DE432854C - Auxiliary drive for the slow gear in rotary printing machines - Google Patents

Description

For rotary printing presses it is a condition that on certain occasions z. B. when pulling in the paper web through the various printing units for folding pre-5 ' direction, not allowed to run at full working speed; the running speed rather, it must be dimensioned so that the paper web can be comfortably guided through the printing units and rollers

ίο can. Provide rotogravure printing presses there is also the condition that the entire machine must be used during a work interruption or the printing units or even just the forme cylinder must continue to circulate alone so that the ink dries easily cannot get stuck on the forme cylinders in a crust. Also rotary rubber printing machines may not stand still during a work break; they must so that the printing plates are always moistened can move on.

It is also advantageous to use rotary printing presses during any work interruption, Even with consideration of the power consumption, to let it run more slowly.

In order to keep the slow gear in the electric drive of rotary machines, too called slow forward, got, has. one except the main engine for the full one Working speed a smaller auxiliary 3c motor for the lower speed arranged.

Between the main engine and the auxiliary engine, which is generally still through Gear ratios are in mesh, an overrunning clutch is switched on, which makes it possible to stop the auxiliary engine at a certain running speed of the main engine.

The overrunning clutch is generally either on the main engine or on an intermediate shaft arranged; the latter kind

the arrangement still has particular disadvantages, including lower peripheral speed and correspondingly high circumferential forces. According to the invention, the auxiliary engine receives 5 or the intermediate transmission of one or more gear pairs with oblique teeth. The use of inclined teeth creates an axial force in addition to the circumferential force Thrust, which at a certain size the ίο a gear out of engagement with the one brings him cooperating gear. The axial pressure or release pressure becomes determined by the greater or lesser inclination of the teeth.

The advantages resulting from the arrangement are the elimination of an overrunning clutch; the main engine that used the old one Arrangement had abnormal shafts can be replaced with a normal motor. In addition, there is a simplification of the operation. To the out of mesh Bringing gears back into mesh is either a magnet that works in any way and any type of current can, or a mechanical engagement device is used.

In Figs. 1 and 2 of the drawing is an embodiment of a drive in two Positions for a rotary printing press shown schematically.

On the main motor α for full operating speed of the rotary printing press sit a brake disc b, a gear c provided with oblique teeth and a pinion d, which drives the printing press through gear e . An auxiliary motor / carries a pinion g with which a gear h is in mesh. A small helical toothed radiator is connected in some way to wheel h and can be brought into or out of engagement with also helical toothed wheel c on the main engine. The two gears h and i serve as a translation from fast to slow and are mounted on a shaft k or on a bolt so that they can be moved longitudinally. On the shaft k there is a magnet I ₁ which is intended for the respective type of current or is adapted to the best type of current and which first pulls the gears h and i to the left when the auxiliary motor is switched on and thus brings the two helically toothed gears i and c into engagement . The magnet Z can also act on one end of the shaft and move the entire shaft. The two intermediate gears h and i must in this case be firmly connected to the shaft k; the magnet can also initiate the engagement movement by means of a lever transmission. The gears h and i can, depending on the most favorable overall arrangement, be spatially separated or arranged at the two ends of the shaft k.

It is assumed that the stationary rotary printing press is to be started. The paper is drawn in, which is why the machine must run at slow speed; so only the auxiliary motor f may be switched on for slow running. First, the brake on disk b of the main motor α is released ; then the magnet / helical gear i is brought into engagement to the left with the gear c on the shaft of the main motor a ; only then is the auxiliary motor / switched on. Because the drive is carried out by the auxiliary motor f , the wheels c, i are held in firm engagement by the axial thrust produced during slow running. Is1> the paper web is completely drawn in and the printing machine is ready for work, the magnet / is de-energized, the auxiliary motor / is switched off and the main motor a is switched on. Since the drive is now from the main motor, the gear i of the intermediate transmission is pushed to the right by the lateral thrust now occurring in the opposite direction and disengaged from the gear c on the shaft of the main motor α . The gear pair g, h can also have helical teeth in order to obtain a small engagement pressure when starting. The small helically toothed wheel i can be arranged to be displaceable by itself.

Claims (2)

Patent Claims: i. Auxiliary drive for the slow gear in rotary printing machines, thereby characterized in that at least one cooperating gear pair can be disengaged and is provided with oblique teeth is. 2. Auxiliary drive according to claim 1, characterized in that the disengageable Gears are brought into engagement by a mechanical or electromagnetic device or automatically can. 1 sheet of drawings.