JPS6352851B2 - - Google Patents

Description

[Detailed description of the invention] [Industrial application field]

The present invention relates to a soil block manufacturing apparatus, and more particularly to a soil block manufacturing apparatus that prevents soil hoppers from collapsing to ensure block formation.

[Conventional technology]

Soil block is used to grow seeds or young seedlings to the required size by applying them to each plant.After growth, the seedlings can be transplanted to the field without changing the root environment, resulting in good seedling growth. Soil blocks are used in cultivation methods that have recently been attracting attention due to their recognized advantages, and soil block manufacturing equipment is used to form these blocks accurately and efficiently.

[Problem to be solved by the invention]

Although such soil block manufacturing apparatuses have already been provided, no apparatus has yet been found that efficiently manufactures blocks by operating the mechanisms necessary to accurately shape the soil blocks in a timely manner.

[Means to solve the problem]

Therefore, the present invention aims at intermittent feeding of the conveyor belt, cutting of the molding section, and block prevention.
The vertical movement of the punch etc. is linked to each other, and furthermore,
The present invention is characterized in that seeds are automatically supplied to the block, and this movement can be linked with the movement described above.

[Effect]

With the above structure, the present invention allows the conveyor belt, the sliding part of the soil hopper, the block forming section, and the seed feeder to work together to continuously form soil blocks to which seeds have been applied.

【Example】

DESCRIPTION OF THE PREFERRED EMBODIMENTS The structure of the present invention will be described below with reference to embodiments shown in the accompanying drawings. First, in FIG. 2, reference numeral 10 indicates a machine frame, which has casters 11 and support legs 12 on its lower surface, so that it can be installed and moved on the ground. Pulleys 1 are provided at both ends of this machine frame 10.
3 and 14, the pulley 14 is provided coaxially with the drive ratchet wheel 15, and an endless conveyor belt 16 is mounted between the pulleys 13 and 14.
The intermediate portion is guided by a guide plate 17 and a floating pulley 13a. A motor 20 as a drive source is mounted on the machine frame 10, and one end of a connecting rod 23 is pivotally attached to the end of a crank arm 22 provided on an output shaft 21 of the motor 20, and the other end is Said ratchet wheel 1
It is pivotally connected to a swinging rod 24 which is fixed to the shaft 15a of No. 5. The swinging rod 24 has a ratchet pawl 25.
The ratchet pawl 25 is held close to the ratchet wheel 15 by a spring 25a. A cam clutch mechanism may be used instead of this ratchet mechanism. A soil hopper 30 is attached to the end of the upper surface of the conveyor belt 16.
A soil supply port 31 is opened on the front side in the direction of movement of the soil hopper 6, and as the conveyor belt 16 moves along the bottom surface of the soil hopper 30, the soil in the soil hopper 30 is placed on the belt from the bottom and fed out. It's summery. A sliding anchor 32 is disposed close to the soil supply port 31 of the soil hopper 30 and above the conveyor belt 16.
2 has a width corresponding to the width of the soil supply port 31, and its lower end has a spatula-shaped curved end 3.
It's becoming 2a. This sliding arm 32 is supported by a swinging rod 33 that is pivotally supported on the machine frame near the soil supply port of the soil hopper 30.
At one end, two pins 33a are fitted into elongated holes 32c formed in the bracket 32b of the sliding armrest 32, so that the sliding armrest 32 moves in an arc. Further, a long hole 33d is formed at the other end of the swinging rod 33 along the length of the swinging rod 33, and a guide roller 34 is fitted into this long hole 33d. One end of a crank arm 34a is pivotally connected to the axis of the guide roller 34, and the other end of the crank arm 34a is attached to a shaft 35 of a chain wheel 35.
It is pivoted to a. A chain 37 is installed between the chain wheel 35 and a chain wheel 36 provided on the output shaft 21 of the motor 20, so that the rotation of the motor 20 is transmitted to the chain wheel 35 (via a reduction gear). I'm getting cozy. A molding section 40 of the soil block is located close to the soil hopper 30, and this molding section 40
As shown in FIG. 3, the cutter 41 includes a cutter 41, block retainers 42 and 43, and a drive unit that moves these up and down. That is, the cutter 41 has vertical blades 41 along the length direction and the width direction of the block B.
a, horizontal blade 41b, horizontal blade 4
Vertical blades 41a are attached at equal intervals to 1b so as to be orthogonal to each other in a plane. The horizontal blade 41b also serves as a frame 44, a horizontal plate 44a is fixed to this frame 44, a support arm 45 is erected on this plate 44a, and a support arm 45a is provided horizontally and horizontally at the top end of the support arm 45a. is fixed along. Holes 45b and 44b are bored on the same axis in both ends of the support arm 45a and in the plate 44a.
Pillar 4 of block retainer 42 passes through 5b and 44b.
2a is arranged, and the block retainer 42 is constantly pushed downward by a pressing spring 46 interposed between the spring receiver 42b protruding from each support 42a and the support arm 45a. , the slit 42c through which the vertical blade 41a can pass is the vertical blade 41.
There are as many as a. Further, a horizontal frame 48 is connected to the horizontal blade 41b via two vertical pieces 47, and this horizontal frame 48 is located at the same level as the horizontal plate 44a provided on the frame 44, and has a support at the center in the width direction. 48a is erected, and a support arm 48b is attached to the top end of this column 48a.
is fixed horizontally. And support arm 48b
Holes 48d and 48 are coaxially connected to the block retainer 43.
A pillar 43a which is erected on the block retainer 43 passes through these holes 48d and 48c, and a push spring 49 is interposed between the spring receiver 43b protruding from the pillar 43a and the support arm 48b. , the block retainer 43 is always pushed downward. Furthermore, an adjustment bolt 70 is provided on the plate 44a. The horizontal frame 48 is provided with punches 49a which are formed and cut and are movable up and down to form seeding holes for sowing seeds and planting seedlings in independent blocks B. The number corresponds to the number in the width direction. Further, the vertical movement stroke of the block forming section 40 is set so that the cutter 41 reaches the conveyor belt, and the block retainer is set so as to maintain a distance from the conveyor belt equal to the thickness of the block. The entire molding section 40 moves up and down, and a crank arm 52 provided on the shaft 35a of the chain wheel 35 is pivotally attached to a frame 50 of the molding section 40, and this frame 50 moves up and down along a guide 51. I am able to move. A spring is interposed between the frame 50 and the molding part 40, so that even if foreign objects such as stones are present, the work will not be hindered. Further, the seed supply device 60 has a seed supply plate 62 that reciprocates along the inclined bottom surface 61a of the hopper 61, and this seed supply plate 62 has holes 62a corresponding to the number of blocks B. One or several seeds are stored in the hole 62a,
After the seed supply plate 62 has moved to the supply hole 63 formed in the bottom surface 61a of the hopper 61, the seeds are dropped from the nozzle 65 into the hole of each block B via the supply pipe 64. The seed supply plate 62 is connected to a swinging drive rod 66 that is pivotally supported on the machine frame 10.
The other end is connected to an arm that is cranked by the rotation of the motor 20, and is constantly pulled by a tension spring 67 so that the seed supply plate 62 moves above the hopper 61. Next, the operation of forming block B shown in FIG. 1 using the soil block manufacturing apparatus of the present invention will be explained. First, soil suitable for the soil block is stored in the soil hopper 30, and a certain amount of soil is allowed to flow out from the soil supply port 31 onto the conveyor belt 16. When the motor 20 is driven in this state, the rotation of the crank arm 22 causes the connecting rod 23 to reciprocate, causing the ratchet pawl 25 to rotate the ratchet wheel 15 when the swinging rod 24 is pulled.
When being pressed, let the ratchet pawl 25 play. The rotation of the ratchet wheel 15 drives the pulley 14 coaxial with the ratchet wheel 15, and the conveyor belt 16 is intermittently fed. It works in the same way when using a cam clutch. The stroke of this intermittent feed is determined by the width dimension of block B, and the conveyor belt 1
6 moves on the bottom surface of the soil hopper 30, so soil is drawn out from the soil supply port 31. Near this soil supply port 31, a sliding arm 32 moves in an arc in conjunction with the rotation of the motor 20, so it trowels the surface of the soil flowing out from the soil supply port 31. These exercises prevent it from collapsing. This sliding arm 32 makes an arcuate motion and reciprocates as the swinging rod 33 swings due to the rotation of the crank arm 34a. Further, the forming section 40 moves up and down in conjunction with the intermittent feeding, and moves downward relative to the soil on the conveyor belt 16, and first, the cutter 41 slits the soil. The horizontal blade 4 is cut by the vertical stroke of the cutter 41.
1b and the vertical blade 41a are used to slit the continuous soil, and after the next feeding, the horizontal blade 41b is used to cut the continuous soil to form a block B. The slit is made by the downward movement of the cutter 41, and the block retainers 42 and 43 are pushed by the pressing springs 46 and 49 while maintaining the distance between them and the conveyor belt 16 by the adjusting bolt 70. , press the surface of the block moderately to harden it. Further, the height of the block B is adjusted by adjusting the adjustment bolt 70. As the cutter 41 moves upward, the block retainers 42 and 43 also move upward.
Since the cutter 41 remains compressed to some extent and does not move up together with the cutter 41, the block retainers 42 and 43 hold down the surface of the block group until the cutter 41 separates from the block B. Therefore, Katsuta 41
The soil of the block will not be brought up by the upward movement of the block.
There is no shape disturbance at all. A punch 49a cooperating with the cutter 41 punches a hole in the formed block B, and the seed grains in the hopper 61 are fed into the hole by the seed supply plate 62 into each supply pipe 64, and then into each nozzle 65. Seed grains are supplied from The seed supply plate 62 reciprocates linearly along the bottom surface of the hopper 61 as a swing drive rod 66 pivotally supported on the machine frame 10 swings by the rotation of the motor 20, and reaches the lowest part of the hopper 61. In the position state, many seeds are placed on the seed supply plate 62, but since the seed supply plate 62 is in the raised state, most of the seeds rotate in a lower direction, and only the seeds in the holes 62a are placed on the seed supply plate 63.
and falls from the supply pipe 64 to the nozzle 65.

【Effect of the invention】

As is clear from the above description, according to the soil block manufacturing apparatus of the present invention, the sliding anchor is driven in conjunction with the intermittent feeding of the conveyor belt to prevent landslides at the soil supply port in the soil hopper. The cutter in the molding section and the block holding punch are moved up and down, and the seed feeder that feeds seeds into the holes drilled in the block is linked, so each mechanism moves in a timely manner to ensure continuous production. A soil block with seeds is obtained.

[Brief explanation of the drawing]

The attached drawings show an embodiment of the soil block manufacturing apparatus of the present invention, and FIG. 1 is a perspective view of the soil block, FIG. 2 is a side view of the same device, FIG. 3 is an exploded perspective view of the molding part, and FIG. 4 is a perspective view of the soil block manufacturing apparatus. This is a slope diagram of Sliding Anson, No. 5.
6 are explanatory diagrams showing the order of slitting by block suppression. 10... Machine frame, 11... Caster, 12... Support leg, 13, 14... Pulley, 15... Drive ratchet, 16... Conveyor belt, 17... Guide plate, 20... Motor, 21... Output shaft, 22...
Crank arm, 23... Connecting rod, 24... Swinging rod, 25... Ratchet pawl, 25a... Spring, 3
0... Soil hopper, 31... Soil supply port, 3
2... Sliding armrest, 33... Swinging rod, 34... Guide roller, 35, 36... Chain wheel, 37... Chain, 40... Molding part, 41... Cuttle, 42,
43...Block suppression, 44...Frame, 45
...Strut, 46...Press spring, 50...Frame,
51...Guide, 52...Crank arm, 60
... Seed supply device, 61 ... Hopper, 62 ... Seed supply plate, 63 ... Supply hole, 64 ... Supply pipe, 65
... Nozzle, 66 ... Swing drive rod, 67 ... Tension spring, 70 ... Adjustment bolt.

Claims (1)

[Claims] 1. A conveyor belt that is attached to a machine frame and is fed intermittently, a soil hopper that is arranged along the feeding direction of this conveyor belt, and a block forming section that is located adjacent to this soil hopper. A soil block manufacturing device equipped with a soil hopper having a sliding plate placed at the soil supply port and sliding on the soil surface to stabilize the soil, and a slit that moves up and down relative to the soil to make the block independent; It is equipped with a block forming section having a punch for punching into the block, and a seed feeder for supplying seeds to the block, and a conveyor belt is intermittently fed in conjunction with the top and bottom of the block forming section, and a sliding plate is interlocked. A soil block manufacturing device characterized by being configured to stabilize the soil surface by reciprocating.