DE19607661C1 - Distribution gear transmitting power from central shaft to multiple-screw plasticising machine - Google Patents

Abstract

This distribution gear drives a multi-shaft screw plasticising machine, from a ring of pinion shafts (5, 6) turned by a central shaft (1). The pinion shafts (5, 6) accept axial forces from the driven screw shafts. The pinion shafts have coated end covers (13) which transfer these axial forces to the coated thrust plate (14) against which they lie, and which rotates with the central shaft. The thrust plate rests in its turn upon a thrust bearing (15) coaxial with the central shaft.

Description

The invention relates to a transfer case for driving a Multi-shaft screw machine, the pinion shafts in a ring are arranged and driven by a central shaft.

Such gears are very expensive to build, especially since they are all in one Intermeshing mixing shafts arranged in the ring and the half have a very small center distance.

In addition, absolute synchronism of all shafts is certain ask, being very high, up to the resilience limit torques approaching these shafts are required. In addition, these shafts act with very high axial forces proposes which of the follow-up tools of such machines be built.

Becomes a multi-shaft screw with viscous substances or high molecular polymers charged under vacuum result enormous sealing problems on the many worm shafts, especially such seals can be designed for temperatures up to 350 ° C must and are therefore very complex and therefore expensive; moreover one or the other seal can leak unpredictably the what for very long, unscheduled repair work leads, which are particularly uneconomical.  

Are such multi-shaft machines with, for example, 8, 10, or 12 worm shafts equipped to ensure a correspondingly long ver Achieving time in the processed goods is for every wave a double-acting thrust bearing combination is required, which - because of the high axial pressures - still axially to each other must be installed offset; so there are insoluble mon day and maintenance problems.

In a device which has become known from DE 40 01 986 C1 in the form of a multi-shaft reactor, the drive and bearing tried to solve the problem that the helical Gears were moved to the process part of the machine. This initially very simple type of drive for one such a reactor could also not be used in practice enforce, especially since no solids can be processed and the processed material in melt form the double gear pass must suffer. Because the worm shafts to be processed have to push melting melt in front of them are because of it Deflection only possible for short lengths.

The view cited there, is due to the new type of drive no impairment of the function of these above Given thin-film reactors cited, is therefore completely inapplicable because gears that are in a planetary system circulate and are charged with melt, the product stream divide so that each half to the outer and inner ring of the worm shafts with the result that the desired and very important and indispensable thin for the process layer is completely lost.

As the recent past has shown, much can shaft screw machine in industry therefore not set, because the sealing and thrust bearing problems so far unsolved solves, despite this type of machine excellent lingering Time and mixing results achieved that no other This type of machine can be achieved so far.

To remedy this fact and with very simple means Solving sealing and bearing problems of this machine type, has set itself the task of the present invention space-saving transfer case of the initially described To create a genus that manages with few parts, the synchro nization of the drive shafts ensures that is constructed so that the resulting tooth forces on the teeth counteract each other cancel the axial forces of the worm shafts on one simple, strongly dimensioned axial bearings can be transferred and, if necessary, the transmission is made vacuum-tight can be, so that it is vacuum tight to the process part of the Multi-shaft screw machine is attachable to all Work around sealing problems.

To solve this task is the distributor mentioned above Gear according to the invention, characterized in that the pinion shafts that absorb the axial forces of the worm shafts, are provided with coated end caps, which are under Ein effect of the axial forces on a rotating with the central shaft, Apply coated pressure plate, which is on a coaxial supports thrust bearing arranged to the central shaft.

The vacuum-tight transfer case makes a difference differs from the normal gearbox only in that an additional, after wearable mechanical seal is used and the sliding sealing ring represents an additional part.

The pinion shafts stand with the zen surrounded by them tralwelle and a ring gear enveloping it, so that the tooth forces cancel each other, whereby 6 Pinion shafts from the ring gear and 8 or more pinion shafts from Central wheel are driven.

If necessary, only a mechanical seal is left in the gearbox the drive side of the central shaft, which with Temperatures not stressed and easily accessible. This Standard gears can basically be used with a multi-shaft machine Are used regardless of whether solids or  Melt are processed, especially since the intermediate Shaft couplings make this possible. Because the thrust washers move relative to the axes of the pinion shafts is theirs Lubrication ensured.

The object of the invention is shown in drawings and is explained in more detail below; show it:

Fig. 1 is a longitudinal section through the transmission standard, attached to a solid machine,

Fig. 2 shows the same gearbox in a vacuum-tight design, vacuum-tightly mounted on a melting machine.

The transfer case shown in Fig. 1 consists of the central drive shaft ( 1 ), on which coated bearing rings ( 2 ) with needle bearings ( 3 ) are provided, between which a central drive wheel ( 4 ) is arranged to the mutually axially offset, massive Pinion shafts ( 5 , 6 ) are ring-shaped, which are enclosed by a ring gear ( 7 ).

The pinion shafts are also coated at their bearings and carry needle bearings ( 8 ), which are each arranged in a common housing disc ( 9 ) with the needle bearings ( 3 ).

The ring gear is also housed in a needle bearing ( 10 ), the running and plane surfaces are coated and start with little axial play against the coated partner surfaces of the housing discs ( 9 ), which the needle bearing ( 10 ) and the surrounding housing ( 11 ) between them hold tight.

The pinion shafts ( 5 , 6 ) carry at the end facing the gear drive, coated end caps ( 13 ) via a fine thread ( 12 ), which transmits the axial forces transmitted to them on a plate driven by the central drive shaft, coated pressure plate ( 14 ) which in turn forwards the axial forces to a strongly dimensionally dimensionable thrust bearing ( 15 ) which is arranged coaxially with the central shaft and which is supported on the housing disc ( 16 ). The resting housing disc ( 15 a) of the bearing ( 15 ) is centered in position by the housing ( 17 ), in which a radial bore ( 17 a) is closed at the top with a threaded plug ( 17 b).

At the non-driven end of the drive shaft ( 1 ) a stitch ( 1 a) is provided in which a divided ring ( 1 b) is located, which is secured against falling out by the ring ( 1 c) against which a thrust bearing ( 18 ) with its wave washer ( 18 a) from which is centered by the drive shaft, and the associated housing disc ( 18 b) of the thrust bearing ( 18 ) is centered in the housing plate ( 19 ), in the compression springs ( 19 a) the pressure bearing keep under tension.

The drive-side end of the central drive shaft is provided with involute gearing ( 1 d), preferably manufactured according to DIN 5480, via which the drive, not shown, is driven by a preferably frequency-controlled drive motor via a reduction gear, which is flanged to the housing disc ( 16 ) by the motor , he follows.

The involute toothing ( 1 d) is followed by a recess ( 1 e) in which there is a split ring ( 1 f), which is prevented from falling out by the pressure disc ( 1 g), in the studs ben ( 1 h) are provided, which act on the thrust washer ( 1 i).

The frictional connection between the thrust bearings ( 15 ) and ( 18 ) is generated with the studs ( 1 h), which act on the thrust washer ( 1 i) and this axial force via the parts ( 2 , 1 k, 14 , 11 , 2 , 4 , 2 , 1 c,) transferred to the split ring ( 1 b), so that the pressure bearing ( 18 ), which is under spring preload, thus holds the pressure bearing ( 15 ) under tension without play.

On the output side, coated pressure rings ( 20 ) are screwed onto the pinion shafts after the needle bearings ( 8 ), which start up with little axial play against coated partner surfaces of the housing pressure plate ( 21 ) and are only effective when the machine is at a standstill.

All housing parts are sealed to each other with the O-rings ( 22 ) against leakage of lubricant and are therefore also vacuum-tight.

The torque of the pinion shafts is transmitted via couplings ( 23 ) to the worm shafts of the multi-shaft machine, in which stud bolts ( 24 ) which are easily accessible from the outside are provided in two rows, the lower cone of which engage in conical grooves in the shafts and axially brace them.

On the coupling peripheral surfaces Laby ring rings ( 25 ) are arranged on both ends, which are effective as a sealant against the housing plate ( 19 ) and the intermediate plate ( 36 ) lenwel machine.

At the drive end of the gearbox labyrinth rings ( 27 ) are also arranged in the thrust washer ( 1 g) and are effective against the screwed washer ( 16 a).

The intermediate plate ( 36 ) of the multi-shaft machine is screwed onto the transfer case with the tie rods ( 32 ), the spacer rings ( 34 ) and the nuts ( 33 ) and fixed with the pins ( 35 ) as a drive for a multi-shaft screw machine for processing solids.

If the multi-shaft screw machine is used to process melt with vacuum, the distributor gear according to FIG. 2 is required, which differs only slightly from that according to FIG. 1 in that the method part of the multi-shaft machine has a different intermediate plate ( 37 ) an intermediate ring ( 38 ) is attached to the transfer case with the screws ( 39 ) and fixed with the pins ( 40 ), each of which contains an O-ring ( 41 , 42 ) and in which a separate vacuum connection ( 43 ) is provided, so that the intermediate space ( 44 ) can be subjected to vacuum.

Instead of the threaded plug ( 17 b), the transfer case is also connected to the vacuum source ( 43 ) at this point and only becomes vacuum-tight when the pressure plate ( 1 i) is replaced by the pressure plate ( 45 ), which is coated on one side and opposite the central drive shaft ( 1 ) is sealed with the O-ring ( 46 ).

The housing washer ( 16 a) is replaced by the housing washer ( 16 b), in which a commercially available mechanical seal ( 47 ) is built in and screwed to the housing washer ( 16 ) in a vacuum-tight manner with the O-ring ( 48 ).

Claims (6)

1. Transfer case for driving a multi-shaft screw machine, the pinion shafts ( 5 , 6 ) arranged in a ring are driven by a central shaft ( 1 ), characterized in that the pinion shafts ( 5 , 6 ), which absorb the axial forces of the screw shafts, with coated end caps ( 13 ) are provided which, under the action of the axial forces, create a pressure plate ( 14 ) rotating with the central shaft, which is supported on a thrust bearing ( 15 ) arranged coaxially to the central shaft ( 1 ). 2. Transfer case according to claim 1, characterized in that the pinion shafts ( 5 , 6 ) which are simultaneously in engagement with the central shaft ( 1 ) and a ring gear enveloping them ( 7 ) are driven by the ring gear in less than 8 pinion shafts and at 8 or more pinion shafts, driven by the central shaft. 3. Transfer case according to claim 1 and 2 characterized in that the axially offset pinions ( 5 , 6 ) engage in a coated on its flat surfaces ring gear ( 7 ), which axially mounted with little play between coated flat surfaces of the gear housing ( 9 ) is. 4. Transfer case according to claim 1 to 3, characterized in that on the pinion shafts ( 5 , 6 ) after the output-side radial bearings ( 3 ) coated pressure rings ( 20 ) are arranged, which are supported with little play against a coated pressure plate ( 21 ). 5. Transfer case according to claim 1 to 4, characterized in that it is vacuum-tight and connected via a ver sliding ring ( 38 ) vacuum-tight to the process part of the multi-shaft worm machine and the drive shaft is provided at the transmission input with a mechanical seal ( 47 ). 6. Transfer case according to claim 1 to 5, characterized in that the shaft couplings ( 23 ) are provided approximately longitudinally with two rows of conical, radially arranged studs ( 24 ) which engage in conical annular grooves of the two shaft ends to axially clamp the shafts to each other , and that at both ends at their peripheral surfaces Chen at least one plate ring group ( 25 ) is arranged as a seal against the housing.