JPH0711102U - Seeder - Google Patents

Abstract

(57) [Summary] [Purpose] The rotation speed of the rotary working body 18 having a plurality of sowing groove forming bodies 32 can be changed according to the humidity condition of the tilled soil with the soil water content being even, and the sowing groove forming bodies 32 can be used for sowing. The ditch can be sufficiently formed and the seeding ditch is cleanly finished even when the soil moisture is low to prevent the seeding ditch from collapsing. [Structure] An output shaft end portion 15 of an output shaft 14 provided on the main frame 2 is rotatably projected at an upper end portion of a transmission case 16. A drive shaft 25, which is located below the output shaft end portion 15 and drives the rotary shaft 30 of the rotary work body 18 to rotate, is rotatably mounted on the transmission case 16. The output shaft end portion 15 of the output shaft 14 is provided with a transmission 36 for changing the output of the output shaft 14 to drive the drive shaft 25 to rotate.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a sowing machine, and relates to a sowing machine, which directly sows a field or sows a sowing groove formed in the field.

[0002]

[Prior art]

 Conventionally, as this type of sowing machine, for example, a rotary cultivator is provided on a machine frame in a rotating manner, and a plurality of drive disks for forming a sowing groove are coaxially and rotatably arranged in the rear part of the rotary cultivator. A structure is known in which a shaft is installed and seeds fed from a seed hopper are sown in a seeding groove formed by each drive disk.

[0003]

[Problems to be solved by the device]

 In the above-mentioned structure, each drive disk is rotationally driven at a constant rotational speed, and the sowing groove is formed by each drive disk.At this time, the crushed soil condition of the cultivated soil cultivated by the rotary tiller. In some cases, the sowing ditches are insufficiently formed due to the humidity condition of the tilled soil, for example, if the soil water content is low. However, there is a problem that seeds cannot be sown at the bottom of the sowing groove, which is not preferable for promoting germination of seeds.

The present invention has been made in view of the above point, and has a rotary operation having a plurality of seed groove forming bodies depending on the crushed soil condition of the cultivated soil or the humidity condition of the cultivated soil such that the soil water content is somewhat constant. The rotation speed of the body can be changed, and the seeding ditch can be sufficiently formed with these multiple seeding ditch moldings, and the seeding ditch can be neatly finished even when soil moisture is low. At the same time, this seeding groove is resistant to collapse and seeds can be seeded on the bottom of the seeding groove, and it is an object of the present invention to provide a preferable seeding machine for promoting germination of seeds.

[0005]

Means for Solving the Problems A seeder of the present invention comprises a main frame in the left-right direction in which an output shaft is rotatably inserted, and a transmission case and a bracket provided opposite to both ends of the main frame. A rotary working body that is rotatably provided between the lower ends of the transmission case and the bracket and has a plurality of seed groove forming bodies arranged at intervals in the axial direction of the rotary shaft, and the seeding of each of the rotary working bodies. A seed hopper having a seeding opening for seeding in a seeding groove formed by a groove forming body, the output shaft end of the output shaft is projected at the upper end of the transmission case, and the lower part of the output shaft end is provided. Is positioned at the transmission case, a drive shaft for rotatably driving the rotary shaft of the rotary work body is rotatably mounted, and the output from the output shaft of the output shaft is changed in speed to drive the output shaft. It is provided with a transmission that rotationally drives the shaft.

[0006]

[Action]

 In the seeding machine of the present invention, when the output shaft is rotated, for example, in a field with a relatively large amount of soil moisture, the output shaft of The output from the output shaft end part causes the transmission to rotate and interlock at a set speed, and the transmission also drives the drive shaft to interlock. It advances while being rotationally driven.

Then, each of the seeding groove forming bodies of the rotary working body is advanced while being rotationally driven with respect to the tillable soil, and the seeding grooves are successively shaped and finished by each of the seeding groove forming bodies. Therefore, the various seedlings fed from the seed hopper are sequentially sown from the seeding mouth at the bottom of the seeding groove.

Further, depending on the crushed soil condition of the cultivated soil or the humidity condition of the cultivated soil such that the soil moisture content is somewhat equal, for example, in a field where the soil moisture content is relatively low, the seeding ditch is neat at the rotation speed set by the transmission. Since the finish is not finished and the seeding groove is likely to collapse, the transmission is variably adjusted to reduce the speed.

When the output shaft is rotated, the output from the output shaft end of the output shaft is decelerated by the transmission and transmitted to the drive shaft. It proceeds while being rotationally driven at a lower rotation speed than in the case of a field with a relatively large amount of water.

Then, each of the seed groove forming bodies of the rotary working body is rotated while being driven with respect to the tilling soil, and the seed groove is sequentially formed into a neat finish by each of the seed groove forming bodies. Since each sowing groove is hard to collapse, various seedlings fed from the seed hopper are sowed at the bottom of the sowing groove sequentially from the sowing mouth, as in the case of the field where the soil water content is relatively high.

[0011]

【Example】

 A configuration of an embodiment of the present invention will be described below with reference to the drawings.

In FIG. 1 and FIG. 2, reference numeral 1 denotes a machine frame, which has a hollow pipe-shaped main frame 2 that is long in the left-right direction, and an intermediate portion of the main frame 2 that is long in the vertical direction. 1, a transmission case 3 is provided, and a transmission 5 is provided at an upper end portion of the first transmission case 3 so as to rotatably project the input shaft 4 forward.

A rotary tiller 6 is rotatably mounted on the lower end of the first transmission case 3. The rotary tiller 6 has a tiller shaft 7 rotatably mounted on the lower end of the first transmission case 3, and a plurality of flanges 8 are provided at intervals in the axial direction of the tiller shaft 7. A plurality of tillage claws 9 are radially provided on the peripheral side of each flange 8 so as to be fixed. The rotary tiller 6 is rotationally driven by the output from the mission 5.

A cover body 10 covering the upper part of the rotary tillage body 6 is disposed and fixed on the upper portion of the first transmission case 3, and a soil-proof plate 11 is provided at a rear end portion of the cover body 10. Is rotatably supported in the front and rear directions. Further, the lower arm 12 is integrally projected forward on both sides of the main frame 2, and the mast 13 is integrally projected forward on the upper end of the first transmission case 3. ing.

Next, an output shaft 14 is rotatably inserted into one side of the main frame 2, and an inner end portion of the output shaft 14 is interlocked with an output portion of the mission 5 and The output shaft end 15 of the outer end of the output shaft 14 is projected outward from one end of the main frame 2.

Further, upper ends of a second transmission case 16 and a bracket 17 which are long and short in the front-rear direction and are disposed opposite to each other are fixedly attached to both ends of the main frame 2, respectively. Between the transmission case 16 and the lower end of the bracket 17, a rotary working body 18 is rotatably mounted on the rear part of the rotary tiller 6 so as to be rotatable.

The second transmission case 16 is formed into a flat hollow rectangular tube shape that is long in the front-rear direction, and the outer end portion of the output shaft 14 is rotated by the left and right side plate portions 19 and 20 of the upper end portion. An insertion hole 21 freely inserted is formed to face each other, and an output shaft end portion 15 of the output shaft 14 is projected outward from the insertion hole 21 of the left side plate portion 20. A base end portion of the portion 15 is rotatably supported by a bearing body 22 fixed to an opening edge portion of the insertion hole 21 of the left side plate portion 20.

Therefore, the output shaft end portion 15 is formed so as to be reduced in diameter from the outer shape of the output shaft 14 through the step portion 23 so as to extend, and a plurality of pieces are formed in the outer axial direction from the step portion 23 to the tip end portion. A spline 24 is formed. The output shaft 14 is positioned and supported by the bearing body 22 that rotatably supports the base end portion of the output shaft end portion 15 through the step portion 23.

Further, a drive which is disposed below the output shaft end portion 15 and is arranged between the left and right side plate portions 19 and 20 of the second transmission case 16 in parallel with the output shaft end portion 15. Both ends of the shaft 25 are rotatably supported by left and right bearing bodies 26, and an input shaft portion 27 of the drive shaft 25 is projected outward from the left side plate portion 20. A plurality of splines 28 are formed in the outer axial direction of the drive shaft 25 having 27. Further, a sprocket 29 is spline-fitted to the drive shaft 25 via a plurality of splines 28, which is located between the left and right side plate portions 19 and 20 of the second transmission case 16.

The rotary working body 18 has a rotary shaft 30 rotatably mounted by a bearing body 30 a between the second transmission case 16 and the lower end of the bracket 17, and the rotary shaft 30 In the axial direction, a plurality of large-diameter agate beads forming drainage grooves 31 and a plurality of small-diameter agate beads forming seed grooves are formed. 32 and 32 are alternately arranged with a space therebetween and fixed, and a cylindrical grounding collar 33 is fitted between each drainage groove molded body 31 and each seeding groove molded body 32.

A sprocket 34 is fitted and fixed to the protruding end of the rotary shaft 30 protruding from the lower end of the second transmission case 16, and the sprocket 34 and the sprocket 29 of the drive shaft 25 are connected to each other. An endless chain 35 is suspended between the two in a freely rotatable manner. Then, the rotary work body 18 is rotationally driven by the drive shaft 25.

Next, the output shaft end portion 15 of the output shaft 14 is interlocked with the input shaft portion 27 of the drive shaft 25 via a transmission 36. This transmission device 36 has a large diameter sprocket 37 removably spline-fitted to the output shaft end 15 via a spline 24, and a spline 28 to the input shaft 27 of the drive shaft 25. It comprises a small diameter sprocket 38 which is detachably fitted through a spline, and an endless chain 39 which is rotatably suspended between the large and small sprockets 37, 38. Reference numeral 62 is a cover body detachably attached to the left side plate portion 20.

The rotation speed of the output shaft end portion 15 is increased by the small diameter sprocket 38 through the endless chain 39 by the large diameter sprocket 37, and the driving shaft 25 having the small diameter sprocket 38 is rotated. The rotary work body 18 is rotatably driven, and the rotation speed (rotation speed) of the rotary work body 18 is a set value for normal work in which soil moisture is relatively large.

Further, the small diameter sprocket 38 removed from the input shaft portion 27 of the drive shaft 25 is spline-fitted to the output shaft end portion 15, while the large diameter sprocket 37 removed from the output shaft end portion 15 is driven. By spline-fitting the input shaft 27 of the shaft 25 and suspending the endless chain 39 between the large and small sprockets 37, 38, the rotation speed of the output shaft end 15 is endless with the small diameter sprocket 38. A large-diameter sprocket 37 is decelerated and rotated via a chain 39, and the rotary work body 18 is decelerated and rotationally driven by a drive shaft 25 having the large-diameter sprocket 37. The rotation speed (number of rotations) of will be converted to the set value for work with relatively low soil moisture.

Next, the front ends of the support frames 40, which are horizontally disposed in the front-rear direction, are horizontally fixed to the rear ends of the left and right lower arms 12 and are integrally fixed to each other. The rear end portions of 40 are connected by a square pipe-shaped connecting frame 41. Brackets 42 projecting downward are fixedly fixed to both ends of the connecting frame 41, and support rods 43 are horizontally fixed between the rear ends of the left and right brackets 42. A plurality of support plates 44 are vertically fixed to each other at predetermined intervals in the axial direction of the support rod 43.

In addition, a plurality of sets of connecting plates 45 are formed in the lengthwise direction of the connecting frame 41, with a space corresponding to each seed groove forming body 32 and a pair separated from each other. Each is projected integrally toward the rear. Further, a seed hopper 47 is placed between the front side portions of the pair of connecting plates 45 of each set via a support frame 46, and a discharge port 49 is opened in a bottom plate 48 of each of the various child hoppers 47.

Further, a conveyor 50 is disposed below the discharge port 49 of each child hopper 47 and between the pair of connecting plates 45 of each set, and an endless traveling body 51 of each conveyor 50 is provided. A large number of seeds A discharged from the respective discharge ports 49 are carried in and placed, and are carried toward the rear carrying-out end along the seed retainer 52. The seed retainer 52 is suspended on the support frame 46.

Further, an upper part of a seeding conduit 53 in the vertical direction is attached between the rear ends of the pair of connecting plates 45 located below the carry-out end of each of the conveyors 50. The seed introduction port 54 formed at the upper end of the conduit 53 is opened to face the carry-out end of each conveyor 50, and the seeding port 55 opened at the lower end of each of the sowing conduits 53 is described above. It is arranged at a position facing the seeding groove formed by each seeding groove molded body 32.

A float 56 sliding along each seeding groove is attached to the lower end of each seeding conduit 53, and the lower end of each seeding conduit 53 is connected to the connecting plate 44 by a parallel link 57. It is supported vertically. In addition, each of the seeding conduits 53 has a bellows tube 58 that extends and contracts in the vertical direction at an intermediate portion. The upper and lower ends of the parallel links 57 are pivotally supported by a support shaft 59 so as to be vertically rotatable.

Next, the operation of the above embodiment will be described.

The connecting portion 12a of the left and right lower arms 12 and the connecting portion 13a of the mast 13 are respectively connected to the three-point suspension mechanism of the tractor, and the input shaft 4 of the mission 5 is connected to the PTO shaft of the tractor via the power transmission shaft. connect.

When the main seeder is pulled by the tractor and the input shaft 4 is rotationally driven via the power transmission shaft by the output from the PTO shaft of the tractor, the output from this mission 5 causes the first The rotary work body 6 of the transmission case 3 is rotationally driven in the downcut direction, and the rotary work body 18 of the second transmission case 16 is rotationally driven by the output from the output shaft 14 connected to the output portion of the mission 5. Then, the drainage groove forming bodies 31 and the seeding groove forming bodies 32 of the rotary working body 18 are rotationally driven at a speed of slip rotation.

That is, depending on the crushed soil condition of the cultivated soil or the humidity condition of the cultivated soil such that the soil water content is somewhat equal, for example, in an agricultural field where the soil water content is relatively high, when the output shaft 14 is rotated, the output shaft 14 is rotated. The rotation speed of the output shaft end 15 is increased by the small diameter sprocket 38 via the endless chain 39 by the large diameter sprocket 37 of the transmission 36, and by the drive shaft 25 having the small diameter sprocket 38. The rotary working body 18 is rotationally driven via the endless chain 35, and the rotary working body 18 is rotationally driven at the rotation speed (rotation speed) of the set value during normal work. The seed groove forming body 32 advances while slip-rotating.

In addition, the output from the mission 5 causes the endless traveling body 51 of each of the conveyors 50 to rotate in the upper rear direction in the arrow direction through an interlocking mechanism (not shown).

Then, the soil in the field is cultivated by the rotary cultivator 6, and the cultivated soil is deep-drained by the respective drainage groove forming bodies 31 of the rotary working body 18 in order and is also sowed. In the groove forming body 32, a plurality of shallow seeding grooves are formed between the plurality of deep drainage grooves, respectively.

At this time, each drainage ditch molded body 31 and each sowing ditch molded body 32 are driven to slip and rotate with respect to the cultivated soil at a rotation speed (rotation speed) set to a field having a relatively large amount of soil water. As a result, the deep drainage grooves and shallow seeding grooves formed by the drainage groove forming bodies 31 and the seeding groove forming bodies 32 are sequentially formed neatly, and the deep drainage grooves and shallow seeding grooves are formed. The groove is hard to collapse.

A large number of seeds discharged from the discharge ports 49 of the various child hoppers 47 are placed on the endless traveling bodies 51 of the respective conveyors 50, and are conveyed upward and rearward. These various offspring are carried out from the carry-out end to the seed introduction port 54 of each sowing conduit 53, and are sequentially sown from the sowing port 55 of each sowing conduit 53 into each sowing groove. At this time, since each seeding groove is formed neatly and neatly by each seeding groove molded body 32 which is driven to slip and rotate, seeds are surely seeded at the bottom of each seeding groove.

Next, when working in a field where the soil water content is relatively low, the small-diameter sprocket 38 removed from the input shaft 27 of the drive shaft 25 is spline-fitted to the output shaft end 15 while the output shaft The large diameter sprocket 37 removed from the end 15 is spline-fitted to the input shaft 27 of the drive shaft 25, and the endless chain 39 is suspended between the large and small sprockets 37 and 38.

With this configuration, the rotation speed of the output shaft end portion 15 is reduced by the small diameter sprocket 38 via the endless chain 39, and the large diameter sprocket 37 is decelerated to rotate the large diameter sprocket 37. The rotary work body 18 is decelerated and rotationally driven by the drive shaft 25 having the endless chain 35, and the rotation speed (rotation speed) of each drainage groove molded body 31 and each seeding groove molded body 32 of the rotary work body 18 is reduced. Is converted to the set value for work with relatively low soil moisture.

Then, the drainage grooved bodies 31 and the seeding grooved bodies 32 of the rotary working body 18 are applied to the cultivated soil at a rotation speed (rotation speed) set to a field where the soil water content is relatively small. Since it is driven to rotate by slip rotation, the deep drainage grooves and the shallow seeding grooves formed by the drainage groove forming bodies 31 and the seeding groove forming bodies 32 are sequentially formed neatly, and the deep drainage grooves and Each shallow seeding groove is finished in a state where it is hard to collapse. Then, seeds are successively and surely sown at the bottom of each shallow sowing groove in the same manner as described above.

Next, in the above-described embodiment, the transmission 36 is described as being composed of the large-diameter sprocket 37, the small-diameter sprocket 38, and the endless chain 39 suspended on these, but is not limited to this. The transmission 36 may be composed of large and small gears 60 and 61 that directly mesh with each other.

In this case, for example, as shown in FIG. 5, a large-diameter gear 60 is spline-fitted to the output shaft end portion 15 of the output shaft 14 and the input shaft portion 27 of the drive shaft 25 is mounted. By spline-fitting the small-diameter gear 61 and meshing the teeth 60a, 61a of the large and small gears 60, 61 with each other, the drainage groove formed bodies 31 and the seed groove formed bodies 32 are formed into Is driven to slip and rotate with respect to the tilled soil at a rotational speed (rotation speed) set to a relatively large number of fields, and the deep groove formed by each drain groove formed body 31 and each sowing groove formed body 32 is formed. The drainage gutter and each shallow seeding gutter are formed beautifully in order, and the deep drainage gutter and each shallow seeding gutter are finished in a state in which they are hard to collapse.

A small diameter toothed gear 61 removed from the input shaft portion 27 of the drive shaft 25 is spline-fitted to the output shaft end portion 15 of the output shaft 14 and output to the input shaft portion 27 of the drive shaft 25. The large-diameter gear 60 removed from the output shaft end portion 15 of the shaft 14 is spline-fitted, and the teeth 60a and 61a of the large and small gears 60 and 61 are meshed with each other to form each drain groove molded body 31. Also, each of the seed groove forming bodies 32 is driven to slip and rotate with respect to the tilled soil at a rotation speed (rotation speed) of a set value that is decelerated according to the field where the soil water content is relatively small. The deep drainage grooves and the shallow seeding grooves formed by the 31 and the seeding groove molded bodies 32 are successively formed neatly, and the deep drainage grooves and the shallow seeding grooves are finished in a state of being hard to collapse.

Further, the transmission device 36 for connecting the input shaft portion 27 of the drive shaft 25 to the output shaft end portion 15 of the output shaft 14 is not limited to the above-mentioned embodiments, and for example, the output shaft end portion 15 of the output shaft 14 can be used. The belt type continuously variable transmission unit may be detachably connected to the input shaft portion 27 of the drive shaft 25. By using this belt type continuously variable transmission unit, the rotation speed of the drive shaft 25 can be set to change gears according to the field with relatively high soil water content and the field with relatively low soil water content. Are sequentially molded cleanly, and the deep drainage grooves and the shallow seeding grooves are finished in a state that they are difficult to collapse.

[0045]

[Effect of device]

 According to the present invention, the output shaft end portion of the output shaft provided on the main frame is rotatably projected at the upper end portion of the transmission case, and is located below the output shaft end portion of the rotary work body in the transmission case. Since the drive shaft for rotationally driving the rotary shaft is rotatably mounted, and the output shaft end portion of the output shaft is provided with the transmission for rotating the drive shaft by changing the output from the output shaft. It is possible to change the rotation speed of the rotating work body having multiple seed groove formations according to the soil crushed condition or the humidity condition of the tilled soil such as the soil moisture content. The seeding ditch can be formed sufficiently and the seeding ditch can be finished neatly even when the soil water content is low, and the seeding ditch is difficult to collapse and seeds can be seeded at the bottom of the seeding ditch. Provide a preferable seeding machine for promoting seed germination Door can be.

[Submission date] June 23, 1994

[Procedure Amendment 2]

[Document name to be amended] Statement

[Name of item to be corrected] 0005

[Correction method] Change

[Correction content]

[0005]

[Means for Solving the Problems]

The seeder according to claim 1 has a main frame in the left-right direction in which an output shaft is rotatably inserted, a transmission case and a bracket provided opposite to both ends of the main frame, and the transmission case. A rotary working body, which is rotatably provided between the lower end of the bracket and a plurality of seed groove forming bodies arranged at intervals in the axial direction of the rotary shaft, and each of the seed groove forming bodies of the rotary working body. and seed hopper having a seeding opening to seed shaped seeded groove, was immediately Bei, the rotating working member is rotated by the output from the output shaft, the transmission for shifting a rotational speed of the rotating work industry body Is provided. Sowing machine of claim 2, wherein, in the seeding machine of claim 1, wherein projecting the output shaft end of the output shaft to the upper end portion of the transmission case, the transmission to case located below the output shaft end the rotation axis of the rotating working member and Jikuka rotatably driving shaft for rotationally driving the, by shifting the output from the output shaft to the output shaft end of the output shaft for rotating the drive shaft transmission Is provided.

[Procedure 3]

[Document name to be amended] Statement

[Name of item to be corrected] 0045

[Correction method] Change

[Correction content]

[0045]

[Effect of device]

According to the invention of claim 1, wherein, the lateral direction of the main frame which is rotatably inserted an output shaft, the main frame and the transmission case and the bracket is provided relative to the opposite ends of, and the heat dynamic case bracket forming a rotating work element which is arranged a plurality of sowing groove forming member at intervals in the axial direction of the rotatably arranged rotary shaft between the lower end portion at each sowing groove forming member of the rotating working member and comprising a seed hopper having a seeding opening to seed has been sown groove, and the rotating working member is rotated by the output from the output shaft, a transmission is provided for shifting the rotational speed of the rotating working member Therefore, by changing the rotation speed of the rotary working body by the transmission according to the work situation in the field, the seeding groove can be reliably formed by each seeding groove forming body of the rotary working body. surely sowing sowing port seeds hopper into the groove It can be possible to prevent that the seeds are sown out sowing groove. According to the invention of claim 2, wherein, protrudes rotatably the output shaft end of the output shaft provided in the main frame in the upper portion of the transmission case, said transmission case located below the output shaft end A drive shaft that rotatably drives the rotary shaft of the rotary work body is rotatably mounted, and a transmission device that rotates the drive shaft by changing the output from the output shaft is provided at the output shaft end of the output shaft. Therefore, it is possible to change the rotation speed of the rotary working body having a plurality of sowing groove formed bodies according to the crushed soil condition of the cultivated soil or the humidity condition of the cultivated soil such that the soil water content is somewhat equal. The seeding groove can be sufficiently formed with the molded body, and the seeding groove can be finished neatly even when the soil water content is low. Sowing that is preferable for promoting seed germination It is possible to provide a.

[Brief description of drawings]

FIG. 1 is a side view of a seeder according to an embodiment of the present invention.

FIG. 2 is an explanatory rear view with a part thereof omitted.

FIG. 3 is a cross-sectional view of the same transmission mechanism section.

FIG. 4 is a cross-sectional view of a speed change mechanism unit in a state in which a speed change is performed as above.

FIG. 5 is a cross-sectional view of a speed change mechanism unit showing another embodiment.

[Explanation of symbols]

 2 Main frame 14 Output shaft 15 Output shaft end 16 Transmission case 17 Bracket 18 Rotating work body 25 Drive shaft 30 Rotating shaft 32 Seeding groove forming body 36 Transmission device 47 Seed hopper 55 Seeding port

─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] June 23, 1994

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be amended] Scope of utility model registration request

[Correction method] Change

[Correction content]

[Scope of utility model registration request]

Claims (1)

[Scope of utility model registration request] 1. A main frame in the left-right direction in which an output shaft is rotatably inserted, a transmission case and a bracket provided opposite to both ends of the main frame, and a lower end portion between the transmission case and the bracket. A rotary work body provided with a plurality of seed groove forming bodies rotatably provided at intervals in the axial direction of the rotary shaft,
A seed hopper having a seeding port for seeding a seeding groove formed by each seeding groove forming body of the rotary working body, and an output shaft end portion of the output shaft protruding from an upper end portion of the transmission case, A drive shaft, which is located below the output shaft end portion and rotatably drives the rotary shaft of the rotary work body, is rotatably mounted on the transmission case, and the output shaft end portion of the output shaft is connected to the drive shaft. A sowing machine comprising a speed change device for changing the output and rotationally driving the drive shaft.