JP5248533B2 - Local fertilization method and fertilizer nozzle - Google Patents

Description

The present invention relates to a local fertilization method and a fertilizer nozzle that spray fertilizer continuously to a set depth portion inside soft soil immediately after rotary tilling of soil .

  Local fertilization, which is one of the fertilizer application methods for cocoons, applies fertilizer only to the roots of the crops planted in the cocoons, and the crops have good efficiency in absorbing fertilizers and can reduce the amount of fertilizer applied. There are advantages.

When local fertilization is performed, the soil is softened by a rotary tiller, and then straw is formed on the soil. Subsequently, a fertilizer groove is formed at a predetermined depth position of the ridge, and fertilizer is sprayed on the bottom of the fertilizer groove. In normal cases, the above-described cocoon forming operation and the fertilizing operation are performed almost simultaneously. Hereinafter, simultaneous simultaneous application of rotary tilling work and work of locally applying fertilizer by forming straw on the soil loosened by the tilling work will be referred to as “simultaneous local fertilizing work”. As shown in FIG. 1, an apparatus in which a fertilizer application C is attached to a work machine W pulled by a tractor T is known as an apparatus for performing simultaneous local fertilization work. The tractor T advances along the longitudinal direction P ₁ of the rod R. Then, the fertilizer application device C feeds the fertilizer S accommodated in the fertilizer hopper (in the case of this embodiment, two fertilizer hoppers 6) by a predetermined amount by the feeding device V built in each fertilizer hopper 6, R (in this case, ridges R 'in the middle of forming) was dropped from the pipe-shaped fertilization nozzles N ₁ inserted in, the fertilization groove G ₁ which is formed by the fertilization nozzle N ₁ is configured to perform local fertilization. As shown in FIGS. 2 and 4, the feeding device V built in the fertilizer hopper 6 on one side is operated by a feeding motor M attached to the fertilizer hopper 6. Then, the driving force of the feeding motor M is transmitted to the feeding device V built in the fertilizer hopper 6 on the other side via the connecting shaft 20, and the feeding device V is operated. Thereby, the two feeding devices V built in each fertilizer hopper 6 are operated simultaneously.

In the simultaneous local fertilization work, when the work machine W reaches the heel end, the work machine W is lifted up from the soil and turned, and after the turn, the work machine W is moved in the width direction P ₂ of the heel R, The work implement W is lowered onto the soil (unstanding portion R ″) and the tractor T is advanced, thereby performing local fertilization while forming the ridge R on the unstanding portion R ″ (see FIG. 7).

With reference to FIG. 26, an operation when local fertilization is performed on the rod R ′ in the middle of molding by the conventional fertilization nozzle N ′ will be described. When the fertilizer nozzle N ′ is inserted into the rod R ′ in the middle of forming and advanced, the soil that comes into contact with the lower end of the fertilizer nozzle N ′ (the portion inserted into the rod R ′) is pushed out and removed, and the fertilizer nozzle A fertilizer groove G ′ is formed immediately after N ′. The fertilizer S dropped from the fertilizer hopper 6 is discharged from the lower end surface (fertilizer discharge port 51) of the fertilizer application nozzle N ′ and is sprayed on the bottom 52 of the fertilizer groove G ′. The fertilizer groove G ′ immediately after the fertilizer S is sprayed loses the support of the fertilizer nozzle N ′ as the fertilizer nozzle N ′ moves forward, and each ridge forming disposed on both sides of the fertilizer nozzle N ′. The ridge R ′ is formed while being backfilled by the soils 53 and 54 that are pressed against the plates F _{1 to} F ₃ (see FIG. 7) and collapse to the inside. Then, the upper surface of the ridge R ′ is smoothed by the smoothing plate 4 disposed behind the fertilization nozzle N ′. As a result of the above, as soon as the ridge R is formed in the soil, local fertilization is performed at a position (deep layer portion) of the predetermined depth D of the ridge R (simultaneous local fertilization work).

  In the case of the conventional fertilization nozzle N ', the fertilizer discharge port 51 of the fertilization nozzle N' inserted into the ridge R 'in the middle of molding is disposed immediately above the bottom 52 of the fertilization groove G'. Further, the lower end portion of the conventional fertilization nozzle N 'is only slightly cut off at an angle. For this reason, the space Q ′ formed between the fertilizer discharge port 51 of the fertilization nozzle N ′ and the bottom 52 of the fertilization groove G ′ is narrow, and the fertilizer discharge port 51 of the fertilization nozzle N ′ is directed rearward. Since it is provided at an angle, there is a risk that the soil 53, 54 to be backfilled will enter the lower end of the fertilization nozzle N 'in the groove. Further, when the fertilizer nozzle N ′ is inserted into the soil at the start of the work, the soil 53 and 54 can easily enter the fertilizer discharge port 51, and when the tractor T is stopped, the work machine W is slightly retracted. In this case, the soils 53 and 54 are particularly likely to enter. When the soil 53 and 54 that has entered the lower end of the fertilizer application nozzle N ′ is condensed, the fertilizer discharge port 51 is blocked, and it becomes extremely difficult to spread the fertilizer S on the bottom 52 of the fertilizer groove G ′.

  In order to avoid the above-described problems, a technique is disclosed in which air is passed through the fertilizer application nozzle N ′ to remove clogging (see, for example, Patent Document 1). However, the configuration of the fertilizer nozzle N ′ becomes complicated.

JP 2004-180613 A

  An object of the present invention is to prevent soil from being clogged at a fertilizer discharge port of a fertilizer application nozzle.

According to a first aspect of the present invention for solving the above-described problem, the working machine attached to the rear portion of the tractor includes a rotary tiller and a fertilizer, and is scattered and landed rearward by the rotary tiller . In the state where the lower end of the pipe-shaped fertilizer nozzle that constitutes the fertilizer is inserted into the later stabilized softened soft soil, the work implement moves forward so that the bulge immediately after rotary tilling of the soil is performed. A local fertilization method for continuously applying fertilizer to a set depth portion inside soft soil, wherein the fertilization nozzle is a lower end portion that is a front side with respect to a traveling direction of the tractor in a pipe-shaped nozzle body to, mounted together in a state where Sakumizo member extending substantially downward, the fertilizer discharge port of the nozzle body of the lower end opening is an arranged structure on the upper end portion of the Sakumizo member, the fertilizer discharge Fertilizer discharged from, while being guided by the Sakumizo member, the Sakumizo through the space portion that is temporarily formed at the back by the progression of the member, the bottom of fertilization groove formed by the Sakumizo member The fertilizer is locally applied to the bottom, and after a little time has elapsed since the fertilizer reaches the bottom of the fertilizer groove, the fertilizer is locally applied to the bottom due to the collapse of the side walls constituting the fertilizer groove. It is characterized in that fertilized fertilizer grooves are backfilled .

  In a rotary plowing work and a work (simultaneous local fertilization work) that simultaneously performs a fertilization work that performs local fertilization to a predetermined depth inside the soil that has been loosened by the work, Then, the work implement is lifted up and turned, and after the turn, the work implement is lowered onto the soil and the next ridge forming work is performed. When lowering the work implement with respect to the soil, the lower end portion of the fertilizer application nozzle of the fertilizer application device is inserted with a predetermined forward speed. Then, since the groove forming member at the lower end of the fertilization nozzle exhibits a groove forming action, a fertilization groove is formed immediately after the drop guide portion.

The fertilizer discharge port of the fertilization nozzle of the invention of claim 1 is the lower end opening of the pipe-shaped nozzle body, and is the length of the groove forming member attached integrally to the lower end portion of the nozzle body so as to extend substantially downward. The position corresponding to the length of the groove forming member is disposed above the lower end of the groove forming member, and is higher than the length of the groove forming member compared to the fertilizer discharge port of the conventional fertilizer nozzle. Will be placed. As a result, the structure of the fertilizer nozzle and the above-described action when the fertilizer nozzle is lowered are combined, and the fertilizer discharge port of the fertilizer nozzle in the groove is disposed above the bottom of the fertilizer groove. . Therefore, when the work implement is turned at the heel end and then lowered, the fertilizer discharge port of the fertilizer application nozzle is not clogged with soil.
Even at the time of fertilization, the fertilizer groove by moving forward in a state where the groove forming member at the lower end of the fertilizer nozzle is inserted into the stabilized loosened soil after being scattered and landed backward by the rotary tiller. There is formed, the fertilizer outlet fertilization nozzles be disposed in the space section by the length upper of Sakumizo member than the bottom of the fertilization grooves, it has been isolated from the surrounding soil to form a fertilization groove The fertilizer discharged from the fertilizer discharge port is formed by the groove forming member through the space portion temporarily formed behind the groove forming member while being guided by the groove forming member. The fertilizer is locally applied to the bottom of the fertilizer groove. Here, in the case of a conventional fertilization nozzle, a fertilizer discharge port is provided at the lower end portion of the fertilization nozzle, and the speed at which the soil collapses is slower than the speed at which the fertilizer is sprayed, but the fertilizer discharge port is a fertilizer groove. There is a possibility that the fertilizer discharge port may be clogged with the soil falling down. However, the fertilizer outlet of the fertilizer application nozzle of the present invention is raised from the bottom of the fertilizer groove (in other words, a large space is formed between the fertilizer outlet of the fertilizer nozzle and the bottom of the fertilizer groove. Therefore, the fertilizer discharged from the fertilizer discharge port is dropped without being affected by the surrounding soil without clogging the fertilizer discharge port of the fertilizer application nozzle, and extends substantially downward to the lower end of the fertilizer nozzle. It is guided by the grooving member attached to, and sprayed on the bottom of the fertilizer groove. Immediately after that, the soil forming the side walls of the fertilizer groove collapses, and if it has a molded plate , the molded plate crushes the fertilizer groove, and the fertilizer groove to which fertilizer is dispersed is backfilled. Applied locally. As a result, the fertilizer discharge port of the fertilizer nozzle is not clogged even during fertilization.

According to a second aspect of the invention, there is provided a fertilization nozzle for carrying out the local fertilization method according to claim 1, wherein the fertilization nozzle, a front-side the traveling direction of the tractor in the pipe-shaped nozzle body with respect the lower end portion comprising, mounted together in a state where Sakumizo member extending substantially downward, the fertilizer discharge port of the nozzle body of the lower end opening is an arranged structure on the upper end portion of the Sakumizo member, The fertilizer discharged from the fertilizer discharge port is guided by the groove forming member and reaches the bottom of the fertilizer groove formed by the groove forming member.
Invention of Claim 2 grasped | ascertained and identified the local fertilization method of Claim 1 from the surface of the fertilization nozzle, and was formed by the groove forming member integrally provided in the front side of the lower end part of a nozzle main body. Fertilizer discharged from the fertilizer outlet of the nozzle body arranged at a position higher than the bottom of the fertilization groove is locally applied to the bottom of the fertilization groove, and then the soil on the side walls constituting the fertilization groove collapses, As a result, the fertilizer discharge port of the nozzle body has a unique effect that there is no possibility of clogging with surrounding soil.

The invention of claim 3 is based on the invention of claim 2 and is characterized in that the groove forming member is bent from the lower end portion of the nozzle body toward the back side of the nozzle body . According to the invention of claim 2, since the fertilization nozzle can be inserted in a substantially vertical posture with respect to the soil, it is easy to adjust the mounting position of the fertilization nozzle.

According to a fourth aspect of the present invention, on the premise of the second or third aspect, the length of the groove forming member is different in the width direction. According to the invention of claim 4 , upper and lower fertilization grooves having different depths are simultaneously formed, and local fertilization can be simultaneously performed at different depth positions in the left-right direction (width direction).

According to a fifth aspect of the invention, on the premise of the invention of the second or third aspect, the lower end portion of the groove forming member is wider than the outer diameter of the nozzle body. According to the invention of claim 5 , wide fertilization can be performed while forming wide fertilization grooves in the soil.

The invention of claim 6 is based on the invention of claim 5 and is characterized in that a lower end portion of the groove forming member is branched into a plurality of parts. According to the invention of claim 6 , local fertilization can be applied to each fertilization groove while forming a plurality of fertilization grooves in the soil at once.

  In the present invention, the groove forming member extends downward from the lower end portion on the front side of the nozzle body. For this reason, the fertilizer discharge port of the nozzle body in the groove is disposed above the bottom of the fertilization groove, so that the fertilizer discharge port of the fertilizer nozzle is not clogged with soil during fertilization or turning.

2 is a side view of a work machine W connected to a tractor T. FIG. It is a back view similarly. It is also a plan view. 1 is an overall perspective view of a work machine W viewed from the rear of a tractor T. FIG. It is a perspective view of fertilization nozzles N ₁ single first reference example. It is a side view of a portion a cutaway fertilization nozzles N ₁ in the state attached to fertilizing device C. (B) is a plan view showing the positional relationship between fertilization nozzle N ₁ and a ridge forming device B, and line X-X sectional view of (b) is (b). Fertilization nozzle N ₁ is an operation explanatory view of a state in which fertilization groove G ₁ is formed. It is the YY sectional view taken on the line of FIG. (A) is a perspective of the lower end view of fertilization nozzle N ₂ of the second reference example, (b) is an operation explanatory view of a state in which fertilization groove G ₁ is formed by the fertilization nozzle N _2. (B) is 'a perspective view of the lower end of, (b), said fertilization nozzle N _2' another reference example of fertilization nozzle N ₂ by the action explanatory view of a state where fertilization groove G ₁ is formed by is there. (A) is a perspective of the lower end view of fertilization nozzle N ₃ of the third reference example, (b) is an operation explanatory view of a state in which fertilization groove G ₁ by the fertilization nozzle N ₃ is formed. (B) is a perspective view of the lower end of the fertilization nozzle N ₄ of the first embodiment, (b) is an operation explanatory view of a state in which fertilization groove G ₁ is formed by the fertilization nozzle N _4. (A) is a perspective of the lower end view of fertilization nozzle N ₅ of the second embodiment, (b) is an operation explanatory view of a state in which fertilization groove G ₁ is formed by the fertilization nozzle N _5. (A) is a perspective of the lower end view of fertilization nozzle N ₆ of the third embodiment, (b) is an operation explanatory view of a state in which fertilization groove G ₁ is formed by the fertilization nozzle N _6. (B) is a perspective view of the lower end of the fertilization nozzle N ₇ of the fourth embodiment, (b) is an operation explanatory view of a state in which fertilization groove G ₁ is formed by the fertilization nozzle N _7. (B) is a perspective view of the lower end of the fertilization nozzle N ₈ of the fifth embodiment, (b), the action of the state where fertilization groove G ₁ which differs by the fertilization nozzle N _8, G ₁ 'is formed It is explanatory drawing. (A) is a perspective view of the lower end portion of the fertilization nozzle N ₉ of the sixth embodiment, and (B) is an action in a state where different fertilization grooves G ₁ and G ₁ ′ are formed by the fertilization nozzle N ₉ . It is explanatory drawing. (A) is a perspective of the lower end view of fertilization nozzle N ₁₀ of the seventh embodiment, (b) is an operation explanatory view of a state in which fertilization groove G ₁ is formed by the fertilization nozzle N _10. It is a perspective view of the lower end of the fertilization nozzle N ₁₁ of the eighth embodiment. (B) is a side view of a work groove state of fertilization nozzle N ₁₁ of the eighth embodiment, (b) is a well back view. It is a perspective view of the lower end of the fertilization nozzle N ₁₂ of the ninth embodiment. (B) is a side view of a work groove state of fertilization nozzle N ₁₂ of the ninth embodiment, (b) is a well back view. It is a perspective view of the lower end of the fertilization nozzle N ₁₃ of the tenth embodiment. (A) is a side view of the groove forming state of the fertilizer application nozzle N ₁₃ of the tenth embodiment, and (b) is a rear view of the same. It is a side view of the groove formation state of the conventional fertilization nozzle N '.

  Hereinafter, the present invention will be described in more detail with reference to reference examples and examples. 1 is a side view of a work machine W connected to the tractor T, FIG. 2 is a rear view of the same, FIG. 3 is a plan view of the work machine W, and FIG. 4 is an overall perspective view of the work machine W viewed from the rear of the tractor T.

Reference example 1

  As shown in FIGS. 1 to 4, a work machine W is attached to the rear portion of the tractor T. The work machine W includes a rotary tiller A for softening the soil, a straw forming device B for forming the straw R on the loosened soil, and a fertilizer S sprayed on the deep layer of the straw R. A fertilizer application device C (local fertilization) is provided. The work machine W is connected to the tractor T by a three-point link hitch method so that the work machine W can be moved up and down, and is lifted from the soil when the tractor T turns.

  The rotary tiller A is connected to a PTO shaft 1 extending behind the tractor T. Due to the driving force of the tractor T transmitted through the PTO shaft 1, a large number of tilling claws 3 attached to the rotary shaft 2 are rotated in a predetermined direction, and the soil is loosened.

As shown in FIG. 3, the cocoon forming device B is disposed behind the rotary cultivating device A, and gathers the soil loosened by the rotary cultivating device A to form the cocoon R. A plurality of different types (three in this example) of ridge-forming plates F _{1 to} F ₃ and each leveling plate 4 for leveling the soil on the upper surface of the ridge R are configured. As the tractor T advances, the soil gathered together inside the fertilization groove G ₁ is pushed by the respective ridge forming plates F _{1 to} F ₃ , and the upper surface of the ridge R is leveled by the leveling plates 4. The trapezoidal cross-section ridges R are formed at a predetermined pitch between the forming plates F _{1 to} F ₃ (see FIG. 7).

As shown in FIG. 1, the fertilizer application C includes a fertilizer hopper 6 supported by a frame 5 (see FIG. 4) of a work machine W, and a device frame of the fertilizer application C provided in connection with the frame 5. 7 and two fertilization nozzles N ₁ (two in the case of this reference example) attached so as to be adjustable in height. If fertilization device C of the present embodiment, the fertilization nozzle N ₁ is between ridge forming plate F ₁ to F ₃ of 3 groups, are arranged corresponding to the pitch of the ridge R to be molded. The lower end portion of each fertilization nozzle N ₁ is disposed in a substantially central portion of the longitudinal direction of each ridge molded plate F ₁ to F ₃ (a direction along the longitudinal P ₁ of the ridge R). As the tractor T advances, the fertilizer S accommodated in the fertilizer hopper 6 is fed out by a predetermined amount by the feeding device V, is sent to the fertilizer nozzle N ₁ through each fertilizer hose 8, and falls by its own weight. In FIG. 1, 9 is a grounding wheel for supporting the work machine W, and 10 is a rear wheel of the tractor T.

The fertilization nozzle N ₁ of the first reference example will be described in detail. FIG. 5 is a perspective view of the fertilization nozzle N ₁ alone of the first reference example, and FIG. 6 is a side view of the fertilization nozzle N ₁ with a part broken away. As shown in FIG. 5 and FIG. 6, the fertilizer application nozzle N ₁ of the first reference example has a substantially L-shaped cross section on the back surface portion (the rear portion with respect to the forward direction of the tractor T) of the nozzle body 11 made of pipe material. The rectangular height adjusting rod 12 is fixed from a portion slightly lower than the central portion of the nozzle body 11 in the axial direction to the upper end portion. The fertilizer application nozzle N ₁ of the first reference example has a support arm 13 extending from the device frame 7 of the fertilizer application device C and a forward inclined posture with an inclination angle θ with respect to the soil (the upper end portion of the nozzle body 11 from the lower end portion). Is also mounted in the front). That is, the a tip portion of the support arm 13, the square tubular body 13a which corresponds to the cross-sectional shape of the height adjustment rod 12 is attached at an angle, the angular cylindrical body 13a, the height of the fertilization nozzles N ₁ The adjustment rod 12 is inserted. Fertilization nozzles N _1, by tightening the pressure screw 14 screwed into the rectangular cylindrical body 13a, are arranged in a forwardly inclined state at a predetermined height position. By loosening the pressing screws 14, the height position of the fertilization nozzles N ₁ (i.e., fertilization depth D of fertilization groove G ₁₎ is adjusted.

As shown in FIGS. 5 and 6, the lower end portion of the nozzle body 11 constituting the fertilization nozzle N ₁ of the first reference example is bent from a portion slightly ahead of the axis CL of the nozzle body 11 to the back surface portion. The opening 15 is formed. When the fertilization nozzle N ₁ is attached to the support arm 13 at an inclination angle θ with respect to the soil, the front lower end edge 11a of the nozzle body 11 and the upper opening edge 15a of the opening 15 are substantially perpendicular to the soil. It is arranged on the straight line L. As a result, the pair of lower opening edge portions 15b in the opening portion 15 are arranged behind (on the back side of) the straight line L. Front lower edge of the (lower end face from 11b to the upper opening edge 15a of the opening 15 the length of the nozzle body 11), fertilization in stoop nozzles N ₁ of the nozzle body 11 opening length H of the opening 15 The height H ′ (H ′ = H / sin θ) from the portion 11 a to the upper opening edge 15 a of the opening 15 is substantially the same as the fertilization depth D of the fertilization groove G ₁ formed in the ridge R. Determined. The fertilization nozzle N ₁ of the first reference example is mounted such that the above-described height H ′ is substantially the same as the fertilization depth D of the fertilization groove G ₁ formed in the ridge R. The height H ′ may be higher or lower than the fertilization depth D.

Wherein at the upper end of the opening 15 of the nozzle body 11, the circular portion perpendicular to the axis CL faces the upper opening edge portion 15a, and has a manure outlet 16 in the fertilization nozzles N _1. Moreover, the part from the said fertilizer discharge port 16 to the lower end surface 11b in the lower end part of the nozzle main body 11 is the fall guide part 17 for guiding the fertilizer S which falls. The fertilizer S dropped by its own weight from the upper end portion of the fertilizer application nozzle N ₁ is discharged from the fertilizer discharge port 16, guided by the drop guide portion 17, and sprayed on the bottom portion 18 of the fertilizer groove G ₁ . The drop guide portion 17 also has a function as a groove forming member for forming the fertilization groove G ₁ in the ridge R.

Next, the scissor forming apparatus B will be described in detail with reference to FIG. Figure 7 is a right side in the drawing view, the side in the width direction P ₂ of the ridge R, turn a diagram showing a state of forming the ridges R to the soil, the precast ridges indicated by "R", the middle molding The cocoon is indicated by “R ′”, and the unsettled soil is indicated by “R” ”. The wrinkle forming apparatus B of the present example has a first first wrinkle forming plate F ₁ disposed substantially in the center in the width direction and the first pitch with an arrangement pitch corresponding to the pitch of the wrinkles R to be formed. It consists of the second scissors forming plates F ₂ and F ₃ disposed on both sides of the scissors forming plate F ₁ . The first ridge forming plate F ₁ will be described. The first cocoon forming plate F ₁ is formed so that the flat cocoon forming plate base 19 has an acute angle in a plan view so that the soil softened by the rotary tiller A can be pushed up on both sides. Moreover, it is a form that is bent at a predetermined angle in the height direction. As a result, the first front portion of the ridge forming plate F _1, a pair of the soil lifting portion 19a is formed at an acute angle shape. Further, the rear portion of the birch-formed base plate 19 formed in a bifurcated shape is bent inward in accordance with the lateral shape of the eaves R to be molded, and pushes the soil pushed up by the earth lifting portion 19a. For this reason, it is a ridge forming part 19b.

Next, the second scissors forming plates F ₂ and F ₃ will be described. Since each second scissors forming plate F ₂ , F ₃ is symmetrical in plan view, here the second scissors are arranged on the right side in the drawing view of FIG. 7 with respect to the first scissors forming plate F ₁ described above. Only the molded plate F ₂ will be described. The second bowl forming plate F ₂ is a form in which the two pieces of bowl forming plate bases 21 and 22 are fixed to each other so as to have an acute angle in a plan view. Outer ridge shaped plate source body 21 in the longitudinal direction P ₁ of the ridge R and is arranged substantially along the upper 21a of the rear end portion is bent outwardly. For this reason, there is no possibility that the outer ridge-formed plate base 21 will damage the adjacent ridge (molded ridge R). Further, the inner side (on the side facing the first side plate F ₁ ) of the original side plate forming plate body 22 is disposed obliquely rearward at a predetermined angle with respect to the outer side plate forming plate base body 21 described above. In addition, an earth lifting part 22a is provided at the front part, and the rear part is bent inward corresponding to the side shape of the ridge R to be molded, and the earth pushed up by the earth raising part 22a. It becomes the ridge forming part 22b for pushing.

Then, the portion between and how each ridge molded plate F ₁ to F _3, and each ridge shaped portion 19b in their longitudinal direction, in part of 22b, for leveling the almost finished upper surface of the ridge R molding A leveling plate 4 is provided. Soil in膨軟by rotary cultivator A, the ridge forming plate F ₁ soil in to F ₃ push-up portion 19a, after being pushed on both sides by 22a, the ridge forming portion 19b, being swept by 22b and ridge Both side surfaces of R are molded. Further, the upper surface of the ridge R is leveled by the leveling plates 4, and the final shape of the ridge R is formed.

As shown in FIG. 7, the fertilization nozzles N ₁ of the first reference example, between and how each ridge molded plate F ₁ to F ₃ constituting the ridge forming device B, the ridge forming plate F ₁ to F ₃ It is arranged slightly ahead of the end portions of the earth lifting portions 19a, 22a. The reason why the fertilization nozzle N ₁ is arranged at the above position will be described. Rotary cultivator soil that is to膨軟by A, the respective ridge molded plate F ₁ to F ₃ soil pushed up unit 19a, were collected pushes asked by 22a, ridge of the ridge forming plate F ₁ to F ₃ The molded parts 19b and 22b are pressed to form a predetermined bowl shape. When each fertilizer application nozzle N ₁ is arranged on the side of the front part of the soil lifting portion 19a, 22a, it is immediately after the start of forming the ridge R, and the approximate shape of the ridge R is not determined. It becomes difficult to determine the application position of the fertilizer S. Further, when each fertilizer application nozzle N ₁ is arranged behind the end portions of the soil lifting portions 19a, 22a and to the sides of the hook forming portions 19b, 22b, since the be advanced by inserting each fertilization nozzles N ₁ to ridge R of the state that is swept ridge forming portion 19b, to 22b, great resistance to the fertilization nozzles N ₁ will act. As a result of the above, each fertilization nozzle N ₁ is in a state where the loosened soil is gathered together and the rough shape of the ridge R is formed, and a large lateral earth pressure K (described later) is not applied. It is most desirable to be disposed at a position where it is inserted into the heel R of the rim.

The above-described embodiment is a case where two ridges R are simultaneously formed by the ridge forming apparatus B, but the present invention is not limited to the above-described embodiment. For example, two first scissors forming plates F ₁ are arranged side by side corresponding to the pitch of scissors R in the substantially central part of the work machine W in the width direction, and second scissors forming plates F ₂ , F ₂ , When F ₃ is provided, three ridges R are formed simultaneously.

The operation of fertilization nozzles N ₁ of the first reference example will be described. First, the operation when inserting the fertilizer nozzle N ₁ into the ridge R will be described. In the case of the first reference example, as shown in FIG. 6, the height of the fertilizer application nozzle N ₁ is such that the upper opening edge 15 a of the opening 15 provided in the nozzle body 11 is approximately the same as the upper surface of the ridge R. It is adjusted so that it is arranged at the same height. When the working machine W is lowered, the lower end of the nozzle body 11 of fertilization nozzles N ₁ mounted in inclined forward is inserted obliquely ridge R 'in the middle of forming.

As shown in FIG. 8 and FIG. 9, the soil is pushed right and left by the drop guide portion 17 of the nozzle body 11 inserted into the ridge R ′ in the middle of molding, and the space portion Q is immediately behind the drop guide portion 17. Is formed. Further, the pair of lower opening edge portions 15 b in the opening portion 15 of the nozzle body 11 is disposed behind the straight line L passing through the front lower end edge portion 11 a and the upper opening edge portion 15 a of the nozzle body 11. For this reason, the back surface part 17a of the drop guide part 17 of the nozzle body 11 is covered with the drop guide part 17, and when the drop guide part 17 of the nozzle body 11 is inserted into the ridge R ′, the drop guide part 17 The amount of soil that directly enters the back surface portion 17a is small. When the work implement W is advanced in this state, the fertilizer application nozzle N ₁ is also advanced. The soil that comes into contact with the drop guide portion 17 of the nozzle body 11 is eliminated, and the fertilizer groove G ₁ is continuously formed at the position of the predetermined depth D of the ridge R ′ during the molding.

As shown in FIG. 8 and FIG. 9, the fertilizer S accommodated in the fertilizer hopper 6 is fed by a predetermined amount by each feeding device V, and is supplied to the fertilization nozzle N ₁ through the fertilizer hose 8. The fertilizer S supplied to the fertilizer application nozzle N ₁ is discharged from the fertilizer discharge port 16 of the nozzle body 11, then guided to the drop guide portion 17, discharged from the lower end surface 11 b of the nozzle body 11, and in the fertilizer groove G ₁ . It is sprayed on the bottom 18 (fertilization effect).

Further, as the work implement W advances along the longitudinal direction P ₁ of the rod R, the rod forming apparatus B is also advanced. The soil softened by each of the ridge forming plates F _{1 to} F ₃ is pushed up to the side to form ridge R (an ridge R ′ in the middle of forming). That is, ridges R are each soil lifting portion 19a of soil that is to膨軟faces inside the pair of left and right ridge forming plate F ₁ to F _3, while being gathered to the center by 22a, the ridge forming portion 19b , 22b to receive the side earth pressure K (see FIG. 9).

The fertilization groove G ₁ formed by the fertilization nozzle N ₁ inserted in the ridge R ′ in the middle of forming immediately after the groove is extinguished from the width direction by the side earth pressure K, and the fertilization groove G 1 _The embankment raised on both sides of the opening of ₁ is buried in synergy with the action of collapsing into the fertilizing groove G _{1 that} is disappearing.

Here, compared to the rate at which the fertilizer S is supplied, because the slower rate backfilling fertilization grooves G ₁ and collapsed soil E _1, E ₂ ambient to form a fertilization groove G _1, fertilization nozzle N _A fertilization groove G ₁ is always formed in a portion immediately after the lower end of ₁ . Then, since the rear side of the lower end portion of fertilization nozzles N ₁ of the first reference example has opening 15 is provided between the bottom 18 of the manure discharge port 16 and the fertilization groove G ₁ of the nozzle body 11 The space Q is temporarily formed. Moreover, the fertilizer discharge port 16 of the fertilizer application nozzle N ₁ is always disposed above the lower end surface 11 b of the nozzle body 11 by the opening length H (in other words, the fertilizer discharge port 16 is “raised”. Have been). For this reason, the fertilizer discharge port 16 is separated from the surrounding soils E ₁ and E ₂ forming the fertilizer groove G _1, and no soil enters the fertilizer discharge port 16.

In the case of the conventional fertilization nozzle N ′, the fertilizer discharge port 51 is disposed in a state close to the bottom portion 52 of the fertilization groove G ′, and is formed between the fertilizer discharge port 51 and the bottom portion 52 of the fertilization groove G ′. The size of the space Q ′ is small (see FIG. 26). For this reason, it becomes easy for soil to enter the lower end portion of the fertilization nozzle N ′, and the fertilizer discharge port 51 of the fertilization nozzle N ′ is likely to be clogged. In contrast, in the case of fertilization nozzles N ₁ of the first reference example, the fertilizer discharge port 16 and the lower end surface 11b of the nozzle body 11 our it very few clogged by the soil.

Then, the soil on the upper surface of the ridge R is smoothed by the leveling plate 4, and the ridge R is finally formed. As a result, the fertilizer S is locally sprayed at the position (deep layer portion) of the predetermined depth D in the ridge R (local fertilization). When the tractor T reaches the end of the ridge R, the work machine W is lifted and swiveled to move the work machine W to the side (width direction P _{2 of the} ridge R), and then the adjacent soil (uncast) Topical R ") is applied locally.

As described above, in the fertilization nozzle N ₁ according to the present invention, when the lower end portion of the fertilization nozzle N ₁ is inserted into the rod R ′, or when the fertilization nozzle N ₁ forms the fertilization groove G ₁ even for any, soil no longer enter the manure discharge port 16 of fertilization nozzles N ₁ of the nozzle body 11, soil the fertilizer outlet 16 is not clogged. In addition, it is not necessary to perform complicated processing on the fertilization nozzle N _1, and it can be applied to the conventional fertilization nozzle N ′.

Reference example 2

The fertilization nozzle N ₁ of the first reference example described above has a configuration in which the opening 15 is provided in a curved shape on the back side of the nozzle body 11. Thereby, the effect that the rigidity of the lower end part of the nozzle body 11 is ensured is produced. However, like the fertilization nozzle N ₂ of the second reference example shown in FIG. 10A, the opening 23 may be provided at a right angle on the back side of the nozzle body 11. In the case of the fertilization nozzle N ₂ of the second reference example, as shown in FIG. 10B, the fertilizer discharge port 16 of the fertilization nozzle N _{2 in} the groove is disposed above the bottom 18 of the fertilization groove G _1. In addition, a space Q is formed below the fertilizer discharge port 16. As a result, in addition to substantially the same advantages as the fertilization nozzle N ₁ of the first reference example, there is an advantage that the opening 23 can be easily processed.

Further, like the fertilizer application nozzle N ₂ ′ shown in FIGS. 11A and 11B, an opening 23 ′ may be provided on the back side of the nozzle body 11 so as to be largely oblique. In the case of the fertilization nozzle N ₂ ′ of this reference example, there is an advantage that the processing of the opening 23 ′ is extremely easy.

Reference example 3

The fertilizing nozzles N ₁ , N ₂ , N ₂ ′ of the above-mentioned reference examples are provided with openings 15, 23, 23 ′ at the lower end of a nozzle body 11 made of a single pipe pipe. 11 is not limited to a single pipe. Next, the fertilization nozzle N ₃ of the third reference example will be described. As shown in FIGS. 12 (a) and 12 (b), a pair of lower nozzle bodies 11 'made of a single pipe is placed at a predetermined angle at the lower end of the nozzle body 11 made of a single pipe. It is installed in a bifurcated shape. That is, fertilization nozzle N ₃ of the third reference example, is branched into two at substantially the same form the lower end of the fertilization nozzles N ₁ of the first reference example, and was extended obliquely them toward the rear Is. The lower end portions of the pair of the lower nozzle body 11 ', respectively in the same manner as fertilization nozzles N ₁ of the first reference example have openings 15 are formed, the upper end portion of the opening portion 15 (upper opening edge 15a Each fertilizer discharge port 16 is provided in the portion of FIG. Each of the openings 15 is configured so that the fertilizer is reliably discharged from the lower end surface 11b of each lower nozzle body 11 ′ (in other words, the fertilizer S does not fall from the middle of each opening 15). The lower nozzle body 11 'is provided slightly closer to the upper side rather than the back side. The position of the upper opening edge 15a in the front-rear direction (the direction along the longitudinal direction of the flange R) is arranged at substantially the same position as the front lower end edge 11a of the lower nozzle body 11 '[FIG. Reference], soil does not enter when inserting the fertilizer nozzle N ₃ .

As shown in FIG. 12B, the fertilizer application nozzle N ₃ of the third reference example is inserted substantially perpendicular to the ridge R ′ in the middle of molding, and advances along the longitudinal direction P ₁ of the ridge R. Two fertilization grooves G ₁ are formed by the drop guide portions 17 formed in the pair of lower nozzle bodies 11 ′. The fertilizer S dropping the upper nozzle body 11 is branched at the joint between the nozzle body 11 and the pair of lower nozzle bodies 11 ′, and passes through the drop guide portions 17 from the pair of fertilizer discharge ports 16 to each fertilizer groove. Drained to the bottom 18 of G ₁ . A large space Q is temporarily formed between each fertilizer discharge port 16 of the pair of lower nozzle bodies 11 ′ and the bottom 18 of each fertilization groove G ₁ , and soil enters each of the fertilizer discharge ports 16. This is the same as the case of the fertilization nozzle N ₁ of the first reference example, and the fact that each fertilization groove G ₁ is backfilled by the action of the rod forming plates F _{1 to} F ₃ .

In the case of the fertilization nozzle N ₃ of the third reference example, the fertilizer S is discharged into each fertilization groove G ₁ while forming two fertilization grooves G ₁ at once in the ridge R ′ during the molding. The fertilizer S dropping on the upper nozzle body 11 is branched in two directions within the nozzle body 11 and then discharged from each fertilizer discharge port 16 of the pair of lower nozzle bodies 11 ′. The fertilizer S is surely branched in two directions and is uniformly discharged into the fertilizer grooves G ₁ . For this reason, multiple strip fertilization (in this example, two strip fertilization) is possible. In addition, since fertilizer can be applied below each line, the effect of fertilizer on crops is enhanced. Furthermore, since each lower nozzle body 11 ′ is formed of a pipe and the front portions of the pair of drop guide portions 17 are bent, the groove forming resistance can be reduced. Fertilization nozzle N ₃ of the third reference example is for two rows, but may be for more number of threads.

Next, the fertilization nozzle N ₄ of the first embodiment will be described. As shown in FIG. 13A, the fertilizing nozzle N ₄ of the first embodiment includes a pipe-shaped nozzle body 24 and a flat groove-forming plate 25 extending below the nozzle body 24. Consists of. The width of the groove plate 25 is the same as the inner diameter of the lower end surface (fertilizer discharge port 26) of the nozzle body 24, and is attached so that the longitudinal direction thereof is substantially along the axis CL of the nozzle body 24. The fertilization nozzle N ₄ of the first embodiment is inserted into the ridge R in a forward tilted posture, as shown in FIG. At this time, the lower edge 25a of the groove plate 25 and the rear edge 26a of the fertilizer discharge port 26 of the nozzle body 24 are arranged on a straight line L substantially orthogonal to the upper surface of the ridge R. By the fertilization nozzle N ₄ advances, fertilization groove G ₁ is formed at a position of a predetermined depth D of the ridge R (deep portion of the ridge R).

When the lower end portion of the nozzle body 24 of the fertilizer application nozzle N ₄ is inserted into the ridge R ′ in the middle of molding, the groove forming plate 25 covers almost the entire fertilizer discharge port 26 of the nozzle body 24. The soil will not enter the area. Then, the fertilizer discharge port 26 in Sakumizo is always be disposed above the bottom 18 of the fertilization grooves G _1, below the該肥charge discharge port 26 is formed a space portion Q. Thus, the fertilizer discharge port 26, fertilization grooves G ₁ have been separated from the surrounding soil forming the ambient soil E ₁ which forms a fertilization groove G _1, E ₂ are, fertilizer outlet of the nozzle body 24 There is very little risk of entering 26. Fertilizer S discharged from the manure discharge port 26 of the nozzle body 24 is sprayed on the bottom 18 of the fertilization groove G ₁ is guided to Sakumizoban 25. The fertilizer groove G ₁ is backfilled with the soils E ₁ and E ₂ .

Fertilization nozzle N ₄ of the first embodiment is in the form obtained by integrally fixed to Sakumizoban 25 in nozzle body 24, be a conventional fertilization nozzle N ', it is attached only by simple modification it can. Moreover, it is possible to easily correspond to the depth D and the width of the fertilization groove G ₁ only by changing the length and width of the groove plate 25.

The fertilization nozzle N ₅ of the second embodiment, as shown in (b) of FIG. 14, with respect to fertilization nozzle N ₄ of the first embodiment, Sakumizoban 27 become substantially V-shaped cross section , moreover, is in a form is extended downward of the nozzle body 24 toward the that occasion bent portion 27a forward (direction fertilization nozzle N ₅ is advanced). In the case of the fertilization nozzle N ₅ of the second embodiment, as shown in FIG. 14B, when the fertilization nozzle N ₅ is advanced, the soil of the ridge R ′ is removed by the bent portion 27a of the groove plate 27. Therefore, there is an advantage that the resistance force that the fertilization nozzle N ₅ receives from the ridge R can be reduced. Also, fertilizer S ejected from the manure discharge port 26 of the nozzle body 24 in order to flow down the rear portion 27b formed in a V groove shape at Sakumizoban 27, spraying position fertilizer S in fertilization groove G ₁ is substantially There is an advantage that it becomes constant. Further, by making the groove plate 27 V-shaped, the strength of the groove plate 27 is increased.

Fertilization nozzle N ₆ of the third embodiment, as shown in (b) of FIG. 15, with respect to fertilization nozzle N ₄ of the first embodiment, shaped substantially "V" in side view a Sakumizoban 28 It is the form bent in the shape and extended below. That is, the groove forming plate 28 constituting the fertilization nozzle N ₆ of the third embodiment is bent from the vicinity of the lower end portion (fertilizer discharge port 26) of the nozzle body 24 toward the rear side (back side). The rear edge 26 a of the fertilizer discharge port 26 of the nozzle body 24 and the lower edge 28 a of the groove plate 28 are arranged on a straight line L along the axis CL of the nozzle body 24. The fertilization nozzle N ₆ of the third embodiment is inserted into the ridge R in a substantially vertical posture as shown in FIG. And the bent part of the groove plate 28 excludes soil. Since most of the fertilizer outlet 26 of the nozzle body 24 is covered with the groove plate 28, there is almost no amount of soil entering the fertilizer outlet 26. Moreover, formed in a Sakumizo, since the space portion Q is formed between the rear portion 28b of the fertilizer outlet 26 and Sakumizoban 28 of the nozzle body 24, the manure discharge port 26 a fertilization groove G ₁ The soils E ₁ and E _{2 that} are separated from the surrounding soil and backfilled in the fertilization groove G ₁ do not enter the fertilizer outlet 26. Fertilizer S discharged from the manure discharge port 26, after being dropped on the back portion 28b of Sakumizoban 28, is sprayed on the bottom 18 of the fertilization groove G _1.

In the case of the fertilizer application nozzle N ₆ of the third embodiment, the fertilizer application nozzle N ₆ is attached to the fertilizer application device C in a vertical posture. For this reason, even if the height position of the fertilizer application nozzle N ₆ is adjusted, there is an advantage that the position in the front-rear direction is always kept constant.

Fertilization nozzle N ₇ of the fourth embodiment, in FIG. 16 (a), as shown in (b), the work groove plate 28 of fertilization nozzle N ₆ of the third embodiment, a substantially V-shaped in cross section This is the groove plate 29. For this reason, the fertilization nozzle N ₇ of the fourth embodiment has the advantages of the fertilization nozzles N ₅ and N ₆ of the second and third embodiments.

For fertilization nozzle N ₈ of the fifth embodiment she will be described. (B) in FIG. 17, as shown in (b), Sakumizoban 31 constituting the fertilization nozzle N ₈ of the fifth embodiment, create grooves plate 28 in fertilization nozzle N ₅ of the second embodiment described above The auxiliary groove plate 31 ′ having a width that is substantially half of the entire width of the groove plate 28 is extended downward as it is. Two fertilization grooves G ₁ and G ₁ ′ having different depths are formed in the ridge R ′ during molding by the fertilization nozzle N ₈ of the fifth embodiment. That is, fertilization grooves G ₁ and G ₁ ′ having different fertilization depths D and D ′ are simultaneously formed in the rod R by the fertilization nozzle N ₈ of the fifth embodiment, and the bottom portion 18 of each fertilization groove G ₁ and G ₁ ′ is formed. , 18 'can be applied simultaneously.

For fertilization nozzles N ₉ of the sixth embodiment will be described. (B) in FIG. 18, as shown in (b), Sakumizoban 32 of the fertilization nozzles N ₉ of the sixth embodiment, the nozzles in the work groove plate 31 of fertilization nozzle N ₈ of the fifth embodiment The extending portion from the main body 24 is shifted in the front-rear direction (longitudinal direction P _{1 of the} ridge R) at substantially the center in the width direction, so that two groove forming plates having different lengths (first and second grooves) It is the form which provided board 32a, 32b). The lower edge 33a of the shorter first groove plate 32a and the lower edge 33b of the longer second groove plate 32b are arranged on substantially the same straight line L. If fertilization nozzles N ₉ of the sixth embodiment, in addition to being achieves the same effect as fertilization nozzle N ₈ of the fifth embodiment described above, the amount of projection of the nozzle body 24 in the second Sakumizoban 32b since the only a small, the overall size of the fertilization nozzles N ₉ can be compact.

The fertilization nozzle N ₁₀ of the seventh embodiment is configured in such a manner that a groove plate 34 having a substantially U-shaped cross section is attached to the lower end portion of the nozzle body 24 as shown in FIGS. is there. The depth of the groove plate 34 (the length along the longitudinal direction P ₁ of the ridge R) is slightly larger than the outer diameter of the nozzle body 24. Therefore, by Sakumizoban 34, most of the lower end portion of the nozzle body 24 is covered, fertilizer S discharged from the manure discharge port 26 of the nozzle body 24 is sprayed on the bottom 18 of the fertilization groove G ₁ Sometimes scattering to the periphery is suppressed, and local fertilization is ensured. Also, in the case of fertilization nozzle N ₁₀ of the seventh embodiment, since the majority of the lower end of the nozzle body 24 is covered, thereby fertilizer outlet 26 of the nozzle body 24 is disposed above the upper surface of the ridge R ( H> D) is also possible. This has the advantage that it is possible to dispense easily height adjustment of fertilization nozzle N _10.

The fertilizer application nozzles N _{1 to} N ₁₀ of the reference examples and examples described above are for local fertilization while forming a fertilization groove G ₁ having a normal width (about 25 mm) in the ridge R. In contrast, fertilization nozzle N ₁₁ of the eighth embodiment is intended for topical fertilization while forming a wide fertilization groove G ₂ only on the bottom 39 of the ridge R in soil. As shown in FIG. 20, the fertilizer application nozzle N ₁₁ includes a pipe-like nozzle body 24 and a groove plate 35 attached to the lower end portion of the fertilizer application nozzle N ₁₁ so as to extend downward. The groove plate 35 includes a substantially trapezoidal main body portion 36 in a front view and a nozzle mounting portion 37 provided at the upper end portion of the main body portion 36. The nozzle mounting portion 37 has a substantially semi-cylindrical shape, and the inner diameter thereof is substantially the same as the outer diameter of the nozzle body 24. Further, a substantially semi-cylindrical fertilizer guide body 38 is fixed along the left-right direction (the width direction P _{2 of the} ridge R) substantially at the center of the back surface of the main body 36 of the groove plate 35. The fertilizer guide 38 projects toward the rear of the main body 36. The fertilizer guide body 38 has a function of evenly spreading the fertilizer S discharged from the fertilizer discharge port 26 of the nozzle body 24 over the entire width direction of the fertilizer groove G ₂ having a wide bottom portion 39. Yes.

As shown in (a) and (b) of FIG. 21, the main body portion 36 of the groove forming plate 34 is bent and attached backward from the lower end portion (fertilizer discharge port 26) of the nozzle main body 24. The rear edge 26 a of the fertilizer discharge port 26 of the nozzle body 24 and the lower edge 36 a of the body 36 of the groove plate 35 are arranged on a straight line L along the axis CL of the nozzle body 24. Therefore, when fertilization nozzle N ₁₁ is inserted into the ridge R 'in the middle molded in a vertical position, the fertilizer discharge port 26 of the nozzle body 24 is covered with the main body portion 36 of Sakumizoban 35, wherein the fertilizer discharge port 26 The soil will not enter. Fertilizer S which is sprayed on the bottom 39 of the fertilization groove G ₂ is is covered with soil by the soil E _1, E ₂ around the fertilization groove G ₂ to crumble later in time. Further, the fertilizer discharge port 26 of the nozzle body 24 of fertilization nozzle N ₁₁ in Sakumizo is be located above the bottom 39 of the fertilization groove G _2, a possibility that the soil E _1, E ₂ enters no. The height of the main body 36 of the groove plate 35 in the fertilizer nozzle N ₁₁ is desirably as low as possible in order to reduce the resistance received from the soil during the groove formation.

When advancing the fertilization nozzle N _11, the ridge R 'in the middle of molding by Sakumizoban 35 temporarily bottom 39 wide fertilization groove G ₂ is formed. The fertilizer S discharged from the fertilizer discharge port 26 of the nozzle main body 24 falls to the back surface portion of the main body portion 36 of the groove plate 35 and is guided to the main body portion 36 and flows down as it is. Of the fertilizer S flowing down, the fertilizer S that has come into contact with the fertilizer guide body 38 gets over the fertilizer guide body 38 and is sprayed at the substantially central portion in the width direction in the fertilizer groove G ₂ and collides with the fertilizer guide body 38. Since S diffuses also in the width direction, it spreads to the bottom of the groove and is sown. Namely, the fertilizer S is localized fertilization throughout the fertilization groove G ₂ wide.

Next, a description will be given fertilization nozzle N ₁₂ of the ninth embodiment. As shown in FIG. 22, fertilization nozzle N ₁₂ is fertilization nozzle N ₁₁ of the eighth embodiment over the entire width direction of the wide fertilization groove G ₂ whereas those for topical fertilization The fertilizer groove G ₂ is used for local fertilization only at both ends in the width direction. Since the fertilizer nozzle N ₁₂ differs from the fertilizer nozzle N ₁₁ only in the main body portion 42 of the grooved plate 41, only the main body portion 42 of the fertilizer nozzle N ₁₂ will be described here. The main body portion 42 of the groove forming plate 41 of the fertilizer application nozzle N ₁₂ has a substantially trapezoidal shape when viewed from the front, and is substantially triangular toward the rear (back side) at the substantially central portion in the width direction at the back surface of the main body portion 42. A cone-shaped fertilizer guide 43 is projected.

As shown in (a) and (b) of FIG. 23, when the fertilization nozzle N ₁₂ is advanced, a wide fertilization groove G ₂ is formed by the groove forming plate 41 in the ridge R ′ being formed. When the fertilizer S discharged from the fertilizer discharge port 26 of the nozzle body 24 abuts on the fertilizer guide 43, the fertilizer S is distributed in either the left or right direction. Then, it flows down along the joint portion 42a of the main body portion 42 and the fertilizer guide body 43, is sprayed on both end portions in the width direction of the fertilized groove G _2. Namely, the fertilizer S is localized fertilization at both ends of the wide fertilization groove G _2.

Each of the fertilization nozzles N ₁₁ and N ₁₂ of the eighth and ninth embodiments described above is for forming a single wide fertilization groove G ₂ on the rod R. The fertilizer application nozzle N ₁₃ of the tenth embodiment to be described next is for forming two fertilization grooves G ₃ in the ridge R at a time. That is, as shown in FIG. 24, a substantially central portion of the lower in the width direction of the main body portion 45 of Sakumizoban 44 constituting the fertilization nozzle N ₁₃ have been cut in a substantially triangular shape in a front view. Thereby, the lower end part of the main-body part 45 is isolate | separated into two forks, and a pair of groove-forming parts 45a and 45b are provided. Further, a fertilizer guide body 46a is attached to the peripheral portion of the cut portion (cut portion 46).

As shown in FIG 25 (a), (b), when advancing the fertilization nozzle N _13, a pair of work groove 45a of the main body 45 of Sakumizoban 44. by 45b, fertilization of Article 2 the ridge R groove G ₃ is formed in parallel. Since the cut portion 46 is provided between the pair of groove portions 45a and 45b, the soil of the portion is not excluded. The fertilizer S discharged from the fertilizer discharge port 26 of the nozzle body 24 is distributed in either the left or right direction when contacting the fertilizer guide 46a. Then, it flows down along the fertilizer guide member 46a, is sprayed on the bottom 47 of each fertilization groove G _3. That is, the fertilizer S is locally fertilized in each of the two fertilization grooves G ₃ . Then, although fertilization nozzle N ₁₃ of the tenth embodiment is for two rows, but may be for more number of threads.

The fertilizer application nozzles N _{11 to} N ₁₃ of the above-described eighth to tenth embodiments each have a configuration in which the groove forming plates 35, 41, 44 are bent rearward (back side). Therefore, the fertilization nozzle N ₁₁ to N ₁₃ may be inserted in a vertical posture with respect to ridge R. However, each groove plate 35, 41, 44 may be attached along the axis CL of the nozzle body 24. In this case, the fertilizer application nozzles N _{11 to} N ₁₃ are inserted in a forward inclined posture with respect to the heel R.

In each reference example and each example described above, the case where simultaneous local fertilization work is performed on the ridge R formed on the loosened soil has been described. However, never being simultaneously locally fertilization limited to ridge R, for example, a fertilization nozzles N ₁ to N ₁₃ of the reference examples and the examples, topical fertilization flat ridge formed plowing plane soil You may use it. However, in this case, the fertilizer grooves G _{1 to} G ₃ need to be backfilled by leveling the entire surface of the soil with the leveling plates 4.

A: Rotary tiller
B: Spear forming device
C: Fertilizer
D: Setting depth
_{G 1 ~G 3, G 1 '} : fertilization groove
L: Straight line
N ₁ ~N _13: fertilization nozzle
Q: Space
R ′, R: 畦 (soil)
S: Fertilizer
T: Tractor
W: Work machine
11, 11 ', 24: Nozzle body
15, 23: Opening (back opening)
16, 26: Fertilizer outlet
17: Drop guide (lower end of fertilizer nozzle)
18, 39, 47: bottom
25, 27 to 29, 31, 32, 34, 35, 41, 44: Grooving plate (grooving member)
38, 43, 46a: Fertilizer guide
45a, 45b: Groove part (lower end part of the groove member)

Claims (6)

The work implement mounted on the rear part of the tractor so as to be able to move up and down includes a rotary tiller and a fertilizer, and the fertilizer is placed in the stabilized soft and soft soil after being scattered and landed rearward by the rotary tiller. In the state where the lower end portion of the pipe-shaped fertilizer nozzle constituting the insert is inserted, the work machine advances to continuously fertilize the set depth portion inside the softened soil immediately after rotary tilling of the soil. A local fertilization method of spraying ,
The fertilizer application nozzle is integrally attached to a lower end portion on the front surface side with respect to the traveling direction of the tractor in the pipe-shaped nozzle body with a groove forming member extending substantially downward, and the lower end of the nozzle body The opening fertilizer discharge opening is a configuration arranged at the upper end of the groove forming member ,
The fertilizer discharged from the fertilizer discharge port was formed by the groove forming member through the space portion temporarily formed behind the groove forming member while being guided by the groove forming member. After reaching the bottom of the fertilization groove, the fertilizer is locally fertilized at the bottom, and after a little time has elapsed since the fertilizer reached the bottom of the fertilization groove, the bottom of the fertilizer groove is collapsed by the collapse of the side wall constituting the fertilization groove A local fertilization method characterized in that a fertilizer groove in which fertilizer is locally applied is refilled. A fertilization nozzle for performing the local fertilization method according to claim 1,
The fertilizer application nozzle is integrally attached to a lower end portion on the front surface side with respect to the traveling direction of the tractor in the pipe-shaped nozzle body with a groove forming member extending substantially downward, and the lower end of the nozzle body The opening fertilizer discharge opening is a configuration arranged at the upper end of the groove forming member ,
The fertilizer nozzle discharged from the fertilizer discharge port is guided by the groove forming member and reaches the bottom of the fertilizer groove formed by the groove forming member. The Sakumizo member fertilization nozzle according to claim 2, the lower end of the nozzle body, characterized in that it is bent toward the rear side of the nozzle body. Fertilization nozzle according to claim 2 or 3 the length of the Sakumizo member is characterized in that different in the width direction. The lower end of the Sakumizo member fertilization nozzle according to claim 2 or 3, characterized in that wider than the outer diameter of the nozzle body. Fertilization nozzle according to claim 5 the lower end of the Sakumizo member, characterized in that it is branched into a plurality.