vertical shape, and is a pipe through which air passes through the operation of the air input pump device 2200 . The air input tube 2100 passes the air transmitted from the motor and serves to transfer the air to the tornado-type air circulation device.

The air input pump device 2200 receives external power to rotate the impeller to pump air into the air input tube 2100 . The operating range of the pump device 2200 for air input is capable of appropriately adjusting the rotation speed of the pump according to the circulation and temperature of the air, which means that when the pump device is rotated at a high speed, the circulation speed of air is increased and the temperature rises rapidly, If the operating speed is slowed, the air circulation speed is slowed and the air temperature rises slowly. In the present invention, the circulation speed is varied and used for the purpose of adjusting the temperature of the air at an optimized speed by appropriately adjusting the rotation speed of the pump device 2200 for air input.

The tornado-type air circulation device 2300 is made of a polygonal panel-shaped upper plate 2310 having a cylindrical pressure control cap 2311 with a closed upper portion installed thereon, and a polygonal panel-shaped air outlet hole ( 2321), the upper plate 2310 and the lower plate 2320 are inserted between the upper plate and the lower plate coupling portion edge to the center direction in a spiral form inserted and coupled in two or more directions tornado panel (2330) is done

The tornado-type air circulation device 2300 installs two or more circuitry-type panels 2330 to generate two or more air input spaces D, and the input air is mixed into one air exhaust pipe 2500 while Inducing flow, this is to increase the temperature of the air while the air flowing in from two or more points gathers in one place.

On the other hand, the reason for installing the pressure control cap 2311 is that overpressure occurs in the process of rotating while the air is mixed, collides with the air existing inside the air output tube 2500 by the pressure, and is pulled upward, at this time The air pulled up to the top plays a role in creating a free space that rotates according to the flow of air.

If the pressure control cap 2311 is not installed, there is no place for the raised air to stay when an aggravated pressure is generated due to the rotation of the air, and in that case, when the air is discharged along the air output pipe 2500, it is If one space part is not secured, a gurgling phenomenon occurs.

Since the pressure control cap 2311 of the present invention secures a space for rotating the air previously present in the air output pipe 2500 according to the overpressure generated by the rotating air, the air discharged along the air output pipe 2500 is pressure The air output space is secured under the influence of the air present in the control cap 2311, so that it can be continuously rotated and discharged smoothly.

That is, the air is smoothly discharged while rotating around the space only when a space is secured at the point where the air is discharged by the pressure control cap 2311. Without the pressure control cap 2311, the space at the air discharge point is not secured. As a result, a gurgling phenomenon appears, and the air cannot be discharged at a constant speed, and then continuous heat generation cannot be achieved.

Therefore, in the present invention, the pressure control cap 2311 is formed and pressure is generated in the pressure control cap 2311 by the rotating air, and accordingly, the pressure control cap 311 is applied to the pressure control cap 311 while raising the air of the air discharge pipe 2500. The first space (A) is secured, and at the same time, the second space (B) is secured on the central axis between the tornado air circulation device and the air output pipe, so that the first space (A) and the second space are Since the air is discharged while rotating in a state that does not invade (B), continuous discharge is made and continuous heat generation is made.

And the reason for further forming a plurality of air circulation holes 2312 on the side of the pressure control cap 2311 is that the air is initially filled in the inner space of the pressure control cap. This is because the air space portion C existing in the cap 2311 is pushed outward to push the air outward, and the air pushed outward must be discharged to the outside. If the air circulation hole 2312 is not formed, the pressure control cap 2311 is filled with air, so that the air cannot be sucked in, and thus the air cannot be smoothly discharged.

Therefore, when the air circulation hole 2312 is formed on the side of the pressure control cap 2311 as in the present invention, the air is pulled up from the air discharge pipe 2500 generated according to the rotation and compression of the air and the air is pulled up. The air present in the pressure control cap 2311 is pushed outward by a certain amount to the outside of the pressure control cap 2311 through the air circulation hole 2312, and the air discharged through the air circulation hole 2312 Air is again input through the tornado-type panel 2330 to be discharged to the bottom through the air discharge pipe (2500).

The case 2400 for the tornado-type air circulation device has a rectangular parallelepiped shape and includes the tornado-type air circulation device 2300 inside to close the outer shell, and the air input tube 2100 is connected through the upper panel and , is made by connecting the air output tube 2500 through the lower panel.

Therefore, the air transferred through the air input tube 2100 is transferred to the case 2400 for the tornado type air circulation device, and then the circuitry type air circulation device 2300 is inserted into the case 2400 for the circuitry type air circulation device. After passing through the air is transferred through the output pipe (2500).

The diffusion chamber 2600 has a cylindrical or polygonal shape connected to the lower end of the air output tube, and the end of the air output tube is configured to be inserted into the body of the diffusion chamber 2600 by a predetermined length.

The reason for the configuration by inserting the diffusion chamber 2600 into the lower portion of the air output tube 2500 as described above is that the air passing through the air output tube 2500 rotates very quickly and is transferred, so as to fall into the diffusion chamber 2600, various This is to allow air to spread in the direction.

The overall operation of the present invention will be described below.

First, when the pump device for air input is operated, air vertically rises through the air input tube 2100 disposed vertically. The vertically raised air flows along the inner periphery of the air input tube 2100 to the inside of the case 2400 for the circuitry-type air circulation device after the air is moved to the upper part of the case 2400 for the circuitry-type air circulation device.

On the other hand, the air that has flowed into the case 2400 for the circuit-less type air circulation device is inserted into the circuit-less panel 2330 of the tornado-type air circulation device 2300, and the circuit-less type air circulation device 2300 is the top plate 2310 ) and the lower plate 2320 and the tornado-type panel 2330 because it is closed by the upper plate 2310 and the lower plate 2320, so the air is between the upper plate 2310 and the lower plate 2320 between the tornado-type panel 2330 It flows while being compressed and rotated while passing through, and then flows through the pressure control cap 2311 and the air output pipe 2500. At this time, a plurality of tornado-type panels 2330 are installed between the upper plate 2310 and the lower plate 2320 Therefore, when the air is compressed and rotated and discharged, heat rises in the process of mixing with each other.

At this time, the pressure control cap 2311 formed on the upper plate serves to adjust the pressure according to the air flow, and when the compressed air passes through the tornado type panel 2330, the pressure inside the tornado type air circulation device 2300 is At this time, a low pressure is formed in the pressure control cap 2311, sucking up the air in the air output tube, so that the pressure of the air is properly adjusted, and accordingly, the air that is rotated and compressed and output is smoothly discharged at a constant speed .

In addition, when the air circulation hole 2312 is formed on the side of the pressure control cap 2311, the air raised by the low pressure pushes the air present in the inner space of the pressure control cap 2311 to the outside. is output to the outside along the air circulation hole 2312, and the output air is again input to the tornado-type panel 2320, so that a continuous circulation process is made.

After all, the present invention is to install a tornado-type air circulation device 2300 inside the case 2400 for a tornado-type air circulation device, but the air is compressed and rotated while flowing between a plurality of tornado-type panels 2330, and the compressed air It is possible to provide a odor reduction device with a simple structure and maximized efficiency by allowing heat to be generated while the ions are combined with each other and also to generate heat again in the diffusion chamber 2600 after passing through the air output tube 2500.

On the other hand, the air input tube can be configured as an assembly type by dividing the double, including a first structure (2100A) and a second structure (2100B), the first structure (2100A), the first structure connector ( 2180) and a protrusion for merging (2180a).

The second structure 2100B, which is combined with the first structure 2100A, includes a first uniting structure 2110, a second coalescing structure 2120, a first repulsion means 2130, and a second repulsion. It consists of a means 2140 , a first reaction means flow part 2150 , a second reaction means flow part 2160 , and a second reaction means support part 2170 .

In addition, the second assembly structure 2120 includes a coalescing groove 2120a, and the second reaction means flow part 2160 is formed by integrally forming the second reaction means operating piece 2160a. In addition, the second repulsion means support portion 2170 is formed at the rear end of the second structure 2100B. The second repulsion means flow part 2160 has irregularities formed on the edge surface, so that it can be easily gripped by hand.

That is, the first structure (2100A) and the second structure (2100B) of the present invention can be combined naturally by one-touch as a combined embodiment of the present invention, and in addition, it is not easily separated during use. It was configured so that it could be separated only if there was.

In other words, in the combined structure of the present invention, the first structure 2100A and the second structure 2100B can be easily combined with one touch. When separating for repair, there is an advantage that the first structure 2100A and the second structure 2100B can be separated more easily because the uneven surface is pulled by hand to separate it.

Hereinafter, the components of the present invention will be described in more detail as follows.

The housing of the first structure 2100A has a cylindrical shape, and a first structure connecting body 2180 is installed as a means of merging with the second structure 2100B, and both ends of the first structure connecting body 2180 have both sides. This inclined protrusion for coalescing 2180a is formed.

The second structure 2100B has a first structure for coalescence 2110 installed on the outermost side, and a second structure structure 2120 for coalescence is installed below it.

A space is formed between the first structure for merging 2110 and the second structure for merging 2120 , and the first structure connector 2110 of the first structure 2100A is inserted and merged into the space.

In addition, the first repulsion means 2130 and the first repulsion means flow part 2150 are installed for one-touch union, and the first repulsion means flow part 2150 is installed inside the first assembly structure 2110, but It is supported on the step 2110a, and the first repulsion means 2130 is located at the rear end of the first repulsion means flow part 2150 .

The operation of the present invention will be described below.

When the first structure connecting body 2180 of the first structure 2100B is inserted between the first coalescing structure 2110 and the second coalescing structure 2120, the first repulsion means flowing part 2150 is attached to the coalescing pin. It is pushed back while being in contact, and then the first repulsion means flowing part 2150 is retracted while compressing the first repulsion means 2130 .

After that, when the first repulsion means flow part 2150 is retreated by a predetermined distance, the protrusion 2180a for merging of the first structure connecting body 2180 is inserted into the merging groove 2120a of the second merging structure 2120. .

Then, the compression of the first repulsion means flowing part 2150 is released and returned to its original position by the repulsive force of the first repulsion means 2130, and accordingly, the first repulsion means flowing part 2150 is for the union of the first structure 2100A. The first structure 2100A and the second structure 2100B are prevented from being easily separated by pressing the protrusion 2180a.

That is, looking at the process in which the first structure 2100A and the second structure 2100B are merged, when the first structure connector 2180 of the first structure 2100A is inserted into the second structure 2100B, for the first coalescence As it enters the gap between the structure 2110 and the second assembly structure 2120 , the first repulsion means flowing part 2150 is pushed back and retreated, and the first repulsion means according to the retreat of the first repulsion means flowing part 2150 . (2130) is compressed, and then, when the coalescing protrusion 2180a is inserted into the coalescing groove 2120a of the second coalescing structure 2120, the first repulsing means flowing part 2150 is returned to its original position while the first repulsing means The flow portion 2150 presses the upper portion of the coalescence protrusion 2180a so that the first structure 2100A and the second structure 2100B are strongly combined and are not easily separated.

As a result, when the present invention is used, it can be seen that the first structure 2100A and the second structure 2100B are combined with one touch.

Meanwhile, a process of separating the first structure 2100A and the second structure 2100B will be described as follows.

First, the second repulsion means flow part 2160 is retracted by holding it by hand. At this time, the second repulsion means flow part 2160 has irregularities so that it is easy to grip the hand.

Then, the second repulsion means actuating piece 2160a is retracted to compress the second repulsion means 2140 , and at the same time, the first assembly structure 2110 combined with the second repulsion means flowing part 2160 is retracted. will do Accordingly, the first repulsion means flowing part 2160 supported on the step 2110a of the first uniting structure 2110 is retreated and deviated from the coalescing protrusion 2180a of the first structure 2100A.

Then, the protrusion 2180a for merging of the first structure 2100A can be naturally separated from the second structure 2100B.

At this time, since the protrusion for merging (2180a) forms an inclined surface, and the groove for merging (2120a) also forms an inclined surface, it can be separated naturally.

And, after separating the first structure 2100A and the second structure 2100B, due to the repulsion of the second repulsion means 2140 of the second structure 2100B, the second repulsion means operating piece 2160a and the first The structure for merging 2110 is returned to its original position, so that the first structure 2100A and the second structure 2100B can be combined with one touch.

As a result, when the present invention is used, the first structure 2100A and the second structure 2100B can be combined with one touch without a separate prior operation, and thus, when manufacturing various three-dimensional structures, very various types of structures are produced. thing becomes possible

100: Feed supply unit to Dongae etc.
200: first transfer conveyor
210: transfer screw
300: first hopper
310: body
320: first filter plate
325: first opening
330: second filter plate
335: second opening
337: dentition
340: first door
350: weight sensor
360: second driving means
370: first driving means
380: control unit
390: rotary roller
400: second hopper
500: second transfer conveyor
600: packaging unit

Claims (4)

a feed supplying unit to the dongae, etc., which is fed into the dongae crushed in the grinder, and continuously discharges the feed to the put dongae, etc. over time;
a first conveying conveyor connected to the feed supply unit to the Dongae, etc. and transferring the feed to the Dongae etc. discharged from the feed supply unit to the Dongae etc.;
The first door formed on the lower end side to discharge the feed to the Dongae, etc. of the quantity corresponding to the set weight, and a weight sensor attached to the first door to measure the weight. a first hopper provided;
a second transfer conveyor positioned under the first hopper to transfer feed to the amount of dongae supplied from the first hopper;
a packaging unit for packaging the feed in the amount of Dongae transferred from the second transfer conveyor;
a control unit controlling the first door to be opened when the weight measured by the weight sensor matches the set weight;
It is installed at one end of the first hopper, and a feed manufacturing system to which dongae etc. is applied, characterized in that it comprises a odor reduction device for collecting and burning odors. The method of claim 1,
The odor reduction device 2000,
An air input tube 2100 into which air is introduced by external power in the form of a cylindrical pipe or a polygonal tube pipe;
a pump device 2200 connected to one end of the air input tube 2100 to transfer air by external electric power;
a case 2400 for a tornado-type air circulation device to which the air input tube is connected to the upper part to receive air;
a tornado-type air circulation device 2300 installed inside the case for the tornado-type air circulation device to rotate and compress the air to heat the air;
an air output pipe 2500 installed on the bottom surface of the case for the tornado-type air circulation device to output air;
a container-shaped diffusion chamber 2600 installed in the lower portion of the air output tube 500 and configured to spread air that has passed through the air output tube while splashing in all directions in the inner space;
a motor input tube 2700 connected to the air input tube to input polluted external air;
a final output line (2800) installed on the output side of the diffusion chamber;

The air input pipe 2100, a first structure connecting body 21800 is installed at the lower portion, the end of the first structure connecting body 2180, both sides of which are inclined on both sides of the protrusion (2180a) for merging is formed 1 structure 2100A; and a second structure (2100B) for connecting to the first structure;
The second structure 2100B,
a first merging structure 2110 installed in the outermost shell;
A second structure for merging is installed spaced apart from the first structure for merging by a certain distance to form a space so that the protrusion for merging enters the space, and a groove for merging is formed at one end so that the protrusion for merging is inserted and fixed. (2120) and;
a first repulsion means 2130 installed between the first merging structure and the second merging structure;
Installed at the front end of the first repulsion means, when the coalescence protrusion of the first uniting structure enters, it retreats to press the first repulsion means, and when the coalescing protrusion is inserted into the coalescing groove of the second uniting structure, the first The first repulsion means flowing part 2150 which is advanced by the repulsion of the repulsion means and is located on the upper part of the protrusion for coalescence;
a second repulsion means 2140 installed at the rear end of the first repulsion means flow part and having a repulsion function;
a second repulsion means flow part 2160 for driving the second repulsion means while retracting backward as a cylindrical structure installed outside the second repulsion means to drive the second repulsion means;
A feed production system to which Dongae etc. is applied, characterized in that it is installed at the rear end of the second repulsion means and comprises a second repulsion means support part 2170 for supporting the movement of the second repulsion means. 3. The method of claim 2,
The tornado-type air circulation device 2300 is,
A polygonal panel-shaped upper plate 2310 having a cylindrical pressure control cap 2311 with a closed upper portion installed thereon, and a polygonal panel-shaped lower plate 2320 having an air discharge hole 2321 at the lower portion; It is installed between the upper plate 2310 and the lower plate 2320, but is inserted and coupled in a spiral form from the edge of the upper plate and the lower plate coupling part to the center, and rotates and compresses flowing air to output at least two tornado-type panels 2330. Feed manufacturing system applied to Dongae, characterized in that it is made by 3. The method of claim 2,
On the side of the pressure control cap 2311,
A feed manufacturing system to which Dongae etc. is applied, characterized in that it is formed by further forming a plurality of air circulation holes (2312).

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