JP6721236B2 - Work machine - Google Patents

Description

The present invention relates to a work machine. In particular, the present invention relates to a rotary working machine that is mounted on a rear portion of a traveling machine body and advances along with forward traveling of the traveling machine body while rotating a tilling rotor to cultivate a field.

Such a rotary working machine has a frame connected to the traveling machine body, and an apron provided at the rear of the frame and capable of being lowered and flipped up and rotated about a rotation fulcrum fixed to the frame. When scraping off the soil attached to the front part of the apron (the side facing the tilling rotor) or the tilling rotor, or when replacing the tilling claws provided on the tilling rotor, the apron is held in the flipped up state. However, the apron has a certain amount of weight, and the work of bouncing the apron is heavy work for the worker.

On the other hand, during the work by the rotary working machine, it is desired that the apron is grounded on the surface of the field to finish the surface of the field evenly.

Under these circumstances, a working machine disclosed in Patent Document 1 is disclosed which can assist the apron to flip up and can press the apron against the surface of the field. Patent Document 1 relates to a working machine including an apron flip-up assist mechanism that assists a spring-up force by utilizing elastic force of a gas spring, and a pressure mechanism that presses the apron downward by a coil spring of a compression rod. The invention is disclosed. This work machine has a configuration in which an apron flip-up assist mechanism and an apron pressurizing mechanism are vertically arranged.

JP, 2010-63367, A

However, in the working machine described in Patent Document 1, since the assist mechanism that allows the apron to flip up and the pressurizing mechanism that pressurizes the apron toward the field are arranged side by side, there is space in each. It is necessary, and there is still room for parts to be used for both mechanisms.

INDUSTRIAL APPLICABILITY The present invention is a work machine having an assist function that allows the apron to flip up and a pressurizing function that pressurizes the apron toward the field, and is capable of achieving miniaturization and reduction of the number of parts. The purpose is to provide a machine.

The working machine according to the embodiment of the present invention is mounted on the rear part of the traveling machine body, and is a working machine that cultivates a field by advancing along with the forward traveling of the traveling machine body while rotating the tilling rotor. A frame to be connected, an apron provided at a rear portion of the frame, rotatably supported by the frame so as to be capable of descending and flipping up, and arranging a field, and a first fulcrum provided on the frame and the apron. A gas spring for exerting a force in a direction in which the apron is flipped up by exerting a force for changing the distance to the second fulcrum, and a tubular first tubular shape in which one end of the gas spring is supported. A member, a second tubular member having a tubular shape in which the other end portion of the gas spring is supported, and the first tubular member is inserted therein, and the second tubular member is the first tubular member. And a permissible restriction mechanism capable of allowing and restricting sliding along.

ADVANTAGE OF THE INVENTION According to the working machine of this invention, the working machine which has the assist function which allows the assist of the apron's flipping up and the pressurizing function which pressurizes the apron toward the field is downsized and the number of parts is reduced. can do.

It is a rear view of the working machine which concerns on 1st Embodiment of this invention. (A) is a side view of the working machine before the apron is flipped up. (B) is a cross-sectional view of a portion of a pin inserted into the other end of the gas spring as seen from above. (C) is a cross-sectional view of the second fulcrum portion as seen from above. (A) is a sectional view showing a state before the gas spring is extended, and (B) is a sectional view showing a state after the gas spring is extended. FIG. 6A is a cross-sectional view showing a state in which a pin of the allowance regulation mechanism is removed from the first hole and the second hole. FIG. 6B is a cross-sectional view showing a state in which the pin of the allowance regulation mechanism is inserted into the first hole and the second hole. (C) is an enlarged side view of the rotating portion. It is a side view showing the state where the apron of the working machine was flipped up. It is a side view which shows the state which locked after the apron of the working machine was flipped up. It is a side view showing the state where the pin in the allowance regulation mechanism was inserted in the 1st hole and the 2nd hole at the time of apron descent. (A) is a front view of the structure of the holder as seen from the axial direction of the second tubular member. FIG. 6B is a side view showing the configuration of the recess of the second tubular member as seen from a direction orthogonal to the axial direction of the second tubular member. FIG. 6C is a front view of the second tubular member when the holder is fitted to the second tubular member, as viewed from the axial direction of the second tubular member. (D) is a side view showing a state in which the holder is fitted to the second tubular member, as seen from a direction orthogonal to the axial direction of the second tubular member. FIG. 6 is a side view of the working machine showing a state in which the protrusion of the holder is fitted into the front recess of the plurality of recesses of the second tubular member. It is a side view of a working machine showing a state where a convex part of a holder is fitted in a concave part on the rear side of a plurality of concave parts of a second tubular member. It is sectional drawing of the tolerance control mechanism which concerns on 2nd Embodiment. It is sectional drawing of the tolerance control mechanism which concerns on 3rd Embodiment.

Embodiments of a working machine of the present invention will be described below with reference to the drawings. However, the working machine of the present invention can be implemented in many different modes, and should not be construed as being limited to the description of the examples below. Note that in the drawings referred to in this embodiment, the same portions or portions having similar functions are denoted by the same reference numerals, and repeated description thereof is omitted. Further, for convenience of explanation, the terms “upper (upper)” and “lower (lower)” will be used, but “upper (upper)” and “lower (lower)” respectively indicate the orientation of the working machine 100 in the working state. Similarly, description will be made using the terms front (front side) or rear (rear side), but the front (front side) indicates the direction of the traveling machine body 300 that pulls the work machine 100 with respect to the work machine 100, and the rear (rear side). The side) indicates the direction of the work machine 100 with respect to the traveling machine body 300.

(First embodiment)
The overall configuration of the working machine 100 and the configuration of the allowance regulation mechanism 141 according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 4. The work machine 100 according to the embodiment of the present invention is connected to the rear part of the traveling machine body 300 such as a tractor, like a tilling work machine or a substituting machine, and works to cultivate or agitate soil by rotating the tiller claw 11. It is a machine. In the embodiment, the structure of the present invention will be described by using a tilling work machine as an example of the working machine 100, but the work machine according to the present invention may be a substitute machine, and a work machine other than the tiller work machine or the substitute machine. May be

(Structure of working machine 100)
FIG. 1 is a rear view of a work machine 100 according to the first embodiment of the present invention. FIG. 2A is a side view of the working machine 100 before the apron 20 is flipped up. FIG. 2B is a cross-sectional view of the pin 35 as viewed from above. FIG. 2C is a cross-sectional view of the portion of the second fulcrum 32 seen from above. As shown in FIG. 1, a working machine 100 according to the embodiment includes a frame 10 (including a main frame 110 and a shield cover 120), a tiller rotor 102, an apron 20, and the like.

The main frame 110 is attached to the rear part of the traveling machine body 300 such as a tractor. The main frame 110 has a cylindrical shape and has a power transmission shaft inside. A gear box 125 is attached to the main frame 110. Rotational power from a traveling machine body 300 such as a tractor traveling forward is transmitted to a PIC shaft 106 (power intake connection shaft) of the work machine 100, a gear (not shown) in the gear box 125, and a shaft (not shown) in the left side of the main frame 110. Then, the rotational power is turned to the left in the traveling direction of the working machine 100 and further transmitted to the chain case 105. The power transmission shaft in the main frame 110 is connected to the side chain case 105 of the work machine 100, and the chain transmission mechanism (not shown) in the chain case 105 causes the rotary shaft 104 of the tiller rotor 102 (see FIG. 2A). ) Is transmitted to.

As shown in FIG. 2(A), the tilling rotor 102 has a rotating shaft 104 and a large number of tilling claws 11 provided on the rotating shaft 104, and is a rotor for tilling a field. As shown in FIG. 1, a large number of tillage claws 11 are bent to the right or left in the traveling direction, and the area (width) in which each tillage claw 11 excavates soil is adjacent to the next tillage claw 11. There is overlap. The tiller rotor 102 rotates so as to scrape up the soil from the front to the rear in the traveling direction. As a result, soil adheres to the inside of the apron 20.

As shown in FIG. 2(A), the apron 20 is provided behind the shield cover 120 and is supported so as to be capable of descending and flipping up about a rotation fulcrum 22 fixed to the shield cover 120, and to be rotated. Used to level the ground. The center of gravity of the apron 20 is behind the rotation fulcrum 22. Therefore, the apron 20 tries to descend due to its own weight.

A leveling plate 21 made of stainless steel or the like is welded to the tip of the apron 20. The ground leveling plate 21 is configured to draw a loop from the inside to the outside of the apron 20. This leveling plate 21 flattens the field excavated by the tilling rotor 102. Since soil may adhere to the inside of the apron 20, the inside of the apron 20 may be covered with a rubber sheet (not shown). The inside of the shield cover 120 may also be covered with a rubber sheet (not shown).

Movable extended leveling plates 132 are provided at both ends of the leveling plate 21 (see FIG. 1). By opening the extension leveling plate 132, it is possible to level a wide width range together with the leveling plate 21.

(Allowable regulation mechanism)
In the embodiment, in addition to the above-described configuration, further, regarding the jumping up of the apron 20, there is further provided an allowance restricting mechanism 141 that combines an allowance mechanism allowing the assist operation and a restricting mechanism restricting the assist operation. .. The allowance regulation mechanism 141 is capable of permitting the second tubular member 50 to slide along the first tubular member 40 and is capable of regulating it. In the present embodiment, the allowance regulation mechanism 141 roughly performs the following three operations.

(Allows assist movement)
The allowance regulation mechanism 141 allows the second tubular member 50 to slide along the first tubular member 40 in allowing the assisting operation of the apron 20 to flip up. By doing so, the gas spring 30 can be extended, and the first fulcrum 31 arranged on the pedestal 111 provided on the main frame 110 and the second fulcrum 32 arranged on the pedestal 134 provided on the apron 20. Will allow the distance between, to be reduced. As a result, a turning force is generated in the jumping direction on the apron 20 connected to the second fulcrum 32.

(Regulates assist operation)
Further, the allowance restricting mechanism 141 restricts the second cylindrical member 50 from sliding along the first cylindrical member 40 when restricting the assisting operation of the apron 20 for flipping up. By doing so, the extension of the gas spring 30 is restricted, and as a result, the flip-up assist operation of the apron 20 is restricted.

(Pressurized against the field)
Further, the allowance regulation mechanism 141 arranges the holder 91 whose position can be changed in front of the compression spring 80 while the assisting operation of the apron 20 for flipping up is regulated, and biases the compression spring 80 rearward. The apron 20 pressurizes the field depending on the position. Hereinafter, these specific configurations will be described in detail.

The allowance regulation mechanism 141 has a first tubular member 40 (inner tubular member), a second tubular member 50 (outer tubular member), and a gas spring 30 (see FIG. 3) located therein. The gas spring 30 will be described first, and then the first tubular member 40 and the second tubular member 50 will be described.

(Composition of gas spring)
FIG. 3A is a sectional view showing a state before the gas spring 30 extends. FIG. 3B is a cross-sectional view showing a state after the gas spring 30 has expanded. The gas spring 30 has a cylindrical cylinder 251 that encloses a space inside, a piston 256 inserted into the cylinder 251, and a piston rod 252 extended from the piston 256.

A bracket is provided at the tip of the piston rod 252, and this portion is referred to as one end 38 of the gas spring 30 here. A bracket is provided at the tip of the cylinder 251, and this portion is referred to as the other end 37 of the gas spring 30 here. A rod guide 258 for stabilizing the piston rod 252 is provided near one end of the piston rod 252 and the cylinder 251.

The first chamber 261 (the chamber on the left side of the piston 256 in FIG. 3) between the piston 256 and the tip of the cylinder 251 is filled with nitrogen. By changing the volume of this nitrogen, the gas spring 30 expands and contracts like a spring, and when the distance between the other end 37 (bracket) and the one end 38 (bracket) is small, the force is increased. To act.

A second chamber 280 (a chamber excluding the piston rod 252 on the right side of the piston 256 in FIG. 3) between the piston 256 and the rod guide 258 inside the gas spring 30 is filled with oil and nitrogen.

An orifice (hole) 259 is formed in the piston 256 along the extending direction of the gas spring 30. The nitrogen filled in the second chamber 280 moves to each other via the orifice 259 formed in the piston 256. Specifically, as the piston rod 252 extends toward the outside of the cylinder 251, the nitrogen in the second chamber 280 moves to the first chamber 261 via the orifice 259 and is formed by the piston 256 and the cylinder 251. The volume of the first room 261 is increased. In this way, the gas spring 30 extends.

(Configuration of combination of first tubular member and second tubular member)
FIG. 4A is a cross-sectional view showing a state in which the pin 61 of the allowance regulation mechanism 141 is removed from the tilling hole 41f and the second hole 51. FIG. 4B is a cross-sectional view showing a state in which the pin 61 of the allowance regulation mechanism 141 is inserted into the tillage hole 41f and the second hole 51. The allowance regulation mechanism 141 is configured such that the second tubular member 50 moves forward relative to the first tubular member 40 when the gas spring 30 extends forward. Further, the allowance regulation mechanism 141 is configured so that the gas spring 30 does not extend forward by fixing the position of the second tubular member 50 with respect to the first tubular member 40. The first tubular member 40 and the second tubular member 50 are movable on the same axis.

The first tubular member 40 is a tubular member having a plurality of first holes 41, and the second tubular member 50 is a tubular member having a second hole 51. The first tubular member 40 is inserted into the second tubular member 50. A resin-made tubular collar (resin collar) (not shown) is provided between the two to prevent generation of abnormal noise due to sliding of the first tubular member 40 and the second tubular member 50. There is.

One end 38 of the gas spring 30 is supported by the first tubular member 40 by the pin 36. The other end 37 of the gas spring 30 is supported by the second tubular member 50 by the pin 35. The pin 35 moves back and forth along the elongated hole 40X formed in the first tubular member 40.

Further, the first fulcrum 31 is provided on the front side portion of the first tubular member 40. The second fulcrum 32 is provided on the moving portion 55 on the outer peripheral surface of the second tubular member 50. In the state of FIG. 4(A), the gas spring 30 is in a state in which the gas spring 30 is urged in the direction of expansion and is compressed. Therefore, in the compressed state as shown in FIG. 4A, the cylinder 251 is about to move in the direction away from the one end portion 38 (direction toward the front side).

When the pin 61 is removed from the tilling hole 41f and the second hole 51 and the apron 20 is lifted, the gas spring 30 extends. Then, the pin 35 attached to the other end 37 of the gas spring 30 moves forward along the elongated hole 40X. Since the pin 35 is connected to the second tubular member 50, the second tubular member 50 moves to the front side, and the rear flange 59 fixed to the second tubular member 50 also moves to the front side. The cushion spring 70, the front side flange 58, the moving portion 55, and the second fulcrum 32 move to the front side together with the rear side flange 59. Of these, the second fulcrum 32 moves to the front side, so that the apron 20 is rotated by applying an assisting force in a flip-up direction.

Further, since the first fulcrum 31 is provided at the connecting portion between the front side of the first tubular member 40 and the pedestal 111 of the main frame 110, the second tubular member 50 does not move to the front side of the first fulcrum 31. The permissible restriction mechanism 141 does not project to the front side of the first fulcrum 31 of the work machine 100. Therefore, the movement of the mechanism can be reduced as compared with the case of the invention of Patent Document 1 described above.

(Plurality of first holes)
Further, the first hole 41 of the first tubular member 40 has a flip-up hole 41a (highest position hole) and a plurality of tilling holes 41b to 41f (midway position holes).

(Bouncing hole)
FIG. 5 is a side view of the working machine 100 according to the embodiment of the present invention when the apron 20 is flipped up. FIG. 6 is a side view of the working machine 100 according to the present embodiment in a state where the apron 20 is flipped up and then locked. The pin 61 is inserted into the flip-up hole 41a when the apron 20 is flipped up to the highest position Y2. In the state where the apron 20 is flipped up to the highest position Y2, the second tubular member 50, the locking mechanism 60, and the other end portion 37 of the gas spring 30 are the frontmost in the traveling direction L with respect to the first tubular member 40. Located in.

The user rotates the rotating portion 66 of the lock mechanism 60 in the first direction J1 in the state of FIG. 5 in which the second tubular member 50 is located on the most front side in the traveling direction L with respect to the first tubular member 40. Then, as shown in FIG. 6, the pin 61 is inserted into the second hole 51 and the flip-up hole 41a. Then, the apron 20 connected to the second tubular member 50 is fixed at the highest position Y2. It should be noted that depending on the user, it is possible to perform the tilling work in which the tilling claw 11 is rotated even when the pin 61 is inserted in the position of the flip-up hole 41a. In that sense, the flip-up hole 41a can be called a tillage hole.

(Hole for tillage)
Here, the plurality of tillage holes 41b to 41f will be described with reference to FIGS. 4 and 2A. The pins 61 are inserted into the plurality of tillage holes 41b to 41f when the tiller rotor 102 tills the field. When the tilling rotor 102 rotates, the apron 20 is placed at a tilling position lower than the highest position Y2 (see FIG. 5), and the second tubular member 50, the lock mechanism 60, and the other end portion 37 of the gas spring 30 are Compared to when the apron 20 is flipped up, the apron 20 is arranged at a position relatively moved rearward with respect to the first tubular member 40.

In such a state, when the user rotates the rotating portion 66 of the lock mechanism 60 in the first direction J1, the pin 61 is inserted into the second hole 51, and any one of the tilling holes 41b to 41f overlapping with the pin 61 is inserted. (In FIG. 4(B) and FIG. 2, the tillage hole 41f) is inserted. Then, the extension of the gas spring 30 is restricted. Although the extension of the gas spring 30 is regulated, it is not regulated until the leveling plate 21 hits the field and the apron 20 jumps up due to a reaction from the field (this will be described later with reference to FIGS. 7 to 10). ..

(Front-back relationship between bouncing holes and tillage holes)
The flip-up holes 41a (a part of the plurality of first holes 41) are arranged in front of the plurality of tilling holes 41b to 41f (a part of the plurality of first holes). When the assist is permitted during the flipping up of the apron 20, the second tubular member 50 is moved relatively to the front side with respect to the first tubular member 40, and the assisting of the apron 20 upward is restricted. This is because the second tubular member 50 is sometimes moved toward the rear side relative to the first tubular member 40 and fixed.

An elongated hole 40X is formed on the surface of the first tubular member 40 along the axial direction of the first tubular member 40. The elongated hole 40X is provided in the first tubular member 40 in a range in which the other end portion 37 moves when the gas spring 30 expands and contracts. The elongated hole 40X is arranged on the rear side in the traveling direction L with respect to the first fulcrum 31.

The pin 35 is inserted into the hole 37a of the other end portion 37 of the gas spring 30, the hole 50a of the side wall of the second tubular member 50, and the aforementioned long hole 40X (FIG. 2(B)). reference). Therefore, when the second tubular member 50 moves forward, the pin 35 moves forward along the elongated hole 40X, the other end 37 moves forward, and the gas spring 30 extends. When the second tubular member 50 moves backward, the pin 35 moves backward along the elongated hole 40X, the other end 37 moves backward, and the gas spring 30 contracts.

In the present embodiment, the distance between the flip-up hole 41a and the tillage hole 41b is set to be larger than the distance between the tillage holes 41b to 41f. This is because the positions of the apron 20 and the second tubular member 50 when maintaining the tiller rotor 102 and the positions of the apron 20 and the second tubular member 50 for adjusting the height when tilling are significantly different. Because.

Further, in order to make it possible to finely adjust the position taken by the leveling plate 21 with respect to the field at the time of tillage, the intervals of the tillage holes 41b to 41f are set small.

(Front-back relationship between tillage holes)
The second tubular member 50 is fixed to the front side relative to the first tubular member 40 so that the pin 61 is inserted into one of the plurality of tillage holes 41b to 41f on the front side. As a result, when the tilling rotor 102 tills a field, the apron 20 and the ground leveling plate 21 are set to be relatively high, so that the traveling speed can be increased, the soil can be increased, and rough soils such as large lumps of stones can be added. In clay fields (effects of field conditions), the soil will be well removed and the required power will be reduced. For example, when the pin 61 of FIG. 4 is inserted into the second hole 51 and the tillage hole 41b, the apron 20 and the ground leveling plate 21 are set high.

The second tubular member 50 is fixed to the rear side relative to the first tubular member 40 so that the pin 61 is inserted into the rear one of the plurality of tillage holes 41b to 41f. As a result, when the tilling rotor 102 tills the field, the apron 20 and the leveling plate 21 are set relatively low. For example, when the pin 61 of FIG. 4 is inserted into the second hole 51 and the tillage hole 41f, the apron 20 and the leveling plate 21 are set low.

(Structure of lock mechanism)
Here, the lock mechanism 60 will be described with reference to FIG. The allowance regulation mechanism 141 has a lock mechanism 60. The lock mechanism 60 is fixed to the second tubular member 50. The force in the direction of reducing the distance between the first fulcrum 31 and the second fulcrum 32 is not applied. As a result, the assist of the apron 20 of the allowance regulation mechanism 141 to jump up can be regulated during the tillage.

In the present embodiment, the lock mechanism 60 includes a pin 61, a spring 62, a rod-shaped portion 63, a spring 64, a support portion 67, and a rotating portion 66. The pin 61 is a member that can be inserted into the first hole 41 and the second hole 51. The pin 61 is inserted into the spring 62. The rod-shaped portion 63 is a rod-shaped member that is arranged substantially parallel to the pin 61 and moves integrally with the pin 61. The rod-shaped portion 63 is inserted into the spring 64.

The support portion 67 supports the pin 61 and the rod-shaped portion 63 so as to be movable in the axial direction. The support part 67 is formed of a housing here. In addition, a guide member 53 that guides the axial movement of the pin 61 and the rod-shaped portion 63 is provided inside the support portion 67. The rotating portion 66 is rotatably supported about a predetermined rotation center 63X provided on the rod-shaped portion 63, and has a cam portion 66a. When the cam portion 66a of the rotating portion 66 rotates while contacting the supporting portion 67, the position of the rotation center 63X moves in the axial direction of the pin 61, the rod portion 63 moves in the axial direction, and the pin 61 moves in the axial direction. Move in the direction.

As shown in FIG. 4C, the rotating portion 66 has a cam portion 66a. The cam portion 66a includes a first protruding portion 66a1 having a large turning radius r1 from the rotating center 63X and a second protruding portion 66a1 having a small turning radius from the rotating center 63X. 66a2.

When the rotating portion 66 rotates in the first direction J1, the cam portion 66a moves from the first contact position M1 where the first protruding portion 66a1 of the cam portion 66a abuts the support portion 67 to the second contact portion of the cam portion 66a. The protrusion 66a2 rotates to the second contact position M2 where it contacts the support 67. Along with this, the rod-shaped portion 63 descends with respect to the support portion 67 and is inserted into the third hole 52 of the second tubular member 50. At the same time, since the rod-shaped portion 63 and the pin 61 are fitted and integrated with the fitting member 65, the pin 61 descends with respect to the support portion 67 and the first hole 41 and the second hole 51 are formed. And the position of the second tubular member 50 with respect to the first tubular member 40 is fixed.

On the contrary, when the rotating portion 66 rotates in the second direction J2, the cam portion 66a moves from the second contact position M2 where the second projecting portion 66a2 of the cam portion 66a contacts the support portion 67 to the cam portion 66a. The first protrusion 66a1 rotates to the first contact position M1 where it contacts the support 67. Along with this, the rod-shaped portion 63 rises with respect to the support portion 67 and comes off from the third hole 52 of the second tubular member 50. At the same time, since the rod-shaped portion 63 and the pin 61 are fitted and integrated with the fitting member 65, the pin 61 rises with respect to the support portion 67 and comes out of the first hole 41 and the second hole 51. When released, the fixation of the position of the second tubular member 50 with respect to the first tubular member 40 is released.

The diameter of the rod portion 63 is larger than the diameter of the pin 61. The lower end of the rod portion 63 is located farther from the lower end of the pin 61 when viewed from the center of the axis of the first tubular member 40. In addition, in the above-mentioned example, the rod-shaped portion 63 is configured to be inserted into or removed from the third hole 52, but the configuration is not limited to this, and the diameter of the rod-shaped portion 63 is the same as that of the pin 61. The rod-shaped portion 63 may be formed in a size so that the rod-shaped portion 63 is also inserted into the first hole 41. In this case, the pin 61 is inserted into the first hole 41 and the second hole 51, and the rod-shaped portion 63 is inserted into the first hole 41 and the third hole 52 next to the pin 61. This makes it possible to more firmly fix the position of the second tubular member 50 with respect to the first tubular member 40 when restricting the flip-up assist of the apron 20.

At the time of tillage, the pin 61 is inserted into the overlapped first hole 41 and second hole 51. Then, the gas spring 30 does not extend, and the second tubular member 50 is restricted from moving forward with respect to the first tubular member 40. As a result, the apron flip-up assist function is not exerted.

On the contrary, the pin 61 is removed from the overlapped first hole 41 and second hole 51. Then, the gas spring 30 can be extended, and the second tubular member 50 can be moved forward with respect to the first tubular member 40. As a result, the apron flip-up assist function is exerted.

(Compression spring)
A compression spring 80 and a moving portion 55 are arranged on the outer surface of the second tubular member 50. The moving portion 55 is arranged on the rear side of the moving direction L of the compression spring 80. The compression spring 80 exerts an elastic force in the extension direction by being compressed by a predetermined length through which the second tubular member 50 is passed. The moving portion 55 is formed in an annular shape, and the second tubular member 50 is passed inside. A rear end of the compression spring 80 is arranged on the front side of the moving portion 55, and the moving portion 55 is provided so as to be movable with respect to the second tubular member 50.

(Cushion spring)
A cushion spring 70, a rear flange 59, and a front flange 58 are arranged on the outer surface of the second tubular member 50. A rear side flange 59 is arranged on the rear side of the traveling direction L of the cushion spring 70, and a front side flange 58 of the traveling direction L is arranged on the front side of the cushion spring 70 in the traveling direction L. Although the front side flange 58 is provided in the present embodiment, the front side flange 58 may be omitted.

The cushion spring 70 is arranged on the outer surface (outer peripheral surface) of the second tubular member 50, and exerts an elastic force in the extension direction by being compressed to a length longer than a predetermined length. The rear flange 59 is fixed to the outer surface (outer peripheral surface) of the second tubular member 50, and is arranged behind the rear end of the cushion spring 70. The front flange 58 is movably arranged on the outer surface (outer peripheral surface) of the second tubular member 50.

(Concave and holder)
The function of the compression spring 80 through which the second tubular member 50 is passed will be described with reference to FIG. 7. The compression spring 80 has a function of pressing the apron 20 and the ground leveling plate 21 against the field with a constant pressure when the apron 20 is in a lowered state. The magnitude of the force applied by the compression spring 80 can be adjusted by the operator changing the position of the holder 91.

(Recess)
As shown in FIG. 7, a plurality of recesses 57a to 57f are formed on the surface of the second tubular member 50. The plurality of recesses 57a to 57f are formed on the surface of the second tubular member 50 along the axial direction at predetermined intervals.

(holder)
FIG. 8A is a front view showing the configuration of the holder 91 as seen from the axial direction of the second tubular member 50. FIG. 8B is a side view showing the configuration of the recess 57 of the second tubular member 50 as seen from a direction orthogonal to the axial direction of the second tubular member 50. FIG. 8C is a front view of the second tubular member 50 in a state where the holder 91 is fitted to the second tubular member 50 as viewed in the axial direction. FIG. 8D is a side view showing a state in which the holder 91 is fitted to the second tubular member 50 as seen from a direction orthogonal to the axial direction of the second tubular member 50. The holder 91 can be attached to and detached from the recess 57 of the second tubular member 50 described above.

As shown in FIG. 8A, the holder 91 is provided with a sandwiching piece 92 on one side, a sandwiching piece 93 on the other side, and a sandwiching piece provided so that a sandwiching force is generated between the sandwiching piece 92 and the sandwiching piece 93. And a spring 94. The holding spring 94 includes a holding piece 92, an annular portion 94a outside the holding piece 93, and a holding piece 92 connected to the holding portion 94a and an arcuate portion 94b provided along the holding piece 93. A planar clamping surface 92a is formed on the inner peripheral side of the clamping piece 92, and a planar clamping surface 93a is formed on the inner peripheral side of the clamping piece 93.

As shown in FIG. 8B, in a side view of the second tubular member 50 seen from a direction orthogonal to the axial direction, the recess 57 of the second tubular member 50 has an outer periphery of the second tubular member 50. It has a bottom surface portion 57A formed by a flat surface that spreads out at a position closer to the center side, and a step portion 57B connecting the bottom surface portion 57A and the outer peripheral surface.

These recesses 57 are formed in two locations on the second tubular member 50, one side surface on the width direction N side orthogonal to the traveling direction L of the traveling machine body 300 and the other side surface. The user spreads the sandwiching piece 92 and the sandwiching piece 93 of the holder 91 and causes the recess 57 to be sandwiched between the sandwiching piece 92 and the sandwiching piece 93 by the urging force of the sandwiching spring 94. At this time, as shown in FIG. 8(C), the sandwiching surface 92a of the sandwiching piece 92 contacts one bottom surface portion 57A, and the sandwiching surface 93a of the sandwiching piece 93 contacts the other bottom surface portion 57A, The sandwiching piece 92 and the sandwiching piece 93 sandwich the recess 57. However, the position of the recess 57 does not have to be one side face and the other side face of the second tubular member 50 in the width direction N as long as the holder 91 is sandwiched therebetween, and may be formed vertically.

As shown in FIG. 8D, when the holder 91 is fitted into the recess 57 while sandwiching the recess 57, the holder 91 is higher than the compression spring 80 on the surface of the second tubular member 50. Form a convex portion. That is, here, the diameter of the holder 91 is formed wider than the diameter of the compression spring 80. Further, the compression spring 80 is arranged between the holder 91 and the second fulcrum 32.

By fitting the holder 91 into the recess 57, the holder 91 prevents the compression spring 80 from moving forward. Then, in a state where the front end of the compression spring 80 is in contact with the holder 91, when the apron 20 hits the field and receives a reaction and the moving portion 55 moves forward, the compression spring 80 tries to extend to the rear side and moves. The apron 20 attached to the portion 55 is urged downward.

(One example where the holder is fitted to the front side)
FIG. 9 shows a process of tilling the working machine 100, and a side surface of the working machine 100 showing a state in which the holder 91 is fitted in the front recessed portion 57 d (when compared with FIG. 10) of the plurality of recessed portions 57. It is a figure. The compression force that the compression spring 80 receives between the holder 91 and the moving portion 55 is so small that the holder 91 is fitted into the front concave portion 57 of the plurality of concave portions 57 in the traveling direction L. Therefore, the force of the compression spring 80 urging the second tubular member 50 rearward in the traveling direction L is weakened. At this time, the leveling plate 21 is set to the height Y3.

(Example of the holder fitting on the rear side)
FIG. 10 shows a process of tilling the working machine 100 and shows the state in which the holder 91 is fitted in the recess 57f on the rear side (when compared with FIG. 9) of the plurality of recesses 57. It is a side view. The compression force applied between the holder 91 and the moving portion 55 by the compression spring 80 is large as the holder 91 is fitted into the recess 57 on the rear side of the traveling direction L among the plurality of recesses 57. Therefore, the force of the compression spring 80 urging the second tubular member 50 rearward in the traveling direction L is increased. At this time, the leveling plate 21 is set to the height Y4.

(Apron flip-up operation)
Hereinafter, the operation of the work machine 100 will be described. First, the operation of flipping up the apron 20 will be described with reference to FIGS. As shown in FIG. 2(A), when the rotating portion 66 is operated in a lying state, the pin 61 rises, and the pin 61 moves to one of the plurality of tillage holes 41 b to 41 f of the first hole 41 ( In FIG. 2A, it is removed from the tilling hole 41f) and the second hole 51. Then, the gas spring 30 extends, and the second tubular member 50, the apron 20, and the other end portion 37 of the gas spring 30 can integrally move to the front side in the traveling direction L.

In this state, as shown in FIG. 5, when the apron 20 is flipped up, the other end portion 37 of the gas spring 30 extends to the front side in the traveling direction L, and the second tubular member 50 moves forward. Then, the assisting force of the gas spring 30 is exerted due to the flip-up operation of the apron 20, and the apron 20 is easily flipped up.

Then, as shown in FIG. 6, the user rotates the rotating portion 66 in the first direction J1 to insert and fix the pin 61 in the overlapping flip-up hole 41a and second hole 51a.

(Field pressure operation)
Next, with reference to FIGS. 7, 9, and 10, the operation of the permissible restriction mechanism 141 when plowing will be described. As shown in FIG. 7, when the rotating portion 66 is rotated in the upright state, the pin 61 is inserted into the tillage hole 41f and the second hole 51. The second tubular member 50 is arranged rearward of the first tubular member 40. Then, the apron 20 is maintained in the lowered state.

Then, as shown in FIG. 9, the working machine 100 moves in the traveling direction L, and the field hits the apron 20, so that the apron 20 moves up and the second fulcrum 32 and the moving portion 55 move in the traveling direction L. The compression spring 80 between the holder 91 and the moving portion 55 contracts. Since the holder 91 cannot move forward any more, the apron 20 is constantly urged to the field, and the leveling plate 21 levels the field.

Further, since the holder 91 cannot move forward any further, the other end 37 of the gas spring 30 cannot move forward either, and the gas spring 30 keeps moving while the field is leveled by the leveling plate 21. You can turn it off. In the state of FIG. 9, since the ground leveling plate 21 is urged against the field, the soil mass can be made finer in general plowing depth than when the holder 91 is not fitted.

If the height of the ground leveling board 21 with respect to the field is low (the height of the ground leveling board 21 with respect to the lowest point of the tilling claw 11 is the height Y4), as shown in FIG. It is necessary to prevent the apron 20 from rising by being fitted into the concave portion 57f of the second tubular member 50 so as to be held rearward. In this case, leveling by the leveling plate 21 can be performed more easily than in the case of FIG. 9, and the clod can be made finer.

(Second embodiment)
11 is a cross-sectional view of the allowance regulation mechanism 241 according to the second embodiment, FIG. 11(A) is a cross-sectional view before inserting the pin 61, and FIG. 11(B) is a cross-sectional view after inserting the pin 61. It is a figure. As shown in FIG. 11, instead of using the lock mechanism 60, the user can insert the pin 61 into the first hole 41 of the first tubular member 40 and the second hole 51 of the second tubular member 50. You can In the present embodiment, the first hole 41 is formed so as to pass through the first tubular member 40 in the radial direction while passing through the axial center. Therefore, the first holes 41 are formed at two locations, above and below the first tubular member 40. The second hole 51 is formed so as to penetrate in the radial direction while passing through the axial center of the second tubular member 50. Therefore, the second holes 51 are formed at two locations, above and below the second tubular member 50.

The pin 61 has a pin body portion 61a and a head portion 61b. The pin body portion 61a is a portion of the pin 61 inserted into the first hole 41 and the second hole 51. The head portion 61b is a portion of the pin 61 that is provided at the end portion of the pin body portion 61a and has a size larger than the second hole 51. The pin 61 is configured to be attachable to and detachable from the first hole 41 and the second hole 51.

The head 61b is caught on the surface of the second tubular member 50 in a state where the pin body 61a is inserted into the first hole 41 and the second hole 51 which are overlapped with each other. As a result, the second tubular member 50 cannot move with respect to the first tubular member 40. That is, movement is restricted. The second tubular member 50 is movable with respect to the first tubular member 40 in a state where the pin body portion 61 a is removed from the first hole 41 and the second hole 51 which are overlapped with each other.

(Third Embodiment)
12 is a cross-sectional view of the allowance regulation mechanism 341 according to the third embodiment, FIG. 12(A) is a cross-sectional view before inserting the pin 61, and FIG. 12(B) is a cross-sectional view after inserting the pin 61. It is a figure. As shown in FIG. 12, the lock mechanism 60 may be configured without the rod portion 63. In this embodiment, the lock mechanism 60 includes a pin 61, a spring 62, a support portion 67, and a rotating portion 66.

The pin 61 is a member that can be inserted into the first hole 41 and the second hole 51. The pin 61 is inserted into the spring 62. The support portion 67 is a member that supports the pin 61 movably in the axial direction. The rotating portion 66 is supported rotatably around a predetermined rotation center 61X located outside the supporting portion 67. Also in the present embodiment, the rotating portion 66 is formed with the cam portion 66a, and the cam portion 66a has the first protruding portion 66a1 and the second protruding portion 66a2.

When the rotating portion 66 rotates in the first direction J1, the cam portion 66a moves from the first contact position M1 where the first protruding portion 66a1 of the cam portion 66a abuts the support portion 67 to the second contact portion of the cam portion 66a. The protrusion 66a2 rotates to the second contact position M2 where it contacts the support 67. Along with this, the pin 61 descends with respect to the support portion 67 and is inserted into the tillage hole 41f and the second hole 51, and the position of the second tubular member 50 with respect to the first tubular member 40 is fixed. ..

Conversely, when the rotating portion 66 rotates in the first direction J2, the cam portion 66a moves from the second contact position M2 where the second protruding portion 66a2 of the cam portion 66a abuts the support portion 67 to the cam portion 66a. The first protrusion 66a1 rotates to the first contact position M1 where it contacts the support 67. Along with this, the pin 61 rises with respect to the support portion 67 and is removed from the tilling hole 41f and the second hole 51, and the fixation of the position of the second tubular member 50 to the first tubular member 40 is released. It

(Operation and effect of the embodiment)
With the above configuration, the following operational effects are achieved. First, based on the configurations of the first to third embodiments of the present invention, in a working machine having a function of assisting the flipping up of the apron 20 and having the apron 20 pressurize a field, downsizing and It is possible to reduce the number of parts. That is, conventionally, the mechanism using the gas spring 30 that assists the flipping up of the apron 20 and the mechanism of the compression rod that the apron 20 pressurizes the field were individually provided. According to the configuration, both axes are shared (shared), which leads to downsizing and the number of parts.

Secondly, assuming the configuration of the second embodiment of the present invention, the configuration in which the pin 61 is directly inserted into the first hole 41 and the second hole 51 allows the configuration of the allowance regulation mechanism 141 to be changed. Simplification is realized and the number of parts is reduced. Further, since the pin 61 is inserted through the upper and lower holes of the first tubular member 40 and the upper and lower holes of the second tubular member 50, the second tubular member 50 is fixed to the first tubular member 40. Strength increases.

Thirdly, assuming the configuration of the third embodiment of the present invention, the rod-shaped portion 63 is omitted, the simplification of the permissible restriction mechanism 141 is realized, and the number of parts is reduced. Further, since the rotating unit 66 has only to raise and lower the pin 61 by one, the load required for the user to operate is reduced.

(Modification 1)
In the above-described embodiment, as shown in FIG. 1, an example in which two allowance regulating mechanisms 141 are provided has been shown, but more allowance regulating mechanisms 141 may be provided. In particular, it is desirable to use a plurality of gas springs in a large tiller, a substitute device, or the like having a heavy apron. In this case, for example, four allowance regulation mechanisms 141 may be provided. In this way, the user can more easily flip up the apron 20. Further, when three or more allowance regulating mechanisms 141 are provided, it is desirable that the allowance regulating mechanisms 141 be arranged at equal intervals so that the weight of the apron 20 and the like can be received evenly.

(Modification 2)
In the above-described embodiment, as shown in FIG. 3, an example in which one gas spring 30 is provided inside one permissible restriction mechanism 141 is shown, but one permissible restriction mechanism 141 includes a plurality of gas springs. A configuration including 30 may be used. In this case, the apron flip-up assist force for each of the permissible restricting mechanisms 141 can be increased, and the configuration can be simplified. Further, in the case of having a plurality of gas springs 30 as described above, the cross section of the gas springs 30 has the cross-section described in the above-described embodiment so that the space inside the first tubular member 40 can be used without waste. Instead of the cylindrical shape as described above, it may be formed in a rectangular tube shape such as a rectangle. This is because the gas springs 30 are easily arranged in the first tubular member 40 in the vertical direction and the horizontal direction. The first tubular member 40 and the second tubular member 50 may not be cylindrical but may be elliptic tubular with an elliptical cross section or rectangular tubular with a rectangular cross section.

Although the present invention has been described above with reference to the drawings, the present invention is not limited to the above-described embodiments and can be appropriately modified without departing from the spirit of the present invention.

100: working machine, 40: first tubular member, 50: second tubular member, 30: gas spring

Claims (9)

Is attached to the rear of the vehicle body, in proceeding with the forward travel of the previous Symbol traveling vehicle body work machine for tilling the field,
A frame connected to the rear part of the traveling body,
An apron that is provided at the rear part of the frame, is supported so as to be capable of descending and flipping up relative to the frame, and lands the field.
An elastic member that exerts a force that changes the distance between a first fulcrum provided on the frame and a second fulcrum provided on the apron, thereby exerting a force in a direction in which the apron is flipped up.
A first tubular member having one end portion of the elastic member is Ru is supported,
The other end of the elastic member is supported, and a second tubular member, wherein the first tubular member is to be inserted slidably therein,
A compression spring in which the second tubular member is inserted;
A moving portion that is provided movably with respect to the second tubular member, in which the second tubular member is passed through, a rear end of the compression spring is disposed forward, the second fulcrum is fixed,
Working machine equipped with. The work machine according to claim 1, further comprising a lock mechanism capable of restricting the second tubular member from sliding along the first tubular member. The locking mechanism is
A first hole formed in the first tubular member;
A second hole formed in the second tubular member;
A pin that can be inserted into the first hole and the second hole that are overlapped,
Have
When the pin is inserted into the first hole and the second hole, the position of the second tubular member with respect to the first tubular member is fixed, and the pin moves from the first hole and the second hole. The working machine according to claim 2 , wherein when fixed, the position of the second tubular member with respect to the first tubular member is released. A recess formed on the surface of the second tubular member,
A holder that is attachable to and detachable from the recess and that can abut the front end of the compression spring ;
Equipped with
Said compression spring is disposed between the holder and the moving part, the working machine according to any one of claims 1 to 3. A plurality of the recesses are formed on the surface of the second tubular member side by side in the axial direction,
The compression spring attaches the second tubular member to the rear side in the traveling direction of the traveling machine body so that the holder is fitted into the front side concave portion of the plurality of recesses in the traveling direction of the traveling machine body. The force to act is weakened,
Enough said holder is fitted into the recess of the rear side of the plurality of recesses, forces the compression spring biases the second tubular member to the rear side is strengthened, according to claim 4 Working machine. It said first hole is for splashing which the pin is disposed and a plurality of tillage holes to be inserted, the front side in the traveling direction of the traveling machine body than said plurality of tillage holes when tilling the圃 field The work machine according to claim 3 , further comprising a hole . The second tubular member is fixed to the front side with respect to the first tubular member such that the pin is inserted into one of the plurality of tillage holes on the front side in the traveling direction of the traveling machine body. The apron is set relatively high,
The second tubular member is fixed to the rear side with respect to the first tubular member so that the pin is inserted into one of the plurality of tillage holes on the rear side in the traveling direction of the traveling machine body. The working machine according to claim 6 , wherein the apron is set relatively low. When the pin is removed from the first hole and the second hole, said second tubular member, the apron, and the other end of the elastic member is a movable integrally, claim The working machine according to item 3 . In a working machine that is attached to the rear part of the traveling machine body and advances along with the forward traveling of the traveling machine body to cultivate a field,
A frame connected to the rear part of the traveling body,
An apron that is provided at the rear part of the frame, is supported so as to be capable of descending and flipping up relative to the frame, and lands the field.
An elastic member that exerts a force that changes the distance between a first fulcrum provided on the frame and a second fulcrum provided on the apron, thereby exerting a force in a direction in which the apron is flipped up.
A first cylindrical member having one end supported by the elastic member and having a first hole;
A second tubular member having a second hole, the other end of the elastic member being supported, the first tubular member being slidably inserted therein, and
A lock mechanism capable of restricting the second tubular member from sliding along the first tubular member;
Equipped with
The lock mechanism has a pin that can be inserted into the first hole and the second hole that are overlapped with each other,
When the pin is inserted into the first hole and the second hole, the position of the second tubular member with respect to the first tubular member is fixed, and the pin moves from the first hole and the second hole. When removed, the fixation of the position of the second tubular member with respect to the first tubular member is released,
The first holes are a plurality of plowing holes into which the pins are inserted when plowing the field, and a flip-up hole arranged on the front side in the traveling direction of the traveling machine body with respect to the plurality of plowing holes. And a working machine having.

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