JPH06319330A - Fertilizer applicator - Google Patents

Abstract

PURPOSE:To uniformize the distribution of an applied fertilizer within an effective scattering range by making a spinner cover perform the reciprocating and rocking motion around a spinner shaft at the rotational center of a spinner disk. CONSTITUTION:A spinner cover 5 is made to perform reciprocating and rocking motion around a spinner shaft 13 at the rotational center of a spinner disk 3 by an electric motor 25 and both ends (5a) and (5b) of the spinner cover are alternately admitted into both ends of a fertilizer scattering region (3) in a neutral state. Thereby, the width of effective application thereof is enlarged as compared with that of the maximum application of the fertilizer to improve the dispersion state of the applied fertilizer.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fertilizer spreader which is mounted on the rear part of a tractor and which drives a spinner disc to rotate to disperse and disperse fertilizer.

[0002]

2. Description of the Related Art First, the structure of a fertilizer sprayer of this type,
The spraying action will be described. FIG. 1 is a diagram showing a state in which a fertilizer sprayer S is attached to the rear part of the tractor T to perform fertilizer spraying, FIG. 2 is a sectional view of the fertilizer sprayer S, and FIG. It is a figure for demonstrating the spraying action of fertilizer. Mainly in FIG. 2, a fertilizer hopper 1 for filling granular fertilizer M is fixedly supported by a support frame 2, and a spinner disc 3 is rotatable directly below a bottom plate portion 1a of the fertilizer hopper 1 in a horizontal plane. It is installed in. A plurality of spinner blades 4 are attached to the upper surface of the spinner disk 3 along the radial direction (see FIG. 3). Further, in the non-scattering area of fertilizer on the outside of the spinner disk 3, a spinner cover 5 in which the plate material is bent in an arc shape is arranged, and thereby, the fertilizer scattering area on the outer peripheral portion of the spinner disk 3 is scattered. Opening 6 (see Figure 3)
Is formed. The spinner cover 5 has a function of assisting the spraying direction of fertilizer. In general, when the term “spinner cover” is used, the spinner disk 3 is arranged directly above the spinner disk 3 with a predetermined space therebetween and functions as a top plate for the spinner disk 3. However, in the context of the present invention, since the disk-shaped member does not perform a special function, in order to simplify the explanation, the term "spinner cover" is used above. Use as. Also, fertilizer hopper 1
A shutter plate 7 is provided in close contact with the lower surface of the bottom plate portion 1a. The shutter plate 7 is connected to a shutter opening / closing lever 9 via a shutter opening / closing rod 8.
By operating this lever 9, the bottom plate portion 1a of the fertilizer hopper 1
When the fertilizer drop port 11 provided on the shutter plate 7 and the fertilizer drop port 12 provided on the shutter plate 7 are matched, the fertilizer M in the fertilizer hopper 1 is driven and rotated through the fertilizer drop ports 11 and 12. The spinner disc 3 is dropped onto the rotating spinner disc 3, and the centrifugal force of the spinner disc 3 and the reaction force received from the spinner blades 4 attached to the spinner disc 3 scatter backward in the traveling direction P of the tractor T. It In addition, the spinner shaft 13 provided at the center of rotation of the spinner disk 3
Is driven and rotated by the power of the tractor T transmitted to the input shaft 15 through the universal joint 14, and the upper end portion of the spinner shaft 13 has entered the bottom portion of the fertilizer hopper 1 and the stirring agitator at this portion. 16
Is installed. In FIG. 2, 17 denotes a bevel gear pair for transmitting a rotational force from the input shaft 15 to the spinner shaft 13, and 18 denotes this bevel gear pair 17
Shows the gearbox housing the.

Next, referring to FIG. 3, the fertilizer spraying action of the fertilizer sprayer S will be described. Grains Ma of the fertilizer M that have dropped onto the spinner disc 3 from the fertilizer drop opening 11 provided in the bottom plate portion 1a of the fertilizer hopper 1 are subjected to a centrifugal force by the rotation action of the spinner disc 3 and the spinner circle It receives frictional force from the plate 3 and is moved along the spinner blades 4 on the spinner disk 3 to the throwing point B which is the outer peripheral edge of the spinner disk 3. After that, the particles Ma of the fertilizer M are thrown at the throwing point B in the direction of the resultant force F of the centrifugal force F ₁ due to the rotation of the spinner disk 3 and the reaction force F ₂ received from the spinner blade 4. In FIG. 3, Q
Indicates the rotation direction of the spinner disc 3.

Countless fertilizer grains Ma dropped from the fertilizer drop opening 11 of the fertilizer hopper 1 onto the spinner disc 3 have the same particle size and specific gravity, and the spinner disc 3
If the dropping conditions such as the falling position and the falling speed on the top are the same, the rotation angle α of the spinner disk 3 from the falling point A of the fertilizer grain Ma to the throwing point B is constant, and The fertilizer particles Ma will be thrown from the throwing point B. However, in reality, variations in the particle size and specific gravity of the fertilizer grains Ma, the fertilizer grains M with respect to the spinner disk 3, and the like.
Due mainly to the variation of the falling position of a, etc., the throwing point of the fertilizer grain Ma on the outer peripheral edge of the spinner disk 3 varies in the range from “B ′” to “B ″”. The range from the throwing point B ′ to the same point B ″ is the scattering area of the fertilizer M, and the angle β formed in this scattering area of the fertilizer becomes the scattering angle.
Are disposed in the fertilizer non-scattering region except the fertilizer scattering region on the outer peripheral portion of the spinner disk 3 to control the spraying direction of the fertilizer M in a supplementary manner. Then, the particles Ma of the fertilizer M dropped from the fertilizer drop port 11 onto the spinner disk 3 are scattered rearward while being irregularly distributed within the range of the scattering angle β. Therefore, when the amount of sprinkled fertilizer M is examined, the distribution is generally as shown in FIG. 4, and the distribution at the work center (C) corresponds to the probability of the dropping point of fertilizer particles Ma. Since the amount becomes maximum and the amount of spraying gradually decreases toward both ends, the effective spraying width (W ₂ ) is narrower than the maximum spraying width (W ₁ ), and moreover, it is dark in the work center (C). There was a problem that mountains were formed and the distribution of sprayed fertilizer was uneven.

[0005]

In view of the problems of the above-mentioned conventional fertilizer spraying machine, the present invention focuses on a spinner cover which controls the spraying direction of fertilizer in a supplementary manner, and swings the spinner cover. It is an object to make the distribution of the sprayed fertilizer uniform and increase the spraying accuracy by moving it or connecting the damper plates to both ends thereof in a rotatable manner.

[0006]

In order to solve this problem, the first means adopted by the present invention is that a spinner disk is located directly below the bottom plate of a fertilizer hopper filled with fertilizer with the spinner shaft as the center. It is rotatably arranged in a horizontal plane, and an arc-shaped spinner cover is arranged in a non-scattering area of fertilizer outside the outer peripheral portion of the spinner disk, and scattered in the fertilizer scattering area of the outer peripheral portion of the spinner disk. An opening is formed, the spinner disc is driven and rotated, and the fertilizer dropped on the spinner disc from the fertilizer drop opening provided in the bottom plate portion of the fertilizer hopper is rotated by the spinner disc. In a fertilizer spreader used by being mounted on a tractor configured to spray fertilizer by being thrown from a scattering opening, the spinner cover is mounted on the spinner shaft by a driving means. To back and forth oscillating motion is that which is configured to penetrate the end portions of the spinner cover alternately at both ends of the manure scattering area at neutral state.
In addition, the second means, in the same fertilizer spreader,
A damper plate is rotatably connected to both ends of the spinner cover in a horizontal plane, and the damper plates are reciprocally rotated in synchronization with each other by a driving means to move the damper plates to a fertilizer scattering area in a neutral state. That is, it is configured so as to alternately enter both ends.

[0007]

In the former case, when the spinner cover is reciprocally swung about the spinner shaft, which is the center of rotation of the spinner disc, by the drive means, both ends of the spinner cover move in the fertilizer scattering area when neutral. The fertilizer scattering angle that enters the both ends alternately changes the fertilizer scattering angle formed in this fertilizer scattering area, and the fertilizer scattering angle is changed by the swing angle of the spinner cover compared to when the spinner cover is fixed. Get smaller. As a result, the amount of fertilizer sprayed at both ends of the fertilizer spray area is significantly smaller than when the spinner cover is fixed, and its effective spread width is wider than the maximum spread width of fertilizer, and at the same time it is effective. The distribution of sprayed fertilizer in the scattering area is also uniform. Also in the latter case, when the damper plates are reciprocally rotated in synchronization with each other by the drive means, the damper plates alternately invade both ends of the fertilizer scattering area at the neutral time, and the fertilizer scattering angle changes momentarily. Compared with the case where the spinner cover is fixed, the fertilizer scattering angle becomes smaller by an angle corresponding to the rotation angle of the damper plate.

[0008]

EXAMPLES The present invention will be described in more detail below with reference to examples. The same parts as those described in the above-mentioned "Prior Art" will be denoted by the same reference numerals, and repeated description will be avoided, and only characteristic parts of the present invention will be described. First, the invention described in claim 1 will be described. Figure 5
FIG. 6 is a plan view of the spinner disc 3 and the spinner cover 5 in a state where the swinging spinner cover 5 passes through the neutral position. In FIG. 5, the spinner cover 5 arranged in the non-scattering area outside the spinner disk 3 is
It is swingable around the spinner shaft 13 and supported by the support frame 2. A guide roller stay 21 is fixed to the outer peripheral surface of the spinner cover 5 along the radial direction of the spinner disc 3. A guide roller 23 is rotatably supported at the tip of the guide roller stay 21 via a connecting pin 22. An electric motor 25 is fixed to the base frame 24, and one end of a crank arm 27 is integrally attached to an output shaft 26 of the electric motor 25. The base frame 2
4, one end portion of the slide link 28 is connected to a portion of the electric motor 25 at a predetermined distance from the electric motor 25, and both end portions of the connecting link 31 are connected to the electric motor 25 via connecting pins 32 and 33. It is connected to the tip of the crank arm 27 and the center of the slide link 28. Further, an elongated hole 28a is formed from the central portion to the tip of the slide link 28, and the guide roller 23 is fitted into the elongated hole 28a. The base frame 24 is fixed at a proper position on the support frame 2. Therefore, when the output shaft 26 of the electric motor 25 is continuously rotated, the crank arm 27 rotates integrally with the output shaft 26, and the slide link 28 reciprocally rotates about the fulcrum pin 29 within a predetermined angle. I do. In this way, when the slide link 28 reciprocally rotates,
Since the guide roller 23 is fitted in the elongated hole 28a provided from the center to the tip, the spinner cover 5 reciprocally swings about the spinner shaft 13 at a predetermined swing angle. To do.

Next, the operation of the fertilizer sprayer in which the spinner cover 5 makes a reciprocating swing motion will be described with reference to FIGS. The electric motor 25 is continuously rotating, the spinner cover 5 is reciprocally rocked through the link mechanism, and the fertilizer M passing through the fertilizer dropping port 11 of the fertilizer hopper 1 is continuously rotating. The spinner disk 3 has fallen onto the disk 3 and is scattered rearward by the rotating action of the spinner disk 3. FIG. 5 shows a state in which the spinner cover 5 passes through the neutral position, the scattering angle (β) of the fertilizer M is maximized, and the fertilizer hopper 1 drops from the fertilizer drop opening 11 onto the spinner disc 3. The fertilizer M is sprayed backward while forming a scattering angle β.
Therefore, the distribution of the sprayed fertilizer when the spinner cover 5 is in the neutral position is the same as when the spinner cover 5 is fixed, and is as shown in FIG.

Here, assuming that the total swing angle of the spinner cover 5 is (2γ), in FIG. 6, the spinner cover 5 swings from the neutral position by an angle (γ) and reaches one swing end. One end 5a of the spinner cover 5 in the state
Is penetrated by one rocking angle (γ) into one end of the fertilizer splash area at the time of neutrality forming the above-mentioned splash angle β, and the other end 5b is different from the fertilizer splash area at the time of neutrality. The swing angle (γ) is retracted. Therefore, the scattering angle (β ′) of the fertilizer in this state is the end 5 of the spinner cover 5.
a is smaller than the initial splash angle (β) by the swing angle (γ) that has entered the fertilizer splash area at neutral, and among the splash angles that change momentarily by the swing of the spinner cover 5. The smallest one. As a result, the fertilizer scattering area is scraped on one end 5a side of the spinner cover 5 as compared with the neutral time shown in FIG. 4, but the other end 5b side remains unchanged. The distribution of the applied fertilizer in the state shown in FIG. 6 is as shown in FIG. Therefore, one end of the effective spread width of fertilizer (W ₂ ') starts from one end of the maximum spread width of fertilizer (W ₁ ').

Thus, when the spinner cover 5 swings from the neutral position toward one swing end, the scattering angle of fertilizer becomes smaller every moment and becomes the smallest at the swinging end (scattering angle β '). . As shown in FIG. 6, when the spinner cover 5 reaches one of the swing ends, the spinner cover 5 swings in the opposite direction until the neutral position shown in FIG. 7 is reached. Becomes bigger every moment. When the spinner cover 5 further swings in the same direction beyond the neutral position shown in FIG. 7, one end 5a of the spinner cover 5 forms the scattering angle β, contrary to the above phenomenon. While retreating from the fertilizer dispersion area at the time of neutrality, the other end 5b enters the other end of the fertilizer dispersion area at the time of neutrality. When the spinner cover 5 reaches the other swing end, as shown in FIG. 8, the fertilizer scattering angle (β ″) in this state is such that the end 5b of the spinner cover 5 enters the fertilizer scattering area when the neutral position. As compared with the initial scattering angle (β), the scattering range of the fertilizer is smaller than that of the initial scattering angle (β). The end 5a side remains the same, but the other end 5b side is scraped off, so that the distribution of the applied fertilizer in the state shown in Fig. 8 is as shown in Fig. 10. In this way, The other end of the effective fertilizer application width (W ₂ ') ends with the other end of the maximum fertilizer application width (W ₁ ').

In this way, when the spinner cover 5 arranged in the non-scattering area of fertilizer on the outer peripheral portion of the spinner disk 3 is reciprocally rocked at a predetermined rocking angle, the spinner cover 5 is rotated. Both end portions 5a and 5b alternately intrude into both end portions of the fertilizer scattering area at the time of neutrality, the scattering angle of the fertilizer changes momentarily, and the amount of fertilizer sprayed at both ends of the fertilizer scattering area fixes the spinner cover 5. Compared with the case of doing, it becomes significantly less. This results in an effective spread width (W ₂ ") compared to the maximum spread width (W ₁ "), as shown in FIG.
As the fertilizer distribution becomes wider, the fertilizer distribution in the effective scattering area becomes uniform, and the distribution state of the sprayed fertilizer is greatly improved.

Further, as shown in FIG. 12, in the above embodiment, each link mechanism for converting the rotational movement of the output shaft 26 of the electric motor 25 into the reciprocating swing movement of the spinner cover 5 is constructed. Of the link members, a plurality of connecting holes 34a for connecting one end of the connecting link 31
34b and 34c are provided on the slide link 28,
When the connecting position of the connecting link 31 with respect to the slide link 28 can be changed, the swing angle of the spinner cover 5 about the spinner shaft 13 can be adjusted. In this example, the connection holes 34a, 34b, 34c close to the fulcrum pin 29 are provided.
The larger is selected, the larger the swing angle of the spinner cover 5 becomes. In this way, if the swing angle of the spinner cover 5 can be changed, the spread width of fertilizer can be adjusted, and the spread work of fertilizer according to the size of the field becomes possible.

FIG. 13 shows an example of a circuit for operating the electric motor 25 described above.
A DC motor is used as the power source, a tractor battery is used as the power source 35, and a power switch 36 is provided. When the variable resistor 37 is provided in this circuit, the rotation speed of the electric motor 25 can be changed by changing the resistance value. As a result, the number of swings of the spinner cover 5 per unit time can be changed, and the number of swings of the spinner cover 5 can be adapted to the working speed of the tractor.

In the above embodiment, an electric motor is used as a drive source for swinging the spinner cover 5, but the one shown in FIG. 14 uses the power extracted from the input shaft 15 to crank the arm. This is an example in which 41 is rotated and the continuous rotation of the crank arm 41 is converted into a reciprocating swing motion of the spinner cover 5 via a link mechanism. That is, the crank arm 41 is attached to the upper end of the vertical axis 42.
Is attached to the bevel gear 44,
It is transmitted to the vertical axis 42 via 45. On the other hand, a chain 48 is hung on a chain gear 46 mounted on the horizontal shaft 43 and a chain gear 47 mounted on the input shaft 15 so that the rotation of the input shaft 15 is transmitted to the horizontal shaft 43. ing.

Further, when the electric motor 25 is used as a drive source of the spinner cover 5, the electric motor 25 is stopped during the swing of the spinner cover 5, and the spinner cover 5 is stopped at a specific position. Then, it is possible to apply the powder to the end of the field or laterally to the tree trunk D or the like in the orchard as shown in FIG.

Next, the invention described in claim 2 will be described. FIG. 16 shows an embodiment thereof, in which damper plates 51 and 52 are rotatably connected to both ends of a spinner cover 5 fixed to the support frame 2 via connecting pins 53 in a horizontal plane. Has been done. Output shaft 26 of electric motor 25 fixed to base frame 24
Has a crank arm 54 integrally attached thereto,
Both ends of the connecting links 55 and 56 are connected to the tip end portion of the crank arm 54 and the arm portions 51a and 52a of the damper plates 51 and 52 via connecting pins 57, respectively. Therefore, when the crank arm 54 is continuously rotated by the electric motor 25, the damper plates 51, 52
Are synchronized with each other about the connecting pin 53 and the angle (γ)
Therefore, the damper plates 51 and 52 alternately invade both ends of the fertilizer dispersion area forming the maximum dispersion angle (β) at the neutral position of the damper plates 51 and 52, and the dispersion angle of the fertilizer is increased. It changes every moment, and an operation similar to that of the above-mentioned invention of claim 1 is achieved.

[0018]

According to the present invention, in the fertilizer sprayer, the spinner cover is reciprocally oscillated around the spinner shaft which is the center of rotation of the spinner disk by the driving means so that both ends of the spinner cover are neutral. By alternately intruding into both ends of the fertilizer scattering area in, the fertilizer scattering angle becomes smaller by the swing angle of the spinner cover than in the case where the spinner cover is fixed. As a result, the amount of fertilizer sprayed at both ends of the fertilizer splash area is
Compared to the case where the spinner cover is fixed, it is significantly less, the effective spread width is wider than the maximum spread width of the fertilizer, and the distribution of the spread fertilizer in the effective scattering area is also uniform, which spreads the fertilizer. The condition is greatly improved.
Also, even if the damper plates are rotatably connected to both ends of the fixed spinner cover and the damper plates are reciprocally rotated in synchronization with each other by the driving means, substantially the same operation as described above is achieved. To be done.

[Brief description of drawings]

FIG. 1 is equipped with a fertilizer spreader S at the rear of the tractor T,
It is a figure which shows the state which is performing fertilizer application.

FIG. 2 is a sectional view of a fertilizer spreader S.

FIG. 3 is a plan view of a spinner disk 3 and a spinner cover 5 for explaining the spraying action of fertilizer.

FIG. 4 is a diagram showing a distribution state of sprayed fertilizer when the spinner cover 5 is fixed (or when the swinging spinner cover 5 passes through the neutral position).

FIG. 5 is a plan view of the spinner disc 3 and the spinner cover 5 in a state where the swinging spinner cover 5 passes through the neutral position.

FIG. 6 is a plan view of the spinner disc 3 and the spinner cover 5 in a state where the swinging spinner cover 5 reaches one swing end.

FIG. 7 is a plan view of the spinner disk 3 and the spinner cover 5 in a state where the swinging spinner cover 5 passes through the neutral position in the direction opposite to the above.

FIG. 8 is a plan view of the spinner disc 3 and the spinner cover 5 in a state where the swinging spinner cover 5 reaches the other swing end.

FIG. 9 is a diagram showing a distribution state of sprayed fertilizer in a state where the spinner cover 5 reaches one swing end.

FIG. 10 is a diagram showing a distribution state of sprayed fertilizer in a state where the spinner cover 5 reaches the other swing end.

FIG. 11 is a diagram showing a distribution state of sprayed fertilizer when the spinner cover 5 is swung.

FIG. 12 is a plan view of a spinner disc 3 and a spinner cover 5 whose swing angle is variable.

FIG. 13 is a circuit diagram for operating the electric motor 25.

FIG. 14 is a view showing another drive mechanism for continuously rotating the crank arm 41.

FIG. 15 is a plan view showing a state in which fertilizer is applied laterally.

FIG. 16: Damper plates 5 on both ends of the spinner cover 5
It is a top view which shows the state which connected 1,52.

[Explanation of symbols]

 M: fertilizer S: fertilizer spreader T: tractor 1: fertilizer hopper 3: spinner disc 5: spinner cover 11: fertilizer drop opening 13: spinner shaft 25: electric motor (driving means) 51, 52: damper plate

Claims (2)

[Claims] 1. A spinner disc is rotatably arranged in a horizontal plane about a spinner axis directly below a bottom plate of a fertilizer hopper filled with fertilizer, and a fertilizer non-scattering region outside the spinner disc. In, the spinner cover is provided by bending the plate material in an arc shape, a scattering opening is formed in the fertilizer scattering area of the outer peripheral portion of the spinner disk, and the spinner disk is driven to rotate, A fertilizer spreader having a configuration in which fertilizer dropped on a spinner disc from a fertilizer drop opening provided in the bottom plate portion of the fertilizer hopper is thrown from the scattering opening by the rotation action of the spinner disc to disperse fertilizer is driven. The spinner cover is reciprocally oscillated about the spinner shaft by means to move both ends of the spinner cover to both ends of the fertilizer scattering area at the neutral time. The fertilizer sprayer is characterized in that it is configured so as to alternately enter the parts. 2. A spinner disc is rotatably arranged in a horizontal plane about a spinner axis directly below a bottom plate of a fertilizer hopper filled with fertilizer, and a fertilizer non-scattering region outside the spinner disc. In, the spinner cover is provided by bending the plate material in an arc shape, a scattering opening is formed in the fertilizer scattering area of the outer peripheral portion of the spinner disk, and the spinner disk is driven to rotate, In the fertilizer spreader having a structure for spraying fertilizer by dropping fertilizer dropped on a spinner disc from a fertilizer drop opening provided on the bottom plate portion of the fertilizer hopper by the rotating action of the spinner disc to spray fertilizer, A damper plate is rotatably connected to both ends of the spinner cover in a horizontal plane, and the damper plates are reciprocally rotated in synchronization with each other by a driving means. The fertilizer spreader is characterized in that the damper plates are alternately inserted into both ends of the fertilizer scattering area at the time of neutrality.