JPH0917A - Planter for raising seedling - Google Patents

Abstract

PURPOSE: To enable a raising seedling box to be automatically housed in a stocker and temporarily reserved and to be automatically returned and transferred one by one. CONSTITUTION: In this planter for raising seedling, during transferring a raising seedling box from one end of a transferring mechanism 1 to another end, a bed soil is supplied into the raising seedling box with a soil scattering device 5, the raising seedling box is temporarily reserved in a stocker 9 and the raising seedling box reserved in the stocker 9 is returned from one end of the transferring mechanism 1 to the other end, the seeding is sown with a sower 7 and is covered with the soil using the soil scattering device 5. In the planter, the raising seedling boxes transferred from one end of the transferring mechanism 1 are automatically piled one by one in the stocker 9 and the raising seedling boxes piled in the stocker 9 are automatically fed to the other end of the transferring mechanism 1 one by one.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a seedling raising seeding machine.

[0002]

2. Description of the Related Art In a conventional seedling sowing machine, for example, a soiling device, a seeding device, and a watering device are provided from one end to the other end of the transfer mechanism on a transfer mechanism for transferring a nursery box.
A stocker for holding the nursery box is provided at the other end of the transfer mechanism, and while transferring the nursery box from one end of the transfer mechanism to the other end, after supplying bed soil to the nursery box with a soil-filling device, the nursery box Temporarily hold the seedlings in the stocker, then send the nursery box held in the stocker to the other end of the transfer mechanism, and transfer it back from the other end to one end by the transfer mechanism, while irrigating the nursery box with a watering device. However, there is one in which the seeding device is used for seeding and the soil filling device is used for covering the soil. However, the conventional seeding machine automatically stores the nursery box in the stocker, and receives the nursery box transferred into the stocker with a pair of left and right descending receivers, descends the descending receivers, and raises the nursery box. There is one in which the seedlings are sequentially stacked and stored (for example, Japanese Examined Patent Publication No. 5-37889), but one by one, the seedling-raising boxes stored in the stocker are automatically taken out one by one from the other end of the transfer mechanism. It was not configured to point back automatically.

[0003]

Therefore, conventionally, it was necessary to manually carry the seedling raising box stored in the stocker to the other end of the transfer mechanism, and the sowing work was very troublesome. In view of the above problems, the present invention can automatically store and temporarily hold the seedling raising boxes transferred from one end to the other end of the transfer mechanism, and automatically transfer the seedling raising boxes stored in the stocker one by one automatically. There is a device in which it can be returned to the other end and transferred from the other end to the one end by a transfer mechanism.

[0004]

A first technical means of the present invention for solving this technical problem is to provide a transfer mechanism 1 on which a nursery box 2 is placed and transferred, and one end of the transfer mechanism 1 is provided. From the other to the other end, a soiling device 5, a seeding device 7, and a watering device 8 are provided, and a stocker 9 for holding the nursery box 2 is provided on the other end side of the transfer mechanism 1 to transfer the nursery box 2. Mechanism 1
During the transfer from one end to the other end of the seedling, the soil is supplied to the seedling raising box 2 by the soil-filling device 5, the seedling raising box 2 is temporarily held in the stocker 9, and the seedling raising box 2 held in the stocker 9 is transferred. 1
In the seedling raising seeding machine in which the seeding device 7 sows and the soil filling device 5 covers the soil while returning from the other end to the one end, the stocker 9 is transferred from one end of the transfer mechanism 1. The boxes 2 are automatically and sequentially stacked, and the seedling-raising boxes 2 stacked in the stocker 9 are sequentially and automatically delivered to the other end of the transfer mechanism 1.

In the second technical means, a receiving member 35 for sequentially placing and raising the seedling raising boxes 2 that have entered the stocker 9 from the transfer mechanism 1 is provided in the stocker 9 in multiple stages. The stocker 9 is provided with an elevating device 36 for intermittently ascending and descending by interlocking with each other. A third technical means is that when the seedling raising box 2 is transferred from the transfer mechanism 1 into the stocker 9, the multistage receiving members 35 are raised intermittently, and the seedling raising box 2 is transferred from the stocker 9 to the transfer mechanism 1. The point is that a control device 101 for controlling the elevating device 36 is provided so as to intermittently lower the multi-stage receiving member 35 when being sent.

[0006] The fourth technical means is that the bed soil leveling device 6 for smoothing the bed soil surface supplied into the seedling raising box 2 on the transfer mechanism 1 can be raised to a position where it does not hinder the transfer of the seedling raising box 2. There is a point that is provided.

[0007]

[Operation] When the seedling raising box 2 is transferred from one end of the transfer mechanism 1 to the other end, after the bed soil is supplied to the seedling raising box 2 by the soil inserting device 5,
The nursery box 2 enters the delivery position D of the stocker 9 from the other end of the transfer mechanism 1. The nursery box 2 that has entered the delivery position D is the receiving member 3
5, the elevating device 36 intermittently elevates and lowers the multistage receiving members 35 in conjunction with each other, whereby the seedling raising boxes 2 that have entered the delivery position D are sequentially received by the multistage receiving members 35, and the elevating device It is raised and lowered step by step by 36. Therefore, the seedling raising boxes 2 transferred from one end of the transfer mechanism 1 are automatically stacked one after another and automatically retained in the stocker 9.

When the seedling raising box 2 is transferred from the other end of the transfer mechanism 1 to the one end side, an elevating device 36 interlocks the multi-stage receiving members 35 with each other to intermittently ascend and descend, whereby the seedlings stacked on the stocker 9 are raised. The boxes 2 are sequentially sent to the other end of the transfer mechanism 1, and the seedling raising boxes 2 retained in the stocker 9 are automatically returned from the other end of the transfer mechanism 1 toward one end. During this time,
The seedling raising box 2 is irrigated with the irrigation device 8 and covered with the soiling device 5. Then, at this time, the floor soil leveling device 6 can be raised to a position that does not hinder the transfer of the seedling raising box 2.

[0009]

Embodiments of the present invention will be described below with reference to the drawings. 1 to 3, reference numeral 1 denotes a transfer mechanism for placing and transferring the seedling raising box 2. On the transfer mechanism 1, a soil filling device 5, a soil leveling device 6, a seeding device 7, and a watering device 8 are provided, and a stocker 9 for holding the nursery box 2 is provided on the other end side of the transfer mechanism 1. While the seedling raising box 2 is being transferred from one end to the other end of the transfer mechanism 1, the soil filling device 5 supplies the bed soil to the seedling raising box 2 and the floor soil leveling device 6 enters the seedling raising box 2 into the seedling raising box 2. After smoothing the supplied bed soil surface, the nursery box 2 is temporarily stored in the stocker 9, and the nursery box 2 stored in the stocker 9 is transferred to the transfer mechanism 1.
While returning from the other end to the one end, the seedling raising box 2 is irrigated with the irrigation device 8, seeded with the seeding device 7, and covered with the soil filling device 5.

The transfer mechanism 1 includes a pair of left and right frames 1
Supporting a plurality of rotating shafts 12 with a space between each other,
A roller 13 is fitted onto and fixed to each of the rotary shafts 12, and the power from the transfer motor 14 is transmitted to the rotary shaft 12 via a chain, a sprocket, etc., and the seedling raising box 2 placed on the roller 13 is mounted. Is transferred at a constant speed in the direction of arrow A by the forward drive of the transfer motor 14, and at a constant speed in the direction of arrow B by the reverse drive of the transfer motor 14.

The soil feeding device 5 comprises a hopper 17 and a soil supply mechanism 18, is mounted on a pair of left and right frames 11 via a pair of left and right mounting plates 19, and is transferred by the transfer mechanism 1 to a seedling raising box 2. It is configured to supply soil inside. The seeding device 7 includes a hopper, a seed feeding device, and the like, and is configured to sow seeds into the seedling raising box 2 transferred on the transfer mechanism 1.

As shown in FIGS. 4 and 5, the floor soil leveling device 6 includes a rotating brush 21 for smoothing the surface of the bed soil supplied into the nursery box 2, and a swelling W of soil on the wall of the nursery box 2. And a leveling member 22 for leveling. The rotating brush 21 is rotatably supported by a support frame 23 about a horizontal shaft 24, and the support frame 23 is swingably supported by a pair of left and right frames 11 about a support shaft 15 to support the support frame 23. The rotating brush 21 can be adjusted up and down by swinging around the shaft 15. The support frame 23 is biased downward by a tension spring 25. The upper end of the leveling member 22 is the support frame 2
3 is rotatably supported on the free end side of the rotary shaft 26 about the horizontal shaft 26, and the rotary brush 21 is rocked by the swing of the support frame 23 about the support shaft 15.
Along with that, it can be adjusted up and down. A tension spring 27 is connected to the lower side of the leveling member 22 and to the front side of the horizontal axis 26 of the support frame 23, and the leveling member 2 is connected by the tension spring 27.
No. 2 is biased to incline slightly forward. Leveling member 2
The lower end of 2 is bent into a hook shape.

An operation lever 29 is rotatably connected to the front portion of the support frame 23 about a horizontal shaft 28, and the operation lever 29 is protruded rearward from the front portion of the support frame 23 so as to be operated.
Is inserted and held in a guide groove 31 of a guide plate 30 provided in the soil inserting device 5. By setting the operation lever 29 to the reverse position 31a of the guide groove 31, the rotary brush 21
Also, the leveling member 22 is positioned above the seedling raising box 2 so as not to interfere with the seedling raising box 2, and the operation lever 30 is set to the guide groove 3.
By setting it to the normal rotation position 31b of No. 1, the rotary brush 21 and the leveling member 22 can be set to a position where the bed soil of the nursery box 2 can be leveled, and the operation lever 30 is set to the off position 31c of the guide groove 31. Therefore, the rotating brush 21
Also, the leveling member 22 can be lowered onto the transfer mechanism 1. A turnbuckle 32 is provided in the middle of the operating lever 29, and the heights of the rotating brush 21 and the leveling member 22 can be finely adjusted by rotating the turnbuckle 32. Also, the guide plate 3
A forward rotation switch SW1 for driving the transport motor 14 to be described below in the forward direction and a reverse switch SW2 for driving the transport motor 14 in the reverse direction are incorporated in 0, and the operating lever 29
When the switch is set to the forward rotation position 31b, the forward rotation switch SW1
Is turned on and the reverse rotation switch SW1 is turned on when the operation lever 29 is set to the reverse rotation position 31a.

The operation of the leveling member 22 will now be described. When the nursery box 2 is transferred in the direction of arrow A, the surface of the bed soil supplied by the rotary brush 21 into the nursery box 2 is smoothed. At this time, the floor soil in the seedling raising box 2 is moved backward by the rotating brush 21 to cause a swelling W of soil near the rear wall of the seedling raising box 2 as shown in FIG. The swelling W can be effectively leveled by the leveling member 22, and this part can be leveled.

That is, when the seedling raising box 2 whose upper surface of soil has been smoothed by the rotating brush 21 is transferred in the direction of arrow A, and the front wall of the seedling raising box 2 presses the lower portion of the leveling member 22 in the direction of arrow A. As shown in FIG. 6, the leveling member 22 swings in the direction of the arrow A against the tension spring 27, gets over the front wall of the seedling raising box 2, and the lower part of the leveling member 22 is raised as shown in FIG. Enter Box 2. Furthermore, the nursery box 2 is transferred in the direction of arrow A,
The rear wall of the nursery box 2 contacts the lower part of the leveling member 22 and the leveling member 22 is pressed in the direction of arrow A. As shown in FIG. 8, the leveling member 22 moves in the direction of arrow A against the spring. Swing, and at this time, the swelling W of the soil near the rear wall of the nursery box 2 is pressed by the lower end of the leveling member 22, thereby eliminating the swelling W of the soil near the rear wall of the nursery box 2 The area near the rear wall is also leveled.

As shown in FIG. 3, an operation plate 20 is provided on the side opposite to the guide plate 31 (the lower right side of the soil inserting device 5), and the operation plate 20 has an irrigation switch 20A and a soil inserting clutch 20B. A seed clutch 20C is provided. As shown in FIGS. 9 to 11, the stocker 9 is
It is formed in a rectangular parallelepiped shape by a U-shaped frame member. The stocker 9 is provided with a plurality of receiving members 35 including a pair of left and right receiving pieces 35a and 35b.
The seedling raising box 2 that has entered the delivery position D in the stocker 9 can be sequentially placed and lifted by the number 5. In addition, the stocker 9 is provided with an elevating device 36 that interlocks the multi-stage receiving members 35 with each other to elevate and lower intermittently.

The elevating device 36 includes rotating shafts 39a, 39b, 4 which are supported by a frame member of the stocker 9 so as to be rotatable around an axis thereof.
0a, 40b, 41, a pair of winding members 45a wound around the rotating shafts 39a, 40a via a wire roller 43a and a sprocket 44a, and rotating shafts 39b, 40b.
A pair of winding bodies 45b wound around a wire roller 43b and a sprocket 44b are provided therebetween. Each of the winding bodies 45a and 45b includes a chain 46 and a wire 4.
7 and 7 are connected in a loop via a turnbuckle 48.

An elevating motor 51 composed of a stepping motor or the like is provided below the stocker 9, and the power of the elevating motor 51 is transmitted to the rotary shaft 40b via the winding transmission mechanism 52 and the winding transmission mechanism 53. Is transmitted to the rotary shaft 40a through the rotary shaft 41 and the gear mechanism 54, and is paired with the wound body 45a and the wound body 45.
b and b are rotated in opposite directions at the same speed. Further, in each chain 46 of the pair of winding bodies 45a and each chain 46 of the pair of winding bodies 45b,
A pair of left and right receiving pieces 35a and 35b of the receiving member 35 are sequentially attached in a multi-step manner at predetermined intervals in correspondence with each other, and the elevating motor 51 drives the multi-step receiving members 35 to move up and down in conjunction with each other. It is like this.

In FIG. 11, the receiving piece 35a on the side of the winding body 45a is shown in the uppermost position, and the receiving piece 35b on the side of the winding body 45b is shown in the lowermost position. However, in reality, the corresponding receiving pieces 35a and 35b of the receiving member 35 are moved up and down by the elevating device 36 while being held at the same height. A transfer mechanism 57 is provided between the transfer mechanism 1 and the stocker 9, and the transfer mechanism 57 transfers the nursery box 2 on the transfer mechanism 1 side to the delivery position D of the stocker 9 and the delivery position D of the stocker 9. The nursery box 2 is transferred to the transfer mechanism 1 side.

As shown in FIG. 12, the carrying mechanism 57 has a rectangular frame body 58 composed of a U-shaped frame member or the like.
And a pair of front and rear rotating shafts 59 and 60 rotatably supported by the frame 58 in the front and rear direction about an axis, and a pair of left and right belts 62 wound around the rotating shafts 59 and 60 via a pulley 61. . A frame 58 of the transport mechanism 57 is supported on the front end of the frame 11 of the transfer mechanism 1 so as to be rotatable about a rotation shaft 59, and can be folded and stored on the transfer mechanism 1 when not in use. There is. A pair of front and rear rotary shafts 59
Is rotationally driven by the power of the transfer motor 14 via a sprocket, a winding transmission mechanism, etc., and the transport mechanism 57 is
The seedling raising box 2 can be conveyed in the same direction as the transfer mechanism 1 in a state where the transfer speed of the transfer mechanism 1 is increased by about 20%. Therefore, a plurality of nursery boxes 2 are transferred by the transfer mechanism 1.
Even when continuously transferring the seedlings to the stocker 9 side, the seedling raising box 2 transported to the delivery position D of the stocker 9 by the transport mechanism 57 and the seedling raising box 2 following the seedling raising box 2 are transferred to the stocker 9 side by the transport mechanism 1. A gap can be created between the seedling raising box 2 and the raising seedling raising box 36 placed on the receiving member 35 without interfering with the seedling raising box 2 at the delivery position D. You can smoothly raise.

The transport mechanism 57 has first detection sensors LS1, LS6, LS for detecting the nursery box 2 as shown in FIG.
2 is provided, the first detection sensor LS1 detects (turns on) the seedling raising box 2 immediately before entering the delivery position D of the stocker 9 or immediately after leaving the delivery position D of the stocker, and the second detection sensor LS6 delivers the stocker delivery. Detects (turns on) the seedling raising box 2 on the way to or from the position D, and detects the third detection sensor LS.
2 detects (turns on) the seedling raising box 2 that is almost completely in the delivery position D of the stocker 9.

The stocker 9 is also provided with an upper limit detection sensor LS3 and a lower limit detection sensor LS4 as shown in FIG. The upper limit detection sensor LS3 detects that the multi-stage receiving member 35 has risen to the uppermost stage by detecting the moving position of the predetermined receiving member 35 or the predetermined positions of the winding bodies 45a and 45b (ON).
However, the lower limit detection sensor LS4 is, for example, a predetermined receiving member 3
5 or the moving position of the winding body 45a, 45b at a predetermined position is detected to detect (turn on) that the multi-stage receiving member 35 has descended to the lowermost stage. The stocker 9 has a count sensor LS as shown in FIG.
5 are provided. As shown in FIG. 13, the count sensor LS5 includes a cam 65 provided on a sprocket of the winding transmission mechanism 52 and a limit switch 66 for detecting irregularities of the cam 65. The limit switch 66 detects a concave portion of the cam 65. By doing so, the intermittent stop position for intermittently moving up and down the multi-stage receiving member 35 step by step is detected (turned off).

FIG. 15 is a block diagram of a control system for controlling the transfer motor 14 and the elevating motor 51. In FIG. 15, 101 is a control device composed of a relay circuit or a microcomputer, which is a first detection sensor. LS1,
The signals from the second detection sensor LS6, the third detection sensor LS2, the upper limit detection sensor LS3, the lower limit detection sensor LS4, the count sensor LS5, the forward rotation switch SW1 and the reverse rotation switch SW2 are input, and the transfer motor 14 and the lifting motor 5 are input.
1, the control device 101 includes a transfer motor forward rotation control means 103, a transfer motor reverse rotation control means 104, a transfer motor stop control means 105, a lift motor forward rotation control means 107, and a lift motor reverse rotation control means. It has 108 and a lifting motor stop control means 109.

The transfer motor forward rotation control means 103, when the forward rotation switch SW1 is ON, the upper limit detection sensor L.
If S3 is on and the third detection sensor LS2 is off, or if the detection sensor LS3 is off, the transfer motor 14 is driven in the normal direction. Transfer motor reverse rotation control means 104
Is the transfer motor 14 when the forward rotation switch SW1 is off.
Drive in reverse.

The transfer motor stop control means 105 stops the transfer motor 14 when the forward rotation switch SW1 and the reverse rotation switch SW2 are off. In addition, the forward rotation switch SW1
When the upper limit detection sensor LS3 is turned on and the third detection sensor LS2 is turned on, the transfer motor 14 is stopped. The lifting motor forward rotation control means 107 is
When the forward rotation switch SW1 is on and the first detection sensor LS1 is off and the third detection sensor LS2 is on when the upper limit detection sensor LS3 is off, the lift motor 51 is driven in the forward direction.

The ascending / descending motor reverse rotation control means 108 detects the lower limit detection sensor L when the reverse rotation switch SW2 is ON.
If the second detection sensor LS6 is off and the third detection sensor LS2 is off when S4 is off, the lift motor 51
Drive in reverse. The lift motor stop control means 109 stops the lift motor 51 when the forward rotation switch SW1 and the reverse rotation switch SW2 are off. Further, when the forward rotation switch SW1 is on, if the upper limit detection sensor LS3 is on and the third detection sensor LS2 is on, or if the first detection sensor LS1 is off, the third detection sensor LS.
If the count sensor LS5 changes from ON to OFF after 2 changes from ON to OFF, the lift motor 51 is stopped. When the reverse switch SW2 is on,
When the detection sensor LS4 is turned on, the lift motor 51 is stopped. Further, when the reverse rotation switch SW2 is on, the second detection sensor LS is on when the detection sensor LS4 is off.
When 6 is off, the first detection sensor LS1 is off, and the count sensor LS5 changes from on to off, the lift motor 51 is stopped.

Next, the transfer motor 14 and the lifting motor 51
The operation will be described with reference to the flowcharts of FIGS. 16 and 17. First, if the forward rotation switch SW1 is turned on, FIG.
As shown in the flow chart of FIG.
1 works. That is, in step 1, the upper limit detection sensor LS
3 is ON or OFF, and if the upper limit detection sensor LS3 is ON, the process proceeds to step 2.

In step 2, it is determined whether the third detection sensor LS2 is on or off. If the third detection sensor LS2 is off, the process proceeds to step 4, where the transfer motor 14 is driven to rotate normally and step 2 Return to. If the third detection sensor LS2 is on, all operations are stopped in step 3. Therefore, when the multi-stage receiving member 35 is raised to the uppermost stage, the transfer motor 14 is driven to rotate in the normal direction until the seedling raising box 2 enters the delivery position D of the stocker 9 almost completely, and all operations are stopped. . As a result, the nursery box 2 is placed in the stocker 9.
Will be all stored.

If the upper limit detection sensor LS3 is off in step 1, the process proceeds to step 5, in which the transfer motor 14 is driven in the forward direction, and in step 6, the first detection sensor LS1.
Is ON or OFF, and if the first detection sensor LS1 is ON, the process returns to step 6, and if the first detection sensor LS1 is OFF, the process proceeds to step 7. In step 7, it is determined whether the third detection sensor LS2 is on or off. If the third detection sensor LS2 is off, the process returns to step 6, and if the third detection sensor LS2 is on, the lifting motor is operated in step 8. 51 is normally driven.

Therefore, when the multi-stage receiving member 35 does not reach the uppermost stage, the transfer motor 14 is driven in the forward direction to transfer the seedling raising box 2 on the transfer mechanism 1 in the direction of arrow A, and the seedling raising box 2 is moved. After passing through the first detection sensor LS1 and almost completely entering the delivery position D of the stocker 9, the elevating device 36 starts the ascending of the multistage receiving member 35 by the forward rotation driving of the elevating motor 51.

The process proceeds from step 8 to step 9, the count sensor LS5 is turned on in step 9, the third detection sensor LS2 is turned off in step 10, and the process proceeds to step 11.
In step 11, it is determined whether the count sensor LS5 is on or off. If the count sensor LS5 is on, the process returns to step 11, and if the count sensor LS5 is off,
Proceed to step 12, stop the lifting motor 51 here,
Return to step 1.

Therefore, the elevating motor 51 is driven in the forward direction until the multi-stage receiving member 35 moves up by one stage, and the multi-stage receiving member 3 is moved.
When the seedling raising box 2 is raised by one step due to the rise of 5, the lifting motor 51 is stopped. After that, repeat the same operation,
The seedling raising boxes 2 transferred from one end of the transfer mechanism 1 are automatically stacked in sequence and are automatically retained in the stocker 9.

If the reverse switch SW2 is turned on,
As shown in the flow chart of FIG. 17, the transfer motor 14 and the lifting motor 51 operate. That is, in step 21, the transfer motor 14 is reversely driven, and in step 22, the lower limit detection sensor LS.
4 is ON or OFF, and if the lower limit detection sensor LS4 is ON, the lift motor 51 is stopped in step 23.

Therefore, when the multi-stage receiving member 35 descends to the lowermost stage, the elevating motor 51 is stopped and the elevating device 36 does not descend. If the lower limit detection sensor LS4 is off in step 22, the process proceeds to step 24. In step 24, it is detected whether the second detection sensor LS6 is on or off. If the second detection sensor LS6 is on, the process returns to step 24, and if the second detection sensor LS6 is off, the process proceeds to step 25. In step 25, the first detection sensor LS
1 is ON or OFF, and if the first detection sensor LS1 is ON, the process returns to step 24, and the first detection sensor LS1
If is off, the routine proceeds to step 26, where the elevating motor 51 is driven in reverse.

Therefore, if the receiving member 35 is at the intermittent stop position, the stocker 9 is driven by the reverse rotation of the transfer motor 14.
The raising / lowering motor 51 is not driven until the seedling raising box 2 in the delivery position D reaches the transfer mechanism 1 side.
When it goes out, the elevating motor 51 is reversely driven to lower the receiving member 35. From step 26 to step 27, in step 27 the count sensor LS5 changes from off to on, and in step 28 it is determined whether the count sensor LS5 is on or off. If the count sensor LS5 is off, return to step 28. If the count sensor LS5 is off, the process proceeds to step 29, where the lift motor 51
And then return to step 22.

Therefore, the elevating motor 51 is driven in the normal direction until the multi-stage receiving member 35 descends by one step, and when the descending member descends by one step, the elevating motor 51 stops. After that, the same operation is repeated, and the seedling raising boxes 2 stacked on the stocker 9 are sequentially sent to the other end of the transfer mechanism 1, and the seedling raising boxes 2 retained in the stocker 9 are automatically moved from the other end of the transfer mechanism 1 to one end. Return to the target.

[0037]

According to the present invention, the seedling raising box 2 transferred from one end to the other end of the transfer mechanism 1 can be automatically stored in the stocker 9 and temporarily held at the same time.
Automatic transfer mechanism 1 for each seedling box 2 stored in
Can be returned to the other end and transferred from the other end to the one end by the transfer mechanism 1.

[Brief description of the drawings]

FIG. 1 is a side view of an apparatus body showing an embodiment of the present invention.

FIG. 2 is a side view of a soil leveling device portion of the same floor.

FIG. 3 is a front view of the same.

FIG. 4 is a perspective view of the soil leveling apparatus portion of the same floor.

FIG. 5 is a schematic side view of the soil leveling apparatus portion of the same floor.

FIG. 6 is a side sectional view for explaining a soil leveling operation of the same floor.

FIG. 7 is a side cross-sectional view for explaining the same floor soil leveling operation.

FIG. 8 is a side sectional view for explaining a soil leveling operation of the same floor.

FIG. 9 is a perspective view of the stocker portion.

FIG. 10 is a side view of the same stocker portion.

FIG. 11 is a rear view of the stocker portion.

FIG. 12 is a perspective view of the transport mechanism portion.

FIG. 13 is a front view of the count sensor portion.

FIG. 14 is a schematic side view of a stocker portion showing an arrangement of the detection sensor.

FIG. 15 is a block diagram of the control system.

FIG. 16 is a flowchart for explaining the control operation.

FIG. 17 is a flowchart for explaining the control operation.

[Explanation of symbols]

 1 Transfer Mechanism 2 Nursery Box 5 Soil Entry Device 8 Watering Device 9 Stocker 35 Receiving Member 36 Lifting Device 101 Control Device

Claims (4)

[Claims] 1. A soil filling device (5) and a sowing device (7) from one end to the other end of the transfer mechanism (1) on the transfer mechanism (1) on which the seedling raising box (2) is placed and transferred. And a stocker (9) for holding the nursery box (2) is provided on the other end side of the transfer mechanism (1), and the nursery box (2) is transferred from one end to the other end side of the transfer mechanism (1). While feeding the soil to the nursery box (2) with the soil-filling device (5), the nursery box (2) is temporarily stored in the stocker (9) and then stored in the stocker (9). While returning (2) from the other end of the transfer mechanism (1) toward one end, sowing with the seeding device (7),
In the seedling raising seeding device, which is made to cover the soil with a soil-filling device (5), the stocker (9) automatically stacks the seedling raising boxes (2) transferred from one end of the transfer mechanism (1) in sequence, and the stocker A seedling raising seeding machine, characterized in that it is configured so that the seedling raising boxes (2) stacked in (9) are automatically delivered sequentially to the other end of the transfer mechanism (1). 2. A receiving member (35) for sequentially mounting and raising the seedling raising box (2) which has entered the stocker (9) from the transfer mechanism (1) is provided on the stocker (9) in multiple stages. The seeding machine for raising seedlings according to claim 1, wherein the stocker (9) is provided with an elevating device (36) for intermittently elevating and lowering the receiving members (35) of the same in relation to each other. 3. A multi-stage receiving member (3) when the nursery box (2) is transferred from the transfer mechanism (1) into the stocker (9).
5) The lifting device is intermittently moved up, and when the seedling raising box (2) is sent from the stocker (9) to the transfer mechanism (1), the multi-stage receiving member (35) is lowered intermittently. The seeding machine for raising seedlings according to claim 2, further comprising a control device (101) for controlling (36). 4. The bed soil leveling device (6) for leveling the bed soil surface supplied into the seedling raising box (2) on the transfer mechanism (1) can be raised to a position where it does not hinder the transfer of the seedling raising box (2). The seeding machine for raising seedlings according to any one of claims 1 to 3, wherein the seeding machine is provided as follows.