DE4042188A1 - Controlling energy characteristics of power press - by pneumatic cylinders on each side of RAM to balance effects of RAM mass - Google Patents

Abstract

In a conventional power press drive energy is normally lost in the form of heat emitted by the clutch and brake during the press working cycle. Here two pneumatic balancing cylinders (23) are fastened to the press frame on each side of the press ram (8). The piston rod (27) passes through the bore of a bracket (25) extending from the ram and has a cushioned ram abutment collar (26, 29) at its end. - At the start of the press cycle, the ram accelerates from top dead centre until the abutment collar is contacted, when it moves against the pressure of air in the lower chamber of the balancing Cylinders. Finally, full forming torque is applied by clutch (2).

Description

The invention relates to a device for influencing the energetic and dynamic behavior of drives in metal forming machines, which on the one hand relate to the start-up and Braking and on the other hand on the crank angle mass forces, especially in articulated presses Sheet metal and solid forming, works.

The start-up and braking processes of intermittent operation working forming machines are preferred with asyn chron switchable friction clutches and brakes reali siert. This creates on the friction surfaces of the alignment ganges in clutch and brake due to the inelastic Rotation shock undesirable as a physical principle of action an irreversible loss of energy due to heat development, accompanied by a constant wear process. The be limited heat resistance of the friction materials on the one hand and the constant increase in their service life at substantially increased continuous stroke and switching numbers have u. a. to considerable material and manufacturing expenses for Manufacturer led.

To reduce the thermal load and wear in clutch and brake, a device according to the DD-WP 1 00 063 proposed where an uncontrolled Working cylinders on the one hand on the machine body and others on the other hand, exzen his piston rod on the crankshaft is arranged so that it is at top dead center Can generate acceleration torque. This outer mo ment in top dead center acts against the holding torque of the Brake, causing the plunger to accidentally fail is accelerated. In addition, energy remains in Form of residual heat in the brake and clutch depending on the overflow angle from the extended position of the Ar working cylinder.  

The larger the overflow angle, the smaller the Degree of energy recovery. Finally, to reali This solution additional material and manufac expenses required. After this DD-WP will further the use of a separate hydraulic servo drive, consisting of one working as a pump and motor tendency displacement unit, a controllable directional valve and proposed a hydraulic accumulator. The high Be acceleration or braking work on the one hand and the short Acceleration or braking time on the other hand and the require time-variant power requirements with its maximum when selecting the device (displacement unit, valves and Hydraulic accumulator) considerable sizes and large nominal widths in the piping system. He is also on this proposal considerable material and manufacturing expenses at the manufacturer and additional expenses for tools and Maintenance required by the operator.

After all, servo drives are with sudden switching the hydraulic accumulator is extraordinary thanks to a directional valve vibrating, accompanied by a high noise level.

In another known solution according to the SU-EB 6 43 683 is the use of springs in between Coupling shaft and secondary gear arranged Pla netenradantrieb that with the friction block carrier the Brake is coupled, proposed. This before too blow is only with high expenses, u. a. for the additional planetary gear, feasible.

There is also work with this solution protection concerns because of against the brake acting preload torque at standstill. The energy recovery rate is unsatisfactory. Furthermore cause dynamic shock loads during start-up Moments and vibrations that lead to increased noise and ver wear.  

For forming machines and especially for lever or joint presses can only increase the number of idle strokes to a limited extent because the dynamic forces and moments in the An drive system to huge shocks and back movements different amounts that have a destructive effect and express themselves as restless running and increased noise. The main cause is the balanced upper tool carrier, whose mass effect is particularly in the upper crank angular range due to the kinematics of the joint system increases the number of strokes clearly.

A solution according to DD-WP 1 47 927 is known in which by using panels between the balancing cylinders and pressure medium storage the pressure below the balancing Part of the plunger when the tappet is ramping up was reduced, thereby reducing the dynamic loading burden has occurred. However, the effect is limited because the aperture has not fallen below a minimum cross-section can be. In addition, there is a on the aperture considerable heat development through energy destruction.

In another known solution according to DD-WP 2 56 288 an additional hydraulic device is proposed, which by generating a variable counter moment Compensation of the hydraulic inertial forces in the game turnover-prone rotation angle phases. To Realization of this facility are additionally hydrau devices with large nominal sizes and sizes as well an excellent timing behavior of the valves due to the extremely high rate of torque change required. In addition, arise during the compensation phase significant irreversible energy losses caused by increase the idle losses.

The object of the invention is to create a Functional and occupational safety-proof facility that on the one hand the braking and acceleration process highly realized and on the other hand the effect of Mass forces of the upper tool carrier significantly reduced. According to the invention, the task is performed in the characterizing parts of the claims described Characteristics achieved.

The advantage of the invention lies in a cost inexpensive and low-noise device the energetic and improve dynamic behavior of drives.

The invention is based on an embodiment example are explained in more detail. The associated drawing shows

Fig. 1 schematic representation of the device.

The drive, the energetic and dynamic Ver hold to be influenced, consists of the flywheel 1 , the clutch 2 and the brake 4 with the actuating element 5th

The parts of the secondary gear to be accelerated and braked are shown as rotating mass 3 . The eccentric or crankshaft 6 is connected via the connecting rod 7 in a known manner to the upper tool carrier 8 and the upper tool 28 arranged thereon. Both sides of the upper tool carrier 8 , the balancing cylinder 23 are arranged, which are additionally connected to the press frame. The respective piston rod 27 of the piston 22 is provided at the end of the balancing cylinder 23 projecting end with a stop 29 and a stop damper 26 . This An impact 29 is operatively connected with a be on the upper tool carrier 8 strengthened stop 25th

The upper pressure medium chambers 31 of the Ausbalancierungszy cylinder 23 are connected via lines to the press safety valve, of which one valve outlet with a silencer 30 and the other via a shut-off organ 18 , which is preferably formed as a check valve, and a pressure regulator 19 with the Druckmit telquelle 11 is in operative connection. This pressure medium source 11 is also connected via a pressure regulator 21 and a pressure medium reservoir 24 to the lower pressure medium space of the balancing cylinder 23 . Furthermore, the pressure medium source 11 feeds via a pressure regulator 12 and a pressure medium reservoir 13, on the one hand, via the press safety valve 16, the actuating element 5 of the brake 4 . The position-monitored directional valve 17 and a silencer are connected to the outlet of the press safety valve 16 . On the other hand, the aforementioned line is connected to the actuating element of the clutch 2 via a pressure regulator 14 and a pressure medium accumulator 15 as well as a directional valve 10 and a press safety valve 9 . From the second access of the directional control valve 10, a line is additionally arranged in parallel with the pressure regulator 14 and the pressure medium reservoir 15 .

After switching on the press safety valve 16 , the actuating element 5 of the brake is quickly released and the clutch 2 is brought into the closed position by the press safety valve 9 and the pressure medium accumulator 15 without overlap in a known manner. In the clutch 2 acts by the pressure regulator 14 significantly reduced acceleration torque, which is a maximum of twice the amount of the friction torque acting in the secondary gear, z. B. in the position, assumes.

This low acceleration torque initiates the start-up process. Depending on the crank angle reached by the decline of the upper tool carrier 8 and the upper tool 28 from the area of the top dead center, a supporting effect of the acceleration process via the connecting rod 7 on the eccentric or crankshaft 6 and the rotating masses of the secondary gearbox. The piston 22 and the piston rod 27 are adjusted by means of the pressure regulators 19 and 21 and the pres safety valve 20 so that when synchronizing in the clutch 2 the stop 25 on the upper tool carrier 8 reaches the stop damping 26 of the stop 29 . By switching on the directional valve 10 , the required torque of the clutch 2 for realizing the forming process is quickly generated.

In the upward motion of the upper tool carrier 8 , the forces of the pistons 22 with the piston rod 27 automatically stop at the same weight. Staggered in time, the clutch 2 is separated from the secondary gear by switching off the press safety valve 9 , so that the rotating masses 3 of the secondary gear come to a standstill at the top dead center due to the braking action of the upper tool carrier 8 and the upper tool 28 . At top dead center, the brake 4 is effective as a holding brake by switching off the press safety valve 16 .

The press safety valve 20 , formed as a directional control valve, is switched off if the upper area of the standstill control is not reached, exceeded or the emergency stop is initiated.

Claims (7)

1. Device for influencing the energetic and dynamic behavior of drives in forming machines during the acceleration and braking process, the drive consisting of flywheel, clutch and brake as well as secondary gear and the transmission of motion to the upper tool carrier from the eccentric or crankshaft by means of a connecting rod or Articulated mechanism takes place and to compensate for the mass of the upper tool carrier and upper tool in the lower pressure medium space a plurality of piston-cylinder units which can be acted upon by compressed air are arranged on both sides of the upper tool carrier and are additionally connected to the press frame, characterized in that the balancing effect for the mass balance of the upper tool carrier ( 8 ) and the upper tool ( 28 ) in the upper crank angle range is lifted and the upper pressure medium spaces ( 31 ) of the balancing cylinder ( 23 ) on the one hand via at least one press safety valve ( 20 ), an Abspe Rrorgan ( 18 ) and a pressure regulator ( 19 ) can be pressurized with compressed air and on the other hand via the press safety valve ( 20 ) and a silencer ( 30 ) and the respective piston rod ( 27 ) at the end protruding from the balancing cylinder ( 23 ) has a stop ( 29 ) and is operatively connected to a stop ( 25 ) attached to the upper tool carrier ( 8 ) via a stop damper ( 26 ). 2. Device for influencing the energetic and dynamic behavior of drives according to claim 1, characterized in that a programmable pressure control device can be used as a pressure regulator ( 19 ). 3. Device for influencing the energetic and dynamic behavior of drives according to claim 1, characterized in that both the stop ( 29 ) and the stop ( 25 ) is adjustable and programmable. 4. Device for influencing the energetic and dynamic behavior of drives according to claim 1, characterized in that the stops ( 25 ) and ( 29 ) adjust smoothly and smoothly. 5. A device for influencing the energetic and dynamic behavior of drives according to claim 1, characterized in that a check valve is preferably used as a shut-off device ( 18 ). 6. Device for influencing the energetic and dynamic behavior of drives according to claim 1, characterized in that for the high-level recovery of the nominal speed of the clutch shaft during the acceleration process and to minimize the remaining wear in the clutch before the start of the braking process of the secondary transmission, the clutch ( 2 ) can only be switched off after the stop ( 29 ) has come to a standstill. 7. Device for influencing the energetic and dynamic behavior of drives according to claim 1, characterized in that the standstill point of the piston rod ( 27 ) tool is specifically adjustable and the friction and the variability of the number of strokes, the upper tool mass, the plunger adjustment and the process-related speed drop considered.