SU829450A1 - Hydraulic-screw press hammer gasohydraulic accumulating multiplicator - Google Patents

Description

The invention relates to forging and mechanical engineering and is used for stepless control of impact energy of a press hammer

A device for controlling the impact of a hydraulic screw press hammer by changing the pressure of the working fluid, containing a pump-accumulator drive made of a separately installed gas-hydraulic accumulator with a floating piston and cylinders with compressed gas [1]. ,

Such a drive does not provide stepless regulation of the pressure of the working fluid and the high-speed regime of its supply, which limits the technological capabilities of the hydraulic screw press hammer.

A gas-hydraulic accumulator-1 tor-multiplier of a hydraulic screw press-hammer is known, comprising a floating piston mounted in the housing separating the hydraulic and gas cavities [2].

However, this accumulator-multiplier does not provide stepless regulation ^{of the} energy of the working fluid and increase of its pressure relative to the gas in the accumulator to ensure a high-speed regime of fluid supply to the working cavity of the hydraulic screw press hammer.

The purpose of the invention is stepless regulation of impact energy.

This goal is achieved by the fact that the gas-hydraulic accumulator-multiplier of the hydraulic screw press hammer, which contains a floating piston mounted in the housing separating the hydraulic and gas cavities, is equipped with an additional step piston with an end face of a larger diameter located in the gas cavity of the battery.

The drawing shows a diagram of a gas-hydraulic accumulator-multiplier.

The hydro-hydraulic accumulator-multiplier contains a cylinder 1, a step piston 2, a floating piston 3, and a control piston 4 with a valve stem 5. The hydraulic actuator includes a high pressure hydraulic pump 6, a controlled valve 7, a spool 8 and 9, a check valve 10. A gas-hydraulic accumulator - fluid pressure multiplier is installed directly on the working cylinder of the press hammer.

The device provides the operation of the press hammer in acceleration and stroke mode and works as follows.

In the initial position '· the control piston 4 by means of the valve stem 5 blocks the working channel I. The stepped piston 2 is in its highest position, and the cavities 12 and 13 are filled with liquid under pressure. The cavity 14 is filled with gas, the pressure of which is 10 ° / o from the nominal developed by the pump. Gas filling of the cavity 14 is made from a cylinder (not shown in the drawing). In the hydraulic cavity 15 of the accumulator, a certain pressure is constantly maintained by the fluid flowing from the pump 6 through the controlled valve 7, the dividing floating piston 3 balances the pressure in the cavities 15 and 14 by reducing or increasing the volume of the cavity 14. When the device is running, the acceleration of the shock parts of the press the hammer is preceded by the opening of the channel 11 of the cavity 12 as a result of the lifting of the valve stem 5 of the control piston 4. Under the action of the gas pressure of the cavity 14 on the back of the staged piston 2, the latter displaces the liquid from the cavity 13 to drain through the slide valve 9, and under the pressure of the small piston stage 2 with the valve 10 closed, the liquid is supplied through the channel 11 to the cavity 16 of the working cylinder of the press hammer. The volume of the displaced fluid from the cavity 12 is determined by the moment of closing the channel 11 by the valve 5, which is controlled through the valve 8. Since the pressure of the displaced fluid from the cavity 12 is proportional to the pressure in the cavities 14 and 15, an adjustable pressure measurement in the cavity 15 leads to a corresponding change in pressure the displaced fluid from the cavity 12. The latter also provides stepless control of the pressure of the working fluid supplied from the gas-hydraulic accumulator-multiplier to the press hammer. The return of the stepped piston 2 to its original position occurs with 5 closed channel 11 under the pressure of the fluid supplied to the cavities 13 and 12 through the spool valve 9 from the common line. Moving to its highest position, the stepped piston 2 compresses the gas in the cavity 14 to a set working pressure of ⁰ pressure. By opening channel 11, the duty cycle of the gas-hydraulic accumulator-multiplier begins again.

The use of a gas-hydraulic accumulator-multiplier in the hydraulic drive 15 of the hydraulic screw press hammer allows for stepless control of the energy of its impact, which increases the efficiency of the machines by 15-25% due to the savings in energy consumption, the accuracy of the parts produced and the increased durability of the base ²⁰ outlets of the press hammer.

Claims (2)

The invention relates to forging and pressing machinery and serves to continuously adjust the impact energy of a press hammer. A device for adjusting the impact of a hydraulic screw press hammer is known by varying the pressure of the working fluid, comprising a pump-accumulator drive made of a separately installed gas-hydraulic accumulator with a floating piston and cylinders with compressed gas 1. Such an actuator does not provide infinitely variable pressure control of the working fluid and the BB1SOCO high-speed mode of its supply, which limits the technological capabilities of the hydraulic screw press hammer. A gas-hydraulic accumulator of a hydraulic screw pressmotor is known, which contains a floating piston mounted in a housing that separates the hydraulic and gas cavities 2. However, this accumulator-multiplier does not provide stepless control of the energy of the working fluid and increase its pressure relative to the gas in the battery to ensure high velocity the mode of supplying fluid into the working cavity of a hydraulic screw press hammer. The purpose of the invention is stepless control of the impact energy. This goal is achieved by the fact that the gas-hydraulic accumulator-multiplier of the hydro-screw press hammer, containing a floating piston mounted in the housing, separating the hydraulic and gas cavities, is provided with an additional stepped port, the end of which has a larger diameter in the gas cavity of the battery. The drawing shows a diagram of the gas-hydraulic accumulator-multiplier. The gas-hydraulic accumulator-multiplier contains a cylinder I, a stepped piston 2, a floating piston 3 and a piston 4 controlling with a stem-valve 5. The hydraulic drive includes a hydraulic pump 6 of high pressure, a control valve 7, a spool 8 and 9, a check valve 10. Gas-hydraulic The accumulator-pressure multiplier of the fluid is installed directly on the working cylinder of the press hammer. The device ensures the operation of the pressmother in the acceleration mode and the working stroke and works as follows. In the initial position, the piston 4 is controlled by means of the valve stem 5 closes the working channel 11. The stepped piston 2 is in the extreme upper position, and the cavities 12 and 13 are filled with pressurized fluid. The cavity 14 is filled with gas, the pressure of which is 10% of the nominal pressure developed by the pump. The gas filling of the cavity 14 is made from a cylinder (not shown in the drawing). In the hydraulic cavity 15 of the accumulator, a certain pressure is constantly maintained by the fluid coming from the pump 6 through the control valve 7, the separating floating piston 3 balancing pressure in the cavities 15 and 14 by decreasing or increasing the volume of the cavity 14. When the device runs The acceleration of the impact parts of the press hammer is preceded by the opening of the channel 11 of the cavity 12 as a result of raising the stem-valve 5 of the piston 4 of the control. Under the pressure of the gas cavity 14 on the back side of the stepped piston 2, the latter displaces the liquid from the cavity 13 to drain through the spool valve 9, and under the pressure of the small stage piston 2 when the valve 10 is closed, the liquid through the channel 11 is fed into the cavity 16 . The volume of the displaced fluid from the cavity 12 is determined by the moment that the channel 11 is closed by the valve 5, which is controlled through the valve 8. As the pressure of the displaced fluid from the cavity 12 is proportional to the pressure in the cavities 14 and 15, the controlled measurement of the pressure in the cavity 15 leads to a corresponding change in the pressure of the displaced fluid from the cavity 12. The latter ensures the infinitely variable control of the pressure of the working fluid supplied from the gas-hydraulic accumulator-multiplier to the press milk . The return of the stepped piston 2 to its original position occurs when the channel 11 is closed under the pressure of the fluid supplied to the cavities 13 and 12 through the slide valve 9 from the common line. Moving to the extreme upper position, the stepped piston 2 compresses the gas in the cavity 14 to the set working pressure. By opening channel 11, the gas-hydraulic accumulator-multiplier operating cycle begins anew. The use of a gas-hydraulic accumulator-multiplier in the hydraulic actuator of the hydro-screw press hammer allows to ensure the infinitely variable energy control of the impact, which increases the efficiency of the machines by 15-25% due to the saving of consumed energy, the accuracy of the produced parts of the press hammer. Claims of the invention Gas-hydraulic accumulator-multiplier hydrointhe press hammer. containing a floating piston mounted in the housing separating the hydraulic and gas cavities, characterized in that, in order to continuously adjust the impact energy, it is equipped with an additional stepped piston, the larger butt end of which is located in the gas cavity of the battery; Sources of information taken into account during examination 1. “Vestnik Mashinostroeni, 1968, № 4, 64-75. 2. USSR author's certificate number 592617, cl. B 30 B 1/23, 08/23/76.