DE3427326C2 - - Google Patents

Description

The invention relates to a mixing head for producing a preferably chemically reactive mixture of at least two plastic compos with a mixing chamber, the inlet openings for the individual Plastic components and an outlet for the plastic compo has a mixture of nents, and one arranged in the mixing chamber, transversely Ejector piston of the same cut, which is actuated by a pressure medium The working piston is connected and the inlet openings are open mixing position up to the area of the front outlet opening, shutting off the inlet openings from the mixing chamber, and is movable.

In a known mixing head of this type (DE-AS 20 07 935) open and close alternately and at the same time the entry openings for the individual plastic components without special control means for the opening and closing must be provided, since the back and forth movement of the ejection piston the inlet openings each be run over. Reini is also connected to the mixture output gung the mixing chamber wall of mixture residues by the with the Mixing chamber of the same cross section discharge piston removed when extending will.

The beginning of the injection process or the so-called shot time is with the beginning of the movement of the ejection piston, but what in some inaccuracies in the dosage of the amount of art leads because of the ejection piston Only begins to move from one end position to the other must be torn. Especially with a larger time interval between two successive shots the ejector piston til Lich, something in its one end position in the area of the outlet the mixing chamber. But this has the consequence that the did physical shot time is less than the theoretical or than the ge wanted shot time, so that the dosing of the plastic components is too small, which leads to unusable foam products.

There is already a lack of time constraints in various ways tried to fix the shot time. In the case of DE-AS 25 55 177 The mixing head described is in the path of movement of the ejection piston a scanning element is provided, via which the start of the shooting time is fixed laying contact element is actuated. Such facilities befriedi  not in every respect, however, as this is particularly a transition from a hydraulic-mechanical control to an electrical control tion takes place, which is generally undesirable directly on the mixing head.

With the invention, a mixing head is to be created by a hydraulic-mechanical control an exact dosing of the plastic comm components and at the same time ensure a good mixing intensity accomplishes.

To solve this task, the measures according to the indicator of Claim 1 proposed.

According to the metering accuracy of the plastic components by improved that the movement of the ejection piston in two partial strokes he follows. For this purpose, is hydraulically actuated in the pressure medium circuit Working piston switched on a disc piston, which ent according to the position of the ejection piston with pressure medium is. The ejection piston is in an intermediate position, ready to fire tion, which is as close as possible to the mixed position. In this way there can be time delays between the movements avoid the plunger and the start of the firing time, d. H. the time for the movement of the ejection piston from its ejection position into the The ready-to-fire position no longer has to be in the actual shooting time be viewed. The actual shooting time is theoretically correct calculated shot time practically match, so that once set shot weights are no longer adversely affected.

The disc piston is in particular coaxial with the working piston arranged and axially freely movable between two stops, by one of them in the ready-to-fire position and the other in the mixed position of the ejection piston defined. The attacks are in the work piston-receiving housing provided. The ejection piston can verver casual and repeatable from its mixed position to the ready-to-shoot Position and vice versa.  

Furthermore, the ejection piston is in the ready-to-fire position Throttle element in or out of the mixing chamber by pressure medium this can be pushed out. The throttle body is used to generate a Mixing pressure in the mixing chamber and has the task of flowing amount of plastic components to influence the To improve the quality of the molding, d. H. especially during the Phase at the beginning and at the end of the injection process when the mixing chamber openings do not have their full entrance cross-section have to compensate for a change in the mixing conditions.

To prevent the throttle element from colliding with the one in the mixing chamber orderly to prevent the discharge piston is the pressure medium circuit for the Movement of the ejection piston with that for the movement of the throttle element interconnected. This can expediently be achieved by that each pressure medium circuit is a function of a control pressure Has switchable valve, of which one valve after reaching the shot-ready position of the ejection piston from its ejection position through the working piston and the other valve after leaving the Throttle position is switched by the piston of the throttle member. It is thus used to control the hydraulic movement of the Throttle organ uses the movement of the ejection piston as a control impulse moved and vice versa. In other words, the throttle body can only then be pushed into the mixing chamber when the ejection piston Has reached the ready-to-fire position and the ejection piston is only then moved from the ready to fire position to the eject position when that Throttle device is pulled out of the mixing chamber. Allowing one Ready to fire position hydraulically by engaging a Target piston in connection with the exact determination of the shooting time can thereby be exploited in an advantageous way to ensure that the throttle element is only retracted or extended, if an overlap with the ejection piston is impossible. The Control engineering effort is comparatively low, the hy drastic control absolutely reliable.

The disc piston forms in the Ready to fire position of the ejection piston a stop for the  Working piston, the stop by the working piston facing footprint of the disc piston formed becomes. This causes the disc piston to move in the direction of movement of the working piston from the ready-to-fire position until it is reached the mixed position taken from the piston. in the Conversely, the piston will move in the direction of movement the piston from the mixing position until the shot is ready Position taken from the disc piston.

An exemplary embodiment of the mixing head according to the invention is shown schematically in the drawings and explained in more detail below tert. It shows

Fig. 1 the mixing head in longitudinal section with flow scheme wherein the discharge piston at the discharge position A,

Fig. 2 the mixing head shown in Fig. 1 with the discharge piston in the firing-ready position C,

Fig. 3 shows the mixing head with the ejection piston in mixing position B.

The mixing head essentially consists of a housing ( 1 ) in which a generally circular cylindrical mixing chamber ( 2 ) is formed. Entry openings ( 3 ) and ( 4 ) lead into the mixing chamber, to which, directly or via nozzles, supply lines for the supply of the plastic components are connected. With ( 5 ) an ejection piston is referred to, which can be moved back and forth in the mixing chamber in order to control the inflow of the plastic components and at the same time to clean the mixing chamber. From the piston is shown in Fig. 1 in its advanced position - Ausstellstel development A - illustrated. In this position, the plastic compo nets do not meet each other, but are returned to storage containers via return grooves ( 8 ) and ( 9 ) through the openings ( 6 ) and ( 7 ). The mixing position takes the ejection piston when its lower end face reaches the broken line B and the ready-to-fire position when it reaches line C ( Fig. 2). At least one throttle organ ( 11 ) between the inlet openings ( 3 ) and ( 4 ) and the outlet opening ( 10 ) for the plastic component mixture can be pushed vertically into the mixing chamber ( 2 ).

The throttle member ( 11 ) preferably consists of a cylindrical pin and is controlled by a piston-cylinder unit ( 12 ) which is attached to the housing ( 1 ) of the mixing head. Piston ( 13 ) and cylinder ( 14 ) of this piston-cylinder unit are ausgebil det as a hydraulic actuator. The piston ( 13 ) is actuated by supplying a hydraulic pressure medium through the connections ( 15 ) or ( 16 ) to one or the other side of the piston. In the throttle body ( 11 ) opposite the end wall of the cylinder ( 14 ) is also an opening ( 17 ) see easily to which a control line ( 36 ) is connected.

The ejection piston ( 5 ) is actuated by supplying a pressure medium into the working cylinder ( 18 ), in which a working piston ( 19 ) which is firmly connected to the ejection piston is contained. For this purpose, the pressure medium connections ( 20 ), ( 21 ) and ( 22 ) are provided. Furthermore, the working cylinder has a disc piston ( 23 ) connected to the pressure medium circuit of the working piston with the positioning surfaces ( 23 a) and ( 23 b) , which is arranged coaxially with respect to the working piston and is axially free between two stops ( 24 ) and ( 25 ) is movable. The stop ( 25 ) defines the mixed position B of the ejection piston ( 5 ) and the stop ( 24 ) the ready-to-fire position C. The shot-ready position C is expediently set so that a circulation of the plastic components just takes place.

The disc piston ( 23 ) is sealed by the seal in its outer surface ge compared to the inner wall of the working cylinder ( 18 ) and by a ring seal device against a protruding from the upper end wall of the working cylinder hub, which also serves as a guide. Channels ( 26 ) and ( 27 ) are guided through the hub, the channel ( 26 ) being connected to the pressure medium connection ( 21 ) and the channel ( 27 ) being connected to a further control line ( 35 ). The channels open at ( 28 ) and ( 29 ) into the pressure chamber ( 30 ) between the working piston ( 19 ) and the disk piston ( 23 ).

The supply of pressure medium through the connections ( 20 ) and ( 22 ) leads to the fact that the disk piston ( 23 ) is moved downwards and with its working surface facing the working piston ( 23 b) on the shoulder-like impact ( 24 ) of the working cylinder ( 18 ) and the working piston ( 19 ) with its larger footprint ( 19 a) remote from the ejection piston ( 5 ) come to rest on the disk piston. The lower end face of the ejection piston is in the ready-to-fire position C. In other words:
the disk piston ( 23 ), in particular its footprint ( 23 b) , forms a stop for the working piston ( 19 ) in the ready-to-fire position C of the ejection piston ( 5 ). In this position, the throttle element ( 11 ) can be inserted into the mixing chamber ( 2 ) by applying pressure to the piston ( 13 ) assigned to it. The control of the throttle organ as a function of the position of the ejection piston is inevitably done by the pressure medium circuit for the movement of the working piston ( 19 ) with the pressure medium circuit for the movement of the throttle organ ( 11 ). For this purpose, each pressure medium circuit contains a switchable valve ( 31, 32 ), an orifice ( 33, 34 ) and a control line ( 35, 36 ). Check valves that can be unlocked by a hydraulic control pressure are suitable as switchable valves. The valve ( 31 ) is connected to the control line ( 35 ) leading into the pressure chamber ( 30 ) between the working piston ( 19 ) and disc piston ( 23 ) and is after reaching the shot-ready position C of the exhaust piston ( 5 ) by the Working piston ( 19 ) is switched while the valve ( 32 ) is connected to the control line ( 36 ) leading to the pressure chamber ( 37 ) in the piston ( 13 ) of the throttle member ( 11 ) in the throttle position and by the piston ( 13 ) of the throttle member ( 11 ) is switched. This arrangement ensures that after reaching the ready-to-fire position C of the ejection piston ( 5 ), the throttle member ( 11 ) is inserted into the mixing chamber ( 2 ) before the ejection piston reaches its mixing position B or the throttle member the mixing chamber is pulled out before the discharge piston is moved from position C to discharge position A.

To reach the mixing position B of the ejection piston ( 5 ) from its ready-to-fire position C , the pressure medium connection ( 22 ) is released and the disk piston ( 23 ) from the working piston ( 19 ) is brought into its upper striking position - stop ( 25 ) . For the subsequent movement of the ejection piston into position A , the connections ( 20 ) and ( 22 ) are pressurized during a first partial stroke, ie until position C is reached , and the connection ( 21 ) is released. The Ar beitskolben ( 19 ) is moved during this phase of the disk piston ( 23 ) to the stop ( 24 ) and held in this position, since the disk piston sits over the working piston, the largest working surface be and thus with the same hydraulic pressure also a correspondingly larger Exerts force. For the further movement of the working piston into its lower end position, ie for the second partial stroke, the connection ( 20 ) is relaxed and the connection ( 21 ) is pressurized.

Provided that a mixing process is to be carried out, ie the ejection piston ( 5 ) is to be moved from position A to position B , a solenoid valve ( 38 ) is actuated, the connection ( 21 ) is relieved and the connection ( 20 ) pressurized. At the circuit ( 22 ) is also pressurized; the disc piston ben ( 23 ) lies against the stop ( 24 ). The pressure medium pump, not shown in the drawings, supplies pressure medium with a constant flow rate to the connection ( 20 ) and via the line section ( 40 ) to the switchable valve ( 31 ). At the same time, a partial flow of the pressure medium reaches the control line ( 35 ) between the working cylinder ( 18 ) and the valve ( 31 ) via the orifice ( 33 ). The partial flow in the Steuerlei device ( 35 ) is guided into the pressure chamber ( 30 ) between the disc piston and the working piston and enters the opening ( 28 ) in the unpressurized port ( 21 ) until the working piston with its footprint ( 19 a) on Disc piston rests and the opening ( 29 ) of the control line closes ver. The ejection piston ( 5 ) then takes the final ready position C. In the control line ( 35 ) builds up a higher pressure and the valve ( 31 ) is switched so that pressure medium flows through the connection ( 16 ) in the piston-cylinder unit ( 12 ) and the throttle organ ( 11 ) in the Insert the mixing chamber ( 2 ). For the further joint movement of the disk piston ( 23 ) and the working piston in the mixing position B of the ejection piston ( 5 ), a solenoid valve ( 39 ) is actuated and the connection ( 22 ) is relieved of pressure.

To end the mixing process, the solenoid valve ( 39 ) is actuated and the connection ( 22 ) pressurized. As a result, the working piston ( 19 ) is moved from the disk piston ( 23 ) into the shot-ready position C of the ejection piston ( 5 ). Since the connection ( 21 ) remains depressurized during this time, it is ensured that the disc piston and the working piston together in the lower stop position of the disc piston - stop ( 24 ) - come to a standstill. The subsequent actuation of the solenoid valve ( 38 ) leads to pressure medium passing through the line section ( 41 ) through the connection ( 15 ) into the piston-cylinder unit ( 12 ), whereby the throttle member ( 11 ) is pushed out of the mixing chamber ( 2 ) . A partial flow of the pressure medium is simultaneously fed via the orifice ( 34 ) into the control line ( 36 ), which connects the cylinder ( 14 ) of the piston-cylinder unit ( 12 ) with the switchable valve ( 32 ). This part stream enters the pressure chamber (37) of the cylinder (14), as long as one to the piston (13) rests in the unpressurized port (16) of the throttle member (11) on the end wall and the opening (17) closing the control line. As a result, a higher pressure builds up in the control line ( 36 ) and the valve ( 32 ) is switched so that pressure medium flows into the connection ( 21 ) and the working piston ( 19 ) and the ejection piston ( 5 ) into the lower one Position, ie ejection position A for the ejection piston, are moved.

Claims (2)

1.Mixing head for producing a preferably chemically reactive mixture of at least two plastic components, with a mixing chamber which has inlet openings for the individual plastic components and an outlet opening for the plastic component mixture, and an ejection piston which is arranged in the mixing chamber and has the same cross-section, and which has a working piston which can be actuated by pressure medium connected and can be moved back and forth from a mixing position leaving the inlet openings into the area of the front outlet opening, thereby blocking the inlet openings from the mixing chamber, characterized in that a disk piston ( 23 ) is switched on in the pressure medium circuit of the working piston ( 19 ), which is arranged opposite the working piston and is axially freely displaceable between two stops ( 24 ) and ( 25 ), one of which ( 24 ) has a ready-to-fire position C and the other ( 25 ) has the mixing position B of the ejection piston ens defined (5), that the disc piston (23) in the shot-ready position C, in which the working piston (19) facing away footprint (23 a) can be acted upon with pressure medium, forms a stop for the working piston (19), while the footprint ( 23 a) for the movement of the ejection piston ( 5 ) in the mixing position B can be relieved, and that in the ready-to-fire position C of the ejection piston a throttle member ( 11 ) by pressure medium into the mixing chamber ( 2 ) or can be pushed out, the pressure medium circuit for the movement of the working piston ( 19 ) being interconnected with that for the movement of the throttle member ( 11 ). 2. Mixing head according to claim 1, characterized in that the disc piston ( 23 ) is arranged coaxially to the working piston ( 19 ).