DE555386C - Spring tilting mechanism for gas meter - Google Patents

Description

Spring tilt mechanism for gas knives while according to patent 5 14 275 the switching lever carrying the valves by the one in the previous stroke period tensioned spring was turned while the second spring in the tensioned state is held and the increased clamping stroke was achieved through this arrangement, the same effect is achieved according to the invention with a single helical spring.

In the drawing, an embodiment is shown, namely Fig. i shows a front view of the tilting clamping mechanism, Fig. 2 shows a section A-B through this work.

The counter drive mechanism is shown in for clarity Fig. I and 2 not shown. This is particularly shown in Fig. 3 and 4, where Fig.4 is a section C-D of Fig. 3. In Fig. 3 are for the sake of clarity the control shaft and the drive lever are omitted.

The control consists of the control shaft r, which is rotated by the drive lever 2 by the angle a and b from its central position. The drive lever 2 is firmly connected to the preload levers 3 and the transmission arms 4 and 5. The two spring arms 6 and 7 are rotatably mounted on shaft i, are coupled by the helical spring 8 and their upper ends are pulled towards the center of the control shaft i. The transmission arm 4 is connected by rod 9 to the coupling shaft io through the arm ii, which receives the adjustable crank pin 12 and the locking block 13. The transmission arm 5 is connected by rod 14 to the counter drive lever 15, which is mounted on shaft 16 and receives the rod 17 for the counter drive. The switching lever r8 is also rotatably mounted on the shaft i, receives the guide rod i9 of the valves in a slot and carries the second locking stone 2o.

In the drawing (see Fig. 2 for the following illustration) the moment is shown when the measuring chamber partition (not shown) is in its extreme right end position and the switching lever 18 has just been turned over by the spring arm 6. The helical spring 8 pulls the two spring arms 6 and 7 with their tips towards the center of the control shaft. Here, the spring arm 7 presses against the tensioning lever 3; Since lever 3 is firmly connected to lever 2, it presses against the measuring chamber divider.d and causes .that the gas pressure, which is reduced shortly after the reversal, due to the occurrence of eddies in the gas caused by the opposite flow direction of the gas, does not widen ; is enlarged by the advance of the measuring chamber partition. The spring arm 6, which had just thrown the switch lever, still presses against the switch lever 18 and secures the sealing holder of the switched valves. If the measuring chamber partition moves to the left; this movement is transmitted by lever 2 to tensioning lever 3 and transmission arm 4 and 5. The transmission arm 4 transmits the movement further through rod 9 to the arm ii, and the inner flank of the locking stone 13, which is attached to the arm ii, slides over the outer flank of the locking stone 2o, which is connected to the shift lever 18, and locks the stroke path of the valves. The transfer arm 5 (Fig. 4) passes on the "movement given to it" through rod 14 to counter drive lever 15, which thereby receives an upward movement around shaft 16 as a rotary shaft and, in this case, by means of pliers 17, which are rotatably suspended on arm ii, the pendulum movement of the After the stroke of the valves has been locked, the over-tensioning travel of the spring arm 7 is also terminated, and this pushes itself against the switching lever 18 with the biasing force of the spring in a free-pressing manner of the membrane, the spring tensioning arm 6 is lifted off the switching lever 18 by the tensioning lever 3 and turned to the right, and at the same time the spring is tensioned again until the measuring chamber partition has reached its extreme left position and the spring tension arm 6 is thereby brought into its extreme right position Moment give the locking blocks 13 and 20 the stroke limit free, and spring tension arm 7, which is below the action of the tensioned spring stands, throws the switch lever 18 and thus the valves connected by the rod i9, and that the switch lever is now turned to the right. The spring tensioning arm 7 now rests against the switching lever and ensures that the valves are kept tight, while the spring tensioning arm 6 exerts a pressure on the measuring chamber partition via the tensioning lever 3. When the measuring chamber partition is now moving again to the right, the process just described is repeated, this time the levers move in the opposite direction of rotation, and with further periodic movement of the measuring chamber partition, the periodic processes, as described above, are repeated in the control.

In that the spring tensioning arms 6 and 7 are preloaded by a standing spring are connected and the spring once from the left and the other time is tensioned from the right by twisting their ends, only this bias dem Gas pressure opposes and this also shortly after the switchover to the gas pressure does not counteract this, but the membrane now vibrating in the other direction is supported, as with the tilting clamping mechanism with two helical springs according to the main patent, reducing pressure loss and pressure fluctuation with just one Feather achieved.

Claims (1)

PATENT CLAIM: Tilting tensioning mechanism according to patent 514275, characterized in that a single pretensioned spring, in particular a helical spring wound around the shaft of the parts, is arranged between the tensioning and tensioned part.