RU225981U1 - Tillage plow with wear-resistant coating - Google Patents

Abstract

The utility model relates to agricultural engineering, in particular to moldboard-type tillage implements. The technical result of the utility model is to create a wear-resistant coating with increased mechanical strength on the plow blade surface of the plow, obtained as a result of laser sintering of chromium carbide powder. A plow of a soil-cultivating implement with a wear-resistant coating, containing a working body with a screw-type plowshare-moldboard surface and elements for connecting it to the base frame of the implement, and the mouldboard surface is made in the form of a part of the surface of an open torus, which is formed by screw rotation of the producing axis around the axis, and the plowshare has a blade in in the form of a spiral edge, wherein the lower and upper edges of the moldboard surface along their entire length are additionally equipped with screw-shaped plates and are associated with them, while the width of the plate is made increasing in the direction from the ploughshare to the edge of the moldboard surface opposite to it, the upper part of the share is made protruding relative to it the lower part, and the upper edge of the moldboard surface is shifted back relative to its lower edge and is located along the longitudinal axis of the tool, while the lower edge of the moldboard part is located at an acute angle to the longitudinal axis of the tool and in the tail part is shifted back relative to its upper part, on a screw plowshare The moldboard surface of the plow has a wear-resistant coating with increased mechanical strength and resistance to abrasive wear, obtained as a result of laser sintering of chromium carbide powder. 1 ill.

Description

The utility model relates to agricultural engineering, in particular to moldboard-type tillage implements.

A feature of the operation of tillage implements is the increased wear of working elements (ploughs) interacting with abrasive particles of the top layer of soil.

In the process of such work, the surface is destroyed and the working elements are deformed, which subsequently requires their replacement. Under conditions of constant abrasive action, the most worn elements of tillage implements are plows, which take the main mechanical loads when destroying the top layer of soil, cutting and digging up soil layers. Since plows are subject to high abrasive wear of the plow-mouldboard surface, their operating time is short, which requires frequent restoration work and regular replacement of plows of soil-cultivating implements. In this regard, the task of developing the design of plows with increased surface wear resistance is relevant and economically in demand in agricultural engineering.

The most commonly used methods of surface hardening in industrial production are surface plastic deformation, electric arc surfacing, hardening, carburization, plasma spraying of wear-resistant coatings, etc.

The design of the working body of a moldboard plow is known [Patent RU No. 2488258, IPC A01B 15/00, 07.27.2013], containing a stand with a shoe and a field board, a ploughshare and a moldboard. Elastic pads are attached to the blade on the back side of the working surface. As a means of regulation, a hinged connection of the plow-mouldboard surface with the stand was used. The edges of the plates are made rounded.

The disadvantage of this design is the insufficiently high resistance of the plow blade surface to abrasive wear, leading to a decrease in operational reliability.

The closest to the proposed solution is the design of a tillage implement [Patent RU No. 2033001, IPC A01B 15/02, 04/20/21995], made in the form of a semi-mounted implement, including a base frame formed from a system of detachable beams connected by identical detachable clamps to each other and to plow bodies; screw plowshare-moldboard bodies are formed by a part of an open torus, a screw share and screw extensions of the side edges of the torus part, and the upper one is expanded and protrudes in front of the lower cutting edge of the ploughshare, and its side edge runs parallel to the axis of the plow and, continuing, cuts off the tail moldboard part with increasing its width. The plow is supported by a ski with a telescopic stand with a system of holes for adjusting the plowing depth. The blade-mouldboard surface of the plow is equipped with a system of through holes for communication with the atmosphere.

The disadvantage of this design is the insufficiently high resistance of the plow blade surface to abrasive wear, leading to a decrease in operational reliability.

The objective of the utility model is to create a plow design for a soil-cultivating implement with increased resistance of the plow-mouldboard surface to abrasive wear and increased operational reliability.

The technical result of the utility model is to create a wear-resistant coating with increased mechanical strength on the plow blade surface of the plow, obtained as a result of laser sintering of chromium carbide powder.

The problem is solved due to the fact that in the proposed design of a plow of a soil-cultivating implement with a wear-resistant coating, containing a working body with a screw-type blade-mouldboard surface and elements for connecting it to the base frame of the implement, and the moldboard surface is made in the form of a part of the surface of an open torus, which is formed helical rotation of the producing axis around the axis, and the ploughshare has a blade in the form of a spiral cut, and the lower and upper edges of the moldboard surface along their entire length are additionally equipped with screw-shaped plates and are associated with them, while the width of the plate is made increasing in the direction from the ploughshare to the opposite one relative to it edge of the moldboard surface, the upper part of the ploughshare is made protruding relative to its lower part, and the upper edge of the moldboard surface is shifted back relative to its lower edge and is located along the longitudinal axis of the tool, while the lower edge of the moldboard part is located at an acute angle to the longitudinal axis of the tool and in the tail part shifted back relative to its upper part, according to a new technical solution, on the helical blade-mouldboard surface of the plow there is a wear-resistant coating with increased mechanical strength and resistance to abrasive wear, obtained as a result of laser sintering of chromium carbide powder.

The structure of the plow of a soil-cultivating implement can be made of structural steels by rolling, machining, and pressure treatment. The formation of a wear-resistant coating is carried out by sintering chromium carbide particles under the influence of pulsed laser radiation and creating a functional surface layer.

Description of the design.

In fig. Figure 1 shows the design of a plow of a soil-cultivating implement with a wear-resistant coating: 1 - plow, 2 - cutting edge of the ploughshare, 3 - screw plow-mouldboard surface, 4 - telescopic stand, 5 - system of holes, 6 - bolt retainer, 7 - system of through holes, 8 - wear-resistant coating.

A plow of a soil-cultivating implement with a wear-resistant coating (Fig. 1) contains a frame (not shown in Fig.), to which plows 1, having a helical plowshare-mouldboard surface 3 and a cutting edge of the ploughshare, are attached by means of telescopic posts 4 with systems of holes 5 and bolt clamps 6 2. On the plow-mouldboard surface 3 of the plow 1 there is a system of through holes 7.

On the screw plow-mouldboard surface 3 of the plow 1 there is a wear-resistant coating 8, which has a thickness of 0.1-0.2 mm. The wear-resistant coating 8 of the helical blade-mouldboard surface 3 is obtained as a result of laser sintering of chromium carbide powder with a dispersion of 200-300 nm and has a microhardness in the range of 11-13 GPa. This coating provides increased mechanical strength of the screw plow-mouldboard surface 3 and its resistance to abrasive wear, which in turn increases the operational reliability of the plow design.

The device works as follows.

Due to tractor traction, each plow 1 of the soil-cultivating implement with a wear-resistant coating is buried into the soil by the cutting edge of the ploughshare 2 to a given depth and cuts soil layers of oval cross-section. The depth of the plow 1 is adjusted by a telescopic stand 4 with a system of holes 5 and a bolt lock 6, which are mounted on the frame (not shown in the figure). In the process of deepening the plow 1 into the soil and during the plowing process, the screw plow-mouldboard surface 3 is exposed to various solid soil particles, which leads to its mechanical destruction and wear, which is especially evident when cultivating rocky and sandy soils. Due to the helical plowshare-moldboard surface of each plow, made in the shape of part of the surface of the open torus, the trimmed layer turns 180°. To combat soil adhesion, there is a system of through holes 7 on the plow blade surface of the plow.

The presence of a wear-resistant coating 8 on the helical plow-mouldboard surface of each plow of the soil-cultivating implement provides increased mechanical strength and resistance to abrasive wear of the plow, which helps to increase its operational reliability.

Research has shown that the optimal parameters for the process of laser pulsed sintering of chromium carbide powder on the blade-mouldboard surface of a plow are: voltage on the pump lamp 250-300 V, focusing spot diameter 0.5-0.7 mm, laser pulse repetition rate 15- 20 Hz, pulse pitch 0.2-0.4 mm, number of scans (process passes) 4-6 times. When the values of these parameters decrease, the hardening effect is not observed, and when they increase, the functional layer obtained as a result of laser sintering of chromium carbide powder is characterized by a rough, heterogeneous structure due to the formation of many defective areas in the form of burns and sagging. In the specified range of parameters, sintering of chromium carbide particles occurs under the influence of pulsed laser radiation and the formation of a wear-resistant coating with a thickness of 0.1-0.2 mm with a microhardness value of 11-13 GPa, which ensures an increase in the resistance of the plow blade surface to abrasive wear of no less than by 45%.

Thus, the proposed design of a plow of a soil-cultivating implement, which has a wear-resistant coating of chromium carbide powder on the screw plow-mouldboard surface with increased mechanical strength and resistance to abrasive wear, provides increased operational reliability of the plow, which allows the design to be used for a longer period of time without undergoing repairs or replacements.

Claims (1)

A plow of a soil-cultivating implement with a wear-resistant coating, containing a working body with a screw-type plowshare-moldboard surface and elements for connecting it to the base frame of the implement, and the mouldboard surface is made in the form of a part of the surface of an open torus, which is formed by screw rotation of the producing axis around the axis, and the plowshare has a blade in in the form of a spiral edge, wherein the lower and upper edges of the moldboard surface along their entire length are additionally equipped with screw-shaped plates and are associated with them, while the width of the plate is made increasing in the direction from the ploughshare to the edge of the moldboard surface opposite to it, the upper part of the share is made protruding relative to it lower part, and the upper edge of the moldboard surface is shifted back relative to its lower edge and is located along the longitudinal axis of the gun, while the lower edge of the moldboard part is located at an acute angle to the longitudinal axis of the gun and in the tail part is shifted back relative to its upper part, characterized in that The screw blade-mouldboard surface of the plow has a wear-resistant coating with increased mechanical strength and resistance to abrasive wear, obtained as a result of laser sintering of chromium carbide powder.