The present invention relates to an escapement system that can be used, for example, in a measuring device such as in a timepiece. The escapement system comprises a drive axle and at least one escape wheel that has at least one impulse tooth. The at least one impulse tooth is connected to the drive axle via at least one spring element and has a starting position in which it is fixed such that the spring element has a preload torque.
It is known that power regulators in driven gear wheels and timepieces are subject to various force fluctuations that are inter alia caused by the quality of the drive spring, of the driven gear wheel or the lubricant. These force fluctuations causatively influence the isochronism of the power regulator and thus the quality of a timepiece. It has therefore been endeavored to keep the drive train that moves during the impulse as short as possible to minimize the number of interference sources. To solve this problem, it is known from CH 708 043 to place the teeth of the escape wheel onto spring elements that are raised to an energy level by the force that is transmitted to the escape wheel by the power train. The energy thus stored is output in part during the impulse transmission to the lifting surfaces of the anchor. The energy transmitted by the rotation of the escape wheel that is known to be subject to strong fluctuations is always added to this energy, however, so that the device described in CH 708043 admittedly attenuates the fluctuations a little, but cannot eliminate them as is also correctly presented in the text quoted there. An absolutely comparable device is shown in U.S. Pat. No. 2,717,488 in which, however, the noise minimization of an escapement is always the focus.
A different objective underlies the present invention, however. It was thus the object of the present invention to provide an escapement system having a constant impulse energy and a high efficiency.
This object is achieved with respect to an escapement system by the features of claim 1 and with respect to a measuring device by the features of claim 11. The respective dependent claims in this respect represent advantageous further developments.
In accordance with the invention, an escapement system is thus provided that comprises a drive axle and at least one escape wheel, wherein the at least one escape wheel has at least one impulse tooth. The at least one impulse tooth is connected to the drive axle via at least one spring element and has a starting position (or preferably adopts a starting position) in which it is fixed such that the spring element has a preload torque.
The impulse tooth or teeth of the escape wheel each has/have at least two positions they can adopt. One of these positions is the starting position in which the impulse tooth has a low energy level and in which the impulse tooth is located as long as it is not raised to its high energy level, is held there, or is in the phase of energy transmission. A further position is e.g. the tensioning position in which the impulse tooth has its high energy level and into which the impulse tooth is brought during the rotation of the escape wheel (Δα) before it returns to the starting position again after its energy output. The starting position can here also be called the position in which the impulse tooth or the spring element has the smallest tension in a cycle of the escape wheel. The tensioning position can here also be called the position in which the impulse tooth or the spring element has the greatest tension in a cycle of the escape wheel. The tension of the impulse tooth or of the spring element is thus generally lower in the starting position than in the tensioning position.
The present invention is characterized in that the impulse tooth has a preload torque (>0 Nm) while it is in the starting position. In other words, the impulse tooth is already preloaded by a torque in its starting position.
The present invention here decisively differs from the devices described in U.S. Pat. No. 2,717,488 and CH 708043. Resilient impulse teeth are likewise proposed there. However, they are used to reduce the escape noises in U.S. Pat. No. 2,717,488. A preload of the resilient impulse teeth in the starting position is not disclosed in U.S. Pat. No. 2,717,388. CH 708043 takes up a similar technical solution, but intends to present a constant force escapement, with the impulse teeth having no preload in their starting position or in their balance position and with the escape wheel not have any separate balance teeth.
Since the at least one impulse tooth has a preload torque in its starting position in the present invention, the escapement system in accordance with the invention has an energy store that is integrated in the escape wheel and that can forward the impulse directly or indirectly to a balance spring (e.g. via an anchor). This energy store is integrated here into every single impulse tooth or in into every group of impulse teeth of the escape wheel.
In the escapement development, the inertia of the impulse generating elements represents a great challenge. It decisively determines the size of the escape wheels and the frequency of the balance spring. At oscillations at 2.5 Hz upward, more than 60% (usually more than 70%) of the energy is typically used for the acceleration of the impulse generating elements. The inertia of the impulse generating elements is minimized by the present invention, whereby less energy is used for the acceleration of the impulse generating elements. The efficiency of the escapement system can hereby be considerably increased.
The efficiency of the escapement system results in a great approximation from the formula:
η=((Mh+Ml)/2−E1/Δα)/Ma where Ma≥MH,
where η is the efficiency, Ml is the preload torque in the starting position or the low torque, Mh is the torque in the tensioning position or the high torque, Ei is the kinetic energy of the escapement parts moved during the impulse toward the impulse end, Δα is the angle of rotation of the escape wheel per impulse, and Ma is the torque of the escape wheel. It is necessary for a correct routine that the drive axle of the escape wheel outputs a higher torque Ma than is required to tension the impulse tooth. The efficiency of the escapement increases decisively due to the preload torque Ml different from 0 Nm since more of the energy required for the tensioning (Δα·Ma) can be stored.
Minimal inertia and a preload torque Ml of the impulse tooth or of the impulse teeth that is as high as possible in the starting position thus decisively contribute to the high efficiency of the escapement system in accordance with the invention, whereas a maximum of 50% of the available energy can be used without a preload in the starting position.
An escapement system having a constant impulse energy and a high efficiency can thus be achieved with the present invention.
A preferred embodiment of the present invention is characterized in that the escapement system has at least one balancing element that has at least one tensioning surface that moves the impulse tooth from the starting position into a tensioning position on a rotation of the escape wheel. The balancing torque preferably has two tensioning surfaces.
It is particularly preferred that the impulse tooth can be pressed against the at least one tensioning surface by rotating the escape wheel with a torque that is greater than the preload torque of the at least one spring element in the starting position of the at least one impulse tooth such that it is moved out of the starting position into the tensioning position and the preload torque of the at least one spring element is increased in this process.
The at least one balancing element is preferably configured as an anchor, as a balance lever, or as part of a balance spring.
It is further preferred that the at least one impulse tooth adopts a starting position in which it is fixed such that the spring element has a preload torque.
This means that the at least one impulse tooth has a starting position in which it is fixed such that the spring element has a preload torque and adopts this starting position. It is here naturally still possible that the impulse tooth is moved out of the starting position into a different position, e.g. the tensioning position.
It is particularly preferred that the at least one impulse tooth or the impulse teeth has/have a (preload) torque>0 in every position it or they can adopt.
In accordance with a further preferred embodiment, the escape wheel has a plurality of impulse teeth. It is preferred here that each of the impulse teeth is connected to the drive axle via a spring element, respectively. It is alternatively also possible that one, several, or all of the impulse teeth are each connected to the drive axle via one or more spring elements. It is further preferred that each of the impulse teeth is configured in one piece with the respective spring element via which it is connected to the drive axle.
In a further preferred embodiment of the escapement system in accordance with the invention, the at least one escape wheel has at least one abutment that fixes the impulse tooth in its starting position. The at least one impulse tooth can, for example, be pressed against the abutment to thus be fixed in its preloaded starting position. The at least one escape wheel preferably has exactly as many abutments as impulse teeth. It is additionally preferred that the abutments are arranged on the balance wheel.
A further preferred embodiment of the escapement system in accordance with the invention is characterized in that the escapement system has one or more balance teeth. The balance teeth are preferably arranged on the escape wheel, preferably on the balance wheel.
In accordance with a further preferred embodiment of the escapement system in accordance with the invention, at least one escape wheel (or the at least one escape wheel) is designed in two parts and comprises as the first part an impulse wheel that has the at least one impulse tooth and as the second part a balance wheel, with the impulse wheel and the balance wheel being fixed in a fixed position with respect to one another and with the running off of the drive train at the balance wheel preferably being controllable or controlled. If the escapement system comprises a plurality of escape wheels, all the escape wheels or only some of the escape wheels can be designed in two parts, for example.
In an alternative preferred embodiment of the escapement system in accordance with the invention, at least one escape wheel (or the at least one escape wheel) is designed in one part and in two planes, with one of the two planes having the at least one impulse tooth and with the running off of the drive train at the balance wheel preferably being controllable or controlled. If the escapement system comprises a plurality of escape wheels, all the escape wheels or only some of the escape wheels can be designed in one part and in two planes.
It is further preferred that the escapement system in accordance with the invention has an efficiency of more than 30%, preferably of more than 35%.
The present invention additionally relates to a measuring device that comprises the escapement system in accordance with the invention.
In a preferred embodiment of the measuring device in accordance with the invention, the measuring device comprises a power regulator.
The measuring device in accordance with the invention is preferably a time measuring device, in particular a timepiece.
This principle can be used for the most varied escapement types:
Anchor escapements:
Chronometer escapements:
Duplex escapements:
The present invention will be explained in more detail with reference to the following examples and Figures without restricting it to the specific embodiments and parameters shown here.
The function of the escapement system in accordance with the invention will be explained in the following with reference to the Figures by way of example in a “constant energy escapement” similar to the “Swiss anchor escapement”.
A special embodiment of the escapement system in accordance with the invention is first shown in
Each of the impulse teeth 1, 8 is here respectively connected to the drive axle 11 via a spring element. It is alternatively also possible, however, that one, more, or all of the impulse teeth are connected to the drive axle via one or more spring elements. As shown in
The escape wheel shown in
In addition, the escape wheel shown in
In
If now the balance spring moves the anchor 5, there is initially a release of the impulse tooth 1 as soon as it no longer rests on the tensioning surface 2. After release of the impulse tooth 1, it impacts the lifting surface 6 and drives the anchor 5 as is shown in
There is now—while the balance spring performs its complementary arc—a movement of the drive axle 11 until the balance tooth 9 is incident on the balance surface 10, as is shown in
If now the balance spring again moves the anchor 5, there is a release of the impulse tooth 8 as soon as it no longer rests on the tensioning surface 7. After release of the impulse tooth 8, it impacts the lifting surface at the input side of the anchor and drives the anchor 5 as is shown in
From here onward, the routines repeat as soon as the balance spring performs a further passage of the balance position.
It is necessary for a correct routine that the drive axle 11 of the escape wheel outputs a higher torque MA than is required to tension the impulse tooth 1, 8. The efficiency of the escapement increases decisively due to a low preload torque ML different from 0 Nm since more of the energy required for the tensioning (Δα·MA) can be stored. This is also illustrated by
Number | Date | Country | Kind |
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10 2018 212 113.3 | Jul 2018 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/062205 | 5/13/2019 | WO | 00 |