DE869565C - Counter with timer for anemometer - Google Patents

Description

Counter with timer for anemometer There are anemometers for measuring of flow processes known which, in addition to the counter, have a timer. The measuring process is controlled by this time measuring clockwork. the latter sits down mostly composed of three stages, the lead time, the measurement time and the follow-up time, During the measuring time, which is a certain time unit, e.g. B. 1 minute, takes wrid the counter with the drive system of the anemometer, e.g. B. an impeller. coupled. This means that after each measurement on the dial of the counter the mean wind speed in meters per unit of time. z. B. m / min., Direct can be read.

The operation of the known devices is, however, very cumbersome and requires separate operations for each measurement. For example 1. Winding of the chronometer mechanism, 2nd zero position of the measuring pointers, 3, starting of the chronometer mechanism.

Due to this complicated operation, incorrect measurements are easily possible, especially by neglecting one or the other operating procedure.

According to the present invention, a counter with a time measuring clockwork was created created, in which all operations are summarized in a single switch-on movement are. By moving e.g. b. an operating lever takes place in an inevitable order the winding, the zero position of the hands and the start of the timer movement.

The counter is characterized according to the invention by two on the same axis, so arranged so that they can be rotated to a limited extent with respect to one another a lever system in such a way as control elements cooperating cams that one of them as a result of the winding movement when tensioning the mainspring of the timepiece movement, under the action of a spring, independent of the spring drive of the chronometer mechanism, a limited one performs the angular rotation in leaps and bounds, while the rest of the angular path up to the full rotation of 360 ° in the time measure and depending on the movement sequence, at the same time takes place with the rotary movement of the second cam. As an example, Fig. 1 to 5 show an embodiment of the invention in principle.

Fig. 1 shows an overall scheme. For the sake of clarity, there are two Springs 19, 20 of the lever system not shown; Fig. 2 shows the principle of the control system in the rest position; Fig. 3 shows the position of the control system after the elevator has moved of the operating lever before it returns to the starting position; Fig. 4 shows this Position after the lead time has ended or at the start of the measuring time; Fig. 5 shows the position at the end of the measuring time.

The device and its function are described below. The axis 1 carries the operating lever 2, the elevator cam 3 and the trigger 4.

If the operating lever 2 is moved in the direction of arrow 5, then if the return spring 6 is tensioned, the elevator cam 3 pushes at the same time (Fig. 1) on the elevator pin 7 and rotates the toothed segment 8 with its axis 9 accordingly.

A drive spring 10 is tensioned in the process. The toothed segment 8 engages into the teeth of the drive shaft 11, on which the ratchet wheel 12 is stuck. The pawl 13 sits on the gear 14 and allows the reverse rotation of the in a known manner Ratchet wheel to without turning the wheel 14.

When the operating lever 2 is subsequently released, it moves back to its initial position by the force of the return spring 6. The elevator cam 3 releases the elevator pin 7 and the drive spring 10 drives over the parts 11, 12, 13 and 14 the movement parts 30, 31 and the balance wheel 32 in a known manner. Of the The starter 33, which is connected to axis 1, ensures that the balance wheel is started reliably is guaranteed.

When moving the operating lever 2 in the direction of arrow 5 (Fig. 3) the trigger 4 is moved accordingly. He presses on the lever nose 15 (Fig. 1 and 3) and thereby rotates the release lever 16, which is on its hub 17 is stuck around the lever axis 18 9 Fig. 1 and 3). As a result, the spring 19 is tensioned, and the trigger pin 21 moves out of the groove 22 of the groove washer 23.

The latter is easily rotatably mounted on the drive axis 11. In their Rotational movement is limited by the grooved disk 23 relative to the cam disk 25 the stop pin 24, which is stuck in the cam disk 25 and by a corresponding larger bore 27 of the grooved washer 23 is sufficient (Fig. 1, 2 and 3).

The cam disk 25 is firmly seated on the drive shaft 11 (Fig. 1). Her Rotation is therefore inevitable from the movement of the movement parts 30, 31 and the balance wheel 32 dependent.

The tension spring 26 (Fig. 1) has one end on the cam disc 25 attached. Its other end holds the grooved washer 23 under spring tension.

After the release by the release pin 21 (Fig. 3), the groove washer rotated so far in the direction of arrow 34 until the hole 27 on the other hand on the stop pin 24 is applied (position according to Fig. 3). This rotation of the groove washer 23 pushes the concentric circumference of the grooved washer under the release pin 21 and locked this en return path (position Fig. 3), when the operating lever 2 is now through the return spring 6 is brought into its initial position and the trigger 4 the Lever nose 15 releases (Fig. 4). The balance wheel 32 (Fig. 1) is activated by the starter 33 started simultaneously. The first part of the measurement process, the so-called lead time, has started. The drive shaft 11 can rotate over time in the direction of arrow 34 and with it also the cam disk 25 with the grooved disk 23.

When the release lever 16 is rotated, the same moves away from the switchover pin 28 (Fig. 3), which is fastened in the switch-on lever 29. the latter is firmly connected to the lever axle 18 and rotatable with it. The return spring 20 gives the switching lever 29 a torque.

The rotary movement is controlled by the control pin 44 on the partial circumference the cam disk 25 (Fig. 2 and 3) rests delayed until the cam disk has twisted so far that the control pin can fall off (Fig. 4). The lead time is finished and the actual measuring time has started at the same time. The clutch wheel 36 has been brought into meshing engagement with impeller 35 at the same instant (Fig. 4). Via the gears 37, 38, 39 and 40, the measuring pointers 41, 42 are now correspondingly the speed of the impeller rotated on a scale. The scale is not shown.

After exactly one minute, for example, the grooved washer has become off the position according to Fig. 4 in the direction of arrow 34 in the position according to Fig. 5. The release pin 21 falls, caused by the force of the spring 19, into the groove 22; the release lever 16 strikes the switch pin 28 and moves the switch lever 29 with the control pin 44 in the position Fig. 5. The clutch wheel 36 comes into play apart from tooth engagement, and the transmission of motion of the impeller 35 to the measuring pointer 41, 42 is interrupted. The measuring time is thus ended.

The chronometer mechanism continues to run until the stop pin 24 comes from position Fig. 5 to position Fig. 2, on the other hand at the hole 24 rests and the groove 22 on the release sitft 21. after completion This follow-up time ends the entire measuring process. the measuring pointers remain the scale in the position of the measured value obtained until the next measuring process. The measuring pointer is reset at the same time as the first movement of the actuating lever 2 in the direction of arrow 5 (Fig. 3) by a zero setting element 43 (Fig. 1) and the zero setting hearts 44 'and 45 in a known manner. The zero setting organ 43 is connected to axle 1 in a suitable manner.

PATENT CLAIMS: 1. Counter with timer for anemometer measurement of flow processes during a certain time unit with multi-stage Measuring process and an actuator through which all the necessary operations must be initiated, characterized by two bearings on the same axis, so mutually limited rotatable arranged, with a lever system such as Controls cooperating cam discs that one of the same as a result of the elevator movement when tensioning the drive spring of the chronometer mechanism, under the action of a spring, independently from the spring drive of the chronometer movement, a limited angular rotation by leaps and bounds executes, while your remaining angular path up to the full rotation of 360 ° in Time measure and depending on the movement sequence, simultaneously with the turning movement the second cam disk takes place.

2. Counter with a timer according to claim 1, characterized in that that the joint actuator is automatically activated after the drive spring has been lifted goes back to its starting position, releasing the balance of the chronometer movement will.

3. Counter with time measuring clockwork according to claim 1 and 2, characterized thereby, that a cam determines the lead time and the start of the measuring time while the second cam limits the duration of the measuring time and the follow-up time.

Claims (1)

Cited publications: Publication No. 361 from R. Fuess, Berlin-Steglitz.