DE668920C - Control eccentric adjusting device for piston machines with planetary gear in eccentric drive - Google Patents

Description

Control eccentric adjusting device for piston machines with planetary gears in the eccentric drive eccentric controls or reversals for piston machines, in particular steam engines, in which in the drive device of the adjusting eccentric a planetary gear is switched on, are already known. In particular it was also already proposed to synchronize between adjusting eccentric and basic eccentric or control shaft to achieve the planetary gear on a parallel to the control shaft To arrange auxiliary shaft. This arrangement of the adjusting eccentric requires a large number of gears or ring gears and bearings. and because of the expansive Auxiliary shaft also has a lot of space and weight.

According to the invention, in this type of eccentric adjustment Synchronization between the twisting eccentric and the basic eccentric or between the adjusting eccentric and control shaft achieved by using two planetary gears on the control shaft are arranged. One of the two planetary gears can be the basic eccentric, the other drive the twist eccentric or corresponding parts of the control, with these rotating in the opposite direction as the control shaft, or it the planetary gears can be connected to one another, whereby the adjusting cam or the control parts in question in the same direction as the control shaft circulate. This is a simple and cheap, space-saving arrangement and low Number of gears achieved.

Fig. I shows a diagrammatic embodiment of the invention. On the control shaft r, the planetary gears 2 and g are arranged, which here are provided in bevel gear design. The bevel gears q. and 5 are keyed on the control shaft. The axis 6 of the planetary gear 7 is attached to a stationary part of the machine, so that the bevel gear 8 is at the same speed, but in the opposite direction Direction of how the control shaft rotates. The axis of the planetary gear g is with the the control shaft pivotable planet carrier io connected so that when held Planet carrier io also the bevel gear ii with the same speed, but in the opposite direction as the control shaft rotates. The planet carrier io is for example with a fork ia; provided, which verbunddi with the standing equipment will. By adjusting or swiveling the planet carrier zo, the relative Position of the two bevel gears 8 and ii rotating in the same direction of rotation changed. The adjustment can be carried out in a known manner by hand or by means of a speed controller or pressure regulator etc. Now that one of the two wheels 8 and ii with the basic eccentric, the other with the twisting eccentric or if only one is used Adjusting eccentric the one of the two bevel gears with the suspension point or the Guide stone of the adjustment eccentric and the other connected to the adjustment eccentric, so when adjusting the planet carrier io changes the lead angle and the eccentricity according to the apex curve of the adjusting eccentric.

For machines that only run in one direction of rotation, the Adjustment angle of the planet carrier zo to the range from zero filling to largest Filling extend, in contrast to the adjustment range of the eccentric when reversing tight from largest forward filling to largest backward filling. li In Fig. i, for example A two-eccentric control is required, with the planetary gear 8 as the basic eccentric is designed around which the twist eccentric 13 can rotate. This is connected to the bevel gear ii, for example by pin 14 and stone 15.

Fig. 2 shows another implementation of the inventive concept, wherein the two planetary gears are coupled to one another and, for example, spur gears to apply. The control shaft is again marked with i and the two Planetary gear with 2 and 3. The pinion 16 of the planetary gear 2 is on the The control shaft is keyed, while the internal toothed ring gear 17. on the control shaft is rotatable and by acting on the fork 18, for example Steilzeug is held. The ring gear ig of the transmission 3 is with a resting Part of the machine is connected, so it has an unchangeable fixed position. The Ritzel2o of the transmission 3 sits loosely on the control shaft. The two planets 7.1 and 22 respectively the gear or: 3 are rotatably mounted on a common axis 23, which in which on the control shaft i loosely seated planet carrier 24 is attached. the the two transmissions are therefore coupled to one another by the planetary axis 23. at the rotation of the control shaft i by means of the pinion 16 attached to it Planet gear 21 on the ring gear of the fixed ring gear 17 in the direction of rotation unrolled, the planet carrier 24 also in the direction of rotation zach stipulation the translation shifts. Thanks to the planetary gear axle fastened in the planetary gear £: ger 24 23 s; planet wheel 22 is also carried out in the same way, so that the same rolls on the stationary ring gear i9, whereby the pinion 2o is also in the direction of rotation is moved. As long as the ring gear 17 is in a certain position is held, the planets 9,1 and 22 and the pinions 16 and 2o lead equal movement off; the pinion2o rotates in the same direction and at the same speed as the pinion 16 or the associated control shaft i. The relative position of the tickle 2o to the control time i thus remains unchanged. Will the ring gear 17 is pivoted about the control shaft z by means of the vertical fork 18: so is the planet axis or the planet carrier in the same direction relative to the control shaft i turned. Since the permanently attached ring gear does not change its position, it must the planetary gear 22 corresponding to the movement of the planetary carrier 24 on the ring gear unroll, creating a corresponding relative movement of the pinion 2o. In In the drawing, for example, the pinion 2o is connected to the adjusting eccentric 25 or made from one piece. It is, for example, an @ eccentric control with internal adjustment eccentric required. The Ritzelzo can of course with others Execution of the control without further ado with a correspondingly different adjustment part the same are connected. The adjusting eccentric 25 therefore runs in the same way and at the same speed as the control shaft i, but changes its relative Location in each case according to the adjustment of the ring gear 17. The same success can also be achieved, for example, when the planet axis 23 is in the planet carrier 24 is rotatably mounted and one of the planetary gears 21 or 22 is fixed to the axis is connected.

Another embodiment is shown in Figure 3. The coupling the two gear is here by connecting the two pinions or union de-the same to a common pinion 26 accomplished. The ring gear 27 of the transmission 2 ibt keyed on the control shaft i, while the common pinion 26 and the Ring gear 28 of the transmission 3 is rotatably mounted on the control shaft. The planetary gear 2g of the gear 2 is rotatable on the planetary gear axis 3o g >> h.gert, which in Planet carrier 31 is attached. This is with a stationary part of the machine tied together. The pinion 32 of the transmission 3 is rotatable on the planetary gear shaft 33 stored, which is attached in the two-part planet-: t ° ager 34, 34 @. This Planet carrier is rotatably mounted on the control shaft and is through the For example, with the planetary gear shaft 33 connected adjusting fork 35 held. The adjusting eccentric 36 is firmly connected to the ring gear 28. When held Adjusting fork 35 rotates the eccentric 36 in the same. Direction of rotation and with the same Speed 'like the control shaft, but changes its position relative to the control shaft, when the planet carrier 34, 34! is adjusted.

In addition to the examples given, there are also other possible designs of the inventive idea given that another compilation of the the two gears by fastening or holding them in the rest position Parts, planetary gear axle, pinion or ring gear, is chosen, with the location of the held Part can be changed by adjustment. For the execution of the gearbox is It is of course irrelevant which type of gears is chosen and whether one instead of each Planet gear of the same stored for several in a common planet carrier the two individual transmissions are provided.

Claims (2)

PATENT CLAIMS: i. Control eccentric adjustment device for piston machines with planetary gears in the eccentric drive, characterized by two planetary gears (2 and 3) arranged on the control shaft, one of which (2) is the basic eccentric (8), the other (3) the rotating eccentric (i3) or corresponding parts of the eccentric adjustment drives, whereby the planet gear (7) of one gear is fixed and the planet gear (9) of the other gear is mounted pivotably about the control shaft (i) (Fig. i). ' 2. Control eccentric adjusting device according to claim i, characterized in that that the two planetary gears (2 and 3) are coupled to each other and. a gear (i9) or a planetary gear axle (3o) of one gearbox is fixed while a gear (i7) or a planetary gear axle (33) of the other gear around the control shaft (i) is rotatable or adjustable (Fig. 2 and 3).