EA031751B1 - Reversible three-point-mounted plough - Google Patents

Abstract

for A reversible three-point-mounted plough (1) is described comprising a depth-wheel arrangement (2), in which two concentric depth wheels (21, 22) are attached to a wheel arm (24) connecting a middle portion (231) of a wheel shaft (23) to a wheel mount (25).

Description

The invention relates to a circulating plow with a three-point linkage, in which the support wheel assembly contains two concentric support wheels with a gap between them.

Currently, plows with a three-point hitch are equipped with a single support wheel. As a rule, this provides sufficient bearing capacity, allowing you to maintain the working depth of the rear of the plow at the right level. If it is necessary to increase the bearing capacity of the support wheel, a problem arises related to the limitations of the diameter of the support wheel due to the clearance requirements when reversing a reversible plow with a three-point linkage.

On the other hand, on a semi-mounted plow, two support wheels are assembled into a single unit with a relatively large distance from each other, taking into account the fact that these wheels will also be used to transport the plow.

Essentially, a single support wheel creates a number of problems, in particular, related to the determination of wheel suspension parameters, since the wheel suspension must be installed asymmetrically with respect to the center plane of the wheel, connecting it with a protruding wheel axle. As a result, the wheel suspension is exposed to torque around the center axis of the wheel arm.

Alternatively, a single support wheel may be mounted on a fork, but this will make it difficult to adapt the wheel suspension to different wheel sizes. In addition, the plug is largely prone to collect soil, plant material, and other substances that adhere to the support wheel.

The use of a single support wheel in a reversible plow with a three-point linkage has another drawback, namely the alternating rotation of the wheel lever inward and outward. When the lever is turned outwards, that is, in the direction of unplowed soil, the wheel lever can easily catch on the fence, fence, and the like when plowing the edge of the field.

The aim of the invention is to eliminate or reduce at least one of the disadvantages inherent in the prior art, or at least to create a useful alternative to the prior art.

This goal is achieved thanks to the features disclosed in the description below and in the appended claims.

The aim of the present invention is to improve the support wheel assembly for a reversible plow with a three-point hitch, the support wheel assembly should have sufficient bearing capacity with moderate wheel size, demonstrate high stability during plowing and transportation, and the support wheel assembly can be used as a support / transport wheel , apply axial load to the wheel suspension with the creation of minimal torsional forces, have clean outer side surfaces easy to adapt to different adjusting devices.

A reversible plow with a three-point hitch was proposed, containing a support wheel assembly in which two support wheels are arranged concentric side by side, with an axial clearance large enough to accommodate the part of the wheel lever that extends from the wheel axle to the wheel attachment.

The height of the wheel arm is preferably significantly greater than the width of the wheel arm, since the symmetrical arrangement of the wheels causes small torsional loads on the wheel arm around its central axis.

The wheel arm can be pivotally connected to the wheel mount around a horizontal swivel, located perpendicular to the working direction of the revolving plow. The hinge joint can be attached to a sleeve that can rotate around a horizontal axis of rotation of the shaft, oriented in the working direction of the revolving plow. The rotary shaft can be rigidly attached to the mounting bracket. A mounting bracket for a depth adjustment device located between the mounting bracket and the wheel lever can preferably be mounted on the pivot bushing, preferably diametrically opposed to the indicated hinge joint. The depth control device may be a crank, an adjustable rod, a hydraulic or electric actuator, or another similar device.

The rotary sleeve may contain one or more spring-loaded locking devices designed to further increase the stability of the support wheel assembly. The locking device contains one or more locking balls or rods placed in the corresponding notches located in the axial direction in the rotary sleeve or on it, and abutting against the compression spring, also located in the notch. The surface from which the rotary shaft protrudes contains, respectively, one or more corresponding recesses, into which a part of the fixing ball or rod enters with the possibility of releasable engagement. Thus, the support wheel assembly can be fixed in one or more positions, for example, in two working positions, and the lock is opened when sufficiently large lateral forces act on the support wheels, for example, caused by gravity when the revolving plow is turned in the opposite direction to plowing . The person skilled in the art will know how to determine the release force by selecting the characteristics of the compression spring, selecting the type of grooves or cuts for the boundary

- 1031751 axial displacement of the locking ball / rod in the recess.

Alternatively, the locking ball / rod may be located in a radial cut-out in the rotary sleeve, the rotary shaft comprising one or more groups of corresponding recesses intended to receive a portion of the locking ball or rod to establish the releasable locking engagement. The compression spring may be located in the housing, protruding from the peripheral region of the rotary sleeve.

A transport lock designed to lock the support wheels in an intermediate position, for example, to support the rear of the revolving plow during transport when the revolving plow is rotated into the intermediate position, is connected to the rotary sleeve. The locking bolt is located in the axial guide in the peripheral region of the rotary sleeve and is designed to interact with a cutout or recess in the surface from which the rotary shaft projects.

Alternatively, the locking bolt may be radially mounted on the rotatable sleeve, wherein the bolt is adapted to cooperate with a recess on the rotary shaft.

In particular, the invention relates to a support wheel assembly for a revolving plow, comprising two concentric support wheels attached to a wheel arm connecting the middle part of the wheel axle to the wheel attachment. The advantage of this is that, basically, the wheel lever is subjected to axial load without any significant torque.

The height of the wheel arm can significantly exceed the width of the wheel arm. The advantage of this is that the support wheel assembly may have sufficient strength in the absence of a distance between the support wheels, which makes it possible to eliminate the impractical increase in the width of the support wheel assembly.

The wheel arm height / width ratio can be 3: 1-10: 1, preferably 4: 19: 1, most preferably 4: 1-8: 1. Thus, the strength of the wheel arm to a large extent can be achieved by adapting the height of the wheel arm. Thus, the wheel lever may have a higher degree of flexibility along its transverse axis and may even be made of spring steel or other material with a high yield strength.

The front part of the wheel arm, located outside the peripheral region of the support wheels, can expand significantly. The advantage of this is that the wheel lever can be given greater rigidity in the area of attachment of the wheel lever and the depth adjustment device.

The wheel arm can be attached to a horizontal swivel located on the rotary sleeve on the wheel mount, the swivel is located perpendicular to the working direction of the revolving plow, and the rotary sleeve is rotatably fixed on the horizontal rotary shaft fixed in the wheel bracket with the axial direction coinciding with the working shaft direction of the revolving plow. The advantage of this is the reliable protection of the adjustment mechanism against the effects of the earth and plant residues adhering to the wheel mounting.

The wheel mount may contain a locking device designed to hold the rotary sleeve with rotation lock and detachably mounted on the rotary shaft.

One or more axial cuts can be made on or in the pivot bushing, each of which is designed to receive the lock body, and the wheel bracket can contain several corresponding grooves, and the locking engagement of the pivot bushing with the wheel bracket can open when the axial force component is applied to the supporting wheels. Alternatively, one or more radial cuts can be made in the rotary sleeve, each of which includes a spring-loaded retainer housing, and the rotary shaft can contain several corresponding grooves. The advantage of this is to increase the lateral stability of the support wheel assembly in its working positions without disturbing the adjustment between different positions.

The recess may contain a slope for guiding the lock body into or out of the recess. This allows you to prevent turning the node support wheels after reaching its working position when reversing the direction of plowing the circulating plow.

The wheel mount may contain a depth adjustment device located between the mounting arm mounted on a rotatable hub mounted on the wheel mount and the front part of the wheel arm. The depth adjustment device thus follows the support wheel assembly as it rotates while the plow is turning, and only one depth adjustment device will be sufficient.

The depth adjustment device can be selected from the group consisting of a crank, an adjustment rod, an electrical or hydraulic actuator. Thus, several alternatives are provided for adjusting the depth, from hand-held devices to remote control by hydraulic or electric drive.

The locking bolt, located in the guide on the rotary sleeve, can be made with the possibility of axial movement in interaction with the cutout, made in the wheel bracket or the rotary shaft. This allows you to get a stable fixation node support wheels in the transport position without a function affecting the operational readjustment support wheels when turning

- 2,031,751 plows.

An example of a preferred embodiment shown in the accompanying drawings, in which FIG. 1 is a perspective view, at an angle from the front, on the back of a revolving plow with a support wheel assembly in accordance with the present invention;

in fig. 2 shows an axonometric view of the support wheels assembly on an enlarged scale, at an angle behind and to the left;

in fig. 3 is a perspective view of the support wheel assembly at an angle behind and to the right;

in fig. 4 shows a side view of the support wheel assembly;

in fig. 5 shows a rear view of the support wheel assembly;

in fig. 6 shows a longitudinal section of the fixing device on an enlarged scale.

First consider the FIG. 1, which depicts a revolving plow 1, equipped with an assembly of 2 support wheels according to the invention. Details are disclosed in FIG. 2-6.

Node 2 support wheels contains the first and second support wheel 21, 22, and the wheels are identical to each other and are concentric on the wheel axle 23. The gap between the support wheels 21, 22 leaves room for the wheel lever 24 mounted on the middle part 231 of the wheel axle 23, the wheel lever 24 is attached to the wheel axle 23. The height of the wheel lever 24 is designated H, and the width of the wheel lever 24 is designated W (see Fig. 2). In this case, the depicted wheel lever 24 is made of plates, screwed bolts. The front part 241 of the wheel arm expands and connects to the rotary sleeve 251 by means of a lateral swivel 252.

The high height H of the wheel lever 24 with respect to its width W provides sufficient resistance to bending in the vertical direction, while the relatively small width W of the wheel lever allows you to use a small gap between the support wheels 21, 22. Thus, the location of the wheel lever 24 is centered relative to support wheels 21, 22 reduces torsional stresses on the wheel lever 24 when exposed to unbalanced loads on the node 2 support wheels. In the case of the manufacture of the wheel lever 24 from a material with a high yield strength, for example from spring steel, the wheel lever 24 will also be distinguished by high lateral flexibility.

In the present embodiment, the ratio of height to width (H: W) is about 4: 1.

The rotary sleeve 251 is installed with the possibility of rotation on the rotary shaft 2561, protruding from the wheel bracket 256, designed to be installed on the reversible plow 1 (see Fig. 1).

The rotary sleeve 251 contains a locking device 255, in the present embodiment, located in the axial direction of the rotary sleeve 251 (see Fig. 3). Now consider FIG. 6, which shows details of the locking device 255. The recess 254 includes a retainer body 2551, which in the present embodiment is a locking ball recessed into the socket 2554, partially protruding from the recess 254 and intended to engage with the notch 2562, in the present embodiment located on the back the surface of the wheel bracket 256. Case 2551 latch spring loaded compression spring 2552, located between the socket 2554 and adjustable spring support 2555, located in the end portion of the housing 2553 spring.

The recess 2562 has a slope of 2563, designed to guide the housing 2551 clamp in the recess 2562 and out of it (see Fig. 2 and 5). In the diametrically opposite direction from the slope 2563, the notch 2562 contains a relatively steep inclined plane. At the same time, the node 2 of the support wheels cannot pass by its working position when reversing the direction of plowing the revolving plow 1.

Specialist in the art it is obvious that the locking device can be implemented in another way, for example by location in the radial direction of the rotary sleeve 251, and the notch 2562 will be located in the peripheral region of the rotary shaft 2561.

In addition, the rotary sleeve 251 contains a locking bolt 258 (in particular, see Fig. 2 and 3) installed in the guide 259, located in the peripheral region of the rotary sleeve 251 in the axial direction of the rotary sleeve 251. The locking bolt 258 is designed to engage with cut 257, located in the wheel bracket 256, when the reversible plow 1 is in the middle position (not shown in Fig.), intended for transportation.

From the rotary sleeve 251 in the rear direction are two mounting levers 253. The device 26 adjusting the depth forms an adjustable connection between the rear end sections of the mounting levers 253 and the front part 241 of the wheel lever, which allows you to fix the crank 261 in the main bearing 262 fixed to the mounting levers 253, and the main nut 263, fixed on the front of the wheel arm 241.

Claims (12)

CLAIM 1. A reversible plow (1) with a three-point hinge, in which the node (2) of the support wheels contains two concentric support wheels (21, 22) attached to the wheel arm (24) connecting - 3 031751 middle part (231) of the wheel axle (23) with a wheel attachment (25) attached to the rear of the specified plow (1), with the specified node (2) of the supporting wheels made with the ability to support the rear of the plow (1) during transport time, characterized in that said support wheels (21, 22) are arranged with a clearance in the axial direction, the value of which is sufficient to accommodate part of the wheel lever (24); wheel lever (24) is installed with the possibility of rotation around a horizontal rotary shaft (2561), the axial direction of which coincides with the working direction of the revolving plow (1); and the wheel mount (25) contains a depth adjustment device (26) passing between the fixing lever (253) mounted on a rotatable sleeve (251), which is rotatably fixed on a horizontal rotary shaft (2561) fixed to the wheel bracket (256 ) wheel mounting (25), and the front part (241) of the wheel lever. 2. A plow according to claim 1, wherein the height (H) of the wheel lever (24) is significantly greater than the width (W) of the wheel lever (24). 3. A plow according to claim 1, wherein the ratio (H: W) of the height / width of the wheel lever (24) is 3: ΙΙΟ:!, Preferably 4: 1-9: 1, most preferably 4: 1-8: 1. 4. A plow according to claim 1, wherein the wheel lever (24) is made of spring steel. 5. A plow according to claim 1, in which the front part (241) of the wheel lever located outside the peripheral region of the support wheels (21, 22) is expanded. 6. A plow according to claim 1, in which the wheel lever (24) is attached to a horizontal swivel (252) located on the rotary sleeve (251) on the wheel mount (25), with the hinge connection (252) perpendicular to the working direction of the plow ( one). 7. A plow according to claim 1, in which the wheel mount (25) comprises a fixing device (255) for holding the rotatable sleeve (251) with its rotation locked and detachably mounted on the rotary shaft (2561). 8. The plow according to claim 7, wherein one or more axial cuts (254) are made on or in the rotatable sleeve (251), each of which is intended to receive a spring-loaded retainer body (2551), and the wheel bracket (256) contains several corresponding recesses (2562), and the locking engagement of the rotary sleeve (251) with the wheel bracket (256) is open when an axial force component is applied to the support wheels (21, 22). 9. The plow according to claim 7, wherein one or more radial cuts (254) are made in the rotary sleeve (251), each of which is intended to receive a spring-loaded retainer body (2551), and the rotary shaft (2561) contains several corresponding grooves ( 2562), and the locking engagement of the rotary sleeve (251) with the rotary shaft (2561) is open when an axial force component is applied to the support wheels (21, 22). 10. A plow according to claim 7 or 8, in which the recess (2562) comprises a slope (2563) for guiding the body (2551) of the retainer into or out of the recess (2562). 11. Plow on π. 1, in which the device for adjusting the depth includes a crank, an adjustment rod, or an electric or hydraulic actuator. 12. The plow according to claim 1, in which the locking bolt (258) located in the guide (259) on the rotary sleeve (251) is adapted for axial movement in cooperation with the notch (257) made in the wheel bracket (256) or in a rotary shaft (2561).