Extruder driving apparatus

Details Extruder driving apparatus Extruder driving apparatus

2001-01-10

2004-03-23

Wright, Dirk (Department: 3681)

Planetary gear transmission systems or components

Input from independent power sources

Plural outputs

Reexamination Certificate

active

06709354

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an apparatus for driving an extruder that is typically represented by a twin continuous kneader for kneading high-molecular resin materials such as plastics and rubber.
2. Description of the Related Art
One known apparatus for driving a resin molding machine comprises a main motor; a planetary gear mechanism including a torque input portion driven by the main motor and an output portion for outputting a driving force after reducing a rotational speed (rpm) of the main motor; an output distributing gear mechanism for distributing the driving force from the output portion of the planetary gear mechanism to a plurality of rotor drive shafts arranged parallel to each other; coupling means for connecting one ends of the rotor drive shafts to a plurality of rotors on the extruder side; and thrust bearings for supporting the other ends of the rotor drive shafts to bear thrust forces from the rotors (see, for example, Japanese Unexamined Patent Application Publication No. 11-115035).
In such an extruder driving apparatus, the main motor is generally constituted by a motor rotating at a constant speed and having a large capacity for the necessity of driving the rotor drive shafts with a very large torque.
To meet a need of changing the number of poles of the main motor or changing the rotational speed of each rotor drive shaft depending on the specifications of extruders, therefore, a speed change gear mechanism (see gears 19 and 20 in the above-cited publication) is provided which enables one pair of gears to be replaced by another pair having a different gear ratio for adjustment of the rotational speed of each rotor drive shaft. The speed change gear mechanism is conventionally disposed between the main motor and the planetary gear mechanism.
However, when the speed change gear mechanism is disposed between the main motor and the planetary gear mechanism, the rotational speed of the speed change gear mechanism is equal to or greater than that of the main motor. This gives rise to a disadvantage that the circumferential speeds of teeth and bearings of gears as components of the speed change gear mechanism are necessarily increased and a noise level is increased.
Also, when the rotational speed of the speed change gear mechanism is equal to or greater than that of the main motor, the bearings for supporting the gears as components of the speed change gear mechanism are required to have a large load capacity for ensuring an improved useful life. This requirement however raises a problem that a seizing trouble is more likely to occur due to an increased value of d·n (d=bearing inner diameter, n=number of rotations).
The above-mentioned problems become more serious, particularly, in an extruder such as a biaxial continuous kneader, for which a scale-up has been keenly demanded in recent days, because a main motor must have larger power and rotate at a higher speed to satisfy such a demand.
SUMMARY OF THE INVENTION
In view of the state of the art set forth above, it is an object of the present invention to provide an extruder driving apparatus in which a speed change gear mechanism is disposed in a position allowing the speed change gear mechanism to rotate at a much lower rotational speed, whereby a noise level is reduced and a seizing trouble is more surely avoided.
To achieve the above object, the present invention is achieved with the following technical features.
An apparatus for driving an extruder, according to the present invention, comprises a main motor; a planetary gear mechanism driven by the main motor and outputting a driving force after reducing a rotational speed of the main motor; a speed change gear mechanism driven by an output of the planetary gear mechanism and outputting a driving force after adjusting an output rotational speed of the planetary gear mechanism; a plurality of rotor drive shafts arranged parallel to each other, each rotor drive shaft being provided at an end thereof on the extruder side with a coupling unit for connecting to a rotor; an output distributing gear mechanism driven by an output of the speed change gear mechanism and outputting a driving force to be distributed to the plurality of rotor drive shafts arranged parallel to each other; and a thrust bearing for supporting an end of each rotor drive shaft on the side opposite to the extruder.
In other words, the present invention provides an extruder driving apparatus mainly comprising a main motor, a planetary gear mechanism, an output distributing gear mechanism, coupling units for connection to rotors, and thrust bearings for bearing thrust forces imposed on rotor drive shafts, wherein a speed change gear mechanism for adjusting a rotational speed of each rotor drive shaft through replacement of one pair of gears by another pair having a different gear ratio is provided between the planetary gear mechanism and the output distributing gear mechanism.
With such an construction, since the speed change gear mechanism is disposed on the output side of the planetary gear mechanism, the rotational speed of each gear as a component of the speed change gear mechanism can be reduced down to a much lower value than that of the main motor (usually about ⅕ to {fraction (1/10)} of the motor rpm).
Accordingly, the circumferential speeds of teeth and a bearing of each gear as a component of the speed change gear mechanism are also reduced and noise from the driving apparatus can be lessened to a level as low as possible. Further, since a value of d·n of the bearing supporting each gear is reduced, a risk of seizing of the bearing can be avoided to the utmost.
A planetary gear mechanism has a structure that a plurality of planetary gears are meshed with a sun gear. Therefore, the vector sum of gear meshing forces acting on the sun gear becomes substantially zero, and the sun gear is subjected to only torque and substantially no radial forces. Also, since the torque is evenly distributed to the plurality of planetary gears, the sun gear is not required to be supported by a bearing. Because of those structural features, when a main motor is directly coupled to a planetary gear mechanism as with the present invention, problems of high noise and seizing of a bearing do not occur with the planetary gear mechanism.
In trying to separately provide a rotational-speed adjusting mechanism in a gearing wherein a planetary gear mechanism serving as a main speed reducer and an output distributing gear mechanism serving as a load distributor are combined with each other, it is general knowledge to those skilled in the art that the speed change gear mechanism is disposed on the input side of the planetary gear mechanism like the related art, for the simple reason that such an arrangement reduces torque acting on gears of the added mechanism. By contrast, in the present invention, the novel advantages described above can be obtained by providing the speed change gear mechanism between the planetary gear mechanism and the output distributing gear mechanism contrary to the general knowledge.
More particularly, in the present invention, the speed change gear mechanism may comprise a driver gear directly coupled to an output shaft of the planetary gear mechanism, and a driven gear held in mesh with the driver gear and directly coupled to an end of one of the rotor drive shafts which penetrates through the thrust bearing and is further extended to the opposite side. In this type of the speed change gear mechanism, preferably, the driven gear is formed with helical gear acting to push the one rotor drive shaft back toward the rotor side.
The reason is as follows. By forming helical gear on the driven gear so as to push the rotor drive shaft back toward the rotor side, the load of a thrust bearing for supporting a thrust force imposed on the rotor drive shaft is reduced and a smaller thrust bearing can be employed. Consequently, the size and cost of the driving apparatus can reduced down to the smallest and lowest possible l

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