DE1053416B - Ratchet drive for parts of a time-keeping device - Google Patents

Description

GERMAN

The invention relates to a ratchet drive for converting the vibrations of a mechanical one Oscillator in a rotary movement for driving parts of a time-keeping device, in particular of the hands of an electric clock, with a single ratchet wheel and a single one directly The pawl acting on the ratchet wheel and actuated by the oscillator and one on the Escape wheel with frictional braking-acting braking device for time-keeping electrical Small appliances, in particular wristwatches.

There are known ratchet drives, the two into each other engaging ratchet wheels, and two brakes associated with these ratchet wheels, the Ratchet wheels are controlled by a vibrator influenced by an electromagnet. Also knows one ratchet drives that use a single ratchet wheel and a single one directly on the ratchet wheel acting, operated by the oscillator pawl work, the braking device from a curved brake spring movable via a hinge, one end of which engages in the ratchet wheel, while the other end rests against the circumference of the ratchet wheel.

Ratchet drives that have two ratchet wheels and brakes assigned to them are proportionate space-consuming, so that they can be used in small appliances such. B. wristwatches cannot be used. Above Articulated braking devices lead to vibrators with a higher frequency at a fairly high rate Frequency vibrating members, whereby the energy ratios are unfavorable and within the Switching step is worked with changing brake pressure. Higher frequency vibrators than the usual ones Because of their high frequency constancy, even with vibrations, pendulums and riots are especially with small portable devices, e.g. B. wristwatches, advantageous.

In a device of the type mentioned at the beginning, it is proposed according to the invention to avoid these deficiencies, when using an oscillator, in particular a tuning fork oscillator, with a frequency that is many times higher than the usual frequency of disturbances and pendulums, preferably an electrically driven one that determines its frequency Schwingers to keep the moment of inertia of the ratchet wheel equipped with a large number of teeth adapted to the high frequency as small as possible and the braking device with at least one practically straight running, exclusively through constant brake pressure, both the reverse rotation of the ratchet wheel and the advance by more than one tooth preventive, constantly at the ratchet wheel scarf ratchet drive
for parts of a time-keeping device

Applicant:

Bulova Watch Company Inc.,
New York, NY (V. St. A.)

Representative: Dipl.-Ing. H. Lesser, patent attorney,
Munich 27, Possartstr. 6th

Claimed priority:
Switzerland from February 10, 1954

Forming device remaining in the braking position, preferably completely stationary braking part. The braking part can for example consist of a leaf spring lying in a plane perpendicular to the plane of the gearwheel, which is supported with its free end on the shaft of the gear and perpendicular to this one exerts pressure directed to the longitudinal axis of the shaft. The braking part can also be made of one in one to Level of the gear parallel plane lying leaf spring consist, which is with its free end on an end face of the shaft of the gear is supported and on this a pressure lying in the axial direction exercises. Another possibility is the braking part from a spring against a To let surface of the gear pressed brake body exist. The braking part can also have a loose have an annular disc placed on the shaft of the gearwheel, which is secured against rotation by a Spring is pressed on the surface of the gear.

The arrangement according to the invention allows the rotational movement in the drive direction of rotation to one angle of rotation to limit, which corresponds to a single tooth step without the risk of turning back exists, despite the fact that the oscillator has a frequency many times higher than the usual frequency of unrest and oscillating higher frequency oscillates. So there are two tasks solved, namely reverse rotation lock and limiting the amplitude of the ratchet wheel movement without changing the brake pressure. The adjustment is made easier by the use of a practically straight brake spring, and it

809 770/191

3 4

better operating conditions are achieved. Practical example shown consists of a leaf spring,

Experiments have shown that with one design of the one end on a non-rotating

Ratchet drive according to the invention is hardly Zer part 9 of the clock is fastened by a screw 10.

Symptoms of disturbance occur while this is at your other end is propping up with light pressure

Use of two pawls and with such a high fre- 5 of the cylindrical surface of the firmly connected to the wheel 1

sequences cannot be avoided. There are bound wave 2 from. As can be seen from FIG

Incidentally, mostly not the pawls, but the fine ones, the leaf spring 8 lies in one to the plane of the

Ratchet teeth destroyed. It concerns here gear vertical plane, so that the pressure, the

not a mere transfer of the stationary with its free end exerts on the shaft 2, perpendicular to the

Brakes, but curved leaf springs working io the longitudinal axis of the shaft is directed.

known arrangement on one with only a single Since the ratchet drive to drive a clockwork

Ratchet working switching device, but in order to serve it, must have its various components

a solution that is only based on extensive restrictions. Conditions are sufficient for the whole

search, in particular the width of the ratchet-ratchet drive work with sufficient accuracy

rades plays a role, can be particularly advantageous,

could be found. Above all, it is necessary that the gear 1

The invention will be illustrated with a few examples of examples of rotation for each shock it receives explained. It shows an angle that corresponds to a single tooth step.

Fig. 1 schematically shows a first embodiment in which speaks. Looking at Fig. 1 one can easily

which the braking device on the cylindrical 20 see that this condition is met when

Surface of the shaft of the gear acts, the entire displacement of the pawl 5 (i.e. its double

Fig. 2 shows another embodiment, in which pelte amplitude) is greater than the length of a tooth

the braking device on the free end of the shaft step, but less than twice the length of the

of the gear acts, tooth pitch. When the vibration amplitude of the

3 shows the embodiment according to FIG. 2, but for 25 oscillators 3 with A, the tooth pitch of the gear wheel 1

seen from the side, with p and the entire displacement of the pawl 2 A

Fig. 4 shows another embodiment in which bears, so must apply
the braking device directly on the gear

acts, ' p <2A <2p.

FIG. 5 shows a side view of the embodiment according to FIG

Fig. 4, On the other hand, the purpose of the wheel 1

Fig. 6 shows another embodiment, in which acting braking device not only in it

the brake also on the side surface of the tooth - prevent the gear wheel from turning backwards,

rades acts, but also to prevent this

Fig. 7 A, 7 B and 7 C different tooth shapes of the 35 gear due to the principle of inertia with constant

Teeth of the gear and speed continues to rotate so that it is at each

Fig. 8 A and 8 B structural details of the shock it receives, an angle of rotation of several

Ratchet. Corresponds to tooth steps.

In the figures, the corresponding If the pawl 5 moves more slowly or parts of the various embodiments with 4 ° when it is completely stationary, the gear wheel 1 may be given the same reference numerals. The one in Fig. 1 also do not turn any further. The ratchet drive placed on the gear 1 contains a braking force acting as a ratchet wheel. Do not exceed a certain value, so that the brake is not unnecessarily This wheel is the first wheel of the mechanical oscillator not shown clockwork. A mechanical, schematically illustrated 45 draws energy; On the other hand, however, a geter oscillator 3 can not fall below approximately straight, in the white minimum, so that the direction of the arrows 4-4 'from oscillations from braking effect is sufficient so that the tooth is guided. One end of a pawl 5, which is formed by a wheel 1 at each stroke of the leaf spring received from the pawl 5, is fixed with the oscillator 3 does not rotate by more than one tooth pitch,
connected and therefore follows its movements. The 5 ° The limits of these frictional forces can easily be calculated from the other end of this pawl 5 engages the teeth 6 of the The pawl is designed so that the oscillation amplitude of the pawl 5 corresponds to the frequency of its natural oscillation greater than the length p of the tooth pitch, ie that the frequency of the mechanical oscillator and that A = p, then applies to the displacement χ of the pawl 5 the force that it exerts on the 55 when moving backwards at each point in time χ = p sincot, with ω = 2nf and gearwheel, multiplied by the friction f = frequency of the oscillations of the oscillator 3.
coefficient is smaller than the braking force, which is the corresponding acceleration
Brake device exerts on the wheel. ..

If now the latch5 is in the direction of the χ - -ρω smcot,

Arrow 4 'moves, it exerts a pressure on the 6o its maximum

Tooth 6 of gear 1 from which it is pending, and - = a, 2

turns it in the direction of arrow 7. ^{max V}

The pawl moves in the opposite direction If you press Θ to refer to the axis of rotation

Direction, ie in the direction of arrow 4, the moment of inertia of the gear slides and with r the off

it over the flank of the tooth 6, and because of the distance of the point of application of the pawl on the

Exercise between the pawl and the tooth flank could be called the force exerted by the wheel k from the axis of rotation,

the gear wheel can be turned back, if so one can write:

there were no means to prevent this. '

This backward movement is now indicated by a & ₌ _ ^. _ω 2 _

Prevents braking device in the in Fig. 1 70 r ²

The force of the braking device is independent of speed, it is sufficient if it is the same

The power N that must be destroyed by the braking device and delivered by the oscillator is

^: f ² f

From this equation it follows that to reduce the power N, it is useful to use a gear 1 with a small moment of inertia and with the smallest possible tooth pitch, which is particularly important at relatively high frequencies, as they were advantageous according to older proposals of the patentee Drive of clockworks are used.

The pawl 5 must also meet certain conditions: First, it must have sufficient rigidity so that the frequency / _{0 of} its natural oscillation is greater than the frequency of the oscillator 3. In the embodiment of the pawl 5 shown in FIG Leaf spring with a rectangular cross-section. Their frequency is

λ-f

where c is the elastic constant of the spring material, b is the thickness of the spring and / the length of the spring.

You now have to choose the dimensions of the spring so that f _ü ^> f .

On the other hand, the pawl 5 must be flexible enough that the product of the through it when it moves backwards force exerted on the tooth and the coefficient of friction between it and the tooth is less than the braking force exerted on the wheel by the braking device. If those If the condition were not met, the wheel would also be turned back when the pawl 5 moved backwards, which is of course not allowed.

2 and 3 show another embodiment of the braking device in which the Brake spring 8 is not supported on the cylindrical outer surface of the shaft 2, but on its end face. Therefore, it lies here in a plane parallel to gear 1.

In the two above exemplary embodiments, the braking device acts on the one with the gearwheel connected shaft 2. However, the arrangement can also be made so that the braking force is applied directly the gear 1 acts. FIGS. 4 and 5 show a corresponding example. Here has the braking device a sleeve 11, one end of which is fixed to a non-rotating part 9 of the watch and of which the other, open end is very close to the surface of the gear 1. A pushes through in this sleeve a coil spring 12 loaded brake body 13, which can consist of any suitable material, Here, too, it must be ensured that the conditions described above for the braking forces are met are.

Another possibility to let the brake pressure act directly on the gear 1 is in the Fig. 6 shown. Here a leaf spring 14 clamped in on one side presses with its free, forked one At the end, with a slight pressure, an annular disk 15 resting loosely on the shaft 2, the inner diameter of which 2 'is a little larger than the outer diameter of the shaft 2, against the surface of the in the Drawing not shown gear 1.

In all of the examples described above, it was assumed that the teeth of the gearwheel have a sawtooth shape, as shown in FIG. 7A. It should be noted, however, that the ratchet drive gear can have any shape; so the teeth can z. B. have the shape of isosceles triangles shown in Fig. 7B or the shape of a sinusoid shown in Fig. 7C. This last-mentioned tooth shape is particularly advantageous when the tooth pitch is very small, because then the use of such a toothed wheel is particularly simple and economical.

Furthermore, it was assumed in the examples mentioned that the pawl 5 by pressure on the Teeth 6 of the gear 1 acts. However, a pawl can easily be used by pulling it transmits a force. Such a pawl is shown in Fig. 8A, from which it can be seen that the pawl at its free end one in the teeth 6 of the gear engaging hook 5 '. When the pawl 5 moves in the direction of arrow 4, practice the holding 5 'exerts a tensile force on tooth 6 of the gear from where he is pending so that the wheel 1 must turn. If the pawl 5 is then in shifts in the direction of arrow 4 ', the hook 5' slides over the back of the next tooth, like this that he will be standing on this tooth afterwards.

In order to prevent the pawl from wearing out as much as possible, it can be made with an end piece provided a hard material, e.g. B. made of hardened steel, sintered metal, glass or a noble one or synthetic stone (e.g. ruby or sapphire). A handle that consists of a Steel spring with a gemstone set at its end. Fig. 8B shows such an embodiment, in which the pawl 5 carries a gemstone 16 at its tip. If you have this stone fastened differently, you can get a pawl according to Fig. 8A, which when pulling a force on the Gear exercising.

Claims (8)

Patent claims: 1. Ratchet drive for converting the vibrations of a mechanical vibrator into a Rotary movement to drive parts of a time-keeping device, in particular the pointer mechanism an electric clock, with a single ratchet wheel and a single one directly on the The pawl acting on the ratchet wheel, actuated by the oscillator, and one on the escape wheel Frictional braking acting braking device for time-saving small electrical devices, in particular wristwatches, characterized in that when using an oscillator, especially a tuning fork oscillator, with a multiple compared to the usual Frequency of riots and pendulums, higher frequency, preferably one of its frequency self-determining, electrically driven oscillator (3), the moment of inertia of the with one of the high frequency adapted large number of teeth equipped ratchet wheel so small is kept as possible and the braking device is at least one practically straight, exclusively through consistent Brake pressure both the reverse rotation of the ratchet wheel and the advance by more than one Tooth preventing, preferably remaining in the braking position when the ratchet wheel shifts, preferably has completely stationary brake part. 2. ratchet drive according to claim 1, characterized in that that the braking part consists of a lying in a plane perpendicular to the plane of the ratchet wheel There is a leaf spring (8) which is located with its free end on the shaft (2) of the ratchet wheel (1) and exerts a pressure on it perpendicular to the longitudinal axis of the shaft. 3. ratchet drive according to claim 1, characterized in that the braking part consists of one in one to the plane of the ratchet parallel plane lying leaf spring (8 '), which is with her free end is supported on an end face of the shaft of the ratchet wheel and on this one in the Exerts pressure lying in the axial direction. 4. ratchet drive according to claim 1, characterized in that the braking part consists of a through a spring (12) against a surface of the ratchet wheel (1) is pressed brake body (13). 5. ratchet drive according to claim 1, characterized in that the braking part has a loose on the Has the shaft of the Klimkenrad inserted annular disc (15), which is secured against rotation by a Spring (14) is pressed onto the surface of the ratchet wheel. 6. ratchet drive according to claim I _1, characterized in that the teeth of the ratchet drive have a sawtooth shape. 7. ratchet drive according to claim 1, characterized in that that the teeth of the ratchet wheel have the shape of isosceles triangles. 8. ratchet drive according to claim 1, characterized in that that the teeth of the ratchet wheel have the shape of a sine curve. Considered publications:
Swiss patent specification No. 107 905,
077. 1 sheet of drawings © 809 770/191 3.59