KR101884531B1 - Apparatus for cultivating and drying of farm produce - Google Patents

Abstract

The present invention relates to a multi-stage lathe rotary plant for cultivation and drying, comprising a plurality of trays disposed inside a chamber and having a tray for supporting or storing contents, a moving section for moving the tray along a set trajectory, And a power supply unit for simultaneously supplying power to all of the illumination units.
Unlike the prior art, a plurality of trays are mounted on a chain that rotates infinitely in the chamber, and the crops are stored or placed on each tray so that the position of the tray is changed according to the degree of cultivation or drying. And the lighting unit is installed on the lower side of each tray, so that the cultivation and drying efficiency can be improved by intensively illuminating the crops of the tray disposed on the lower side.

Description

[0001] APPARATUS FOR CULTIVATING AND DRYING OF FARM PRODUCE [0002]

The present invention relates to a multistage lathe rotary plant for cultivation and drying, and more particularly, to a multistage lathe rotary plant for cultivation and drying, in which a plurality of trays are placed in a chain which rotates infinitely in the chamber, and then the crops are stored or placed on each tray, By changing the position, crops can be evenly grown or dried, and lighting units can be installed on the lower side of each tray to concentrate the crops on the lower tray, thereby improving the cultivation and drying efficiency. The present invention relates to a multi-stage lathe rotary facility.

Generally, in rural areas, special crops using vinyl houses have been cultivated to raise farm household income. In the conventional method, a pedestal is installed on the ground, a bone is formed on the pedestal plate to allow the nutrient solution to flow, The cover was installed and planted at regular intervals on the lid to receive nutrients from the nutrient solution.

However, since the conventional hydroponic cultivation method can cultivate crops only as much as the area set on the ground surface of the vinyl house, the cultivation area needs to be widened so that an unnecessary area is wasted. Also, since the vinyl house and the hydroponic cultivation device are required There is a problem that unnecessary expenditure is caused.

As a prior art for solving such a method, a fixing rod is installed at a predetermined interval in an inner ceiling of a plastic greenhouse, a hook is formed on a top of the fixing rod, a reed hole is formed on the front surface, (Korean Patent No. 205614), a method for cultivating greenhouses for greenhouses in which crops grow so that nutrient solution flows from upper to lower ends in each cultivation pit.

The technical structure described above is a background technique for assisting the understanding of the present invention, and does not mean the prior art widely known in the technical field to which the present invention belongs.

Conventional plant cultivation methods could cultivate large crops in a narrow area, but since the hydroponic cultivation tank is fixed in a fixed shape on the fixed rods, there is a disadvantage that the crops are difficult to receive light, and as a result, Crops that grow well but do not receive light are slow to grow and have no commercial value.

Therefore, there is a need to improve this.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems as described above, and it is an object of the present invention to provide a method and a system for mounting a plurality of trays on an endless chain inside a chamber, The present invention provides a multi-stage lathe rotary plant for cultivation and drying.

It is another object of the present invention to provide a multistage lathe rotary plant for cultivating and drying crops to be cultivated or dried evenly by changing the position of trays according to the degree of cultivation or drying while rotating the chain.

In addition, according to the present invention, a lighting unit is provided on the lower side of each tray, and the crops of the tray disposed on the lower side are intensively illuminated, and all the lighting units are simultaneously emitted. Thus, The present invention provides a multi-stage lathe rotary plant for cultivation and drying.

The multi-stage lathe rotary plant for cultivation and drying according to the present invention comprises: a chamber; A plurality of trays disposed inside the chamber for supporting or containing the contents; A moving unit for moving the tray along a setting trajectory; An illumination unit provided in each of the trays to irradiate light for growing the contents of the adjacent trays; And a power supply unit for simultaneously supplying power to the entire illumination unit.

The moving unit includes a rotatable wheel member disposed inside the chamber along a constant trajectory and rotatable; At least a pair of conveying members wound around the rotation wheel member and rotated infinitely; A connecting member connected to the conveying member and composed of a plurality of conveying members; And a mounting member connected to the connecting member and horizontally holding the tray on both sides of the corresponding tray.

Wherein the power supply unit comprises: a current-carrying wire disposed along a locus of one of the transfer members and having electric conductivity; A power supply block that is supplied with power from the outside to supply current to the energizing wire and is fixed to the chamber; And a power applying unit connected to the conveying member corresponding to a portion adjacent to each of the trays and connected to the energizing wire, wherein the illumination unit is supplied with positive power from the power applying unit, (-) power supply.

The power supply block includes an insulating block fixed to the chamber and made of an insulating material; A power supply bracket fixed to the insulating block and having a conductive property and supplied with (+) power from the outside; And an elastic contact guide portion for maintaining the edge of the power bracket elastically contacting the energizing wire.

As described above, the multistage lathe rotary type plant for cultivating and drying according to the present invention has a structure in which a plurality of trays are mounted on a chain which rotates infinitely in the chamber, and the crops are stored or placed in a narrow space Crops can be cultivated or dried.

In addition, the present invention can cultivate or dry the crop evenly by changing the position of the tray according to the degree of cultivation or drying while rotating the chain.

In addition, according to the present invention, a lighting unit is installed on the lower side of each tray, and concentrated illumination is performed on the crops of the tray disposed on the lower side, so that all the lighting units are simultaneously emitted. Thus, cultivation and drying efficiency can be improved have.

1 is a perspective view of a multi-stage lathe rotary plant for cultivation and drying according to a first embodiment of the present invention.
2 is a front view of a multi-stage lathe rotary plant for cultivation and drying according to a first embodiment of the present invention.
3 is a configuration diagram of a moving part of a multi-stage lathe rotary plant for cultivation and drying according to the first embodiment of the present invention.
4 is an enlarged perspective view of a connection fixture of a multi-stage lathe rotary plant for cultivation and drying according to a first embodiment of the present invention.
FIG. 5 is an enlarged perspective view of a fastening part of a multi-stage lathe rotary plant for cultivation and drying according to a first embodiment of the present invention.
6 is a perspective view of a multi-stage lathe rotary plant for cultivation and drying according to a second embodiment of the present invention.
7 is a front view of a multistage lathe turning plant for cultivation and drying according to a second embodiment of the present invention.
8 is a configuration diagram of a moving part of a multi-stage lathe rotary plant for cultivation and drying according to a second embodiment of the present invention.
9 is an enlarged perspective view of a connection fixture of a multi-stage lathe rotary plant for cultivation and drying according to a second embodiment of the present invention.
10 is a configuration diagram showing a power transmission relationship of a moving unit of a multi-stage lath rotary type facility for cultivation and drying according to a second embodiment of the present invention.
11 is a front view of a multi-stage lathe rotary plant for cultivation and drying according to a third embodiment of the present invention.
12 is an enlarged perspective view of a power supply unit of a multistage lathe turning plant for cultivation and drying according to a third embodiment of the present invention.
13 is an enlarged exploded perspective view of a power supply unit of a multi-stage lathe rotary plant for cultivation and drying according to a third embodiment of the present invention.
FIG. 14 is a front elevational view of a power supply part of a multi-stage lathe rotary plant for cultivation and drying according to a third embodiment of the present invention.
15 is a front elevational view of a power supply part of a multi-stage lath rotary type facility for cultivation and drying according to a fourth embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a multi-stage lathe rotary plant for cultivation and drying according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a perspective view of a multi-stage lathe rotary facility for cultivation and drying according to a first embodiment of the present invention, FIG. 2 is a front view of a multi-stage lathe rotary facility for cultivation and drying according to a first embodiment of the present invention, Is a configuration diagram of a moving part of a multi-stage lathe rotary plant for cultivation and drying according to the first embodiment of the present invention.

FIG. 4 is an enlarged perspective view of a connection fixture of a multistage lathe rotary type plant for cultivation and drying according to a first embodiment of the present invention, FIG. 5 is a perspective view of a multi-stage lathe type rotary plant for cultivation and drying according to the first embodiment of the present invention. It is an expanded perspective of the government.

Referring to FIGS. 1 to 5, a multi-stage lathe rotary plant for cultivation and drying according to a first embodiment of the present invention includes a chamber 10, a tray 20, and a moving part 100.

The chamber 10 forms the outer shape of the multi-stage lathe rotary plant for cultivation and drying according to the present invention, and can be modified into various materials and various shapes. The chamber 10 accommodates the tray 20 and the moving part 100 therein.

At this time, the contents should be crops that require cultivation or drying.

Particularly, the chamber 10 can be formed so that the tray 20 and the moving part 100, in which the contents are lifted or housed, are installed inside, are easy to maintain, and open to one side for facilitating the withdrawal of contents. In addition, although not shown, an open side of the chamber 10 can be opened and closed by a door.

On the other hand, the tray 20 is arranged in the up-and-down direction inside the chamber 10, and functions to store the contents or to store the contents. At this time, the tray 20 serves as a shelf for supporting the contents, and can be modified into various shapes and various materials.

In addition, the moving unit 100 moves the entire plurality of trays 20 up and down simultaneously.

At this time, when the contents of the respective trays 20 are different from each other in the growth state or the drying state, the moving part 100 moves the entire upper and lower positions of the tray 20.

In more detail, the chamber 10 has a heating member 12 on its inner upper side. The heating member 12 can be applied as a heater coil or a hot air blower.

In addition, the contents of the tray 20 located relatively close to the heating member 12 are slower in growth or drying than the contents of the tray 20 located relatively far from the heating member 12 side.

Thus, the operator operates the moving part 100 periodically or intermittently to move the tray 20 relatively far from the side of the heating member 12 to a position close to the heating member 12. The tray 20 located relatively close to the heating member 12 is moved to a position farther from the heating member 12 side.

Therefore, the moving part 100 functions to grow or dry the contents evenly.

In addition, the chamber 10 may include a temperature sensor 14 on the upper side and a temperature sensor 14 on the lower side, respectively.

In addition, the chamber 10 may be provided with a sprinkler that can give water to the contents for growth.

Here, the moving unit 100 includes a rotating wheel member 110, a feeding member 120, a connecting member 130, and a mounting member 140.

The rotary wheel member 110 is disposed inside the chamber 10 along a circular or polygonal locus, and is rotatably provided.

For convenience, four rotary wheel members 110 are arranged along a rectangular trajectory.

The feeding member 120 is wound around the entire rotating wheel member 110 and rotated at an infinite speed, and at least one pair of the feeding member 120 is provided.

That is, the transfer member 120 is connected to the front edge and the rear edge of each of the rotary wheel members 110. At this time, the rotary wheel member 110 may be applied as a gear, and the transfer member 120 may be applied as a chain.

Of course, the rotary wheel member 110 is a rotary drum, and the conveying member 120 is applicable as a flat belt.

In addition, as shown, a pair of rotating wheel members 110 or respective rotating wheel members 110 can be supported on the shaft 114. As shown in Fig.

Thus, each of the rotating wheel members 110 feeds the corresponding feeding member 120, and the pair of rotating wheel members 110 connected to the shaft 114 are rotated in the same direction and at the same speed.

Further, the end of the rotating wheel member 110 or the shaft 114 located on the open side of the chamber 10 should be rotated while being supported. Thus, the chamber 10 has a support (not shown) on the open side.

Particularly, the temperature sensors 14 provided on the upper side and the lower side of the chamber 10 detect the mutual temperature deviation.

All or any one of the rotating wheel members 110 is connected to the driving motor 112. For convenience, one rotating wheel member 110 is connected to the driving motor 112 and is forcibly rotated.

In particular, the driving motor 112 rotates the driving wheel 113 in one direction, and the driving wheel 113 is gear-coupled to the feeding member 120. Thus, when the drive motor 112 is driven, the transfer member 120 is transferred by the rotational force transmission of the drive wheel 113.

The control unit 16 controls the driving motor 112 to change the vertical position of the tray 20 while forcibly rotating the feeding member 120 when a temperature deviation of more than a set value occurs.

On the other hand, the connecting members 130 are connected to the facing conveying members 120, and a plurality of the connecting members 130 are provided by the required number of trays 20.

In particular, the connecting member 130 can be struck in the downward direction by connecting the tray 20. In this case, when the conveying member 120 is conveyed, the tray 20 may vigorously shake, causing the trays 20 to hit each other or the contents to fall down.

In order to prevent this, the connecting member 130 may be connected to the corresponding conveying member 120 on both sides while maintaining the tension.

That is, the connection member 130 can be connected to the transfer member 120 while maintaining the tension by the connection fixing unit 200.

Here, the connection fixing part 200 includes the opening hole part 210, the thread part 220, and the nut member 230.

The opening hole portion 210 is opened to both sides of the conveying member 120. At this time, the formation position, diameter, number and the like of the opening hole portion 210 are not limited.

In particular, when the conveying member 120 is a chain, a tube may be applied instead of a conventional pin to form the opening hole 210.

The threaded portion 220 is formed on both side edge surfaces of the connection member 130 inserted into the opening hole portion 210 formed in each of the transfer members 120.

The nut member 230 is screwed to the threaded portion 220 of the connecting member 130 at one side or both sides of the feeding member 120 with respect to each of the feeding members 120 in a state where the nut member 230 is inserted into the opening hole portion 210. As the nut member 230 is threaded to the threaded portion 220, the connecting member 130 can maintain the tension by fastening the nut member 230 on both sides.

Meanwhile, the stationary member 140 is connected to each of the connecting members 130, and serves to hold the tray 140 on both sides of the corresponding tray 20.

At this time, the mounting member 140 connects the both sides of the tray 20, and then the upper portion is connected to the connecting member 130. The slip is formed along the axial direction of the connecting member 130 by the weight of the tray 20 Lt; / RTI >

To prevent this, the mounting member 140 is connected to the connecting member 130 in a positioned state.

That is, the mounting member 140 is prevented from moving after being positioned along the axial direction of the connecting member 130 by the mounting and demounting unit 300.

Here, the loading and unloading section 300 includes a sleeve 310, a flange 320, and a binding member 330.

The sleeve 310 inserts both sides of the connecting member 130, respectively. Accordingly, a pair of the sleeves 310 are provided on each of the connecting members 130. Of course, the sleeve 310 can be deformed into various shapes. In particular, the sleeve 310 inserts the connecting member 130, which is rotatable in the circumferential direction with respect to the connecting member 130.

The flange 320 is provided on the circumferential surface of the sleeve 310 so that at least one pair of the flange 320 is spaced apart in the axial direction so that the fixing member 140 is fixedly connected. Thus, the fixing member 140 is wound on the corresponding sleeve 310 between the pair of adjacent flanges 320.

Of course, the flange 320 can be deformed into various shapes.

In addition, the binding member 330 serves to bind the sleeves 310 to the connecting member 130 in a fixed position. Here, the binding member 330 is a mechanical fastening element such as a bolt that passes through the sleeve 310 and the connecting member 130.

FIG. 6 is a perspective view of a multi-stage lathe rotary facility for cultivation and drying according to a second embodiment of the present invention, and FIG. 7 is a front view of a multi-stage lathe rotary facility for cultivation and drying according to a second embodiment of the present invention.

FIG. 8 is a schematic view of a moving part of a multistage lathe turning apparatus for cultivating and drying according to a second embodiment of the present invention, FIG. 9 is a perspective view of a connecting part of a multistage lathe turning apparatus for cultivation and drying according to a second embodiment of the present invention, It is an expanded perspective of the government.

10 is a configuration diagram showing a power transmission relationship of a moving unit of a multi-stage lath rotary type facility for cultivation and drying according to a second embodiment of the present invention.

6 to 10, a multi-stage lathe rotary plant for cultivation and drying according to a second embodiment of the present invention includes a chamber 10, a tray 20, and a moving part 100.

The chamber 10 forms the outer shape of the multi-stage lathe rotary plant for cultivation and drying according to the present invention, and can be modified into various materials and various shapes. The chamber 10 accommodates the tray 20 and the moving part 100 therein.

In addition, the tray 20 is formed as a case open to the upper side so that the tray 20 can be transported while stably supporting the pollen or the like. Of course, the tray 20 can be deformed into various shapes.

Accordingly, the tray 20 can form the drain hole 22.

The moving part 100 also includes a rotating wheel member 110, a feeding member 120, a connecting member 130, and a mounting member 140.

Here, the rotary wheel member 110, the conveying member 120, the connecting member 130, and the mounting member 140 are replaced with those described above.

In particular, the conveying member 120 is arranged along a roughly zigzag trajectory so as to connect as many trays 20 as possible. Of course, the transfer member 120 can be arranged along various trajectories within a range that the space inside the chamber 10 allows. At this time, the trays 20 should be arranged so as not to hit each other.

In addition, the chamber 10 may have a tension roller 122 that is gear-engaged with the conveying member 120 to maintain the tension to prevent the conveying member 120 from shaking. At this time, the tension roller 122 is rotatably provided in the chamber 10, and is not limited to the number.

In addition, the chamber 10 may include a lighting unit 400 to illuminate the light for growth of the contents. Particularly, the transfer member 120 is disposed along a zigzag trajectory, and the illumination unit 400 is arranged in a zigzag manner, so that light can be irradiated to as many contents as possible with a minimum number of the illumination units 400. [ So that light can be irradiated to both sides. Of course, the illumination unit 400 may be installed in various ways such as a fluorescent lamp, an LED, and the like.

And, the chamber 10 may have a spraying unit 500 to spray water for the growth of the contents. At this time, the spraying unit 500 is disposed between the conveying members 120 arranged in a zigzag manner, so that water can be sprayed to the contents passing through one side.

Here, the spraying unit 500 can be applied as a sprinkler.

Particularly, the control unit 116 can control the driving motor 112, the illumination unit 400, and the spraying unit 500 simultaneously or individually to control the optimum conditions such as the growth and drying of the contents.

The connection member 130 may be connected to the transfer member 120 while maintaining the tension by the connection fixing unit 200.

The mounting member 140 is connected to both sides of the tray 20 and then connected to the connecting member 130. The slider 140 is slid along the axial direction of the connecting member 130 by the weight of the tray 20 Lt; / RTI >

To prevent this, the mounting member 140 is connected to the connecting member 130 in a positioned state by the mounting and fixing unit 300.

The reference numerals not described are replaced with those described above.

FIG. 11 is a front view of a multi-stage lathe rotary plant for cultivating and drying according to a third embodiment of the present invention, FIG. 12 is an enlarged perspective view of a power supply section of a multi-stage lathe rotary plant for cultivation and drying according to a third embodiment of the present invention, And FIG. 13 is an enlarged exploded perspective view of a power supply unit of a multi-stage lathe rotary plant for cultivation and drying according to a third embodiment of the present invention.

FIG. 14 is a front elevational view of a power supply part of a multi-stage lathe rotary plant for cultivation and drying according to a third embodiment of the present invention.

11 to 14, a multi-stage lathe rotary facility for cultivation and drying according to a third embodiment of the present invention includes a chamber 10, a tray 20, a lighting unit 400, and a power supply unit 600 do.

The chamber 10 and the tray 20 are replaced with those described above.

The illumination unit 400 is provided in each of the trays 20 and irradiates light to grow the contents of the adjacent trays 20. In detail, the illuminating unit 400 is provided on the lower side of each tray 20 and irradiates light to the upper side of the tray 20 coming in. Accordingly, crops of each tray 20 are improved in growth and drying efficiency through focused illumination from the illumination unit 400 of the upper tray 20. At this time, the illumination unit 400 may be installed on the lower side of each tray 20 in various ways.

Of course, the illumination unit 400 is not limited to the number provided in each of the trays 20, and is fixedly installed on the tray 20 in various ways.

Particularly, as each of the trays 20 rotates infinitely by the conveying member 120 included in the moving unit 100, the power supply unit 600 can be stably installed in the lighting unit 400 of each tray 20, Simultaneously supply power.

Here, the power supply unit 600 includes an energizing wire 610, a power supply block 620, and a power applying unit 630.

The energizing wire 610 is disposed along the locus of the conveying member 120 of any one of the pair of conveying members 120 arranged side by side. In particular, the energizing wire 610 may include a guide roller 612 to correspond to each of the rotating wheel members 110 so as to be continuously or non-continuously disposed along the same track as the feeding member 120. Thus, the energizing wire 610 is turned by the guide roller 612 and becomes infinitely movable.

In particular, the energizing wire 610 can be applied to various materials having electric conductivity.

Further, the power supply block 620 is supplied with power from the outside to supply a current (power) to the energizing wire 610. In particular, the power supply block 620 is made of an insulating material, and the power supply cable 623 can be inserted therein. In addition, the power supply block 620 is fixed inside the chamber 10. Of course, the power supply block 620 is provided by the number of the energizing wires 610, and can be modified into various shapes.

The power applying unit 630 is connected to the conveying member 120 corresponding to a portion adjacent to each of the trays 20 and is connected to the energizing wire 610.

In this case, the connector 636, which is not electrically connected to the feeding member 120 of the power applying unit 630, becomes a (-) power source from the feeding member 120, do.

The illumination unit 400 emits light by applying a (-) power source and a (+) power source. In particular, the lighting unit 400 of each tray 20 is electrically connected, and the outermost lighting unit 400 is assumed to emit light simultaneously when a (-) power source and a (+) power source are applied.

In addition, the number of the power applying units 630 may be equal to the number of the trays 20.

Here, the power supply block 620 includes an insulation block 622, a power supply bracket 624, and an elastic contact guide 626.

The insulating block 622 is fixed to the inside of the chamber 10 as an insulating material and inserts a power cable 623 to which external power is applied.

The power supply bracket 624 is fixed to the insulation block 622 and is electrically conductive and electrically connected to the power supply cable 623 to receive a (+) power from the outside. Of course, the power bracket 624 can be deformed into various shapes and fixed to the insulating block 622 by various methods such as bolting.

The elastic contact guide portion 626 is formed at the edge of the power bracket 624 and serves to maintain the contact with the energizing wire 610 elastically.

For example, the elastic contact guide 626 may include an elastic curvature member 627 which curvedly extends in the direction of conveyance of the energizing wire 610 conveyed in the conveying direction of the conveying member 120.

Of course, the elastic curvature member 627 can be deformed into various shapes without limiting the curvature. In addition, the elastic contact guide portion 626 and the power source block 620 can be variously applied.

On the other hand, the power applying section 630 includes a clip 632, a support section 634, and a connector 636. [

The clip 632 is made of a metal material while keeping the contact state by covering the energizing wire 610. Thus, the clip 632 applies a (+) power source from the energizing wire 610. [ Of course, the clip 632 can be deformed into various shapes.

The supporting portion 634 is connected to the conveying member 120 for supplying the negative power to the illumination unit 400 and is made of an insulating material.

At this time, the support part 634 is formed so that the transfer member 120 and the clip 632 are not in contact with each other, and the transfer member 120 and the support part 634 are detachably coupled by the first fastening member 635. Here, the first fastening member 635 can be applied as a bolt or a screw.

Particularly, the specific conveying member 120 can be shaped so as to stably engage with the supporting portion 634.

The connector 636 is held on the edge of the clip 632 so as to be prevented from coming into contact with the conveying member 120 and is fixed to the supporting portion 634 to fix the clip 632. That is, the edge of the clip 632 is engaged with the support portion 634, and the connector 636 is engaged with the clip 632 and the support portion 634 by the second fastening member 637. The second fastening member 637 can be applied as a bolt or a screw.

In addition, the connector 636 is made of a metal material and serves to supply (+) power to the illumination unit 400. Of course, the connector 636 can be deformed into various shapes.

As a result, the negative cable 124 is contacted to the conveying member 120 by the first coupling part 635 and the negative cable 124 is connected to the second coupling member 638 And contacts the connector 636 to apply (+) power.

Then, the (-) cable 124 and the (-) cable 124 contact the illumination unit 400, so that the illumination unit 400 emits light. In particular, the (-) power source can be supplied by contacting the (-) power cable 124 to the chamber 10. That is, the (-) power source may be grounded.

The reference numerals not described are replaced with those described above.

15 is a front elevational view of a power supply part of a multi-stage lathe rotary plant for cultivation and drying according to a fourth embodiment of the present invention.

Referring to FIG. 15, a multi-stage lathe rotary plant for cultivation and drying according to a fourth embodiment of the present invention includes a lighting unit 400 and a power supply unit 600.

The illumination unit 400 is replaced with the one described above.

The power supply unit 600 includes an energizing wire 610, a power supply block 620, and a power applying unit 630.

The energizing wire 610 and the power applying section 630 are replaced with the above.

The power supply block 620 includes an isolation block 622, a power supply bracket 624, and an elastic contact guide 626.

Here, the insulating block 622 and the power supply bracket 624 are replaced with those described above.

The elastic contact guide portion 626 is formed at the edge of the power supply bracket 624 and serves to maintain the contact with the energizing wire 610 elastically.

The elastic contact guide 626 includes an elastic curvature member 627 curvedly extending in the conveying direction of the energizing wire 610 conveyed in the conveying direction of the conveying member 120, And a pressing spring 629 elastically pressing the elastic curvature member 627 toward the energizing wire 610 side.

Of course, the elastic curvature member 627 can be deformed into various shapes without limiting the curvature.

In addition, the pressing spring 629 can be fixedly disposed between the insulating block 622 and the elastic curvature member 627 in various ways.

The reference numerals not described are replaced with those described above.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. I will understand. Accordingly, the true scope of the present invention should be determined by the following claims.

10: chamber 12: heating member
14: temperature sensor 16:
20: Tray 100:
110: rotating wheel member 112: driving motor
120: conveying member 130: connecting member
140: stationary member 200:
210: opening hole part 220:
230: Nut member 300: Mounted and fixed
310: Sleeve 320: Flange
330: binding member 400: illuminating unit
500: Sprinkler unit 600: Power supply unit
610: energizing wire 620: power supply block
630: Power supply unit

Claims (5)

chamber; A plurality of trays disposed inside the chamber for supporting or containing the contents; A moving unit for moving the tray along a setting trajectory; An illumination unit provided in each of the trays to irradiate light for growing the contents of the adjacent trays; And a power supply unit for simultaneously supplying power to the entire illumination unit,
The moving unit includes a rotatable wheel member disposed inside the chamber along a constant trajectory and rotatable; And at least a pair of conveying members that are wound on the rotating wheel member and rotate infinitely,
Wherein the power supply unit comprises: a current-carrying wire disposed along a locus of one of the transfer members and having electric conductivity; And a power supply block that is supplied with power from the outside to supply current to the energizing wire and is fixed to the chamber,
The power supply block includes an insulating block fixed to the chamber and made of an insulating material;
A power supply bracket fixed to the insulating block and having a conductive property and supplied with (+) power from the outside; And
And an elastic contact guide portion for elastically maintaining the edge of the power bracket in contact with the energizing wire.
The apparatus according to claim 1,
A connecting member connected to the conveying member and composed of a plurality of conveying members; And
And a mounting member connected to the connecting member and horizontally holding the tray on both sides of the corresponding tray.
The method according to claim 1,
Wherein the power supply unit includes a power applying unit connected to the conveying member corresponding to each of the trays and connected to the energizing wire,
Wherein the illumination unit is supplied with a (+) power from the power applying unit, and is illuminated by receiving (-) power from the feeding member.
delete The power supply unit according to claim 3,
A metallic clasp wrapping the conductive wire to maintain a contact state;
A supporting member which is in contact with the edge of the clip in a face contact manner and is coupled to the conveying member for supplying power to the lighting unit, And
And a connector for clamping the clip and being connected to the support unit so as to be prevented from coming into contact with the conveying member and supplying positive power to the lighting unit. Lathe revolving equipment.

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