RU2531425C2 - Caterpillar carrier steering hydraulic system - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: system comprises oil station with delivery and drain lines, metering pump articulated with steering wheel and communicated with pressure and drain hydraulic lines and, via hydraulic lines and normally-closed three-line two-way hydraulic pressure control valves with rod ends of friction gear hydraulic cylinders, their piston ends being communicated via normally-open three-line two-way hydraulic control valves with oil station hydraulic pressure line, and brake hydraulic cylinders with piston spring loaded towards cut-off side. Brake hydraulic cylinders are connected with friction gear control hydraulic cylinders via extra hydraulic lines and extra normally closed three-like two-way hydraulic control valves via extra orifices made in friction gear control hydraulic cylinders to communicate extra hydraulic lines with piston ends at extended rods and, with rod ends, at pulled-in rods.

EFFECT: separate control over LH and RH sides at whatever radius of turn.

3 cl, 2 dwg

Description

The invention relates to devices for controlling vehicles on a caterpillar track and is used in hydraulic steering systems of vehicles.

A feature of the drive control mechanisms for turning vehicles on caterpillar tracks is the need to control separately the right and left sides of the vehicle.

Known mechanical drives for controlling the rotation mechanisms [Anilovich V.Ya., Vodolazhchenko Yu.T. "Design and calculation of agricultural tractors." Reference manual. Ed. 2nd, overwork, and add., M., "Mechanical Engineering", 1976, p.1, 280-283.], In which the driver acts on one body - the brake lever, or on two bodies: a turn clutch or a mechanism brake for a smooth turn and a stop brake for a sharp turn. To reduce the number of controls, in some designs the swivel clutch and brake control one lever for each side.

The main disadvantages of the integrated control drive:

- the complexity of regulation (it is necessary to ensure complete shutdown of the clutch before tightening the brake), reducing its reliability;

- increased effort on the lever, leading to driver fatigue and requiring the use of a servo drive (amplifier), which uses energy, for example, a hydraulic actuator;

- the presence of at least two control levers, so the steering wheel is more convenient for control.

The current trend in the design of control drives for turning mechanisms is the use of a steering wheel and hydraulic amplifiers, which can be used as metering pumps or motor pumps.

A hydraulic steering system for a wheeled vehicle is known [patent RU 2036815], comprising a main distributor kinematically connected through a pump-motor to a steering wheel and hydraulically connected to a power cylinder and a hydraulic tank, a pump-motor and through an auxiliary distributor driven by a piston position sensor, with cavities of the master cylinder, a three-line on-off distributor controlled by the pressure of the working fluid, a control line connected to one of the hydraulic lines of the pump a motor.

In this system, the power cylinder cannot control the right and left sides of the vehicle separately, which is unacceptable for tracked vehicles.

The closest technical solution to the proposed one is the hydraulic steering system of a wheeled vehicle [patent RU 2030317], comprising a main four-line three-position valve, hydraulically connected to the pump and hydraulic tank on the one hand and the power cylinder cavities on the other, kinematically connected to the steering wheel and the power rod cylinder, two-way valve, auxiliary four-line three-way valve, controlled by the pressure of the working fluid, connected through a normally open second two-position distributor to the power cylinder by means of two additional holes made in the power cylinder with the possibility of opening the piston in the neutral position and closing one of them when the piston is displaced.

The specified system has a significant drawback - the power cylinder does not have the ability to control separately the right and left sides of the vehicle, which is unacceptable for tracked vehicles.

The technical problem solved by the claimed invention is to provide the possibility of separate control of the right and left sides of the vehicle on a caterpillar track for turns with both small and large turning radii.

The technical result is achieved by the fact that in the hydraulic steering system of the vehicle on a caterpillar track containing an oil station with a pressure and drain hydraulic lines, a metering pump kinematically connected to the steering wheel, hydraulically connected to a pressure and drain hydraulic lines, and hydraulic lines through normally closed three-line two-position hydrodistributors - with rod cavities of hydraulic cylinders for controlling friction transmissions, piston cavities of which are hydroline through a hole openly open three-line two-way directional control valves are connected to the pressure head hydraulic line of the oil station, as well as brake hydraulic cylinders with a piston spring-loaded towards the brake turn-off, brake hydraulic cylinders are connected to hydraulic control cylinders by additional hydraulic lines through additional normally closed three-line two-position hydraulic control valves, thus controlling additional that they connect q additionally hydraulic line with piston cavities during nominated rods and with the rod end - when retract rods, besides three-way two-position valves hydraulically performed, the control hydraulic line connected to the hydraulic lines of the metering pump.

To ensure turning with a large turning radius in additional hydraulic lines between the hydraulic clutch control cylinders and additional hydraulic control valves, additional electrically controlled normally open two-line two-position hydraulic control valves are installed. When the latter are activated, the operation of the brake hydraulic cylinders is blocked and the movement of the vehicle with a large turning radius in the "steering" mode is ensured.

The set of distinctive features of the claimed technical solution allows to obtain a previously unknown effect, expressed in that the connection of the brake hydraulic cylinders to the hydraulic cylinders for controlling the friction gears with additional hydraulic lines through additional normally closed three-line two-position directional control valves by means of additional holes made in the hydraulic cylinders for controlling the friction gears in such a way that they connect additional hydraulic lines with piston cavities with extended rods and with rod cavities - with retracted rods, the execution of three-line on-off directional control valves is hydraulically controlled, the connection of control lines to the metering pump lines, the installation in additional hydraulic lines between the clutch control cylinders and the additional control valves of additional electrically controlled normally open two-line two-way control valves right and left sides transport caterpillar tracks for turns with both small and large turning radii, which for a specialist clearly does not follow from the prior art.

The stated essence of the claimed invention is illustrated by drawings (figure 1 and figure 2), which presents a diagram of the hydraulic systems of the steering of vehicles on a caterpillar track.

The hydraulic steering system of the vehicle on a caterpillar track contains an oil station 1 with a pressure head 2 drain 3 hydraulic lines, a pump - dispenser 4, kinematically connected to the steering wheel 5, hydraulically connected to a pressure head 2 and drain 3 hydraulic lines, and hydraulic lines 6 and 7 through normally closed three-line on-off directional control valves 8 and 9, respectively, along hydraulic lines 10 and 11 with rod cavities (not shown in FIG.) of hydraulic cylinders 12 and 13 for controlling friction gears (not shown in FIG.). Piston cavities (not indicated in FIG.) Of the latter by hydraulic lines 14 and 15 through normally open three-line on-off directional control valves 16 and 17 are connected to the pressure hydraulic line 2 of the oil station 1.

The brake hydraulic cylinders 18 and 19 with a piston spring-loaded towards the brake release side (not indicated in FIG.) Are connected to the hydraulic cylinders 12 and 13 by additional hydraulic lines 20 and 21, respectively, through additional normally closed three-line two-position control valves 22 and 23 through additional holes (not shown in FIG. ) made in hydraulic cylinders 12 and 13 in such a way that they connect additional hydraulic lines 20 and 21 with piston cavities with extended rods and with rod cavities with retracted rods.

Three-line on-off directional control valves 8, 9, 16, 17, 22 and 23 are made hydraulically controlled, while the control lines (not shown in FIG.) Are connected to the hydraulic lines 6 and 7 of the metering pump 4. To return the control valves 8, 9, 16, 17 , 22 and 23 in the initial position, the control lines are connected via chokes 24 and 25, respectively, with a drain.

In additional hydraulic lines 20 and 21 between the hydraulic cylinders 12 and 13 for controlling friction gears and additional hydraulic valves 22 and 23 are installed (Fig. 2) additional electrically operated normally open two-line two-position hydraulic valves 26 and 27, respectively.

The hydraulic steering system of the vehicle on a caterpillar runs as follows.

In the initial state, in the absence of a steering wheel turn 5, the working fluid from the oil station 1 along the pressure hydraulic line 2 through the metering pump 4 is returned via the drain hydraulic line 3 to the oil station 1. At the same time, the working fluid from the oil station 1 is through normally open three-line two-position control valves 16 and 17 hydraulic lines 14 and 15, respectively, enters the piston cavity of the hydraulic cylinders 12 and 13 control friction gears. Rod stock cavities of hydraulic cylinders with hydraulic lines 10 and 11 through normally open three-line on-off directional control valves 8 and 9 are connected to the drain. Under the influence of the pressure of the working fluid, the rods of the hydraulic cylinders 12 and 13 extend, while the friction gears are closed and transmit the full torque to the left and right tracks. The cavities of the brake hydraulic cylinders 18 and 19 through the control valves 22 and 23 are respectively connected to the drain, so the hydraulic cylinder springs retract the rods and the brakes are turned off. The vehicle is moving in a straight line.

To turn the vehicle to the left with a small turning radius, the steering wheel 5 must be turned to the left. In this case, the working fluid from the oil station 1 along the pressure hydraulic line 2, through the metering pump 4, the hydraulic line 6 enters the control valve 8 and into the control cavity of the control valves 8, 16, and 22, switching the latter.

When switching the valve 8, the working fluid through the hydraulic line 10 enters the rod cavity of the hydraulic cylinder 12, when switching the valve 16, the piston cavity of the hydraulic cylinder 12 is connected to the drain. The hydraulic cylinder 12 draws the rod, the working fluid through the additional hole through the additional hydraulic line 20 enters the valve 22. When the hydraulic cylinder 12 is activated, the friction transmission opens and the torque transmission to the left track stops.

When switching the control valve 22, the working fluid enters the brake hydraulic cylinder 18, the hydraulic cylinder is activated, the brake is applied, the left track stops.

At the same time, the working fluid from the oil station 1 through the valve 17 through the hydraulic line 15 enters the piston cavity of the hydraulic cylinder 13. The rod cavity of the hydraulic cylinder by the hydraulic line 11 through the valve 9 is connected to the drain. The hydraulic cylinder is triggered, extends the rod, the friction gear closes and transmits full torque to the right track.

Thus, the vehicle turns left with a small turning radius.

To turn the vehicle to the left with a large turning radius, the “steering” mode is used, in which the left brake is released, the left track does not stop completely, but torque is not transmitted to it, the vehicle rolls over it, and torque is transmitted in full only to right caterpillar.

To implement the mode of “taxiing” before the above operations, an electrically controlled directional control valve 26 (FIG. 2) is supplied with an electric signal, the directional control valve switches and cuts off the supply of working fluid to the directional control valve 22 and the brake hydraulic cylinder 18. The cavity of the brake hydraulic cylinder 18 is connected to the drain, the hydraulic cylinder spring retracts the rod and the brake turns off.

Thus, the vehicle turns left with a large turning radius.

When the steering wheel 5 is returned to the middle position, all elements of the hydraulic system return to their original state. The working fluid from the control lines of the control valves 8, 16, and 22 through the throttle 24 enters the drain.

The vehicle is turned to the right when the steering wheel 5 is turned to the right, while the corresponding elements of the hydraulic system are triggered.

Thus, it is possible to separately control the right and left sides of the vehicle on a caterpillar track for turns with both small and large turning radii.

The claimed technical solution of the hydraulic steering system of a vehicle on a caterpillar track is suitable for industrial implementation in the conditions of mass production of the production association "Gomselmash" using existing equipment and existing production technology. The design of the hydraulic system has been tested for manufacturability at the stage of design and manufacture of prototypes in the Republican Unitary Enterprise “GSKB for grain and forage harvesting equipment”.

Thus, the claimed technical solution meets the criterion of "industrially applicable".

Claims (3)

1. The hydraulic system of the vehicle’s steering on a caterpillar track, comprising an oil station with a pressure and drain hydraulic lines, a metering pump kinematically connected to the steering wheel, hydraulically connected to the pressure and drain hydraulic lines, and hydraulic lines through normally closed three-line two-position directional control valves with rod ends hydraulic cylinders for controlling friction gears, the piston cavities of which are connected by hydraulic lines through normally open three-line two-position Hydrodistributors are connected to the hydraulic pressure line of the oil station, as well as brake hydraulic cylinders with a piston spring-loaded in the direction that the brake is turned off, characterized in that the brake hydraulic cylinders are connected to the hydraulic cylinders for controlling friction gears with additional hydraulic lines through additional normally closed three-line two-position hydraulic distributors in the additional control holes made gears in such a way that they connect tional hydraulic line with the piston cavity in stocks and put forward with the rod cavity - with inverted stems. 2. The hydraulic system according to claim 1, characterized in that the three-line on-off directional control valves are made hydraulically controlled, while the control lines are connected to the hydraulic lines of the metering pump. 3. The hydraulic system according to claim 1, characterized in that in the additional hydraulic lines between the hydraulic clutch control cylinders and the additional control valves, additional electrically operated normally open two-line two-position control valves are installed.

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