SU206982A1 - C. HYDRAULIC SCREW MANAGEMENT SYSTEM - Google Patents

Description

A hydraulic screw press hammer control system comprising a movable working cylinder and an individual accumulator and a distribution valve connected to it, as well as a source of high-pressure liquid supply, are known.

The proposed control system differs from the known one in that it is equipped with two sequentially operating slide valves connected to the working cylinder and the accumulator.

Such an implementation of the control system allows to obtain full kinetic energy in any part of the stroke of the working cylinder.

The proposed control system of a hydraulic screw press hammer is shown in the drawing.

Press press cycles a.

The slave cylinder / hammer combines three functions: it is a hydraulic cylinder, a screw and a flywheel.

I. The stroke of the press hammer, in contrast to the hydraulic presses, is not carried out until the upper striker or the stem is in contact with the forging, but before the high-pressure liquid is turned on and acceleration begins. To complete this turn, the electromagnet 2 pilots is turned on. By pressurizing the fluid from the pump 3, the spool 4 moves to the left, opening the path of the fluid from the cavity under the piston 5 to the tank. The liquid from the pump 3 through the retaining valve 6 and the check valve 7 flows through the annular channel of the plunger (not shown) into the working cavity of the cylinder. Under the pressure of this fluid, the screw cylinder (not shown) moves downwards. After overcoming the resting friction, the moving parts (not shown in the drawing) move under their own weight, sucking the liquid through the check valve 8 into the working cylinder.

Ii. Acceleration is the most important part of the cycle. During the acceleration period, the moving parts acquire the kinetic energy necessary for plastic deformation.

Acceleration is carried out by supplying a high pressure fluid from the accumulator 9 to the working cylinder. When moving downward at the end of the stroke, the zoom cam attached to the slider (not shown in the drawing) switches the valve 10 B to the left position. The liquid from the pump enters the left cavity of the spool // and switches it to the right. This opens the way for high-pressure fluid from the accumulator 9 through the central channel of the plunger to the working cavity of the cylinder.

1-3 w / sec and the cylinder, making a downward screw motion, accumulates the kinetic energy of the screw motion of the masses. To accumulate the total energy, a part of the full stroke, for example 1/5 of the working cylinder, is required. This makes it possible to obtain full kinetic energy at any point, for example, at 4/5 full speed, which greatly expands the technological capabilities of the press. All existing, their hydraulically driven helical hammers need full speed to obtain full energy.

By setting the cam on the slider of the new press hammer, it is possible to regulate the magnitude of the kinetic energy in exact accordance with the value required for the technological operation.

III.Working course.

During the working stroke, the action of the high pressure fluid from the accumulator 9 continues until the end of the stroke, therefore the position of the spools remains the same, which ensures plastic deformation of the forging due to the joint action of the pressure force of the fluid, like in a hydraulic press and the kinetic energy of the screw movement, screw hammer.

Unlike a hydraulic press, deformation occurs at a high (1–2 m / s) speed.

In addition, the presence of kinetic energy, which seems to accompany the force of the pressure of the fluid, makes it possible to overcome the resistance of deformation, significantly (4 or more times) higher than its nominal force of the hydraulic cylinder.

This interaction of two types of energy (pressure energy and kinetic energy) makes it possible to perform cold die forging and extrusion, as well as other operations requiring a large amount of energy from the forging machine.

IV.Returnal course.

In order to increase the energy and economic performance of the machine, the return stroke is divided into two periods: the acceleration period

and braking period. At the end of the working stroke, the valve W returns under the action of the spring to the initial right position, which ensures discharge from the cavity at the left end of the valve // simultaneously.

Using the end switch, the electromagnets 12 are turned off and the pilot electromagnet 13 is turned on. The spool 4 moves to its original position, and the spool 11 moves to the left, opening the path of high pressure fluid from the accumulator 9 to the return cavity of the working cylinder. Moving parts rise, accelerate in a short stretch

up, which is part of a full stroke, for example 1/5, up to a certain speed, which provides for the accumulation of kinetic energy sufficient to complete the upward stroke. During braking when moving up

at the end of the acceleration section, the cam attached to the slider presses the limit switch, which de-energizes all electromagnets, and the spools occupy the initial position.

The movement of the moving parts continues at the expense of kinetic energy until the end of the stroke upwards. The liquid from the working cavity of the cylinder is discharged into the tank through the spool 4 and the retaining valve 14. A part of this liquid flows through the supporting valve 15 into the return cavity of the working cylinder.

Subject invention

A hydraulic screw press hammer control system comprising a movable working cylinder and an individual accumulator and a distribution valve connected to it, as well as a high-pressure liquid supply source, characterized in that, in order to obtain full kinetic energy in any part of the working cylinder stroke, it is equipped with two successive valves-valves,

connected to the working cylinder and the battery.