KR101036666B1 - Saving fuel of rotovator - Google Patents

Abstract

The present invention relates to a rotor saver in which fuel is saved.

According to the present invention, by crushing the soil cultivated by the tiller blade of the rotor in the rotation direction of the rotor crusher, or by restricting the progress in the rotation direction to reduce the rotational load applied to the tiller blade to protect the tilling blade This reduces the fuel of the tractor and provides the effect of shortening the tilling time.

Rotor, tillage, dirt blocking, shredding

Description

Fuel-saving rotorbait {SAVING FUEL OF ROTOVATOR}

The present invention relates to a rotorbait mounted on the tractor for tilling the soil, in detail, finely crushing the soil tilled by the tiller blades of the rotorbait in the rotational direction of the rotorbinder, or restricts the progress in the rotational direction to be limited By reducing the rotating load applied to the tilling blade, it is configured to reduce the fuel of the tractor.

In general, the rotor is equipped with a cultivator or a tractor is configured to cultivate the soil to an appropriate depth while rotating a plurality of cultivating blades provided on the cultivation shaft receives power from the engine of the cultivator or tractor.

This rotor Vaporator will be described with reference to the accompanying drawings.

1 is a perspective view schematically illustrating a conventional rotorbator structure, FIG. 2 is a side view of a main part of FIG. 1, and FIG. 3 is a side view of a main part of an operating state of FIG. 1.

As shown in Figures 1 to 3, the conventional rotorbait is a plurality of tilling blades arranged so as to be spaced apart at intervals in the axial direction to the tillage shaft 100 by the tractor or tiller ( 120) the farmland is dug to a certain depth.

The rotor is fixed to the outer circumferential surface of the tillage shaft 100 to arrange a plurality of flanges 200 to be spaced apart in the axial direction, and to fix the plurality of tillage blades 120 in the circumferential direction to the flange 200 with bolts or the like. Let's go.

In this case, the plurality of flanges 200 fixedly spaced apart in the axial direction on the outer circumferential surface of the tillage shaft 100 have a plurality of tillage blades 120 spaced apart to maintain an appropriate radius from the center of the tillage shaft 100. It is fixed to, so that the blade tip trajectory 121 is drawn during the tilling blade tip is rotated is designed to form a large circle from the center of the tillage axis (100).

In addition, it is designed to maintain the spacing of the blade end trace 121 and the scattering plate 301 of the upper side plate 300 when the end of the tilling blade 120 is rotated.

In the conventional rotorbator structure designed as described above, when a plurality of tilling blades 120 are mounted away from the tillage shaft 100, the soil resistance is increased, and when the number is close, the tilling depth becomes shallow.

As a result, such a tilling blade 120 is subjected to a lot of load, thereby causing severe vibrations and noises during rotation, as well as the wear of the parts fixed to the flange 200, as well as the damage of itself is accelerated to shorten the life, excessive Due to the soil resistance, there was a problem such that more power is required than the amount of work.

In addition, while the soil spread by the tilling blade 120 passes between the blade tip trace 121 and the scattering plate 301 as it is, the gap is narrower than the amount of soil, so the soil collides with the scattering plate, but it must be scattered. The soil is always accumulated between the tilling blade 120 and the scattering plate 301, and the more the soil is clay, the deeper the accumulation.

Therefore, the soil accumulated in the space between the tilling blade 120 and the scattering plate 301 is repeatedly cut by the tilling blade 120 so that the particle size becomes excessively small, so that a graining phenomenon occurs, and the tilling blade ( It will act as a rotational resistance that interferes with the progress of 120).

At this time, when the soil accumulated in the space between the tillage blade 120 and the scattering plate 301 acts as a rotational resistance of the tillage blade, it requires a larger horsepower to overcome this, and thus the tractor The problem is that a lot of fuel consumption.

The present invention has been made in order to solve such a conventional problem, the present invention is to crush the soil tilled by the tiller blade of the rotor in the rotation direction of the rotorba to the appropriate granularity, or limited to the progress in the rotation direction It is possible to reduce the rotational load applied to the tilling blade by blocking, thereby providing a fuel-saving rotorbait configured to save the fuel of the tractor.

The problem solving means of the present invention is provided with a plurality of tilling blades as flanges on the tilling shaft rotated by the power of the tractor, the rotor is configured to maintain the proper distance with the blade tip trace of the tilling blade and the scattering plate provided on the lower side of the upper plate. In the bait, a soil crushing device for crushing the soil tilled by the tilling blade provided on the lower front horizontal frame provided in front of the upper side plate, the soil crushing device corresponding to the lower front horizontal frame of the upper side plate A fixed bracket to be fixed; A rotating shaft having both ends rotatably arranged between the fixing brackets; A driving motor connected to one end of the rotating shaft to rotate the rotating shaft; It is characterized by consisting of a plurality of shredding blades for crushing the soil tilled by the tilling blade is provided to maintain an equal interval on the outer periphery of the rotary shaft.

According to the present invention, by crushing the soil cultivated by the tiller blade of the rotorbait in the rotation direction of the rotorbait, or by restricting the progress in the rotational direction to reduce the rotational load applied to the tiller blade to protect the tilling blade This reduces the fuel of the tractor and provides the effect of shortening the tilling time.

Hereinafter, with reference to the accompanying drawings will be described in detail the specific content for the practice of the present invention.

4 is a perspective view showing a first embodiment of a fuel-saving rotorbator according to the present invention, FIG. 5 is a front sectional view of the main part of FIG. 4, and FIG. 6 is a sectional side view of the main part of FIG. 4. FIG. 7 is a side view illustrating main parts of the operating state of FIG. 4.

As shown in FIGS. 4 to 7, the fuel-saving rotorbait receives the power of the tractor engine from the tillage shaft 10 as a power transmission device 1 so that the tillage blade 12 rotates. Will be constructed.

On the outer circumferential surface of the tillage shaft 10, a plurality of flanges 16 are arranged and fixed to be spaced apart in the axial direction, and the plurality of tillage blades 12 are fixed to the flange 16 in a circumferential direction by a fastening force such as a bolt. Will be tilled to a certain depth.

At this time, the blade tip trajectory 14, which is drawn when the tip of the tillage blade 12 rotates, is designed to form a large circle from the center of the tillage axis 10, and the knife tip trace 14 is provided below the upper side plate 20. Proper spacing with the scattered plate 21 is designed.

Then, the soil tilled by the tilling blade 12 accumulates in the area between the cutting edge trace 14 of the tilling blade 12 and the front side of the scattering plate 21 to become the portion P where the load is most applied. .

On the other hand, the lower side of the front horizontal frame 24 provided in front of the upper side plate 20 is provided with a soil crushing device 30 for crushing the soil tilled during tilling of the tilling blade 12, the blade of the tilling blade 12 The soil accumulated between the end trajectory 14 and the scattering plate 21 front side is moved in the rotational direction to reduce the load applied to the tilling blade 12.

The soil crushing device 30 is fixed bracket 32, 33 fixed to correspond to the lower portion of the front horizontal frame 24 of the upper side plate (20); A rotation shaft 35 rotatably arranged at both ends between the fixing brackets 32 and 33; A driving motor 37 connected to the other end of the rotating shaft 35 to rotate the rotating shaft 35; The outer circumferential edge of the rotating shaft 35 is provided at equal intervals and consists of a plurality of shredding blades 39 for crushing the soil tilled by the tilling blade 12.

At this time, the bearing 34 is installed in the fixing brackets 32 and 33 to rotate the rotating shaft 35. One end of the rotation shaft 35 is connected to the driving motor 37 by a coupling means such as a coupling to transmit the rotational force of the driving motor 37.

In addition, the drive motor 37 is configured to rotate in the direction opposite to the rotation direction of the tilling blade 12 to rotate the shredding blade 39.

Then, the end of the shredding blade 39 is installed so that the end of the tilling blade 12 is close to the blade end trajectory 14, which is drawn during rotation. The shredding blade 39 may be configured in various types such as circular, polygonal and plate shapes.

8 is a front configuration diagram showing a second embodiment of a fuel-saving rotor according to the present invention, and FIG. 9 is a side configuration diagram of a main part of the operating state of FIG. The basic structure is the same as the embodiment, but instead of the earth crushing device shown in the first embodiment, the earth block device 40 for blocking the soil is provided.

The soil blocking device 40 includes a plurality of lower plates 42 fastened to the lower portion of the front horizontal frame 24 of the upper side plate 20; The blocking plate 44 is fixed to the lower plate 42 to protrude downward.

At this time, the lower plate 42 is fastened to the lower portion of the front horizontal frame 24 by bolts and nuts. In addition, the blocking plate 44 is fixed to the lower portion of the lower plate 42 to be inclined inward with respect to the center, and the lower end thereof is close to the blade tip trace 14 which is drawn at the end of the tilling blade 12.

And, Figure 10 is a front configuration diagram showing a third embodiment of a fuel-saving rotor according to the present invention, Figure 11 is a side configuration of the main operation state of Figure 10, which is a fuel-saving rotor of the rotor The basic structure is the same as that of the first embodiment, but instead of the soil crushing device shown in the first embodiment, a different type of front soil crushing device 50 is provided.

The front soil crushing device 50 includes a plurality of lower plates 52 fastened to the lower portion of the front horizontal frame 24 of the upper side plate 20; The front plate 54 is fixed to each of the lower plate 52 so as to protrude downwards at equal intervals.

At this time, the lower plate 52 is fastened to the lower portion of the front horizontal frame 24 by bolts and nuts. In addition, the front blade 54 is inclined inward with respect to the center of the lower portion of the lower plate 52, the lower end is close to the blade end trajectory 14, the end of the tilling blade 12 is drawn during rotation.

And, Figure 12 is a front configuration diagram showing a fourth embodiment of a fuel-saving rotor according to the present invention, Figure 13 is a main portion back configuration of Figure 12, Figure 14 is an operating state of the main portion of Figure 12 As a schematic diagram, the basic structure is the same as that of the first embodiment of the rotorbaver in which the fuel is reduced, but instead of the soil crushing apparatus of the first embodiment, the front and rear soil crushers 60 and 70 of different types are respectively provided. Will be provided.

The front soil crushing device (60) includes a plurality of lower plates (62) fastened and fixed to the lower portion of the front horizontal frame (24) of the upper side plate (20); The front plate 64 is fixed to each of the lower plate 62 so as to protrude downwards at equal intervals.

At this time, the lower plate 62 is fastened to the lower portion of the front horizontal frame 24 by bolts and nuts. In addition, the front blade 64 is inclined inward with respect to the bottom of the lower plate 62 vertically, the lower end thereof is close to the blade end trace 14, the end of the tilling blade 12 is drawn during rotation.

The rear soil crushing device 70 includes a rear horizontal frame 72 provided behind the upper side plate 20; The rear horizontal frame 72 consists of rear blades 74 which are respectively provided to protrude downward by maintaining equal intervals in front. At this time, the rear blade 74 is fixed to protrude downwards on the front of the rear horizontal frame 72, the lower end is close to the blade end trajectory 14, the end of the tilling blade 12 is drawn during rotation.

Referring to the operating state according to the present invention configured as described above are as follows.

First, as shown in FIGS. 4 to 6, the tillage blade 12 fixed on the flange 16 is rotated by receiving the power of the tractor engine from the tillage shaft 10 as the power transmission device 1 so that the farmland is fixed. Digging deeply.

When the tilling blade 12 rotates in a counterclockwise direction as shown in FIG. 7, the soil moved along the tilling blade 12 and the blade tip trajectory 14 is scattered plate 21 below the upper side plate 20. In the direction of travel of the tractor. At this time, it is accumulated in the area P between the blade tip trace 14 and the scattering plate 21, and a lot of load is generated on the tilling blade 12.

In order to prevent this, the soil crushing device 30 is provided in the lower portion of the front horizontal frame 24 in front of the upper side plate 20 so as to finely crush the tilled soil and accumulate between the blade tip trace 14 and the scattering plate 21. At the same time, the soil is quickly moved in the rotational direction and a part is blocked by the shredding blade 37 to reduce the load on the tilling blade 12.

That is, the drive motor 37 constituting the soil crushing device 30 at the same time as the tilling blade 12 is rotated is rotated in the opposite direction of the tilling blade 12. Accordingly, as the rotating shaft 35 between the fixed brackets 32 and 33 fixed to correspond to the lower portion of the front horizontal frame 24 of the upper side plate 20 is rotated, a plurality of shredding blades 37 are rotated. Cultivated soil is crushed finely. The shredding blade 39 may be configured in various types such as circular, polygonal and plate shapes.

Meanwhile, the contents shown in FIGS. 8 and 9 relate to a soil blocking device 40 for cutting the amount of soil tilled by the tilling blade 12 and supplied to the scattering plate 21. The explanation is as follows.

First, as the tiller blade 12 rotates in a counterclockwise direction while the rotor is moved along the traveling direction of the tractor, some of the soil tilled by the tiller blade 12 is blocked about 60% to 70%, About 30% to 40% is moved along the scattering plate 21, so that the load on the tilling blade 12 is reduced.

That is, about 60 to 70% of the soil cultivated by the rotation of the tiller blade 12 to the blocking plate 44 below the lower plate 42 fastened to the lower portion of the front horizontal frame 24 of the upper side plate 20 is fixed. Is blocked.

10 and 11 are related to the front soil crushing device 50 for crushing the soil tilled by the tilling blade 12 and supplied to the non-swash plate 21, and an operation state thereof. In detail, some of the soil cultivated by the tiller blade 12 is rotated by the tiller blade 12 while the rotorbait moves along the traveling direction of the tractor. Blocking and crushing is moved along the scattering plate 21 to reduce the rotational load applied to the tilling blade (12).

That is, the soil is crushed by the front blade 54 of the lower plate 52, which is fastened and fixed to the lower front horizontal frame 24 of the upper side plate 20, some of the load is reduced to reduce the load.

At this time, the front blade 54 is made to be inclined inward with respect to the lower portion of the lower plate 52, the lower end portion of the soil in close proximity to the blade end trajectory 14, the end of the tilling blade 12 is drawn during rotation of the soil Crushing becomes easy.

Meanwhile, the contents shown in FIGS. 12 to 14 relate to before and after soil crushing devices 60 and 70 for crushing the soil tilled by the tilling blade 12 and supplied to the non-swash plate 21. The operation state for this is as follows.

That is, as the rotor blade moves along the traveling direction of the tractor, the tilling blade 12 rotates in the counterclockwise direction, so that some of the soil tilled by the tilling blade 12 is blocked by the front soil shredding device 60. It is crushed and moved along the scattering plate 21, so that the load on the tilling blade 12 is reduced.

At the same time, as the secondary soil is crushed by the rear soil crusher 70 and supplied in the traveling direction, the load applied to the tilling blade 12 is reduced.

To explain this schematically, the soil is crushed finely by the front blade 64 below the lower plate 62 fastened to the lower portion of the front horizontal frame 24 of the upper side plate 20 and scattered along the tilling blade 12. Supplied to the plate 21, part is blocked by the front blade 64 will reduce the load.

As such, the primary crushed soil supplied to the scattering plate 21 is moved along the scattering plate 21, and a plurality of rear blades 74 provided on the front of the rear horizontal frame 72 behind the upper side plate 20. By secondary crushing and falling in the direction of travel is reduced the rotational load.

1 is a perspective view schematically showing a conventional rotorbator structure.

FIG. 2 is a side view of main parts of FIG. 1. FIG.

3 is a side view of the main portion of the operating state of FIG.

Figure 4 is a perspective view showing a first embodiment of a fuel-saving rotor according to the present invention.

5 is a front sectional view of the main part of FIG. 4;

FIG. 6 is a side view of main parts of FIG. 4. FIG.

7 is a side view of the main portion of the operating state of FIG.

Figure 8 is a front configuration diagram showing a second embodiment of a rotor-saving fuel according to the present invention.

9 is a side view of the main portion of the operating state of FIG. 8;

10 is a front configuration diagram showing a third embodiment of a rotor-saving fuel according to the present invention.

FIG. 11 is a side configuration diagram of an operation state main part of FIG. 10; FIG.

12 is a front configuration diagram showing a fourth embodiment of a rotor saver according to the present invention in which fuel is saved.

FIG. 13 is a sectional view showing the main parts of FIG. 12.

14 is a side view of the main portion of the operating state of FIG.

<Description of the symbols for the main parts of the drawings>

10: tillage axis 12: tillage blade

14: blade tip trace 16: flange

20: upper side plate 21: scattering plate

24: horizontal front frame 30: earth shredding device

32,33: fixing bracket 35: rotating shaft

37: drive motor 39: shredding blade

40: earth blocker 42: lower plate

44: blocking plate 50,60: front soil shredding device

52,62: lower plate 54,64: front blade

70: rear soil crusher 72: rear horizontal frame

74: rear blade

Claims (8)

A plurality of tilling blades 12 are provided as flanges 16 on the tilling shaft 10 that is rotated by the power of the tractor, and is provided below the blade tip trace 14 and the upper side plate 20 of the tilling blade 12. In the rotor configured to maintain the proper spacing with the scattering plate 21, Is provided with a soil crushing device 30 for crushing the soil tilled by the tilling blade 12 in the lower portion of the front horizontal frame 24 provided in front of the upper side plate, The soil crushing device 30 A fixing bracket (32) (33) fixed to correspond to a lower portion of the front horizontal frame (24) of the upper side plate (20); A rotation shaft 35 rotatably arranged at both ends between the fixing brackets 32 and 33; A driving motor 37 connected to one end of the rotating shaft 35 to rotate the rotating shaft 35; The rotor is provided with maintaining a uniform interval on the outer periphery of the rotary shaft 35 is composed of a plurality of shredding blades (39) for shredding the soil tilled by the tilling blade (12) . The rotor of claim 1, wherein the shredding blade (39) has an end portion installed close to the blade tip trajectory (14). A plurality of tilling blades 12 are provided as flanges 16 on the tilling shaft 10 that is rotated by the power of the tractor, and is provided below the blade tip trace 14 and the upper side plate 20 of the tilling blade 12. In the rotor configured to maintain the proper spacing with the scattering plate 21, Is provided with a soil blocking device 40 for blocking the soil tilled by the tilling blade 12 in the lower front horizontal frame 24 provided in front of the upper side plate,  The soil blocking device 40 includes a plurality of lower plates 42 fastened to the lower portion of the front horizontal frame 24 of the upper side plate 20; The rotor is reduced fuel, characterized in that consisting of the blocking plate 44, each fixed to protrude downward to the lower plate (42). The method of claim 3, wherein the blocking plate 44 Rotorbatter is a fuel-saving, characterized in that fixed to the lower portion of the lower plate 42 inclined to the inside in a vertical direction, the lower end portion is adjacent to the blade tip trajectory (14). A plurality of tilling blades 12 are provided as flanges 16 on the tilling shaft 10 that is rotated by the power of the tractor, and is provided below the blade tip trace 14 and the upper side plate 20 of the tilling blade 12. In the rotor configured to maintain the proper spacing with the scattering plate 21, A front soil crushing device 50 is provided at the bottom of the front horizontal frame 24 provided in front of the upper side plate 20 for crushing the soil tilled by the tilling blade 12. The front soil crusher 50 A plurality of lower plates 52 fastened and fixed to a lower portion of the front horizontal frame 24 of the upper side plate 20; The rotor is reduced fuel, characterized in that consisting of the front blades (54) fixed to protrude downward by maintaining equal intervals on the lower plate (52). The method of claim 5, wherein the front blade 54 is Rotorbator is fuel-saving, characterized in that the lower plate 52 is made to be inclined inward with a vertical center, the lower end portion is installed in close proximity to the blade tip trace (14). A plurality of tilling blades 12 are provided as flanges 16 on the tilling shaft 10 that is rotated by the power of the tractor, and is provided below the blade tip trace 14 and the upper side plate 20 of the tilling blade 12. In the rotor configured to maintain the proper spacing with the scattering plate 21, Front and rear soil crusher 60 for crushing the soil tilled by the tilling blade 12 in the lower front horizontal frame 24 and the rear horizontal frame 72 provided in front of the upper side plate 20 ( 70) each, The front soil crusher 60 A plurality of lower plates 62 fastened and fixed to a lower portion of the front horizontal frame 24 of the upper side plate 20; Consists of the front blades 64 fixed to each of the lower plate 62 to protrude downwards at equal intervals, The rear soil crusher 70 The rotor-saving rotor, characterized in that consisting of the rear blades (74) provided to protrude downward by maintaining equal intervals in front of the rear horizontal frame (72). The rotor blade of claim 7, wherein the front blade (64) and the rear blade (74) have a lower end installed in close proximity to the blade tip trace (14).

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