EP0068147A1 - Device for pressure admission at the squeeze cylinder in a pressure die casting machine - Google Patents

Abstract

1. Apparatus for the pressure-charging of the press cylinder of a die-casting machine, especially a cold-chamber die-casting machine with three-phase working system, in which the press-in part consists of a press cylinder (1) with single-stage press piston (4) and at least the filling-, final- and after-pressure necessary for the second and third phases is supplied from a fluid-filled high-pressure reservoir (7a, 7b) under gas pressure, while the pressure for the first phase can be supplied by a system separated from the high-pressure reservoir (7a, 7b), characterised by the following features : (a) a compensating reservoir (8a, 8b) valve lessly opens into a connecting conduit between high-pressure reservoir (7a, 7b) and press cylinder (1), (b) the gas-charged high-pressure reservoir (7a, 7b) consists of a gas-filled high-pressure vessel (7a) and a high-pressure cylinder (7b) placed thereafter in the direction towards the press cylinder (1) with piston (10) displaceable therein to separate the hydraulic fluid from the gas of the high-pressure vessel (7a) loading the high-pressure cylinder (7b), (c) the compensating reservoir (8a, 8b) consists of a gas-filled compensating vessel (8a) with compensating cylinder (8b) placed thereafter in the direction towards the press cylinder (1), with piston (11) displaceable therein to separate the hydraulic fluid from the gas of the compensating vessel (8a) loading the compensating cylinder (8b), (d) the pressure in the compensating reservoir (8a, 8b) is lower than the pressure in the high-pressure reservoir (7a, 7b), (e) into the connecting conduit leading from the high-pressure reservoir (7a, 7b) to the press cylinder (1), between the compensating reservoir (8a, 8b) opening into this connecting conduit and the high-pressure reservoir (7a, 7b) there is arranged a valve (9) which is opened only during the course of the second and third working phases.

Description

The invention relates to a device for pressurizing the press cylinder of a die casting machine according to the preamble of claim 1.

The three-phase casting process in this type of die casting machine is composed as follows. In the initial phase of the casting process (phase 1), only a low speed of the plunger is provided in order to avoid splashing of the melt. In the actual filling phase (phase 2), high velocities of the plunger are selected in order to carry out the filling process quickly, while in the final and holding pressure phase (phase 3) considerably higher baling pressures are required and therefore the plunger is subjected to high pressure.

Generically comparable devices for pressurizing die casting machines are described, for example, in DE-OS 23 56 711. According to this, a typical construction of such a device is that the plunger is driven by hydraulic fluid coming from a pressure accumulator. The pressure in the pressure accumulator is generated by compressed gas stored above the hydraulic fluid. The gas pressure in the pressure accumulator is generated by filling hydraulic fluid under pressure from a pump directly in the pressure accumulator. It is considered disadvantageous in this device that after the completion of the filling process in the filling phase 2 there is a pressure shock which affects a good casting. This is particularly the case when the pressure level in the accumulator is chosen to be high, in order to be able to realize the fastest possible mold filling process through a large pressure difference between the accumulator and the plunger. By setting a lower accumulator pressure, the pressure surge can then be reduced after the second working phase, but with the inevitable consequence that the actual filling process is also slowed down by the correspondingly lower pressure difference between the plunger and the accumulator. However, this is precisely what is possible, especially when processing light metals, by accepting poorer casting quality.

In order to alleviate the harmful pressure surge at the end of the third working phase, it is proposed in DE-OS 23 56 711 that the plunger should not be driven with the interposition of a hydraulic fluid, but rather directly by gas coming from the pressure accumulator. As a result of the lower mass of the hydraulic medium and the compression property of the hydraulic medium gas, the pressure surge occurring at the end of the third working phase should be considerably reduced. Apart from the fact that undesirable gas suspension processes are to be expected with this solution and therefore the pressure surge problem seems to be solved only unsatisfactorily, this device has other disadvantages. In particular, the three work phases, namely pre-filling, form filling and reprinting processes cannot be regulated and carried out independently of one another. Because in all three phases must be practical work with the same pressure difference between the ram and pressure accumulator. Since a high pressure difference - as explained above - is required in the actual mold filling phase, this pressure then also automatically exists at the end of the third working phase in which the pressure surge builds up. In addition, high forces are required for the retraction of the plunger, since the plunger must be moved against the full working pressure in the pressure accumulator. Furthermore, gas pressure on many components creates significant safety problems.

Based on this prior art, the invention has for its object to provide a pressurizing device working in all working phases with hydraulic fluid with a similar device simple structure, as described in such devices in DE-OS 23 56 711, in which a safe Damping the pressure surge at the end of the 2nd and 3rd Working phase can be achieved while maintaining the highest possible pressure difference between the pressure accumulator and the plunger in the actual filling phase.

This object is achieved by designing the device for pressurizing according to the characterizing features of claim 1.

Further embodiments of the invention contain the subclaims.

The drawing shows a flow diagram of an embodiment of the invention.

Press cylinder and plunger of the casting machine, not shown in the rest, are designated 1 and 4. The valves 2, 3, 5 and 6 and the lines leading to the press cylinder 1 are used essentially only for carrying out the first working phase and for the return of the plunger 4 and the emptying of the compensating cylinder 8b). Only the valve 5 also performs a function in the 2nd and 3rd working phases in such a way that it ensures a rapid drainage of the hydraulic fluid from the press cylinder. The valve 3, on the other hand, only ensures at the end of the 2nd and 3rd working phases that the line which opens from the pressure side of the plunger 4 is closed. The high-pressure accumulator 7a, 7b and the compensation accumulator 8b, 8b are essential elements for realizing the invention. Both stores open into a common supply line to the press cylinder 1 and can be separated from one another in this line by a valve 9. The high-pressure accumulator 7a, 7b and the compensating accumulator 8a, 8b each consist of a cylinder (high-pressure cylinder 7b or compensating cylinder 8b), each with a piston 10 or 11 displaceable therein and downstream pressure vessels (high-pressure container 7a or compensating container 8a). Instead of the pistons 10, 11, other separating elements such as storage bladders can be used. The volume of the pressure containers 7a, 8a is designed such that the pressure level of the stored gas remains approximately constant over the entire displacement paths of the pistons 10 and 11, or changes slightly progressively in the compensating cylinder 8b. The final pressure in the high-pressure accumulator 7a, 7b is built up by pushing back the piston 10 under the pressure of hydraulic fluid introduced into the high-pressure cylinder 7b. The pressure in the compensating accumulator 8a, 8b is predetermined as a function of the desired holding pressure in the 3rd phase and is below the final pressure in the high-pressure accumulator 7a, 7b. The pressure setting in the expansion tank 8a is carried out by the amount of hydraulic fluid that is introduced via the pressure setting valve 12.

The operation of the pressurizing device is as follows.

The first working phase takes place with the valve 9 closed and the valves 2 and 3 actuated in a manner known per se. The transition to the second work phase is initiated by opening the valve 9 provided with an adjustable throttle. At this time, the piston 11 of the compensating cylinder 8b is in the position shown in the drawing. The piston 10 of the high-pressure cylinder 7b now presses the hydraulic fluid under the full pressure of the high-pressure container 7a into the press cylinder 1 on the press piston 4 at the beginning of the second work phase. By moving the press piston 4 in the second work phase, the line between the press cylinder 1 prevails and high-pressure accumulators 7a, 7b a lower pressure than that set in the expansion tank 8a. As a result, the piston 11 does not change its position during the second working phase. In the event of a pressure surge at the end of the 2nd working phase and during the 3rd working phase, ie the final and holding pressure phase, the piston 11 then deflects under the pressure which builds up in the press cylinder and has a pressure-damping or reducing effect. In this way it is possible to limit pressure surges at the end of the 2nd phase as well as the final and final pressure as well as pressure surges in the 3rd working phase to a predetermined value in the simplest way. It is important that this restriction does not in any way affect the course of the 2nd work phase, in which the highest possible pressure difference between the ram and the high-pressure accumulator 7a, 7b is to be used. The working pressures for both phases can rather be selected independently of one another. This is one of the main advantages of the device according to the invention. A prerequisite for the functionality of the device is that the displacement paths of the pistons 10 and 11 are designed such that when the piston 10 is fully extended, the piston 11 is still freely movable at the end of the 3rd working phase, ie it is not yet in the direction of has reached the downstream expansion tank 8a. The pressure in the high Pressure vessel 7a can be set to 300 bar, for example. In this case, the pressure to be selected for the expansion tank 8a is approximately in a range between 80 and 270 bar. The pressure level actually set depends on the level of the desired reprint at the end of the 3rd work phase.

In addition, there are no switching times between the end of the 2nd work phase and the start of the 3rd work phase, since no valves have to be used.

In the exemplary embodiment shown, the compensating cylinder 8b is connected in the narrowest cross section of a Venturi tube 13 arranged in the connecting line between the press cylinder 1 and valve 9. This ensures that the hydraulic fluid always flows in the direction of the press cylinder 1 at the high flow velocities in the venturi tube, since the static pressure on the piston 11 is lower than that which acts on the press piston 4.

After the press-in cycle, the compensating cylinder 8b is emptied by switching the valves 6, 2 and 3 until the piston 11 is in the starting position.

Claims (7)

1. Device for pressurizing the press cylinder of a die casting machine, in particular cold chamber die casting machine with three-phase work system, in which the press-in part consists of a press cylinder (1) with a single-stage plunger (4) and at least the one required for the 2nd and 3rd phases Filling, final and holding pressure from a liquid-filled high-pressure accumulator (7a, 7b) are applied, while the pressure for the 1st phase can be applied by a system separate from the high-pressure accumulator (7a, 7b), characterized by following features: (a) a compensating store (8a, 8b) opens into a connecting line between the high-pressure store (7a, 7b) and the press cylinder (1) without a valve, (b) the gas-loaded high-pressure accumulator (7a, 7b) consists of a gas-filled high-pressure container (7a) and one in the direction of the press cylinder (1) switched high pressure cylinder (7b) with piston (10) displaceable therein for separating the hydraulic fluid from the gas of the high pressure container (7a) acting on the high pressure cylinder (7b), (c) the compensating memory (8a, 8b) consists of a gas-filled surge tank (8a) with a downstream in the direction of the press cylinder (1) Ausgleichz ^y lin- of (8b) with sliding-in piston (11) for separating the hydraulic fluid from the gas of the expansion tank (8a) acting on the expansion cylinder (8b), (d) the pressure in the compensating accumulator (8a, 8b) is lower than the pressure in the high-pressure accumulator (7a, 7b) 2. Device according to claim 1, characterized in that in the high-pressure accumulator (7a, 7b) leading to the pressing cylinder (1) connecting line between in this connecting line einmündendem _A usgleichsspeicher (8a, 8b) and high-pressure accumulator (7a, 7b), a valve (9 ) is arranged, which is only open during the course of the 2nd and 3rd work phases. 3. Device according to claim 1 or 2, characterized in that for returning the piston (10) in the high-pressure cylinder (7b) in its working starting position in the part of the hydraulic line lying between the valve (9) and the high-pressure cylinder (7b) is provided for introducing hydraulic fluid. 4. Device according to one of the preceding claims, characterized in that the level of the gas pressure in the expansion tank (8a) through a connection of the expansion tank (8a) to the hydraulic fluid can be set as desired via a pressure relief valve (12). 5. Device according to one of the preceding claims, characterized in that the connecting line between the press cylinder (1) and high pressure cylinder (7b) at the point at which the compensating cylinder (8b) opens, is designed as a Venturi tube (13) and the junction point in Area of the narrowest flow cross section of the Venturi tube is. 6. Device according to one of the preceding claims, characterized in that the return of the piston (11) into the starting position is carried out by actuating the valves (6, 2, 3). 7. Device according to one of the preceding claims, characterized in that the piston (11) bears in the starting position at the upper stop of the compensating cylinder (8b) in the direction of the venturi tube (13).

Images