DE102011120588A1 - Screw coupling and plasticizing with this screw coupling - Google Patents

Abstract

Described is a worm clutch with a hollow cylindrical screw holder having an opening for positively receiving a worm shaft and transmitting a torque to the worm shaft. The worm clutch has a means for transmitting an axial force to the worm shaft. According to the invention, a recess is provided in the worm clutch in a first region of the shell inner surface at one end of the worm holder. The means has at least one ring segment, the radially outer part of which is received in the recess of the worm holder and whose radially inner part protrudes radially inwardly from the shell inner surface of the worm holder and can be brought into engagement with a groove of the worm shaft. Furthermore, in a second region of the shell inner surface of the screw holder, the shell inner surface is polygonal in radial cross section. The first area is preferably located on the side of the screw holder on which the screw holder is to be attached to an injection piston. In other words, the recess may be provided in a contact area of the screw holder with an injection piston. In this case, the recess may be provided in steps. By thus configured a worm clutch, it is possible to shift the position where the retraction force is applied to the worm shaft into a region of less torsional stress.

Description

The invention relates to a worm clutch and a plasticizing an injection molding machine with this worm clutch.

A screw coupling has in plasticizing an injection molding machine the task of transferring injection force, torque and worm retraction force from the injection unit or injection piston on a screw conveyor. High nominal voltages and high numbers of cycles occur.

In the prior art, screw couplings are known in which the torque is transmitted via a toothed or splined shaft profile. The transmission of the worm retraction force occurs over part of a toothed or splined profile annular surface of a split ring which sits adjacent to the splined or splined shaft portion on the worm shaft.

A prior art screw clutch is disclosed in US Pat 3 shown. The worm clutch consists of a worm holder 101 and a split ring 102 , The snail holder 101 is formed as a hollow cylinder and is provided on its outer surface with a toothing, which at one end of the worm shaft 103 provided toothing 104 one in the snail holder 101 to be received worm shaft 103 corresponds. The length of the toothing 104 is provided according to the length of the toothing on the shell inner surface. The transition from the toothed area in the area without teeth is formed in the form of a step, wherein the outer diameter or tip circle diameter of the toothing 104 greater than the diameter of the adjacent area without teeth. The split ring 102 consists of two ring segments and has an inner diameter smaller than the inner diameter of the screw holder 101 and smaller than the outer diameter or tip circle diameter of the toothing 104 the worm shaft 103 is. The snail holder 101 and the split ring 102 or the ring segments are provided with axial bores for mounting on an injection piston or injection unit 105 Mistake.

The in 3 As shown in the prior art construction shows an arrangement in which the worm shaft 103 with the worm clutch on the injection piston 105 is attached.

The assembly of the worm shaft 103 at the injection piston 105 is done first by the fact that the screw holder 101 on the toothed area 104 the worm shaft 103 is postponed and in a next step, the ring segments of the split ring 102 adjacent to the snail holder 101 and to the gearing area 104 to the shaft of the worm shaft 103 be created. Subsequently, a screw connection of the ring segments of the split ring 102 with the snail holder 101 and the injection piston 105 , At the same time, this pushes the teeth 104 facing annular surface of the split ring 102 to an area of the step. This will cause the end of the worm shaft to the injection piston 105 pressed and the worm shaft 103 in total at the injection piston 105 fixed. By this arrangement, it is possible, a thrust force of the injection piston 105 directly on the worm shaft 103 transferred to.

As already described above, the transmission of a retraction force to the worm shaft takes place 103 over the on the snail holder 101 attached split ring 102 , As it is in 4 is shown, the part of the toothed area facing annular surface 106 , which transmits the worm retraction force to the worm shaft, very small. In addition, at the transition of the toothed area to the untoothed area of the worm shaft 103 a very small radius may be provided to provide a corresponding area for transmitting the retracting force without having to excessively reduce the diameter of the worm shaft. Therefore, there is a high notch effect in this area and thus a local increase in stress, which increases the risk of snail fractures. It has also been found that the use of a toothing during insertion of the screw into the screw holder can be problematic in terms of damage.

It is therefore an object of the invention to provide an improved worm clutch and to avoid the disadvantages of the prior art.

The object of the invention is achieved by a worm clutch according to claim 1 and a plasticizing an injection molding machine according to claim 9.

Advantageous developments can be found in the dependent claims.

According to the invention, the worm clutch has a hollow cylinder-like worm holder with an opening for the positive reception of a worm shaft and for transmitting a torque to the worm shaft. Furthermore, the worm clutch has a means for transmitting an axial force to the worm shaft. According to the invention, a recess is provided in the worm clutch in a first region of the shell inner surface at one end of the worm holder. The means has at least one ring segment, whose radially outer part in the recess of the Snail holder is received and protrudes radially inwardly of the inner circumferential surface of the screw holder radially inwardly and can be brought into engagement with a groove of the worm shaft. Furthermore, in a second region of the shell inner surface of the screw holder, the shell inner surface is polygonal in radial cross section. The first area is preferably located on the side of the screw holder on which the screw holder is to be attached to an injection piston. In other words, the recess may be provided in a contact area of the screw holder with an injection piston. In this case, the recess may be provided in steps. By thus configured a worm clutch, it is possible to shift the position where the retraction force is applied to the worm shaft into a region of less torsional stress.

Preferably, the ring segment is configured such that the radially outer part extends in the axial direction of the screw holder and the radially inner part extends radially inwardly from the radially outer part. This design of the ring segment on the one hand a correct fit in the screw holder can be made possible and on the other hand, the radially inner part can be formed according to the groove width in the worm shaft.

Desirably, the at least one ring segment has an L-shaped cross-section. Then, the ring segment can be placed in the recess such that it is clamped during assembly of the screw holder to the injection piston between the screw holder and the injection piston and is ensured at the same time due to the L-shape that the radially inner part of the at least one ring segment with a predetermined distance is arranged to the injection piston. This ensures that the at least one ring segment can be arranged immovably in the worm holder and the groove can be provided on the worm shaft in a sufficient distance from the end of the worm shaft for the transmission of force.

However, it is not necessary that the outer part of the ring segment be clamped between the screw holder and the injection piston. It is only generally desirable that the length of the radially outer portion of the ring segment in the axial direction of the screw holder is less than or equal to the width of a bottom of the recess.

In a preferred embodiment, the recess in the casing inner surface is formed circumferentially.

Advantageously, at least two ring segments are provided, which together form a circle. This arrangement allows the retraction force to be uniformly transmitted to the worm shaft. The screw holder may have at least two through-holes in the axial direction. This makes it possible to attach the screw holder easy and low-box on the injection piston.

In the second region, the shell inner surface may be conical in the axial direction. In this case, the inner diameter of the screw holder tapers in the direction of the first region. By this arrangement, it is possible to simplify the centering of the worm shaft.

The plasticizing of an injection molding machine according to the invention has a worm clutch of the type described above. Furthermore, it has a worm shaft which is formed at its one end polygonal corresponding to the shell inner surface of the worm holder and the groove into which engages the ring segment. In addition, the injection molding machine has the injection piston described above. The polygonal part of the worm shaft is received in the worm holder. The at least one ring segment is placed in the recess and engages in the groove of the worm shaft. In addition, the screw holder is fastened with screws to the injection piston.

The length of the polygonal portion of the worm shaft may be equal to the length of the worm holder. For transmitting a thrust force to the worm shaft, the worm shaft is desirably in direct contact with the injection piston.

It is advantageous if the groove is formed circumferentially in the worm shaft.

A concrete embodiment of the present invention will be explained below with reference to the accompanying drawings. The drawings show in

1 a schematic representation in the axial cross section of a worm clutch according to the invention,

2 a schematic representation in radial cross section along the line AA in 1 .

3 a schematic representation in the axial cross section of a worm clutch of the prior art and

4 an enlarged view of the area Z in 3 ,

The worm clutch according to the embodiment is in 1 to recognize and consists of a snail holder 2 and a split ring consisting of two ring segments 4 consists. The snail holder 2 is formed like a hollow cylinder and its inner surface 21 has a stepped recess at one end of the screw holder 22 , In the remaining area is the shell inner surface 21 of the snail holder 2 formed in the radial cross-section polygonal, as in 2 is apparent.

At the in 1 shown construction is the screw holder 2 to an injection piston 5 screwed. The recess 22 is formed at the end of the screw holder, where the screw holder in contact with the injection piston 5 is and extends inwards from the end of the auger holder. In the embodiment, the recess 22 stepped. To the recess 22 adjacent adjoins the polygonal shaped part of the shell inner surface 21 at.

Like it out 1 is apparent, is a worm shaft 3 in the snail holder 2 used. Here is the worm shaft 3 in the area that is in the snail holder 2 is inserted, polygonal corresponding to the inner surface of the shell 21 of the snail holder 2 educated.

At a predetermined distance from the end of the worm shaft 3 in contact with the injection piston 5 is, is a circumferential groove 31 in the worm shaft 3 intended. The one in the recess 22 arranged split ring is L-shaped and has a radially outer part 41 and a radially inner part 42 , The radially outer part is in the recess 22 arranged and the radially inner part 42 protrudes into the groove 31 the worm shaft. Furthermore, the split ring is between snail holders 2 and injection piston 5 trapped.

By virtue of this configuration, the region in which the retraction force is transmitted to the worm shaft is shifted to a region of lower torsional stress. Thus, a transition of the worm shaft from the polygon profile to a round profile in terms of stress distribution can be optimally designed.

LIST OF REFERENCE NUMBERS

1

screw coupling

2; 101

screw holder

21

Inner surface area

22

recess

3; 103

worm shaft

31

groove

4; 102

ring segment

41

Radially outer part of the ring segment

42

Radial inner part of the ring segment

5; 105

injection piston

104

gearing

106

ring surface

Claims (12)

Worm clutch ( 1 ) with a hollow cylindrical screw holder ( 2 ) with an opening for the positive reception of a worm shaft ( 3 ) and for transmitting a torque to the worm shaft ( 3 ) and a means for transmitting an axial force to the worm shaft ( 3 ), characterized in that in a first region of the shell inner surface ( 21 ) at one end of the screw holder ( 2 ) a recess ( 22 ) is provided, the means at least one ring segment ( 4 ), whose radially outer part ( 41 ) in the recess ( 22 ) of the screw holder ( 2 ) and its radially inner part ( 42 ) from the shell inner surface ( 21 ) protrudes radially inwardly and with a groove ( 31 ) of the worm shaft can be brought into engagement, wherein in a second region of the shell inner surface ( 21 ) of the screw holder ( 2 ), the shell inner surface is formed polygonal in radial cross-section. Worm clutch ( 1 ) according to claim 1, wherein the radially outer part ( 41 ) in the axial direction of the screw holder ( 2 ) and the radially inner part ( 42 ) from the radially outer part ( 41 ) extends radially inwardly. Worm clutch ( 1 ) according to claim 2, wherein the ring segment ( 4 ) has an L-shaped cross section. A worm clutch according to claim 2 or 3, wherein a length of the radially outer part ( 41 ) of the ring segment ( 4 ) in the axial direction of the screw holder ( 2 ) smaller than or equal to the width of a bottom of the recess ( 22 ). Worm clutch ( 1 ) according to one of the preceding claims, wherein at least two ring segments ( 4 ) are provided, which together form a circle. Screw coupling according to one of the preceding claims, wherein the recess ( 22 ) is formed circumferentially. Screw coupling according to one of the preceding claims, wherein the screw holder ( 2 ) at least two through holes ( 23 ) in the axial direction. Screw coupling according to one of the preceding claims, wherein in the second region the shell inner surface ( 21 ) is conically formed in the axial direction and the inner diameter of the screw holder ( 2 ) tapers in the direction of the first region. Plasticizing an injection molding machine with a screw clutch ( 1 ) according to one of claims 1 to 9, a worm shaft ( 3 ), which at one end polygonal corresponding to the inner surface of the shell ( 21 ) of the screw holder ( 2 ) is formed and the groove ( 31 ), and an injection piston ( 5 ), wherein the polygonal part of the screw in the screw holder ( 2 ), the at least one ring segment ( 4 ) in the recess ( 22 ) and the groove ( 31 ) and the snail holder ( 2 ) on the side of the first portion of the screw holder ( 2 ) on the injection piston ( 5 ) is attached. Plasticizing device of an injection molding machine according to claim 9, wherein the length of the polygonal part of the worm shaft ( 3 ) equal to the length of the screw holder ( 2 ). Plasticizing device of an injection molding machine according to claim 9 or 10, wherein the worm shaft ( 3 ) at one end in contact with the injection piston ( 5 ). Plasticizing device of an injection molding machine according to one of claims 9 to 11, wherein the groove ( 31 ) of the worm shaft ( 3 ) is formed circumferentially.

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