KR200392887Y1 - Compost spreaders - Google Patents

Abstract

The present invention relates to a compost spreader, the vehicle body towed by the cultivator (1); A loading box (2) mounted on the vehicle body (1) and loaded with compost; A floor conveyor (4) installed on the floor of the stacking box (2) for transporting the loaded compost to the discharge end; A fork portion 50 installed across the upper rear end of the loading box 2 and having a plurality of rakes 56 for dropping compost transported by the floor conveyor through a discharging end; And a spreading plate 12 disposed below the rear of the loading box 2 and having a spreading blade 13 formed to spread the compost discharged through the unloading end evenly, wherein the floor conveyor 4 includes: A ratchet wheel 110 fixed to the drive pulley shaft 111; A pair of plates 122 rotatably coupled to the drive pulley shaft 111 via the ratchet wheel 110 and having a support arm 124 radially; A pole shaft 126 connected between the support arms 124 of the pair of plates 122 facing each other; A pole arm (120) installed on the pole shaft (126) and having a pole (128) which is supported by a spring so that the tip is pressed against the teeth of the ratchet wheel (110); Rotatably coupled between the ratchet wheel 110 and the plate 122 to the drive pulley shaft 111, and has a radially extending arm 132 positioned to the rear of the pole shaft 126, One of the arms 132 is coupled to the other end 105 of the link arm 106 coupled to the crankshaft 104 coupled to the power output shaft 103 receives the power of the drive source, and rotates in one direction while repeatedly rotating and reciprocating. Seesaw arm 130 for driving the ratchet wheel 110 by pushing the pole arm 120 while the arm 132 is in contact with the pole arm 120; A pole arm spring 140 having an end fixed to the pole arm plate 122 to support the pole arm 120 to be returned to a direction opposite to the direction in which the rod is pushed by the seesaw arm 130; And adjusting means for adjusting a range in which the pole arm 120 is returned by the pole arm spring 140 to adjust an amount of driving of the pole arm 120 to drive the ratchet wheel 110. It is configured to be intermittently transported by the eastern part 100.

Description

Compost spreader {COMPOST SPREADERS}

The present invention relates to a compost spreader.

In general, the compost spreader is a device that is towed by a cultivator, a tractor, and the like, and includes a loading box installed on the vehicle body, and is automatically sprayed while the compost is transferred to the rear by a conveyor installed on the floor of the loading box.

A known example of such a compost spreader is disclosed by Korean Utility Model Registration No. 282467, Figure 1 is a perspective view of a compost spreader according to a known example.

Referring to FIG. 1, the floor surface of the storage box 2 installed in the vehicle body 1 has a pulley 5 positioned at the front and rear sides, a pair of chains 6 and a chain 6 which are rotated by the pulley 5. The floor conveyor 4 which consists of a several conveyance board 8 fixed to the horizontal direction is provided in this. A pair of opening and closing plates 10 are rotatably installed at the opening and carrying out end of the rear side of the loading box 2, and a pair of spraying compost transported by the floor conveyor 4 is evenly disposed below the opening and closing plate 10. Circular spray plate 12 is rotatably installed. The spreading plate 12 is rotated by receiving a driving force from the hydraulic motor 14 attached to the rear.

The driving force of the hydraulic motor 14 is distributed in the gearbox 16 and distributed to the driving input shaft of the spreading plate 12, the driving input shaft of the floor conveyor 4, and the driving input shaft of the fork portion 20.

The floor conveyor 4 is intermittently driven by an intermittent drive (not shown) using a ratchet wheel (ratchet gear) connected to the drive pulley shaft 5.

On the other hand, the fork 20 includes a fork shaft 23 to which a plurality of rakes 22 are attached along the circumference and in the longitudinal direction, and the rake 22 composts while the fork shaft 23 rotates continuously. Incisions are made to allow compost to fall through the discharging end.

Such a known compost spreader has the advantage of spreading the compost uniformly while adjusting the conveying amount of the floor conveyor, but has a complex disadvantage of intermittent electric motor. In addition, since the rake is simply rotated by the fork shaft, the compost is dried on the fork shaft.

The present invention aims to provide a compost spreader capable of uniformly spreading compost transported by the floor conveyor on the floor of the cargo box.

The present invention provides a compost spreader configured to adjust the rotational stroke of the ratchet wheel with a simplified structure, as well as to reduce the number of parts and ensure ease of assembly by simplifying the configuration of the intermittent electric motor driving the floor conveyor. For other purposes.

Another object of the present invention is to provide a compost spreader having an improved performance of drawing compost toward the discharge end while uniformly cutting compost by a fork extractor.

The present invention to achieve the above object, the vehicle body towed by the cultivator; A loading box mounted on the vehicle body, in which compost is loaded; A floor conveyor installed on the floor of the storage box and transferring the loaded compost to the carrying out end; A fork portion having a plurality of rakes installed across the upper rear end of the stack and dropping compost transported by the floor conveyor through a discharge end; And a spreading plate having a spreading vane disposed below the rear of the stacking box to spread the compost discharged through the carrying out end, wherein the floor conveyor comprises: a ratchet wheel fixed to a driving pulley shaft; A pair of plates rotatably coupled to the drive pulley shaft with the ratchet wheel interposed therebetween and having a support arm radially; A pole shaft connected between the support arms of the pair of plates facing each other; A pole arm installed on the pole shaft and having a pole installed on the pole shaft by a spring to be pressed against the teeth of the ratchet wheel; A rotatably coupled between the ratchet wheel and the plate to the drive pulley shaft and having a radially extending arm positioned behind the pole shaft, one of the arms coupled to a power output shaft receiving power from a drive source. A seesaw arm coupled to the other end of the link arm coupled to the crankshaft to repeatedly drive the ratchet wheel while pushing the pole arm while the arm contacts the pole arm while rotating in one direction; A pole arm spring having an end fixed to the pole arm plate and supporting the pole arm so as to be returned in a direction opposite to the direction in which the rod is pushed by the seesaw arm; And an adjusting means for adjusting the range in which the pole arm returns by the pole arm spring so that the pole arm can adjust an amount of driving for driving the ratchet wheel. .

Preferably, the adjustment means is a pole arm support which is adjustable in the pole arm spring to the extent that the pole arm return rotation by the pole arm spring by supporting the pole arm in the opposite direction in which the pole arm spring is pulled upwards wire; And an adjuster for supporting the other end of the pole arm support wire to adjust a degree of pulling the pole arm support wire upward, wherein the adjuster includes an operation unit located on a cockpit installed in the vehicle body, and along the side of the stacker. And a wire arm extending upwardly of the pole arm and having an end portion of the pole arm supporting wire fixed to the end thereof so that the wire arm rotates and pulls or lowers the wire according to an operation of the operation unit. It is configured to adjust the rotatable range of the pole arm.

In addition, the fork portion is operatively connected to a plurality of rake reciprocating rotation, is installed across the upper rear end of the inside of the loading bin and one end protrudes to the side of the loading bin, the projecting end, to transmit the power of the drive source It comprises a rotating shaft fixed to the rotating shaft link arm connected to the power output shaft receiving the shaft rotation through the link mechanism reciprocating the projecting end to the center of rotation, preferably the rake is fixedly mounted on the outer peripheral surface Fork shaft is installed across the inside of the loading box; At least two connecting rods having one end fixed to the pivot shaft and the fork shaft inserted and supported by a shaft hole formed at the other end; A first fork shaft link having one end coupled to both front ends of the fork shaft and extending inclined upward; A support shaft installed inside the loading box under the rotation shaft; And a second fork shaft link having one end coupled to the first fork shaft link and the other end coupled to the support shaft.

Next, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Detailed description of the same configuration as the known configuration will be omitted.

2 is a side view of the compost spreader according to the present invention, Figure 3 is a plan view of the compost spreader shown in FIG.

As shown in the figure, the compost spreader according to the present invention is towed by the cultivator 1, and the compost to the rear discharging end by the floor conveyor 4 mounted on the vehicle body 1 and mounted on the vehicle body (1) (2), the fork 50 having a rake 56 for dropping the compost of the stack (2) to the discharge end, and the spreading plate for evenly spraying the compost discharged through the discharge end ( 12) and an intermittent electric motor 100 for driving the floor conveyor 4.

In the present specification, the cultivator refers to a retractor for driving by driving a compost spreader according to the present invention, and the vehicle body 1 is towed by the cultivator to travel.

A floor conveyor 4 is installed on the floor of the stack 2 to transfer the compost toward the back of the stack. The floor conveyor 4 is intermittently conveyed while the conveyance amount is adjusted by the intermittent electric motor 100 installed on the side of the loading box 2. In addition, the opening and closing plate 10 is rotatably installed at the opened discharging end, which serves as a passage through which compost is discharged to the rear surface. Reference numeral 11 denotes a guide plate.

A fork shaft 54 having a rake 56 formed on an outer circumferential surface of the rear end upper end side across the inside of the loading box 2 is configured to be operated by the rotation shaft 52 while being supported by the links.

According to the present invention, the rake 56 is operatively connected to the rotation shaft 52 to perform a reciprocating rotation, thereby making a pivoting movement within a range of a certain rotation angle, and the rake 56 moves downward to incise the compost. And the compost entanglement occurring in the structure in which the bar rake 56 is simply rotated after the transfer and then moves upward again and returns downward.

In addition, the rake 56 is the fork shaft 54 supported by the connecting rod 62 and the operation by the pivoting movement of the connecting rod 62 about the rotating shaft 52 by the rotational reciprocating motion of the rotating shaft 52 When the movement by the reciprocating rotation of the superimposed movement moves downward, the tip moves in the direction toward the rear discharging end. Therefore, the movement radius of the rake 56 is increased, so that the transfer toward the compost cutting and the discharging end of the cut compost is smoother.

Spread plate 12 is installed below the rear of the loading box. Two circular spreading plates 12 having a plurality of spreading wings 13 protruding from the top surface are evenly sprayed by the floor conveyor 4 to compost falling through the discharge end to the rear of the compost spreader.

A height adjusting plate (not shown) is installed between the circular spreading plate 12 to adjust the spreading angle. The spreading plate 12 is rotated by receiving the power of the driving source through the gearbox 40 (see FIG. 4), and the gearbox 40 located on the lower surface of the spreading plate 12 distributes the power of the driving source to each driving device. do.

Figure 4 is a view partially showing the power transmission system of the compost spreader according to the present invention. As shown in the figure, the present invention includes an engine 30 installed in the vehicle body 1 in front of the loading box 2 as a drive source. The first pulley 32 is fixed to the engine shaft, and the second pulley 34 is fixed to an end portion of the propulsion shaft 31 extending rearward through the lower surface of the vehicle body. The power is transmitted between the first pulley 32 and the second pulley 34 by the belt 36. Meanwhile, a clutch lever (not shown) connected to the pressure lever 38 is installed in the driver's seat. Therefore, according to the operation of the clutch lever, the pressure lever 38 presses or loosens the belt 36 so that power transmission can be interrupted. Power of the engine 30 is input to the gearbox 40 through the propulsion shaft 31.

5 is an enlarged cross-sectional view of the gearbox shown in FIG. 4. The gearbox 40 of the compost spreader according to the present invention has a structure in which each bevel gear is installed and meshed with each surface in a cube-shaped housing 41. Therefore, each bevel gear inside the gearbox has four bevel gears that mesh with the opposite bevel gear at 90 degree intervals.

Referring to the drawings, the gearbox 40 is a pair of upper and lower horizontal bevel gears 42 and 43 installed in the box-shaped housing 41 facing each other on the upper and lower sides, and simultaneously with the upper and lower horizontal bevel gears. It consists of two pairs of front, rear, left and right vertical bevel gears 44, 45, 46 and 47 which are installed to face each other and face each other at equal intervals in the vertical direction. The propulsion shaft 31 extending through the lower surface of the vehicle body is connected to the right vertical bevel gear 47 to input power, and the circular spray plate 12 is rotated through the upper horizontal bevel gear 42 engaged with it. In addition, the front and rear vertical bevel gears 44 and 45 are connected to a shaft for inputting power to the other gearbox and a shaft for transmitting power to the reducer, respectively.

According to the present invention, since the shaft can be connected to any side of the gearbox 40, the assembly can be performed regardless of the direction when assembling, and the bevel gear connected with the shaft is always four bevels engaged at equal intervals with the opposite bevel gear. By having a gear, the load is smoothly distributed evenly without concentrating on one side, so that power transmission is smooth and damage of the bevel gear due to eccentric load can be prevented. This increases durability and reduces maintenance requirements due to failures.

6 is a configuration diagram of an intermittent electric motor according to the present invention, and FIGS. 7 and 8 are operation diagrams of the intermittent electric motor shown in FIG. 6.

As shown in the figure, the floor conveyor 4 according to the present invention is driven by the intermittent electric drive (100).

One end of the crank arm 104 is connected to an end of the power output shaft of the reducer 102, and one end of the link arm 106 is rotatably coupled to the other end of the crank arm 104. Therefore, the rotation of the power output shaft is converted to the vertical reciprocating motion of the other end 105 of the link arm 106 by the mechanical connection of the crank arm 104 and the link arm 106.

The chain 6 of the floor conveyor 4 is supported and rotated by a pulley (not shown) located in the lower part of the loading box to the front and rear sides. The pulley drive shaft 111 extends to protrude toward the side of the loading box 2 and its end portion. On the side, the ratchet wheel 110 having a tooth formed in one direction on the outer circumferential surface is fixed to be rotated together with the pulley drive shaft 111.

The ratchet wheel 110 is driven by the pole arm 120. The pole arm 120 is composed of a pair of plates 122, pole shaft 126 and poles (128, pawl). The pair of plates 122 rotatably coupled to the pulley drive shaft 111 with the ratchet wheel 110 interposed therebetween includes three support arms 124 radially and opposed to each other. Between the 124, the poles 128 are detonated by the pole shaft 126. The pole 128 is, for example, a coil having both ends supported by the pole 128 and the plate 122 so that the tip of the pawl-shaped pawl 128, which is supported by the pole shaft 126, is pressed against the teeth of the ratchet wheel 110. It is installed while being carried by a spring (not shown). Therefore, when the pole arm 120 rotates counterclockwise (refer to FIGS. 6, 7, and 8), the tip of the pole 128 is engaged with the teeth of the ratchet wheel 100 so that the ratchet wheel 110 is counterclockwise. When the pole arm 120 rotates clockwise, only the pole arm 120 rotates without being engaged with the ratchet wheel 110. Accordingly, the pole arm 120 intermittently drives the ratchet wheel 110 in one direction, and thus the floor conveyor 4 is intermittently transferred. On the other hand, the ratchet wheel 110 is installed a general pole type stopper (not shown) to prevent the reverse rotation of the ratchet wheel (110).

Between the ratchet wheel 110 and the plate 122 of the pole arm 120, one of the three arms 132, which are radially coupled to the pulley drive shaft 111 and formed radially, is extended to the other end of the link arm 106. Seesaw arm 130 is rotatably coupled to. Each arm 132 of the seesaw arm 130 is disposed to be positioned behind each support arm 124 of the pole arm 120 plate 122 and is installed to push and rotate the pole arm 120. Therefore, when the seesaw arm 130 rotates counterclockwise by the link arm 106, the pole arms 120 rotate together in the counterclockwise direction. The clockwise return rotation of the pole arm 106 is adjusted by the pole arm spring 140 and the adjustment means.

The seesaw arm 130 repeats the clockwise rotation and the counterclockwise rotation like the seesaw in a range of a constant rotational angle (see Φ of FIGS. 7 and 8) by the link arm 106.

When the seesaw arm 130 rotates in a counterclockwise direction, the pole arm 120 is pushed to rotate the pole arm 120 counterclockwise, and when the pole arm 120 rotates counterclockwise, the tip of the pole 128 is rotated. The ratchet wheel is rotated by the amount of rotation of the pole arm 120 in combination with the teeth of the ratchet wheel 110.

When the seesaw arm 130 rotates in the clockwise direction, the seesaw arm 130 is in contact with the pole arm 120 and only the seesaw arm 130 returns. The clockwise rotation of the pole arm 120, that is, the return, is made by the elastic force of the pole arm spring 140 that holds the pole arm 120 clockwise. And the return amount of the pole arm 120 is regulated by the adjusting means including the pole arm support wire 145. By adjusting the rotational angle of the pawl arm 120 for rotating the ratchet wheel 110 to adjust the rotational stroke of the ratchet wheel 110 and the feed amount of the floor conveyor (4) driven thereby.

Adjusting the rotational stroke of the ratchet wheel 110, that is, the counterclockwise rotation range of the pole arm 120 extends upwardly of the pole arm 120 along the side of the pole arm support wire 145 and the loading box 2. And an adjusting means including an adjusting table having a wire arm 153 rotated at the end according to the operation of the adjusting unit 151. The operation unit 151 of the adjustment table 150 is installed in the driver's seat in front of the loading box 2 in the vehicle body 1 so that the driver can be adjusted. The operation unit 151 may have various adjustment stages to variously adjust the stroke of the ratchet wheel 110.

One end of the pole arm support wire 145 such as a chain is connected to the wire arm 152 located at the end side of the adjustment table 150, and the other end of the wire 145 is fixed to the plate 122 of the pole arm 120. have. Therefore, when adjusting the adjustment stage using the handle 151 of the adjustment table 150, the range in which the pole arm 120 is returned to the counterclockwise direction by the pole arm spring 140 according to the adjustment stage.

For example, when the adjusting stage is adjusted to the lower stage, the wire 145 is pulled upward as compared to the case in which it is adjusted by the design (see FIG. 8), and the pole arm 120 is rotated clockwise by the pole arm support spring 140. The range that can be rotated is reduced. That is, the range in which the pole arm 120 can rotate in the clockwise direction is limited according to the adjustment stage.

Referring to the operation of the pole arm 120 together with the seesaw arm 130, when the seesaw arm 130 rotates counterclockwise by the link arm 106, the pole arm 120 by the seesaw arm 130. Rotates counterclockwise, where the tip of the pawl 128 is engaged with the teeth of the ratchet wheel 110 to rotate the teeth. When the seesaw arm 130 rotates clockwise by the link arm 106, the pole arm 120 rotates clockwise by the elastic force of the pole arm support spring 140, and the pole arm support spring 140 is rotated by the pole arm 120. Since the wire 145 is connected in a direction opposite to the direction of pulling), the pole arm 120 may rotate clockwise only to the extent that the wire 145 is expanded. When the wire 145 is pulled a lot, the degree of return of the pole arm 120 to the clockwise direction is small, and in the opposite case, the degree of return of the pole arm 120 to the clockwise direction is large. As the range in which the pole arm 120 returns to the clockwise direction is adjusted, the rotation angle of the pole arm 120 rotating counterclockwise by the seesaw arm 130 is adjusted.

7 and 8 show the operation when the adjustment stage is set to the high stage and the low stage, respectively. As can be seen from the contrast of FIGS. 7 and 8, the seesaw arm 130 is formed by the link arm 106. Rotate by Φ. However, the range of rotation of the pole arm 120 depends on the degree to which the wire 145 is pulled by the wire arm 152. First, referring to FIG. 7, since the wire 145 is long, the pole arm 120 has a large range of return to the clockwise direction by the pole arm spring 140. Therefore, when the seesaw arm 130 rotates Φ, the pole arm 120 drives the ratchet wheel 110 while rotating by θ ₁ rotation angle. However, referring to FIG. 8, the wire arm 152 is rotated and the wire 145 is pulled upwards a lot. Therefore, the degree to which the pole arm 120 returns clockwise by the pole arm spring 140 is small. In this state, when the seesaw arm 130 rotates Φ, the seesaw arm 130 rotates at a predetermined rotational angle and then contacts the pole arm 120 to rotate the pole arm 120 by θ ₂ rotation angle while rotating the ratchet wheel 110. Drive. That is, as can be seen from the contrast of FIG. 7 and FIG. 8, it can be seen that the rotation range of the pole arm 120 can be adjusted to the extent that the wire 145 is pulled by the wire arm 152, and the pole arm 120 can be adjusted. Since the ratchet wheel is driven by the rotation, the rotational stroke of the ratchet wheel is changed accordingly. Therefore, according to the present invention, the transport amount of the floor conveyor can be adjusted in various ways with a simple structure.

9 is a configuration diagram of the fork of the compost spreader according to the present invention, Figure 10 is a view from the side of the operation of the fork shown in FIG.

First, referring to FIG. 6, one end of the second link arm 107 is connected to the other end of the link arm 106 together with the long arm of the seesaw arm 130 to extend upward, and the second link arm 107 is connected to the other end of the link arm 106. The third link arm 108 is connected to the other end of the pivot shaft 52 of the fork portion 50 protruding to the outside of the loading box (2). As a result, the vertical reciprocating motion of the link arm 106 is converted into the rotational reciprocating motion of the rotation shaft 52 via the second link arm 107 and the third link arm 108.

9, at least one end of at least two connecting rods 62 is fixedly attached to the rotating shaft 52 that performs the reciprocating rotational movement at a predetermined rotation angle, and shaft holes are formed at the other end of the connecting rod 62. A plurality of rakes 56 are coupled to the fork shaft 54 formed on the outer peripheral surface.

 One end of the first fork shaft link 64 is coupled to both ends of the fork shaft 54 so as to be inclined upwardly, and the second fork shaft link 68 is coupled to the other ends of the first fork shaft link 64. It extends inclined to the lower side of the rotation shaft 52 is coupled to the support shaft 70 protruded into the loading box (2). Therefore, the rake 56 is connected by the kinematic connection of the connecting rod 62 for supporting the fork shaft and the first fork shaft link 64 and the second fork shaft link 68 when the rotary reciprocating shaft 52 rotates. ) Works similarly to a forklift pulling out dirt.

FIG. 10 is a view illustrating the operation of the fork, and as shown in the drawing, when the third link arm rotates the rotation shaft 52 while rotating c <-> c ', the rake 56 rotates the rotation shaft 52. As the pivoting motion of the connecting rod 62 centering on) and the pivoting motion of the rake around the fork shaft 54, the rake 56 changes while changing d <-> d '. As a result, the movement path of the rake 56 is increased, and it is possible to draw the compost to the drop point completely behind.

If the rake is not cut or pulled out by the rakes 56, lumps or coarse composts may block the discharge end, so it is difficult to discharge the compost through the discharge end just by transferring the floor conveyor 4, and in the case of dry compost Once it starts to collapse, a large amount of compost falls at once, like a landslide, which takes time until the next fall, so you cannot spread the compost evenly. However, according to the present invention, while the rake 56 repeats the operation between d <-> d ', the compost is cut evenly and draws the compost toward the discharge end, so that the compost can be sprayed constantly. will be.

Hereinafter will be described the operation of the embodiment of the present invention.

When power is transmitted through the propulsion shaft by the engine clutch, power is distributed through the gearbox. The compost in the stack is moved backward by the floor conveyor, and the rotating shafts of the circular spreading plate and the fork portion rotate to spread the compost.

The floor conveyor moves the compost to the rear while moving according to the ratchet wheel's adjusted rotational stroke of the intermittent transmission, and the fork rotates about the rotation axis of the fork repeatedly, and the lump is moved by the rake attached to the fork. The compost is cut to a certain amount and forcedly dropped through the carry-out. The compost discharged through the unloading end is spread evenly behind the loading box as it strikes the spreading wing of the circular spreader.

At this time, the amount of compost spread is made by adjusting the distance that the floor conveyor intermittently transfers the compost by the intermittent electric drive. When the adjustment bar installed in the driver's seat is adjusted, the position where the pole arm is returned by the pole arm spring is adjusted by the wire. Accordingly, the section where the teeth of the pawl and the ratchet wheel engage when the pole arm is pushed and rotated by the seesaw is adjusted. That is, the distance that the ratchet wheel rotates by the pole is determined by the pole arm per rotation of the seesaw, and the floor conveyor intermittently transfers the compost by an amount corresponding to the rotation stroke of the ratchet wheel. In order to increase the compost spreading amount, the ratchet wheel is increased to increase the rotational stroke, and if it is to be reduced, the ratchet wheel is adjusted to reduce the rotational stroke.

Although the present invention described above is limited to one embodiment, the present invention is not limited thereto, and the present invention may be easily modified by those of ordinary skill in the art to which the present invention pertains. It is obvious that it belongs to the technical idea.

The compost spreader according to the present invention can simplify the configuration of the intermittent electric motor that rotates the floor conveyor, thereby achieving a reduction in the number of parts, improved assembly and materials. In particular, the present invention omits the disk-type guide and the link mechanism for rotating the same in the conventional structure, and has the effect of reliably adjusting the conveying speed of the floor conveyor with a simplified structure called a wire and pole arm spring. In addition, according to the present invention, the power of the driving source is reliably and simply transmitted to each driving device of the compost spreader. Further, according to the present invention, the compost loaded in the loading box is cut evenly by the fork, and the compost is evenly sprayed to the discharge end.

1 is a view showing the configuration of a known manure spreader.

2 is a side view of the compost spreader according to the present invention.

3 is a plan view of the compost spreader according to the present invention.

Figure 4 is a partial configuration of the power transmission system of the compost spreader according to the present invention.

5 is a view showing a gearbox structure of the compost spreader according to the present invention.

6 is a block diagram of an intermittent electric motor according to the present invention.

7 and 8 are operation diagrams of the intermittent electric motor shown in FIG. 6.

9 is a fork configuration of the compost spreader according to the present invention.

FIG. 10 is an operation diagram of the fork part shown in FIG. 9.

Claims (7)

A vehicle body 1 towed by the tiller; A loading box (2) mounted on the vehicle body (1) and loaded with compost; A floor conveyor (4) installed on the floor of the stacking box (2) for transporting the loaded compost to the discharge end; A fork portion 50 installed across the upper rear end of the loading box 2 and having a plurality of rakes 56 for dropping compost transported by the floor conveyor through a discharging end; And And a spreading plate 12 provided below the stacking box 2 and having a spreading wing 13 to spread the compost discharged through the unloading end evenly. The floor conveyor 4, the ratchet wheel (110) fixed to the drive pulley shaft (111); A pair of plates 122 rotatably coupled to the drive pulley shaft 111 via the ratchet wheel 110 and having a support arm 124 radially; A pole shaft 126 connected between the support arms 124 of the pair of plates 122 facing each other; A pole arm (120) installed on the pole shaft (126) and having a pole (128) which is supported by a spring so that the tip is pressed against the teeth of the ratchet wheel (110); Rotatably coupled between the ratchet wheel 110 and the plate 122 to the drive pulley shaft 111, and has a radially extending arm 132 positioned to the rear of the pole shaft 126, One of the arms 132 is coupled to the other end 105 of the link arm 106 coupled to the crankshaft 104 coupled to the power output shaft 103 to which the power of the driving source is transmitted. Seesaw arm 130 for driving the ratchet wheel 110 by pushing the pole arm 120 while the arm 132 is in contact with the pole arm 120; A pole arm spring 140 having an end fixed to the pole arm plate 122 to support the pole arm 120 to be returned to a direction opposite to the direction in which the rod is pushed by the seesaw arm 130; And Intermittent electric motor including an adjustment means for adjusting the driving range of the pole arm 120 to drive the ratchet wheel 110 by adjusting the range that the pole arm 120 is returned by the pole arm spring 140. Compost spreader, characterized in that configured to be intermittently transported by (100). The method of claim 1, wherein the adjusting means One end is fixed to the pole arm plate 122 and extends upward to support the pole arm 120 in the opposite direction to which the pole arm spring 140 pulls, so that the pole arm 120 is pivoted back by the pole arm spring 140. A pole arm support wire 145 which is controllable to a range to be defined; And Compost spreader, characterized in that it comprises an adjuster 150 for supporting the other end of the pole arm support wire (145) to adjust the degree to which the pole arm support wire (145) is pulled upwards. The method of claim 2, The adjuster 150 includes an operation unit 151 located on a cumulus seat installed in the vehicle body 1, and extends upwardly of the pole arm 120 along the side of the loading box 2 and at the end of the pole arm support wire. Including the wire arm 152, the end of the 145 is fixed and rotated, The wire arm 152 is rotated according to the operation of the operation unit 151 to pull or lower the wire 145 to adjust the rotatable range of the pole arm 120 by the pole arm spring 140. Compost spreader, characterized in that configured. The method of claim 1, The drive source includes an engine 30 installed in the vehicle body 1 in front of the loading box 2, The power of the engine 30 may include a first pulley 32 fixed to the engine shaft, a second pulley 34 fixed to an end of the propulsion shaft 31 extending rearward through the lower surface of the vehicle body 1; The first pulley 32 and the second pulley 34 are connected to the first pulley 32 and the second pulley 34 by loosely adjusting the belt 36 and the belt 36. Compost spreader characterized in that the power transmission is intermittently configured by the pressure lever (38) to enable power transmission between the) and the clutch lever for adjusting the operation of the pressure lever. The method according to claim 1 or 4, The power of the drive source is input to the gearbox 40 through the propulsion shaft 31 is distributed to the drive parts, the gearbox 40 is a cube-shaped housing 41 and the six installed on each side of the housing Four bevel gears each of which bevel gears 42,43,44,45,45,47 mesh laterally with opposing bevel gears, including four bevel gears 42,43,44,45,46,47 Compost spreader, characterized in that configured to have. A vehicle body 1 driven by the tiller; A loading box (2) mounted to the vehicle body (1) and loaded with compost; A floor conveyor (4) installed on the floor of the stacking box (2) to transfer the compost loaded to the discharge end while being intermittently transported by an intermittent electric motor which receives power from a driving source and intermittently operates the driving pulley shaft; Spreading plate 12 is installed below the rear of the loading box (2) discharge end to evenly spray the compost discharged through the discharge end; And A plurality of rakes 56 are operatively connected to reciprocally rotate, and are installed across the upper rear end of the loading bin and one end protrudes to the side of the loading bin so that the protruding end receives power from the drive source. Is connected to the rotating power output shaft 103 via a link mechanism includes a fork portion 50 including a rotating shaft 52 fixed to the rotating shaft link arm 108 reciprocating rotation of the projecting end to the rotation center Compost spreader, characterized in that configured. The method of claim 6, wherein the fork 50 is The fork shaft 54 is fixed to the outer circumferential surface and installed across the inside of the loading box; At least two connecting rods 62 having one end fixed to the pivot shaft 52 and the fork shaft 54 being inserted into and supported by a shaft hole formed at the other end thereof; A first fork shaft link 64 having one end coupled to both front ends of the fork shaft 54 and inclined upwardly; A support shaft (70) installed inside the loading box (2) to the lower side of the rotation shaft (52); And Compost spreader characterized in that it further comprises a second fork shaft link (68) having one end coupled to the first fork shaft link (64) and the other end coupled to the support shaft (70).