RU203465U1 - HAND CULTIVATOR - Google Patents

Abstract

The utility model relates to hand tools for tillage, mainly gardening tools for loosening the soil and combating weeds under fruit and berry bushes. The technical solution is aimed at increasing the level of manufacturability of the manufacture of the loosening depth limiter and the working body of the hand cultivator, as well as, if necessary, to increase the safety of transportation of the hand cultivator. The specified technical effect is achieved by the fact that the hand cultivator contains at least a main handle and a working body with teeth , at least one limiter of the depth of loosening the soil, having a rectangular cross-section with coaxial through circular holes in its lateral sides, with which the limiter is planted on at least part of the teeth of the working body with the ability to move along the teeth, as well as at least one screw device for fixing the limiter in the required position along the teeth, located on the end side of the limiter and interacting with the supporting tooth, and the coaxial through circular holes in which the supporting tooth of the working member is placed are made of a smaller diameter in comparison with other coaxial through round holes in which other teeth are placed. To increase the safety of transportation of the hand cultivator, additional holes can be made on the end side of the stopper opposite to the end side with the hole for the fixing screw to accommodate the teeth of the working body. In this case, the limiter of the depth of loosening the soil serves as a "cover" for the teeth of the working body.

Description

The utility model refers to hand tools for soil cultivation, mainly to gardening tools for loosening the soil and fighting weeds under fruit and berry bushes.

A known design of a manual cultivator, which includes at least the main handle and a working body with teeth, as well as at least one limiter of the depth of loosening the soil, which in cross section has an L-shaped, U-shaped or closed profile, and in its lateral sides are made through holes, with the help of which the stopper is seated on at least part of the teeth of the working member with the possibility of movement along the teeth, as well as at least one screw device for fixing the stopper in the required position along the teeth (Patent RU No. 2731983, IPC А01В 1/06, А01В 1/14, 09.09.2020). The considered manual cultivator allows you to loosen the soil under fruit and berry bushes, minimizing unwanted damage to their root system due to the presence of a loosening depth limiter on the forks.

This design is selected as a prototype as the closest to the claimed device in terms of technical essence and the achieved result.

The weak side of this device is the insufficient use of standard metal profiles in the design of the loosening depth limiter, as well as the execution of coaxial through round holes in its lateral sides of the same diameter for all bearing teeth of the working body, which limits the possibilities for improving the manufacturability of the manual cultivator and expanding its consumer properties ...

The task of the technical solution is to improve the manufacturability of the loosening depth limiter and the working body of the hand cultivator and to create conditions for expanding its consumer properties.

The task is achieved by the fact that the manual cultivator, as in the prototype, contains at least a main handle and a working body with teeth, at least one limiter of the depth of loosening of the soil, which has a closed profile in cross-section with coaxial through circular holes in it. lateral sides, with the help of which the stopper is seated on at least part of the teeth of the working member with the ability to move along the teeth, as well as at least one screw device for fixing the stopper in the required position along the teeth, located on the end side of the stopper and interacting with the supporting tooth.

According to the technical solution, the closed profile in the cross-section of the limiter has a rectangular shape, and the coaxial through circular holes in which the supporting tooth of the working member is placed are made of a smaller diameter in comparison with other coaxial through circular holes in which other teeth are placed.

The essence of the proposed technical solution, firstly, lies in the fact that the implementation of the limiter of the depth of loosening in the form of a closed profile in its cross-section provides a sufficiently high rigidity with a relatively small wall thickness of the closed profile, which reduces the weight of the limiter. In turn, the implementation of such a rectangular cross-section of the limiter makes it possible to use a standard rectangular metal profile for its manufacture, which excludes the operations of bending the limiter from sheet material and increases the manufacturability of its manufacture. The presence of two end sides of sufficient width for the rectangular limiter in cross-section allows to place a screw fixing device on one end side, and, if necessary, to make additional round holes on its other end side, in which the sharp ends of the teeth of the working body can be placed during transportation manual cultivator, which prevents possible damage to surrounding objects and is injury-free for people. Secondly, the execution of coaxial through circular holes in the lateral sides of the stopper, in which the abutment tooth is placed, with a minimum clearance for sliding along the abutment tooth, ensures the orientation of the stopper in the transverse direction relative to the abutment tooth and, accordingly, relative to the working member. The prevention of rotation of the limiter around the axis of the support tooth is provided by the arrangement of the other bearing teeth of the working member in coaxial through circular holes with a larger diameter than the diameter of the hole for the support tooth. The gaps between the diameters of these holes and the diameters of the circumscribed circles of the cross-sections of the teeth are selected from the condition of free movement of the limiter along the teeth at the maximum possible technological deviations, for example, according to the location of the teeth along the cross member of the working body and their parallelism relative to each other. This makes it possible to reduce the requirements for the accuracy of the working body, which increases the manufacturability of its manufacture.

Thus, the implementation of the ripping depth limiter of rectangular shape in cross-section, for example, from a standard metal rectangular profile, makes it possible to simplify its manufacture, and also makes it possible, if necessary, to give it new properties - to use it as a cover for the sharp ends of the teeth of the working body in the process of transporting the hand cultivator. The simplification of the manufacturing technology of the working body is also facilitated by the execution of round through holes in the lateral sides of the stopper, used to locate it on the supporting teeth, of a smaller diameter compared to other round through holes necessary for passing other bearing teeth through the stopper.

FIG. 1 shows a possible embodiment of a rotary-type manual cultivator with the function of limiting the depth of loosening of the soil in its working condition.

FIG. 2 shows a variant of the design of the working body of a manual cultivator with a limiter of the depth of loosening of the soil installed on its teeth.

FIG. 3 shows an example of a limiter for the depth of loosening the soil using a rectangular steel profile and with a threaded hole for a fixing screw in its end side.

FIG. 4 shows the limiter of the depth of loosening of the soil in Fig. 3 with a screw provided with a handle for manual locking.

FIG. 5 shows the limiter of the soil loosening depth with a screw device in the form of a wing screw with a wing nut.

FIG. 6 shows the limiter of the soil loosening depth with a screw device in the form of a wing screw with a rectangular nut.

FIG. 7 shows a limiter for the depth of loosening the soil with a screw device in the form of a wing screw with a nut equipped with a support lever.

FIG. 8 shows the limiter of the soil loosening depth with a nut fixed on its outer end surface for a fixing screw.

FIG. 9 shows the limiter of the soil loosening depth with additional holes in its lower end side.

FIG. 10 shows a possible embodiment of a rotary-type manual cultivator with the function of limiting the depth of loosening of the soil in the state of transportation.

The essence of the proposed design of a manual cultivator with a limiter for the depth of loosening of the soil can be further illustrated by various examples of its implementation. In one of the variants (Fig. 1), it is a manual cultivator 1 of a rotary type with a working body 2 equipped with straight teeth 3. The handle 4 of the cultivator 1 is integral with the stand 5, which is fixed on the working body 2 with an offset relative to its axis of symmetry (shown is the offset option for a right-handed operator). The block of the main handle 6 and the rotary handle 7 is mounted with screws 8 on the handle 4 of the cultivator 1. The limiter 9 of rectangular shape in cross-section is mounted on the teeth 3 and fixed to them by means of a screw 10 for manual fixation.

The working body 2, in turn, can consist of a square steel profile 11, in which three teeth 3 are fixed (Fig. 2). On the teeth 3 there is a stop 9, which is a body 12 of a rectangular profile in cross section, in the lateral sides 13 of which there are holes for the teeth 3, and on the upper end side 14 there is a thumbscrew 15 abutting against the central support tooth 3 to fix the longitudinal position of the stop 9 on the working body 2.

Coaxial through circular holes 16 for the central support tooth 3 are made with a diameter that ensures a sliding fit on it of the limiter 9, and the coaxial through circular holes 17 for other bearing teeth 3 are made of a larger diameter, taking into account, for example, the possible technological deviation of the extreme teeth 3 from the central tooth 3 in any longitudinal position of the limiter 9 along the working body 2 (Fig. 3). The hole 18 in the upper end side 14 of the housing 12 for the screw 10 for manual fixation can be made with a larger diameter than the diameter of the screw 10, or with a thread for the screw 10, if the wall thickness of the upper end side 14 allows it. In the latter case, for example, a screw 10 with a handle 19 can be screwed directly into the body 12 of the stopper 9 (Fig. 4). Holes 16,17,18 can be made, for example, by drilling.

With a small thickness of the housing 12, inside it can be placed, for example, a wing nut 20, into which a fixing screw, for example, wing type 15 (Fig. 5) is screwed. In this case, the wing nut 20 with its base faces the upper end face 14, and the transverse size of the body 12 of the limiter 9 and the maximum transverse dimension of the wing nut 20 should be chosen so as to exclude the circular rotation of the wing nut 20 during the rotation of the wing screw 15.

As a nut placed inside the housing 12, a rectangular nut 21 can be used, in which, for example, a threaded hole is displaced to one of its end sides (Fig. 6), or a standard nut, for example, a hexagonal shape 22 with a thrust lever 23 (Fig. 7).

It is also possible to secure the nut 22 on the upper end surface 14 of the housing 12 coaxially with the hole 18 for the fixing screw, for example, by welding (Fig. 8).

The presence of a rectangular profile at the housing 12 of the lower end surface 24 of sufficient width allows, if necessary, to make additional holes 25 in it to accommodate the teeth 3 during transportation of the hand cultivator 1 (Fig. 9). An example of a variant of a hand-held cultivator 1 in a transport state with a stopper 9 installed at the ends of the teeth 3 in the "cover" position is shown in FIG. 10. Here the handle 4 and the post 5 are made of a square metal profile and form a telescopic connection with the screws 8 pressing the post 5 to the inner lower edge of the handle 4. The main handle 6 and the rotary handle 7 are made of plastic and are installed at the ends of the main and rotary levers of the handle 4 The teeth 3 of the working member 2 are inserted into the additional holes 24 of the limiter 9 and are held on them by friction forces, due, for example, to some additional displacement of the extreme holes 24 relative to the normal position of the ends of the extreme teeth 3 and, accordingly, the elastic deformation of the extreme teeth 3.

It should be noted that the implementation of the working member 2 with three bearing teeth 3, one screw fixture for fixing relative to the central supporting tooth 3 is similar to FIG. 2 and with the strut 5 displaced relative to the axis of symmetry of the working member 2 along the cross member 11, as shown in FIG. 1, 10 for a right-handed operator (for a left-handed operator - offset in the opposite direction), is preferable for loosening under fruit and berry bushes. For this, in some cases, it is more convenient to use a small-width working body 2 (with three teeth) in order to freely penetrate between closely spaced bushes. When using a manual cultivator mainly for loosening the soil in an open space, the number of teeth 3 on the working body 2 can be increased (relative to three). In such operating conditions, the stop 9 can be pushed against the stop against the crosspiece 11, or completely removed from the teeth 3. In the case of a larger number of teeth in comparison with FIG. 2, the number of supporting teeth 3 and, accordingly, screw fixing devices can be increased, for example, up to two, and the extreme teeth 3 on the working body 2 are selected as the supporting teeth 3.

The ratio of the lengths of the sides of the body 12 of a rectangular shape can be selected different based on the requirements for the accuracy of compliance with the established loosening depth and other design considerations, including equal to one, i.e. a square profile can be used.

As screws for fixing the stopper 9 can be used not only screws for manual fixing of the type of screws in Fig. 4, 5, but also tool-retained screws such as hexagon socket head bolts or screwdriver screws.

A combination of manual and instrumental fixation is also possible in the design of one screw fixture.

All the considered designs of the manual cultivator 1 with the limiter of the soil loosening depth do not exhaust all possible options for the implementation of the claimed technical solution.

The proposed model of the hand cultivator 1 works as follows. The screw fastening of the limiter 9 on the teeth 3 of the working body 2 is loosened by turning the screw 10 for manual fixation (or for instrumental fixation using an appropriate tool). The limiter 9 moves along the teeth 3 to a position that provides a predetermined depth of loosening of the soil under the bushes (on average from 2 cm to 12 cm), after which it is again fixed with the screw 10 relative to the supporting tooth 3, against which the end part of the screw 10 rests. wing nut 20 (Fig. 5), the elongated shoulder of the rectangular nut 21 (Fig. 6) or the thrust lever 23 of the nut 22 (Fig. 7) prevent the counterpart of the screw device from rotating in the body 12 of the stopper 9 during fixation. After that, the hand cultivator 1 can be used for loosening under the appropriate type of shrub and at a selected distance from its base. In this case, preference is given to a manual cultivator 1 of a rotary type (Fig. 1, 10), since when the working body 2 is located at an acute angle to the soil (to penetrate under the crown of the bushes), it provides loosening without tilting the operator's body by rotating the working body 2 around the rack five.

All longitudinal and transverse forces acting on the limiter 9 from the soil side are transferred to the central support tooth 3 by means of the screw 10 and the bearing surfaces of the holes 16, which ensures the preservation of the spatial position of the limiter 9 during operation. In this case, the rotation of the limiter 9 around the supporting tooth 3 is limited within acceptable limits, which are determined by the values of the gaps between the surfaces of the holes 17 and other bearing teeth 3.

Adjusting the depth of loosening the soil or removing the limiter 9 from the working body 2 are carried out using the operations described above.

If it is necessary to use the limiter 9 with additional holes 25 as a "cover" for the teeth 3 when transporting the hand cultivator 1, the limiter 9 is fitted with additional holes 25 on the ends of the teeth 3, where it is held by friction forces and can be additionally fixed in this position relative to crossbars 11 with improvised means (for example, a lace).

Thus, the proposed design of a manual cultivator allows not only to reduce damage to the root system of plants by limiting the depth of soil cultivation under shrubs in accordance with the requirements of agricultural technology of specific crops, regardless of the experience and care of the operator, and to adjust this parameter at the discretion of the operator, but also to improve the manufacturability the limiter and the working body, and also, if necessary, protect against the sharp ends of the teeth of the working body when transporting the hand cultivator.

Claims (10)

1. A manual cultivator containing at least a main handle and a working body with teeth, at least one limiter of the depth of loosening of the soil, having a closed profile in cross-section with coaxial through circular holes in its lateral sides, with which the limiter is planted at least on a part of the teeth of the working body with the ability to move along the teeth, as well as at least one screw device for fixing the limiter in the required position along the teeth, located on the end side of the limiter and interacting with the supporting tooth, characterized in that the closed profile in the cross-section of the limiter has rectangular shape, and the coaxial through round holes, in which the supporting tooth of the working body is placed, are made of a smaller diameter in comparison with other coaxial through round holes in which other teeth are placed. 2. Manual cultivator according to claim 1, characterized in that the screw device includes a screw for manual fixation, which is located in the hole on the end side of the limiter and is abutted against the supporting tooth of the working body. 3. The hand cultivator according to claim 1, characterized in that the screw device includes a screw or bolt for instrumental fixation, which is located in the hole on the end side of the limiter and is abutted against the supporting tooth of the working body. 4. Manual cultivator according to any one of paragraphs. 1-3, characterized in that the threaded hole of the screw device is made in the end side of the limiter. 5. Manual cultivator according to any one of paragraphs. 1-3, characterized in that the screw device includes a wing nut located inside the limiter so that its base faces the end side with a hole for the fixing screw. 6. Hand cultivator according to any one of paragraphs. 1-3, characterized in that the screw device includes a rectangular nut, the threaded hole of which is displaced to its end side, and the nut itself is located inside the limiter. 7. Hand cultivator according to any one of paragraphs. 1-3, characterized in that the screw device includes a nut with a thrust lever attached to it, and the nut itself is located inside the limiter. 8. Hand cultivator according to any one of paragraphs. 1-3, characterized in that the screw device includes a nut fixed on the outer surface of the end side of the limiter coaxially with the hole for the fixing screw. 9. Manual cultivator according to any one of paragraphs. 1-3, characterized in that on the end side of the limiter, opposite to the end side with a hole for the fixing screw, additional holes are made to accommodate the teeth of the working body in the transport state of the manual cultivator. 10. Hand cultivator according to any one of paragraphs. 1-3, characterized in that the working body contains three teeth, of which the central tooth is supporting, and the main handle is offset relative to the axis of symmetry of the working body.

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