KR101419417B1 - Garlic planter - Google Patents

Abstract

A garlic seeder according to the present invention includes a frame having a pulling portion to be engaged with a coupling portion of a tractor, an exhausting device formed on both sides of the frame so as to be adjustable in height and digging troughs, A hopper in which a garlic seed is stored inside and a divided discharge port corresponding to a garlic seeding interval is formed by a partition wall; a rotary disk installed so as to correspond to the split discharge port; A garbage conveying means including a bucket in which a receiving groove for receiving garlic seed is formed and a bucket cover for opening and closing the receiving groove; And an arcuate discharge path connected to the inclined discharge path and passing through the garlic transfer means to receive the garlic seed in the receiving recess A guide hopper for guiding the roots of the garlic seeds flowing into the receiving groove so as to face the soil, seeding means for seeding the garlic seeds introduced from the guide hopper into the soil, And a rolling wheel coupled to both sides of the frame to generate rolling action of the tractor by driving the tractor.
According to this, by providing the buffering means at the tip of the frame connected to the tractor, the rolling wheels are brought into close contact with the ground surface, so that the transmission of rotational force by the rolling wheels and the chain connection is smooth and the seeding depth of garlic seeds can be kept constant .
In addition, by forming the split discharge port in the hopper and the rotating means in the discharge path, clogging of the garlic seed is prevented on the discharge port side of the hopper, and the garlic species is uniformly transferred to each bucket.

Description

Garlic planter {GARLIC PLANTER}

The present invention relates to a garlic seeder, and more particularly to a garlic seeder, which comprises a buffering means connected to a tractor so that a rolling wheel is brought into close contact with a ground surface even in a bending land, The present invention relates to a garlic sowing machine capable of increasing the precision of sowing of garlic and thus improving the productivity of garlic by forming an upper and a lower height adjusting means on a rolling wheel.

Generally, garlic seeder is driven by own power such as cultivator or tractor, and is mounted on an agricultural machine which is running, and automatically distributes and sowes garlic seeds one by one while traveling.

As a prior art of such garlic sowing machines, the applicant of the present invention has filed a patent application entitled " Garlic Sowing Apparatus " in Korean Registered Utility Model No. 20-0339899 (hereinafter referred to as "Prior Art"). The frame 100 includes a garlic receptacle 110 in which garlic 1 is received and a sub-wheel 120 in a lower portion of the garlic receptacle 110, A rotor blade 151 that is rotated by the power transmitted from the power output section P of the agricultural machine and breaks the ground to the lower part of the tip of the rotor 100 and the crushed soil A stopper 150 for stopping the garlic 1 in the garlic receptacle 110, a distribution unit 200 for transporting the garlic 1 in the garlic receptacle 110, ) To the agricultural land.

However, the garlic seeding apparatus according to the prior art has a simple structure in which the front portion of the coupling portion C of the agricultural machine and the frame 100 are fixed. Therefore, the auxiliary wheels 120 are not brought into close contact with the ground due to the bending of the ground, There is a problem that the seeding depth of the seedling 1 is not constant and a deviation occurs according to the inclination of the ground.

In addition, there is a problem that the garlic 1 discharged from the garlic receptacle 110 to the rotating portion 200a is clogged by the discharge passage formed narrowly in the lower portion of the garlic receptacle 110.

The garlic 1 discharged from the garlic receptacle 110 is intensively inflowed into the garlic gripping member 11 at one side or unevenly flows into the side of each garlic gripping member 11 so that the garlic 1 is not uniformly sowed In order to prevent such a problem, there has been a problem that the worker has to constantly check the congestion of the garlic 1.

In addition, when the slope or the curvature of the soil to be sown by the garlic 1 is severe, the depth of sowing of the garlic 1 is not constant, or the sowing depth is thin over a certain period of time, .

In addition, in the course of the garlic gripping member 11 rotating along the garlic feed wheel 210 passing through the bucket passing-in recess 160a, a failure often occurs due to the pressure of the stagnant garlic 1, There is a problem in that the garlic 1 is pulled out between the garnish 162 and the garlic.

In addition, since each component is rotated by the power transmitted from the power output unit P of the agricultural machine, the garlic seeding interval is formed irregularly according to the moving speed of the farm machinery.

In order to solve the above-described problems, the present invention has an object of providing a towing portion connected to a tractor so as to be rotatable and forming a buffering means so as to smoothly rotate the rolling wheel so that rolling wheels always come into close contact with the ground surface.

Another object of the present invention is to allow the garlic discharged from the hopper through the split discharge port to the seed discharge path to be continuously introduced into the garlic transfer means side without being clogged by the narrow outlet port.

In addition, the rolling wheel mounted on the frame is formed so that the height of the top and bottom can be adjusted so that the seeding depth of the garlic is kept constant even on the curved terrain.

Further, garlic flowing into the garlic feeding means through the seed discharge path is smoothly supplied to the garlic feeding means without being caught or lost in a gap between the seed discharging path and the garlic feeding means.

Another object of the present invention is to maintain the garlic seeding interval formed at predetermined intervals along the traveling direction of the garlic sowing machine to be constant even if the traveling speed of the garlic sowing machine trailed by the tractor is not constant but variable.

According to the present invention, there is provided a tractor comprising: a frame having a traction unit coupled to a coupling portion of a tractor; a tiller installed on both sides of the frame so as to be adjustable in height and digging troughs; A hopper in which a garlic seed is stored in the inside of the hopper and in which a divided outlet corresponding to the intervals of sowing of garlic is formed by a partition wall; a rotary disk installed so as to correspond to the split outlet; A garment conveying means including a bucket in which a receiving groove for receiving garlic seeds is formed and a bucket cover for opening and closing the receiving groove; And an arc-shaped discharge path connected to the inclined discharge path and passing through the garlic transfer means to receive the garlic seed in the receiving recess. A guide hopper for correcting the roots of the garlic seed so that the roots of the garlic seeds flow into the soil so that the receiving grooves are opened so that the roots of the garlic seeds flow into the soil, seeding means for sowing the garlic seeds introduced from the guide hopper into the soil, And rolling wheels coupled to both sides of the tractor to generate rolling action of the tractor by driving the tractor.

Preferably, the vibrating means comprises a rotating cam plate that rotates in contact with the bottom surface of the divided discharge port, and prevents rotation of the rotating cam plate from stagnating the malleable material to the divided discharge port, As shown in Fig.

The rolling wheel is coupled to the other end of a rotating frame rotatably coupled to both sides of the frame, one end of the rotating frame is coupled to the hydraulic cylinder, and a slave shaft provided at one end of the rotating frame Chain or belt connected to the garlic conveying means by a chain or belt, and the garlic conveying means is connected to the vibrating means and the seeding means by a chain or a belt.

The pulling portion includes a fixing bracket formed at a front upper end portion of the frame, a pivotal bracket pivotally coupled to the fixing bracket and coupled to the coupling portion, and a pair of paired Of compression spring.

The bucket is radially formed on one side of the rotating disk, and the bucket cover includes a bucket cover for opening and closing the receiving groove, and a rotating shaft connected to the other side of the rotating disk by a tension spring and connected to the bucket cover. And the bucket cover opens and closes the receiving groove by rotation of the rotating lever.

The pressing roller is hinged to the left and right sides of the frame, and the opposite ends of the pressing plate are hinged to the middle of the pressing plate. A connecting roller connecting the ends of the extension plate to each other, and a buffer spring formed between the connection frame and the frame.

In addition, the discharger may include a support frame coupled to the frame so as to be adjustable in height, a clay part coupled to a lower end of the support frame and having inclined surfaces at both sides thereof, and a dispersing blade for dispersing the clayey soil to both sides, .

The flat rotary includes a rotary shaft coupled to both sides of the frame, a rotary wheel formed at equal intervals in the rotary shaft, and a crush plate rotatably coupled to the rotary wheel and bent at the middle .

According to the present invention, since the buffering means is formed at the tip of the frame connected to the tractor, the rolling wheel is brought into close contact with the ground surface, so that the rotational force is smoothly transmitted by the rolling wheel and the chain connection, and the seeding depth of the garlic seed is kept constant There is an effect that can be.

In addition, by forming the split discharge port in the hopper and the rotating means in the discharge path, clogging of the garlic seed is prevented on the discharge port side of the hopper, and the garlic species is uniformly transferred to each bucket.

In addition, the height of the rolling wheel is adjusted up and down, so that the depth of seeding can be adjusted according to the inclination or curvature of the sown soil.

In addition, since the garlic feeding means, the rotating means and the seeding means are connected and rotated by the rolling wheels, the garlic seeding interval can be accurately maintained according to the progress of the garlic seeder regardless of the moving speed of the tractor.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a front view showing the overall configuration of a garlic planter according to a preferred embodiment of the present invention; FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a garlic sowing machine.
3 is a plan view showing a part of a garlic seeder according to a preferred embodiment of the present invention.
FIG. 4A is an exploded perspective view illustrating a partially assembled structure of a garlic seeder according to a preferred embodiment of the present invention. FIG.
FIG. 4B is a front view of a partly assembled structure of a garlic planter according to a preferred embodiment of the present invention; FIG.
FIG. 5 is a perspective view showing a part of a garlic seeder according to a preferred embodiment of the present invention. FIG.
6 is a partial cross-sectional view showing a part of the structure of a garlic seeder according to a preferred embodiment of the present invention.
7A is a front view showing a part of a garlic seeder according to a preferred embodiment of the present invention.
FIG. 7B is a rear view showing a part of a garlic seeder according to a preferred embodiment of the present invention; FIG.
8A and 8B are front views showing a part of the structure of a garlic seeder according to a preferred embodiment of the present invention.
9 is a front view showing a part of a garlic seeder according to a preferred embodiment of the present invention.
10 is a side view showing a part of a garlic seeder according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

It will be understood by those of ordinary skill in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

In addition, the sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation, and the terms defined specifically in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user, operator And the definitions of these terms should be based on the contents throughout this specification.

In the drawings illustrating the embodiments of the present invention, the same reference numerals are applied to the same parts.

FIG. 1 is a front view showing the overall structure of a garlic seeding machine according to a preferred embodiment of the present invention, FIG. 2 is a front view showing an overall power transmission structure of a garlic seeding machine according to a preferred embodiment of the present invention, 4a is an exploded perspective view showing a part of the assembled structure of the garlic seeder according to the preferred embodiment of the present invention, and FIG. 4b is a perspective view showing a preferred embodiment of the present invention FIG. 5 is a perspective view showing a part of the structure of a garlic seeding machine according to a preferred embodiment of the present invention, and FIG. 6 is a perspective view showing a garlic seeding machine according to a preferred embodiment of the present invention, FIG. 7A is a partial cross-sectional view showing a part of the seeder according to the preferred embodiment of the present invention, FIG. 7B is a rear view showing a part of the structure of a garlic seeder according to a preferred embodiment of the present invention, and FIGS. 8A and 8B are views showing a part of a garlic seeder according to a preferred embodiment of the present invention FIG. 9 is a front view showing a part of a garlic seeder according to a preferred embodiment of the present invention, and FIG. 10 is a side view showing a part of a garlic seeder according to a preferred embodiment of the present invention.

1 to 10, a garlic seeder 1 according to a preferred embodiment of the present invention roughly includes a frame 100, a dresser 170, a flat rotary 200, a stop plate, a hopper A seed hopper 470, a seeding means 500, a pressure roller 600, and a rolling wheel 700. The seed hoppers 440,

1 to 3, the frame 100 includes left and right side panels 110 and a plurality of joining frames 120 that connect the left and right side panels 110 in a lateral direction, so that the respective components of the garlic seeder 1 are arranged inside and outside A pulling part 130 provided at the front of the frame 100 and assembled to the first and second engaging parts J1 and J2 of a tractor (not shown) A spline shaft S1 connected to a power connection shaft (not shown) of a tractor (not shown) and a spline shaft S1 connected to a rolling wheel 700 and connected to the garlic feeding means 400, the seeding means 500 and the vibrating means 374 And a first driven coaxial shaft S2 for transmitting a rotational force is formed.

The spline shaft S1 is formed in front of the frame 100 and connected to a power connection shaft (not shown) of a tractor (not shown). The garlic seeder 1 of the present invention drives the flat rotary 200 by the power of a tractor (not shown). To this end, the spline shaft S1 is connected to a power coupling shaft (not shown) formed behind the tractor (not shown) and a universal joint U.

A gear box 140 is formed at the rear of the spline shaft S1 to change the rotational direction of the spline shaft S1. Although not shown, a bevel gear (not shown) is formed in the gear box 140 and is connected to the side of the gear box 140 by a second driven shaft S3 parallel to the rotary shaft 210 of the flat rotary 200, . The second type coaxial shaft S3 is connected to the flat rotary 200 and the chain C to transmit rotational force to the flat rotary 200.

The rolling wheels 700 are pivotally coupled to both sides of the frame 100 so that the height adjustment is performed. When the rolling wheel 700 is rotated and the height adjustment is performed, the following effects are produced.

That is, it is possible to adjust the height of the rolling wheel 700 at the irregular height of the soil so that the seeding depth of the seeding means 500 can be kept constant, and the depth of seeding can be adjusted according to the soil condition, Can be changed.

The coupling structure includes a rotation frame 710 having one end rotatably coupled to the side of the frame 100 and the other end rotatably coupled to the drive shaft 730 of the rolling wheel 700, An extension frame 711 extending from one end of the frame 100 and connected to the upper side of the frame 100 and a hydraulic cylinder 720 having both ends connected to the frame 100 and the extension frame 711.

The hydraulic cylinder 720 is connected to a hydraulic pump (not shown) connected to a power take-off connected to a power shaft of a tractor (not shown) and connected to a hydraulic hose (not shown) and driven. That is, the rolling wheel 700, which is coupled to the other end of the rotating frame 710 by rotating the extension frame 711 in the forward and reverse directions by the operation of the hydraulic pump (not shown) Down direction.

At one end portion of the pivot frame 710 rotatably coupled to the frame 100, a first slave axis S2 connected to the rolling wheel 700 and the chain C is formed.

The first type coaxial shaft S2 is connected to the rolling wheel 700 by a chain C and transmits rotational force to the garlic feeding means 400 and the seeding means 500 and the vibrating means 374. [ Of course, it is also possible to connect the chain C with a timing belt (not shown).

The garlic seeder 1 of the present invention is characterized in that the pulling portion 130 is connected to the first and second engaging portions J1 and J2 of the tractor (not shown) and pulled by a tractor (not shown) The rolling wheel 700 is rotated by friction with the ground.

When the rotational force of the rolling wheel 700 is transmitted to the garlic conveying means 400, the seeding means 500 and the vibrating means 374, the garlic conveying means 400 The seeding means 500 and the vibrating means 374 are operated. Therefore, an accurate seeding interval can be maintained, and an appropriate number of garlic seeds G are transferred according to the seeding interval.

The first type coaxial shaft S2 is connected to the rolling wheel 700 by the chain C and receives the rotational force of the rolling wheel 700 and is connected to the garlic feeding means 400 by the chain C, 700).

The garlic conveying means 400 is connected to the seeding means 500 and the vibrating means 374 by a chain C so that when the rolling wheels 700 are rotated on the ground, the garlic conveying means 400 and the seeding means 500 are rotated, And the vibration means 374 are simultaneously rotated.

The evacuator 170 includes a support frame 171 which is height-adjustably coupled to both sides of the frame 100 and a clay section 173 for covering the soil on both sides.

The support frame 171 is coupled to the frame 100 to support the clay 173 and a plurality of first fixing holes 172 are longitudinally formed to adjust the height of the frame 100 in a height-adjustable manner. Preferably, a fastening part 150 formed of a square pipe is formed on both sides of the frame 100, and a support frame 171 is inserted into the fastening part 150. The fastening part 150 is formed with a second fixing hole 151 to be coupled to any one of the plurality of first fixing holes 172 by the fixing pin 137.

The slope 174 is formed on both sides of the slope 173 so that the slope of the slope 174 is smoothly shifted to the left and right sides of the slope 174. On the upper side, The dispersing vanes 175 are formed so as to be dispersed to both sides without falling over.

The flat rotary 200 includes a rotary shaft 210 coupled to both sides of the frame 100, a rotary wheel 220 formed at regular intervals on the rotary shaft 210, And a shredding plate 230.

The rotary shaft 210 is connected to the second driven shaft S3 by a chain C and rotated by the rotational force of a power connecting shaft (not shown) of the tractor (not shown).

It is preferable that the rotary wheel 220 is formed at equal intervals on the rotary shaft 210 and is formed in correspondence with the garlic seeding interval. That is, the rotating wheel 220 is formed at each of the portions where the garlic seed G is sown, so that the soil of the soil in which the garlic seed G is sown is evenly broken.

The shredding plate 230 is formed of a flat plate having an obtuse angle bend 231 and is rotatably coupled to the rotary wheel 220. Preferably, the shredding plates 230 are formed symmetrically with respect to the rotary shaft 210 so that the shredding plates 230 do not collide with each other during operation.

The stop plate 240 is formed behind the flat rotary 200 to prevent the soil crushed by the crush plate 230 from scattering backward and to stop the soil.

4A and 4B, the pulling portion 130 includes a fixing bracket 131 formed on the frame 100, a rotation bracket 132 coupled to the fixing bracket 131 so as to rotate in the pulling direction, And a buffering means 133 formed between the bracket 131 and the rotation bracket 132.

The fixing bracket 131 is fixed to the front upper end portion of the frame 100 and includes a first rotation hole 131a to which the rotation bracket 132 is rotatably coupled, A first fixing hole 131c for fixing the rotation bracket 132 and a fourth rotation hole 136 for inserting the buffering means 133 are formed in the partition wall 131d, And a second traction hole 131e coupled with the second engagement portion J2 of the tractor T. [

The rotation bracket 132 includes a first traction hole 132a for engaging with the first engaging portion J1 of the tractor (not shown) and a second traction hole 132a for engaging with the second rotation hole 131a A third rotation hole 132c corresponding to the rotation rail hole 131b and a second fixing hole 132d corresponding to the first fixing hole 131c are formed.

The buffering means 133 is constituted by a pair of compression springs 134a and 134b and a center member 135. [ The center member 135 is formed inside the compression springs 134a and 134b to form the compression orbits of the compression springs 134a and 134b. That is, one end of the center member 135 is fixed to the rotation bracket 132 so as to protrude toward the traction direction, and the other end is inserted into the fourth rotation hole 136 formed in the partition 131d of the fixing bracket 131 And compression springs 134a and 134b are coupled to both sides of the fourth rotation hole 136, respectively.

The second rotation hole 132b of the rotation bracket 132 is engaged with the first rotation of the fixing bracket 131 so that the rotation of the fixing bracket 131 The third rotation hole 132c of the rotation bracket 132 is coupled to the rotation rail hole 131b of the fixing bracket 131 by the fixing pin 137, The rotation bracket 132 and the fixing bracket 131 coupled to the first and second coupling portions J1 and J2 of the first and second rotation holes 132b The rotation of the fixing pin 137 fixed to the third rotation hole 132c of the rotation bracket 132 is caused to rotate in the rotation rail hole 131b.

At this time, a pair of compression springs 134a and 134b formed on both sides of the fourth rotation hole 136 are respectively compressed by the forward and reverse rotation of the rotation bracket 132, The fixing pin 137 coupled to the third rotating hole 132c and the rotating rail hole 131b of the fixing bracket 131 is elastically rotated in the forward and reverse directions in the rotating rail hole 131b.

That is, when the garlic seed G is sown, the rolling wheel 700 moves upward and downward according to the bending of the soil by the hinged structure of the rotating bracket 132 and the fixing bracket 131, The impact force due to the flow is absorbed by the elastic members 134a and 134b so that the seeding depth of the garlic seed G does not change suddenly and the even seeding depth is maintained.

On the other hand, the garlic seeder 1 of the present invention takes the garlic seeder 1 to the garlic field or storage warehouse with the tractor T before the seeding in the garlic field. When the garlic seeder 1 is pulled for movement, the rolling wheel 710 is rotated so that the rolling wheel 700 and the garlic feeding means 400 connected with the chain C and the seeding means 500 do not rotate So that the towing is performed after the rolling wheel 700 is separated from the ground.

When the pulling portion 130 is separated from the first and second engaging portions J1 and J2 of the tractor (not shown), the fixing pin 137 coupled to the rotating rail hole 131b and the third rotating hole 132c, Is coupled to the first fixing hole 131c and the second fixing hole 132d so that the rotation bracket 132 is fixedly coupled to the fixing bracket 131. [ The fixing pin 137 can be replaced with the bolt B and the nut N. [

5, the hopper 300 includes a space 310 in which garlic seeds G are stored, and a split discharge port 340 divided by first and second partition walls 320 and 330 .

The space portion 310 is formed in such a shape that the lower side thereof is narrowed so that the garlic seed G injected from the upper portion of the hopper 300 to be seeded is smoothly discharged to the seed discharge path 370.

The split discharge port 340 is formed to separately inject the garlic seed G into the seed discharge path 370 and is divided by the first and second partition walls 320 and 330 formed on the left and right sides, As shown in Fig.

The split discharge port 340 is formed to correspond to the garlic seeding interval, and discharges the garlic seed G according to the garlic seeding interval. The bucket 430 and the guide hopper 470 and the breeding hopper 300 which are provided at the lower portion of the split discharge port 340 and feed the garlic seed G discharged from the split discharge port 340 are also fed to the split discharge port 340, respectively.

The seed discharge path 370 includes an inclined discharge path 371 hinged to the bottom surface of the split discharge port 340 and an arc discharge path 373 for receiving the garlic seed G through the garlic transfer means 400 ).

6, the inclined discharge passage 371 is formed on the bottom of the divided discharge port 340 to form a ramp for allowing the garlic seed G to flow into the garlic conveying means 400 side. Although not shown, the first and second partition walls 320 and 330 are formed so as to extend so that the garlic seed G does not separate from the left and right sides of the inclined discharge path 371 on the left and right sides of the inclined discharge path 371 do.

A cam shaft 376 is attached to the side panel 110 by a vibrating means 374 that rotates in contact with a bottom surface of an inclined discharge path 371 hinged to the bottom surface of the discharge outlet 340, (Not shown). The bottom surface of the inclined discharge path 371 is repeatedly rotated about the hinge point 372 on the lower side of the split discharge port 340 by the rotating cam plate 375 connected to the chain C and connected to the garlic conveying means 400, The garlic seed G is prevented from clogging the split discharge port 340 caused by excessive accumulation of the garlic seed G between the split discharge port 340 and the inclined discharge path 371, And is uniformly supplied to the arcuate discharge path 373 side.

The arcuate discharge path 373 is formed in the first partition 320 so that the discharge path of the garlic seed G is extended to the lower end of the inclined discharging path 371, The buckets 430 and the bucket cover 440 formed on the side of the bucket cover 440 pass through the discharge passage to receive and transport the garlic seed G. The buckets 430 and the bucket cover 440, (430) and the bucket cover (440).

7A and 7B, the garlic conveying means 400 includes a rotary disk 420 in which the disk shaft 410 is rotated by a chain (C) connected to the first driven shaft S2, And a bucket cover 440 that opens and closes the bucket 430. The bucket 430 is provided on the side surface of the bucket cover 430 to receive and transport the garlic seed G,

The rotary disc 420 is formed in the shape of a disc and is formed adjacent to one side end of the inclined discharge path 371 and extends in a direction opposite to the inflow direction of the garlic seed G flowing into the arc- Rotate.

The bucket 430 is provided with a receiving groove 431 for receiving the garlic seed G flowing into the arcuate discharge path 373 in the direction of rotation so that the rotation of the rotary disk 420 in the direction of the inclined discharge path 371 (Hereinafter referred to as " receiving surface 421 ").

The bucket cover 440 is configured to open or close the receiving groove 431 of the bucket 430 according to the rotation of the rotating disk 420 and includes a bucket cover 441 for rotating and opening and closing the receiving groove 431, A rotation lever 443 connected to the bucket cover 441 and the connection rod 442, a fixing block 444 for rotatably fixing the connection rod 442 to the rotary disk 420, And a first tension spring 447 connecting the one end of the bucket cover 441 and the rotating disk 420. The spring connecting piece 446 is formed of a spring connecting piece 446,

The fixing block 444 is coupled to the opposite surface of the rotating disk 420 to the receiving surface 421 (hereinafter referred to as the receiving surface 422) for fixing the bucket cover 440 to the rotating disk 420 do. In the fixing block 444, a receiving hole 445 formed in the radial direction of the rotating disk 420 to receive the connecting rod 442 is formed.

The connecting rod 442 is rotatably coupled to the receiving hole 445 of the fixed block 444.

The bucket cover 441 is formed to be coupled to one end of the connecting rod 442 protruding to the edge side of the rotating disk 420 and protruding toward the receiving surface 421 side. A concave groove is formed at the edge of the rotating disc 420 so that the turning operation of opening and closing the receiving groove 431 of the bucket cover 441 projected toward the receiving surface 421 occurs within a certain angle range without interference of the rotating disc 420. [ (423) are formed.

The first tension spring 447 elastically connects one side of the rotating disc 420 and the spring connecting piece 446 formed on one side of the connecting rod 442 so that when the rotating lever 443 is not rotated, The bucket lid 441 is pulled by the compression force of the spring 447 in such a manner that a predetermined compressive force remains so as to close the receiving groove 431 and is coupled to both sides.

The rotating lever 443 is formed at the other end of the connecting rod 442 and is formed to protrude obliquely toward the rotating direction of the rotating disk 420. The rotating lever 420 is rotated by interference with the rotating disk 420, (441) opens the receiving groove (431).

A guide 321 for interfering with and rotating the rotation lever 443 is protruded from the first partition 320 extending to the accommodation back surface 422 for a certain period along the rotation direction of the rotation lever 443.

The guide 321 is opened at the upper portion of the guide hopper 470 to be described later according to the rotation of the bucket 430 and the bucket cover 440 so that the garlic seed G is guided to the opening of the guide hopper 470 And the opened bucket 430 enters the arc-shaped discharge path 373 into which the garlic seed G flows so that the garlic seed G is received again in the receiving groove 431 and the bucket cover 441 Is formed along the circumferential direction from the upper side of the guide hopper 470 to a portion adjacent to the lower end of the inclined discharge path 371 so as to rotate and grip the garlic seed G. [

The garlic conveying means 400 may further comprise a remaining amount collection vat (not shown) for collecting the garlic seed G falling off from the bucket 430 in accordance with the rotation of the rotating disc 420.

8A, the guide hopper 470 is formed below the garlic conveying means 400 to receive the garlic seed G falling from the bucket 430 and to guide the roots of the garlic seed G toward the ground . The front and rear pivoting covers 471 and 474 are pivotally supported on both sides of the front pivoting cover 471. The rear pivoting cover 474 and the frame 100 And a second tension spring 475 coupled to the second spring 475.

The front and rear pivot covers 471 and 474 are coupled to the coupling plate 476 coupled to the frame 100 by a hinge portion 477 and the front and rear pivot covers 471 and 474 are coupled between the hinge portions 477 An interlocking projection 478 is formed so as to be simultaneously rotated.

The catching piece 472 is formed at the lower end of the forward rotation cover 471 so that the upper end of the seeding hopper 540 to be rotated can easily push the lower end of the forward rotation cover 471. When the seeding hopper 540 pushes the engagement piece 472 formed at the lower end of the front rotation cover 471, the forward rotation cover 471 rotates about the hinge portion 477 formed on the upper side, The interlocking protrusion 478 rotates at the same time and the rear rotation cover 474 rotates in the opposite direction. As described above, the garlic seeds G contained therein are dropped into the seeding hopper 540 by the front and rear rotating covers 471 and 474 rotating at the same time so that the bottom is opened.

On the other hand, on the lower side of the front rotation cover 471, there is formed a latching groove portion 473 for catching the pointed upper portion of the garlic seed G inside the latching piece 472. Accordingly, when the roots of the garlic seeds G are received in the guide hopper 470 upwardly, the pointed upper portions of the garlic seeds G are caught by the engagement groove portions 473, so that the front and rear rotation covers 471 and 474 The garlic seed G is dropped and rotated by the rotating inertia of the front rotation cover 471 so that the root is held downward in the seeding hopper 540.

The second tension spring 475 is provided on both sides of the rear pivot cover 474 and the frame 100 so as to maintain the front and rear pivot covers 471 and 474 in a closed state when no external force is applied by the seeding hopper 540 .

8A, 8B, and 9, the seeding means 500 is disposed below the guide hopper 470 to seed the garlic seed G falling and flowing into the guide hopper 470 into the soil, A hopper shaft 520 formed in a circumferential direction between the gear case 510 and the pair of gear case 510, and a pair of gear case 510 coupled to the hopper shaft 520, And a seeding hopper 540 coupled to the seed hopper 520.

The gear case 510 is rotatably connected to the garlic conveying means 400 through a chain C and is rotatably coupled to both sides of the inside of the frame 100 and is connected to a sun gear 511 An outer gear 512 formed at an equal angle along the edge of the gear case 510 and an idle gear 512 coupled to the sun gear 511 and the outer gear 512 for transmitting rotational force, Gear, 513).

The sun gear 511 is fixed to the gear case 510 and transmits rotational force to the idle gear 513 and the outer gear 512 rotatably installed in the gear case 510 according to the rotation of the gear case 510 The sun gear 511 and the outer gear 512 are formed with the same number of teeth and the outer gear 512 is maintained in the upward and downward directions even when the gear case 510 rotates.

Both ends of the hopper shaft 520 are fixedly coupled to an outer gear 512 formed in correspondence with the pair of gear cases 510 so as to rotate upwardly and downwardly like the outer gear 512.

The seeding hopper 540 is fixedly coupled to the hopper shaft 520 and seeds the garlic seed G falling from the guide hopper 470 into the soil as the lower side of the front and rear seeding covers 541 and 544 spread.

A turning piece 545 is formed on the rear seeding cover 544 so that the upper side thereof is coupled to the frame 100 with a third tension spring 547. The forward seeding cover 541 is connected to the turning piece 545 A rail piece 542 is formed. The projecting portion 546 is formed in the rotating piece 545 so as to be fitted in the rail portion 543 formed on the rail piece 542 in the transverse direction so that the rear seeding cover 544 is rotated, ) Are simultaneously rotated.

The rear seeding cover 544 has an upper portion fixed to the hopper shaft 520 and an intermediate portion coupled to the hopper pivot shaft 530 rotatably coupled to the hopper shaft 520. A cylindrical rail 514 is formed on the gear case 510 at both ends of the hopper shaft 520 to have protrusions 515 over a predetermined interval. A cylindrical rail 514 is attached to both ends of the hopper pivot shaft 530 The roller 531 is rotated. When the gear case 510 rotates and the lower side of the seeding hopper 540 forms a groove in the soil, the roller 531 rotates along the outer circumferential surface of the cylindrical rail 514 at the same time as the protrusion 515, The hopper pivot shaft 530 is rotated together with the rollers 531 so that the front and rear sowing covers 541 and 544 are opened so that the garlic seed G is sown in a dotted manner in the groove formed in the soil .

Referring to FIG. 10, the suppressing roller 600 is disposed behind the seeding hopper 540 so that the garlic seed G is sown to cover the soil in which the seeding grooves are formed while covering the soil in the seeding grooves, A rolling roller 620 having both ends axially coupled to each other in the middle of the extending plate 610 and an end portion of the extending plate 610 are connected to each other to form a middle And a cushion spring 640 hingedly connected to the connection frame 630 and coupled to the frame 100.

The buffer springs 640 absorb the impact even when the buffer springs 640 pass through the curved terrain in the soil during the cover so that the connection roller 630 and the frame 100 .

The suppressing roller 600 may be replaced with a soil drag chain which connects and bonds the chain C to the rear of the garlic seeder 1.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

Accordingly, the above-described embodiments are to be considered illustrative and not restrictive, and the scope of the present invention should be construed in accordance with the invention as set forth in the appended claims, And may further include various modifications, alternatives, and equivalents by those skilled in the art.

1: garlic planter 100: frame
200: flat rotary 300: hopper
400: Garlic feeding means 500: Sowing means
600: Ramping roller 700: Rolling wheel
110: side panel 210: rotary shaft
120: coupling frame 220: rotating wheel
130: pull section 230: crush plate
131: Fixing bracket 231:
131a: first rotating hole 240: stop plate
131b: rotating rail hole 310:
131c: first fixing hole 320: first partition
131d: partition wall 321: guide
131e: second pull hole 330: second partition
132: rotation bracket 340: split outlet
132a: first pull hole 370: seed discharge path
132b: second rotating hole 371: inclined discharge passage
132c: third rotating hole 372: hinge point
132d: second fixing hole 373: arcuate discharge passage
133: buffer means 374: vibration means
134: compression spring 375: rotating cam plate
135: center member 376: cam shaft
136: fourth rotating hole 410: disk shaft
137: fixing pin 420: rotating disk
140: gear box 421: receiving surface
150: fastening part 422: accommodating backing
151: second fixing hole 423: concave groove
171: Support frame 430: Bucket
172: first fixing hole 431: receiving groove
173: clay part 440: bucket cover
174: slope surface 441: bucket cover
175: Dispersing blade 442: Connecting rod
510: gear case 443: rotating cover
511: Sun gear 444: Fixed block
512: outer gear 445: receiving hole
513: idle gear 446: spring connecting piece
514: Cylinder rail 447: First tension spring
515: protrusion 470: guide hopper
520: hopper shaft 471: forward rotating cover
530: Hopper pivot shaft 472:
531: roller 473:
540: seeding hopper 474: rear rotating cover
541: forward seeding cover 475: second tension spring
542: rail piece 476: engaging plate
543: rail part 477: hinge part
544: rear seeding cover 478:
545: Rotating piece 710: Rotating frame
546: protrusion 711: extended frame
547: Third tension spring 720: Hydraulic cylinder
610: Extension plate U: Universal joint
620: Roller Roller C: Chain
630: connection frame J1, J2: first and second coupling parts
640: Buffer spring
S1: Spline shaft
S2: First type coaxial
S3: second type coaxial

Claims (9)

A frame having a pulling portion coupled with a coupling portion of the tractor;
An embankment which is formed on both sides of the frame so as to be adjustable in height and which digs a trough;
A flat rotary mounted on the rear of the shaker to pick soil;
A hopper in which a garlic seed is stored internally and a divided discharge port corresponding to a garlic seeding interval is formed by the partition wall;
A garbage conveying means including a bucket cover for opening and closing the receiving groove formed in a side surface of the rotary disk and having a receiving groove for receiving garlic seeds;
An incline type discharge path hingedly connected to a lower side of the split discharge port and formed with a vibrating means so as to rotate in a section; an arcuate discharge port connected to the inclined discharge path and passing through the garlic conveying means to receive the garlic seed in the receiving recess; A seed discharge path comprising a furnace;
A guide hopper which corrects the roots of the garlic seed so that the receiving grooves are opened and the roots of the garlic seeds flow into the soil;
Seeding means for seeding the garlic seed introduced from the guide hopper into the soil;
And a rolling wheel coupled to both sides of the frame to generate a rolling action with the ground by driving the tractor. The method according to claim 1,
Wherein the vibrating means comprises a rotating cam plate that rotates in contact with the bottom surface of the split outlet and prevents the garlic species from stagnating at the split outlet by rotation of the rotating cam plate. The method according to claim 1,
Wherein the vibrating means is rotated by the rotational force of the rolling wheels. The method according to claim 1,
The rolling wheel
And the other end of the pivoting frame is connected to the other end of the pivoting frame and coupled to the hydraulic cylinder,
Wherein the drive shaft of the rolling wheel is connected to a slave shaft provided on the rotating frame by a chain or a belt, the slave shaft is connected to the garlic conveying means by a chain or a belt, and the garlic conveying means comprises the vibrating means and the seeding means And a chain or belt connected to the garlic seeder. The method according to claim 1,
The pulling portion
A fixing bracket formed at a front upper end portion of the frame, a pivotal bracket pivotally coupled to the fixing bracket and coupled with the coupling portion, and a pair of compression springs coupled to both sides with respect to one side of the fixing bracket And the garlic seeder. The method according to claim 1,
The bucket is radially formed on one side of the rotary disc. The bucket cover includes a bucket cover for opening and closing the receiving groove, a rotary lever coupled to the other side of the rotary disc by a tension spring and connected to the bucket cover ≪ / RTI &
And the bucket cover opens / closes the receiving groove by rotation of the rotating lever. The method according to claim 1,
A pressing roller disposed behind the seeding means to cover the ground,
The pressure roller
An extension plate hinged to left and right sides of the frame, a rolling roller having both ends axially coupled to an intermediate portion of the extension plate, a connection frame connecting the ends of the extension plate to each other, And a buffer spring formed between the garbage disposer and the garbage disposer. The method according to claim 1,
The discharger
A support frame height-adjustably coupled to the frame,
And a clay connected to a lower end of the support frame and having inclined surfaces formed on both sides thereof and having a dispersing vane for dispersing clay soils on both sides. The method according to claim 1,
The flat rotary
A rotary shaft coupled to both sides of the frame, a rotary wheel formed at regular intervals in the rotary shaft, and a crush plate rotatably coupled to the rotary wheel and folded in the middle.

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