DE2203354A1 - PRESSURE HAMMER SYSTEM WITH SPRING DRIVE - Google Patents

Description

Print hammer system with spring drive The invention relates to a print hammer system for flying printing units, in which the pivotably mounted hammer is under controllable Spring and magnetic action is available.

The drive source for the print hammer is generally used here a spring which can be tensioned via an eccentric and which, when idle, is operated by one on both Legs with coils provided with permanent magnets is held.

There are already a number of printing devices known as Use electromagnetic and electrodynamic converters for the drive. Because the efficiency but this is only between 5 to 10%, are proportionate to printing high electrical energies. This leads in particular to parallel printers, at where up to 1n6 printing devices are arranged side by side, create difficulties in heat dissipation.

Printing devices with servo actuation are also known.

In these systems, the pressure energy is taken from a mechanical storage device, e.g. obtained from a continuously rotating shock wheel and the electromechanical Converter only required for a very short time to trigger the drive process. Through this a good electrical efficiency is achieved and the problem of heat dissipation largely defused.

Pressure systems with tensioned springs as energy storage are also available to be included in the servo drives. With the known spring systems, the largest part are constructed in such a way that the hammer and the spring are firmly connected to each other, there is the disadvantage that the hammer after the impression - due to the relaxed Spring - cannot return to its original position, but close to the pressure point remains. Since the hammer still has some residual energy, this can lead to bouncing vibrations and double printing. There are therefore auxiliary measures in systems of this type required to prevent bouncing and the hammer after the impression to hold in a defined position. With systems that have become known for this the hammer is sniffed during the backswing by friction or clamping devices, i.e. form-fitting Connections, fixed or by stopping against a second movable inertial mass, which is loosely connected to the hammer, brought to rest.

The disadvantage of this type of servo drive is that the functional reliability of relatively undefined properties, e.g. independent of the coefficient of friction and, moreover, a great deal of wear and tear occurs.

This disadvantage can be avoided by using a hammer and spring decoupled after the acceleration phase. Because the hammer speed is very high however, there is very little time available for this process. That's why the coupling must be able to be released very quickly and safely.

The object of the invention is, in the case of the printing hammer system mentioned at the outset a quick and reliable detachable coupling for the pressure hammer for flying pressure to create, and this is achieved according to the invention in that the drive spring attacks the print hammer via a force-fit element and the force-fit Connection shortly after the hammer movement caused by the removal of the magnetic force releasable and in the rest position of the print hammer caused by the magnetic force is restored.

The clutch is abruptly canceled by a forced sequence, which is independent of undefined and changeable properties, whereby a very high functional reliability is guaranteed.

The invention is described in more detail below with reference to the drawing.

It shows Fig. La a system in the tensioned, ready-to-print state with a leaf spring as energy storage, Fig. Ib the system after the pressure in the relaxed State, Fig. 2a and 2b a similar embodiment in which as an energy store tensioned tension spring is used.

According to FIG. 1 a, the spring 2 is tensioned by an eccentric or lever 1. The pawl 3, which only acts in a force-fit manner, engages behind the driver nose 4 of the print hammer 5 with the aid of the pawl return spring 14. The print hammer 5 is by a permanent magnet 6, on the legs 7 and 8 of which the coils 9 and 10 sit, held on. By feeding a current into the coils 9 and 10 at the time of printing the force field of the permanent magnet is temporarily canceled. The duration of the interruption should be shorter than the hammer flight time, so that the hammer on return can be held in its starting position by the magnet without bouncing again.

After releasing the magnet, the hammer 5 snaps under the action of the force the spring 2 forward in the direction of the printing position. Shortly before the impact on the Type carrier 11, the driving spring 2 is separated (decoupled) from the hammer. this on the other hand happens by the fact that the leg 12 of the pawl 3 / has a fixed stop 13 runs and the pawl 3 abruptly from the driver nose 4 separates. Since the hammer 5 and the pawl 3 have about the same speed when separating, if the contact pressure and the frictional force between the two parts are very low, see above that a long service life is guaranteed.

At the same time, the stop 13 also serves as a limit stop for the spring 2. This ensures that the pawl 3 securely in the decoupled Position remains and the hammer 5 also safely return to its starting position can.

The hammer 5 flies after the decoupling process by virtue of its kinetic Energy free continues against ink and recording media and prints the selected one Type from.

After this process, during which the hammer approx. 90% of its kinetic Loses energy, the hammer returns to its original position unhindered and is held there by the magnet without bouncing, as shown in Fig. Ib.

After the print line from the print hammer systems arranged in parallel has been printed in full or the type set has passed the printing location once, the spring 2 is tensioned by the tensioning mechanism 1, the pawl 3 without friction behind the driver nose 4. The facility is now ready to print again.

The pressure arrangement in FIGS. 2a and 2b is constructed similarly and is correct the operation of the latch corresponds to the described arrangement. Bs will but instead of a leaf spring a coil spring 15 with a drive arm 16 used, on which the pawl 3, which is under the action of a spring 17, is mounted is.

Fig. 2a shows the system with a tensioned spring, Fig. 2b with a relaxed spring.

Patent claims:

Claims (2)

Claims: 1. Print hammer system for flying printing units which the pivotably mounted hammer is under controllable spring and magnetic action, characterized by the fact that the mainspring has a force-locking mechanism element attacks the print hammer and the positive connection shortly after the by lifting the magnetic force caused hammer movement releasable and in the by the rest position of the print hammer caused by the magnetic force is restored. 2. Print hammer system according to claim 1, characterized in that the frictionally acting element is mounted on a spring against a Fixed stop is the latch that hits against a point where the hammer is placed presses. ). Pressure hammer system according to claim 1, characterized in that the frictionally acting element is a pawl that can be pivoted to a Spring action standing arm is mounted and under the action of a fixed on the arm Pen stands. L e r s e i t e