RU168991U1 - Hydraulic cylinder for tractor attachments - Google Patents

Abstract

The utility model relates to transport engineering. The hydraulic cylinder for tractor attachments contains a cylindrical body, which is closed on both sides by covers, one of which is blind, and the other is made with a central hole equipped with seals for the outside of the rod carrying the attachment unit to one attachment design element. Opposite axes are mounted on a cylindrical body in its central part from the outside for mounting in sockets on another structural member of the attachment. An inlet channel is made in the front cover for connecting a hydraulic pressure supply hose through a channel made in this cover to the rod cavity of the hydraulic cylinder, and in the blind cover there is a channel for communicating the piston cavity of the hydraulic cylinder with a pressure supply source into this cavity. On the rod, the attachment unit to one construction component of the attachment is made in the form of a cardan joint, and the hydraulic hose for supplying pressure to the rod cavity of the hydraulic cylinder through the channel in the cover is made in the form of a metal pipe carrying a head with a channel, a conical tip with seals inserted into the input channel and bolted to the cover. The hydraulic cylinder is equipped with a junction box mounted on a cylindrical body and made with inlet channels in communication with a pressure source for supplying this pressure in the cavity of the hydraulic cylinder, and with output channels, in one of which the other end of the metal pipe is fixed, and the other is made in the head with a conical tip with seals inserted in the inlet to

Description

The utility model relates to transport engineering and relates to the design of a power hydraulic cylinder for controlling the rotation or lifting of the working body of the attachment of an agricultural or construction tractor.

In tractors, hydraulic systems for various purposes are most widely used - from the steering gear (power steering) to the hydraulic drives of excavators, hoists and other equipment. All these systems are built on the same principles and common component base, and in all of them the key details are hydraulic power cylinders. A hydraulic cylinder is a power element of a hydraulic system that converts the hydrostatic pressure of a working fluid into mechanical work. The cylinder is one of the simplest types of hydraulic motors that convert fluid pressure into reciprocating movement of the working body. At the same time, hydraulic cylinders have high efficiency and are capable of developing efforts of tens of tons, which is why they have secured the widest possible distribution.

All hydraulic cylinders used on tractors can be divided into five large groups: cylinders for hydrostatic power steering, rear / front link cylinders, hydraulic rams, dumps and other equipment, outrigger cylinders and transmission unit control cylinders (gearbox, reduction gear and rear axle) ) All these cylinders have one thing in common - they are mounted directly on the tractor and are powered by the tractor hydraulic system. There is another category of hydraulic cylinders - mounted on attachments, and often (but not always) powered by an autonomous hydraulic system. Such equipment includes excavators, wheel loaders, special road vehicles, agricultural machines, etc.

By the method of attachment, such hydraulic cylinders are divided into two groups. The first is the attachment of the rod to one element of the link system and the end of the cylinder body to another element of the same link system. The fastening of the hydraulic cylinders of the first group is used for small cylinders in size and provided that these cylinders fit in the space between the connected links. The second group is the overall hydraulic cylinders. The rod of such, for example, a long cylinder, is fixed on one element of the link system, with another element of the same link system connected supports mounted on the housing of the hydraulic cylinder in its middle part. With this fastening, the free end of the hydraulic cylinder body makes angular movements in space at the moment of its swinging on the supports. The use of such hydraulic cylinders is caused by the need to create large displacements, that is, significant in terms of rod outputs.

The described hydraulic power cylinders are double-acting. In the General case, the hydraulic cylinder has the following device. Its basis is a cylindrical body, which is closed on both sides by covers - the front, through which the stock goes, and the back, which carries an eye. Inside the housing is a rod on which the piston is fixed with a nut. For tightness on the external and internal (on the side of the contact with the rod) sides of the piston there are O-rings. An eye is attached to the outer end of the stem. The front cover of the cylinder through which the stem passes has O-rings inside and out (at the point of contact with the stem), and there may also be a wiper inside to remove dirt from the stem. The cover is fixed by a stopper, and can be additionally held on top by a union nut.

Inputs for supplying and discharging oil are provided on the cylinder body; they can be of two types: fittings are simple and threaded, the thread being on the outside, and bonks are fittings with an internal thread that can go up or sideways.

Moreover, the cylinder can be equipped with two fittings, two bonks or one fitting and one brisk. On some hydraulic cylinders, threaded angles are also installed, which facilitate the installation of hoses, preventing their kinks and twisting.

The principle of operation of a double-acting hydraulic cylinder is simple. The piston divides the cylinder into two sealed chambers, which are connected through the fittings to the hydraulic distributor. The distributor is designed so that when oil is supplied to one cylinder chamber, oil from the opposite chamber is drained into the reservoir, and vice versa. Thus, when oil is supplied to one chamber, the pressure in it increases and the piston, which does not experience resistance from the opposite side, begins to move, pushing the rod and the working element connected to it. If necessary, return the working body to its previous position, the oil is drained from the newly filled cavity, and the opposite cavity, on the contrary, is filled - due to this, the pressure changes and the piston moves in the other direction. If it is necessary to stop the working body in one or another position, the distributor blocks access to the chambers of the hydraulic cylinder, and the oil remaining in them ensures that the piston is held in the selected position.

Thus, a hydraulic cylinder is known for attachments of an agricultural or construction tractor, comprising a cylindrical body, which is closed on two sides by covers, one of which is blind, and the other is made with a central hole equipped with seals, for the outside of the stem carrying the attachment unit to one to the construction component of the attachment, the rod located inside the cylindrical body is made with a piston, and on the cylindrical body in its central part it is fixed outside the opposite axes are for mounting in sockets on another structural element of the attachment, while the front cover has an inlet channel for connecting through the fitting of the hydraulic pressure supply hose through the channel made in this cover into the rod cavity of the hydraulic cylinder, and the channel for communication is made in the blind cover the piston cavity of the hydraulic cylinder as a source of pressure supply to this cavity (see "The hydraulic cylinder for lifting the blade 700-79-4277SP", posted on the website "IMPEL" of the company "Agrosnabzhenskaya company IMPEL" Internet on-line access at the address: http://www.impel.com.ua/cylinder/cg_700-79-4277sp.shtml discovered in 2015 (copy attached).

The disadvantage of this hydraulic cylinder is its low operational reliability, due to the fact that when mounting the cylinder body with opposed axles in the pins, the rod also has a rigid mount to the working link of the attachment. Since the links of the attachment at the hinge points of the joints wear out and acquire backlash and lateral displacements, the hydraulic cylinder begins to act as a compensator for these deviations, which is unacceptable for the hydraulic cylinder. This leads to the appearance of bending loads on the stem and loss of tightness in the area of the front cover (from which the stem exits). In addition, the connection diagram of the hydraulic hoses provides for direct connection directly through the fittings to the caps. The hoses are long, move in space and overload the fittings under pressure, which leads to leaks and the need to replace hoses.

The technical result, the achievement of which the proposal is directed, is to increase operational reliability when working with high pressures.

This result is achieved by the fact that in the hydraulic cylinder for tractor attachments containing a cylindrical body, which is closed on both sides by covers, one of which is blind, and the other is made with a central hole equipped with seals, for the outside of the stem carrying the attachment unit to one the construction component of the attachment located inside the cylindrical body the rod is made with a piston, and on the cylindrical body in its central part the opposite is fixed axles for mounting in sockets on another construction component of the attachment, while the front cover has an inlet channel for connecting a hydraulic pressure supply hose through the channel made in this cover to the rod cavity of the hydraulic cylinder, and in the blind cover there is a channel for communicating the piston cavity of the hydraulic cylinder with as a source of pressure supply to this cavity, on the rod the attachment unit to one attachment design element is made in the form of a cardan joint, the hydraulic supply hose In the rod cavity of the hydraulic cylinder through the channel in the cover, it is made in the form of a metal pipe carrying a head with a channel, a conical tip with seals inserted into the inlet channel and bolted to the cover, while the hydraulic cylinder is equipped with a junction box mounted on a cylindrical body and made with output channels, in one of which the other end of the metal pipe is fixed, and the other is made in the head, with a conical tip with seals inserted into the inlet channel in the blind cover, and with one of the channels used to communicate with the pressure source for supplying this pressure to the hydraulic cylinder cavities, and for each hydraulic cylinder cavity in the junction box two opposite input channels are made, one of which is closed by a plug.

The present utility model is illustrated by a specific example of execution, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the required technical result.

In FIG. 1 is a longitudinal section of a hydraulic cylinder;

FIG. 2 is a top view of the hydraulic cylinder.

According to this utility model, the design of a hydraulic cylinder for tractor attachments is considered, mainly for heavy agricultural or construction equipment (weighing 35 tons or more). More specifically, we consider the design of the power hydraulic cylinder, which allows to realize a long exit of the rod from the body of the hydraulic cylinder.

Such a hydraulic cylinder for tractor attachments (Figs. 1 and 2) contains a cylindrical body 1, which is closed on both sides by covers 2 and 3, one of which 2 is blind, and the other 3 is made with a central hole equipped with seals 4, to exit rod 5, bearing the node 6 of the attachment to one structural element of the attachment. On the rod, the attachment unit to one structural element of the attachment is made in the form of a cardan joint. Opposite axes 7 are fixed on a cylindrical body in its central part from the outside for mounting in sockets on another structural member of the attachment. The rod 5 located inside the cylindrical body is made with a piston 8.

The axes 7 are displaced along the axis of the cylindrical body towards the blind cover 2 so that the center of mass 9 of the hydraulic cylinder is located on the section of the housing 1 between the axes 7 and the cover 3. This allows the axes 7 to be fixed in the sockets to ensure that the hydraulic cylinder is in a vertical position (when not fixed attachment node 6). In reality, this arrangement of the center of mass allows to reduce the inertia of the upper part of the hydraulic cylinder when it is rotated (when working with attachments).

The implementation of the attachment unit 6 in the form of a cardan joint allows reducing bending loads on the rod in the position of its maximum extension and leveling inaccuracies in the layout of the elements of the tractor hinged system. It is known that attachments are made according to the scheme of free-of-tolerance connection of links to each other. This leads to the appearance of backlash when moving the links. During operation, such backlash is formed both as a result of the action of power loads on the equipment and as a result of the natural wear of the hinges. The hydraulic cylinder itself is installed in sockets in which the axes 7 are clearly positioned and have no displacements, except for rotation or rotation around the axis of rotation. Thus, in a hinge system with backlash and free displacements of the links in the transverse direction relative to the attachment points, the hydraulic cylinder is positioned from one end without taking into account the compensation of these displacements at the end of the rod. Therefore, a gimbal hinge is selected as the attachment point, which allows simultaneous transfer of power loads to the links of the hinged system from the movement of the rod and provides compensation for misalignment or displacements of the links with respect to the axis of the rod. Since we are talking about heavy equipment weighing 35 tons and above, the application of this solution significantly removes the effect of transverse loads from the links of the attachment to the rod.

The hydraulic cylinder is a long construction, the end parts of which make significant angular displacements relative to the 7 axes. In this regard, the use of flexible pressure supply hoses in the hydraulic cylinder cavities and their traditional connection schemes (by screwing in the fittings) with separate hoses for the rod and piston cavities becomes unsuitable . This is due to the fact that with a long length of the hydraulic cylinder itself, the lengths of the hoses become very large, despite the fact that the hoses must move behind the hydraulic cylinder. The movement of hoses under high pressure leads to their spatial deformation, which, of course, affects the reliability of the hoses in the fittings.

To exclude the possibility of damage to the hoses, elements of their connection with the caps and to eliminate excessive length and free sagging in the claimed hydraulic cylinder, a stationary hydraulic system of the following design is used.

An inlet channel 10 is made in the front cover 3 for connecting a hydraulic pressure supply hose through a channel made in this cover to the rod cavity of the hydraulic cylinder, and in the blind cover 2, a channel 11 is made for the piston cavity of the hydraulic cylinder to communicate with the pressure supply source to this cavity. The hydraulic hose for supplying pressure to the rod cavity of the hydraulic cylinder through the channel in the cover 3 is made in the form of a metal pipe 12, carrying a head 13 with a channel 14, a conical tip with seals inserted in the inlet channel 10 and attached by bolts 15 to the cover 3. The pipe 12 is welded to its end inserted into the head or by pressing fit into the hole in this head. In any case, the pipe is rigidly bonded to the head and has no movement relative to the head.

The hydraulic cylinder is equipped with a junction box 16 (for the distribution of the agent supplied to the cavity of the hydraulic cylinder, it is fashionable to mean oil as an agent), which is mounted on a cylindrical body or on a blank cover. Box 16 is made with output channels (one for the rod cavity, the other for the piston cavity of the hydraulic cylinder), and for each cavity of the hydraulic cylinder in the junction box 16 there are two opposite input channels 17 and 18 (one pair of input channels is in communication with the output channel in communication with the piston the cavity of the hydraulic cylinder, another pair of input channels is in communication with the output channel in communication with the rod cavity of the hydraulic cylinder). In the initial state, before entering the tractor, all input channels are closed with plugs 19 (see Fig. 2).

In working condition, that is, after installing on the tractor and connecting to a pressure source, one of the input channels in each pair in the box remains closed with a plug, and the other, after removing the plug, can be communicated with a hydraulic hose from the pressure supply system. Since, as a rule, a symmetric arrangement of hydraulic cylinders is used to control the movement of the links of the same name in the hinged system, the hoses can be connected to the junction box both on one side of this box and on the other. This reduces hose lengths. Since the box is located on the cylinder body near the blank cover or on the blank cover, short hydraulic hoses can be used for small movements in space.

In one of the output channels of the junction box 16, the other end of the metal pipe 12 is fixed, and the other output channel in this box is made in the head 20, with a conical tip with seals inserted in the inlet channel or in the channel 11 in the blind cover 2.

Thus, the externally placed hydraulic part of the hydraulic cylinder is made stationary, non-moving and rigidly fixed on the cylinder body. This allows us to solve the problem of reliability of joints and seals in the system and to ensure a guaranteed high resource of this part.

The above features of the design of a hydraulic cylinder operating under high pressures to ensure large stroke of the rod, allow to achieve a technical result - increase the long-term operational reliability of the hydraulic cylinder when working with high pressures by reducing the length of the hydraulic hoses and forming a rigid hydraulic part on the cylinder body and eliminating bending loads on stock at its large exits.

This utility model is industrially applicable and has shown in the practice of trial operation the possibility of eliminating the deformation of the hydraulic cylinder rod and its hydraulic parts.

Claims (1)

A hydraulic cylinder for tractor attachments, containing a cylindrical body, which is closed on both sides by covers, one of which is blind and the other is made with a central hole equipped with seals, for the outside of the rod carrying the attachment unit to one attachment structure element located inside the cylindrical body the rod is made with a piston, and on the cylindrical body in its central part, the opposite axis are fixed on the outside for mounting in sockets on another e an attachment design element, in this case, an inlet channel is made in the front cover for connecting a hydraulic pressure supply hose through a channel made in this cover to the rod cavity of the hydraulic cylinder, and in the blind cover there is a channel for communicating the piston cavity of the hydraulic cylinder with a pressure supply source into this cavity the fact that on the rod the attachment unit to one structural element of the attachment is made in the form of a universal joint, a hydraulic hose for supplying pressure to the rod polo The hydraulic cylinder through the channel in the cover is made in the form of a metal pipe supporting the head with the channel, a conical tip with seals inserted into the inlet channel and bolted to the cover, while the hydraulic cylinder is equipped with a junction box mounted on a cylindrical body and made with output channels, in one of which is fixed to the other end of the metal pipe, and the other is made in the head, with a conical tip with seals inserted into the inlet channel in the blind cover, and with inlet channels, using connected to a pressure source for supplying this pressure to the hydraulic cylinder cavity, and for each hydraulic cylinder cavity in the junction box two pairs of opposed input channels are made, one of which in each pair can be closed by a plug.

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