DE10003711A1 - Hydraulic clamp locking itself in slide bar grooves to apply closure pressure to mold, comprises casing around bar with internal spring-loaded pistons and locking segments - Google Patents

Abstract

The coupling casing (2) surrounds the slide bar (1). It includes locking segments and internal pistons which first lock the unit in grooves on the bar, then apply closure pressure to the injection mold : Preferred features: Segments (3) are arranged concentrically around the bar inside the casing, to perform the locking duty. In order to convert axial- to radial force, the segments are conical. The operating pistons are operated under pressure (e.g. hydraulic), both pistons sharing a common pressure chamber (below 9). All retractions are promoted by spring loading (7, 8) (Bellville washer packs are shown). Use of springs having differing spring constant, automatically assures the correct operating sequence. In an alternative, retractions may be promoted under pressure (e.g. hydraulic). Any piston chambers provided for this purpose, are interconnected. In this case also, for correct movement sequencing, chambers have differing effective areas. Fully independent pressure connections may be provided for operation and retraction. Electric motor operation may be employed. Segment retraction is promoted by spreader springs acting between side faces of the segments. Unlocking of the segments employs the inclined plane principle.

Description

The invention relates in particular to a form-fitting tension coupling for use in plastic injection molding machines to close the Injection molds.

So far, two mechanisms have been used to move and close molds in plastic injection molding machines:

• 1. Mechanisms with toggle levers.
• 2. Mechanisms with long-stroke hydraulic cylinders.

Ideally, the coupling should ideally have the following main features, especially for applications in which a high clamping force in combination with high cycle rates with little technical effort is required:

• 1. Low moving mass.
• 2. High closing force.
• 3. High closing speed.
• 4. Simple construction of the clutch.
• 5. Functional separation of the traversing and closing movement of the injection mold.

The object of the invention is therefore seen in a tension coupling create a high with a low dead weight and simple construction Has closing force and closing speed and therefore the basic requirements offers opportunities for the economical operation of plastic injection molding machines.  

Previously known mechanisms are not able to do all of these at the same time Requirements.

• 1. With toggle lever mechanisms, high closing forces can occur at high cycle rates can be realized, however, a considerable technical effort is required.
• 2. With long-stroke hydraulic cylinders can be done with reasonable effort achieve either only high cycle rates or only high closing forces.

The principle underlying the invention is now the method Functionally separate movement and the closing process of the injection mold. The movement can be done using a small hydraulic cylinder or Electromechanical drive take place, with high travel speeds can be achieved.

The clamping coupling on which the patent is based comes to close the mold to be used, which achieves high locking forces at high cycle rates.

The following advantages are achieved with the invention:

The tension coupling is simple and has a relatively low Mass, which enables high cycle rates of the injection molding machine. In addition, high closing forces can be achieved with the coupling according to the invention produce.

Further features of the invention emerge from the subclaims.

The invention provides a form-fitting tensioning coupling, which in Essentially consisting of a cylindrical coupling body and arranged therein Locking and tensioning elements exist.

Analogously, the sequence of operations of the tensioning coupling between  as a result of the locking and tensioning process taking place. The so-called locking segments are ring-shaped around a guide column or pillar of plastic specially provided for the purpose of locking Injection molding machine arranged and preferably engage when locking in one circular puncture of the column.

When tensioning, the locking segments and thus the column are one Axial force applied, which is supported on the injection mold and clamps it.

Exemplary embodiments of the invention are described below with the aid of drawings described.

Show it:

Fig. 1 shows a first embodiment in longitudinal section in the locked, untensioned position

Fig. 2 shows another embodiment in the representation as Fig. 1 also in the locked, untensioned position.

In the embodiment of the tensioning coupling shown in Fig. 1, the movements are realized with a combination of pressure-actuated cylinders and spring assemblies.

The locked and unclamped state of the coupling is shown.

In the unlocked and untensioned state, the locking piston ( 5 ) is in its left end position. The segments ( 3 ) are radially in their outer end position and allow the axial movement of the bolt ( 1 ) in the housing ( 2 ).

The process of tensioning the coupling is as follows: The basic requirement is that the tensioning coupling is in a position in which the segments ( 3 ) lie over a groove in the bolt ( 1 ).

A pressure is applied to the pressure connection ( 9 ).

First, the locking piston ( 5 ) moves against the weak springs ( 7 ) to the right and leads to a radial movement of the segments ( 3 ) against the force of the spreading springs ( 4 ) until the segments engage in the groove of the bolt ( 1 ) and Locking piston ( 5 ) abuts the segments ( 3 ) on the plane side. The pressure at the pressure connection ( 9 ) continues to stiffen and the tensioning piston ( 6 ) moves against the force of the strong springs ( 7 ) to the left until the mold of the injection molding tool is closed and the full closing force has built up.

The relaxation process of the coupling of FIG. 1 is compared to the tensioning process in exactly the reverse order.

In the embodiment of the clutch shown in Fig. 2, the movements are consistently implemented by pressure-actuated cylinders. The locked and unclamped state of the coupling is also shown here. In the unlocked and untensioned state, as in FIG. 1, the locking piston ( 5 a) is in its left end position.

The segments ( 3 a) are radially in their outer end position and allow the axial movement of the bolt ( 1 a) in the housing ( 2 a).

The process of tensioning the coupling is as follows: The basic requirement is that the tensioning coupling is in a position in which the segments ( 3 a) lie over one of the grooves of the bolt ( 1 a). A pressure is always present at the constant pressure connection ( 12 a) regardless of the actuation state of the clutch.

A pressure is also applied to the pressure connection ( 9 a).

First, the locking piston ( 5 a) moves against the pressure in the pressure chamber ( 10 a) to the right and leads to a radial movement of the segments ( 3 a) against the force of the spreading springs ( 4 a) until the segments enter the groove of the bolt ( 1 a) intervene and the locking piston ( 5 a) abuts the segments ( 3 a) on the plane side.

The pressure at the pressure connection ( 9 a) continues to increase and the tensioning piston ( 6 a) moves against the pressure in the pressure chamber ( 11 a) to the left until the mold of the injection mold is closed and the full closing force has built up. The sequence of movements of the locking piston ( 5 a) and the tensioning piston ( 6 a) is predetermined by the ratio of the piston areas in the pressure chambers ( 10 a) and ( 11 a)

The relaxation process of the coupling of FIG. 2 is compared to the tensioning process in exactly the reverse order.

Claims (16)

1. Clamping coupling for preferred use for clamping molds in plastic injection molding machines, characterized in that the coupling consists of a housing arranged above the bolt and therein piston and actuating elements for locking and tensioning the coupling between the grooves of the bolt and the injection mold. 2. Tension coupling according to claim 1, characterized in that for locking ment in the housing are arranged concentrically around the bolt segments. 3. Tension coupling according to claims 1 and 2, characterized in that the segments for converting an axial into a radial movement at least one side is tapered. 4. Tension coupling according to claims 1 to 3, characterized in that the axial movement of the actuating piston for clamping by pressure medium is produced. 5. Tension coupling according to claims 1 to 4, characterized in that to tension the clutch, both actuating pistons have a common one Have pressure room. 6. Tensioning coupling according to claims 1 to 5, characterized in that the relaxation movement of the clutch is achieved by means of springs. 7. Tensioning coupling according to claims 1 to 6, characterized in that to determine the sequence of movements of the two pistons of different strengths Attack the relaxation spring packs on the pistons. 8. Tensioning coupling according to claims 1 to 7, characterized in that the relaxation movement of the clutch is achieved by pressure medium.   9. Tensioning coupling according to claims 1 to 8, characterized in that the piston chambers to accomplish the relaxation movement of both pistons have a spatial connection to relax. 10. Tensioning coupling according to claims 1 to 9, characterized in that the piston chambers to determine the sequence of movements of the two pistons are designed to relax with different sized active surfaces. 11. Tensioning coupling according to claims 1 to 10, characterized in that the pistons for clamping each with their own, spatially independent Pressure fluid connections are operated. 12. Tensioning coupling according to claims 1 to 11, characterized in that the pistons to relax with their own, spatially independent Pressure fluid connections are operated. 13. Tensioning coupling according to claims 1 to 12, characterized in that the clamping movement is generated by electromotive pistons. 14. Tensioning coupling according to claims 1 to 13, characterized in that the relaxation movement is generated by electromotive pistons. 15. Tensioning coupling according to claims 1 to 14, characterized in that the unlocking movement of the segments by between the segment End spreading springs is realized. 16. Tensioning coupling according to claims 1 to 15, characterized in that the unlocking movement of the segments like the locking movement is realized by an inclined plane system.