A stackfreed is a simple spring-loaded

cam Calmodulin (CaM) (an abbreviation for calcium-modulated protein) is a multifunctional intermediate calcium-binding messenger protein expressed in all eukaryotic cells. It is an intracellular target of the secondary messenger Ca2+, and the bind ...

mechanism used in some of the earliest antique spring-driven

clock A clock or a timepiece is a device used to measure and indicate time. The clock is one of the oldest human inventions, meeting the need to measure intervals of time shorter than the natural units such as the day, the lunar month and the ...

s and

watch A watch is a portable timepiece intended to be carried or worn by a person. It is designed to keep a consistent movement despite the motions caused by the person's activities. A wristwatch is designed to be worn around the wrist, attached by ...

es to even out the force of the

mainspring A mainspring is a spiral torsion spring of metal ribbon—commonly spring steel—used as a power source in mechanical watches, some clocks, and other clockwork mechanisms. ''Winding'' the timepiece, by turning a knob or key, stores energy in ...

, to improve timekeeping accuracy. Stackfreeds were used in some German clocks and watches from the 16th to the 17th century, before they were replaced in later timepieces by the

fusee Fusee or fusée may refer to: * Fusee (horology), a component of a clock * Flare, a pyrotechnic device sometimes called a Fusee * Fusee, an old word for "flintlock Flintlock is a general term for any firearm that uses a flint-striking lock (fi ...

. The term may have come from a compound of the German words ''starke'' ("strong") and ''feder'' ("spring").

History

Spring-driven clocks were invented around 1400 in Europe.

Mainspring A mainspring is a spiral torsion spring of metal ribbon—commonly spring steel—used as a power source in mechanical watches, some clocks, and other clockwork mechanisms. ''Winding'' the timepiece, by turning a knob or key, stores energy in ...

s allowed clocks to be portable and smaller than the previous weight-driven clocks, evolving into the first large watches around 1500. However, the early spring-driven timepieces were much less accurate than weight-driven clocks, because the drive force (

torque In physics and mechanics, torque is the rotational equivalent of linear force. It is also referred to as the moment of force (also abbreviated to moment). It represents the capability of a force to produce change in the rotational motion of th ...

) exerted by a coiled spring, unlike a weight, is not constant, but is maximum when the spring is wound up and declines as the spring unwinds to turn the movement's wheels. The main cause of inaccuracy in early spring-driven timepieces was the large variation in force provided by the

as it unwound during the timepiece's running period. The force of the mainspring, transmitted through the clock's gears, gives pushes to the oscillating

balance wheel A balance wheel, or balance, is the timekeeping device used in mechanical watches and small clocks, analogous to the pendulum in a pendulum clock. It is a weighted wheel that rotates back and forth, being returned toward its center position by a ...

which keeps time. The primitive ''

verge and foliot The verge (or crown wheel) escapement is the earliest known type of mechanical escapement, the mechanism in a mechanical clock that controls its rate by allowing the gear train to advance at regular intervals or 'ticks'. Its origin is unknown. V ...

'' movement used in all early timepieces was very sensitive to the amount of force applied to it, particularly before the

balance spring A balance spring, or hairspring, is a spring attached to the balance wheel in mechanical timepieces. It causes the balance wheel to oscillate with a resonant frequency when the timepiece is running, which controls the speed at which the wheels of ...

was added in 1658; the weaker the drive force applied by the mainspring, the slower the balance wheel would oscillate back and forth. So without some device to equalize the force of the mainspring, early clocks and watches slowed down drastically during the clock's running period as the mainspring lost force, causing inaccurate timekeeping. Two devices appeared in the first spring powered clocks to even out the power of the mainspring: the ''

'' and the ''stackfreed''. The origin of the stackfreed is unknown. It is assumed it was invented in the southern Germanic states (

Nuremberg Nuremberg ( ; german: link=no, Nürnberg ; in the local East Franconian dialect: ''Nämberch'' ) is the second-largest city of the German state of Bavaria after its capital Munich, and its 518,370 (2019) inhabitants make it the 14th-largest ...

and

Augsburg Augsburg (; bar , Augschburg , links=https://en.wikipedia.org/wiki/Swabian_German , label=Swabian German, , ) is a city in Swabia, Bavaria, Germany, around west of Bavarian capital Munich. It is a university town and regional seat of the ' ...

) during the 16th century, since the early spring clocks which incorporated it came from there, but it may have been invented earlier. Drawings of stackfreeds appear in

Leonardo da Vinci Leonardo di ser Piero da Vinci (15 April 14522 May 1519) was an Italian polymath of the High Renaissance who was active as a painter, Drawing, draughtsman, engineer, scientist, theorist, sculptor, and architect. While his fame initially res ...

's Codex 1 (1492-1497) and M3 (1497-1499); possibly the device was brought to his attention by his German assistant Giulio. While the fusee went on to become the standard mainspring equalizer in European timepieces, the less satisfactory stackfreed was used exclusively in a few German timepieces; and disappeared after about a century. Surviving examples of stackfreed timepieces date from about 1530 to 1640.

How it works

See drawing, right. The stackfreed consists of a stiff spring arm ''(A)'' with a roller at the end ''(B)'' which presses against an eccentric

''(D)''; usually the roller rides in a groove in the cam's edge. The cam is shaped like a snail. It has a gear on it ''(E)'' that is turned by a gear on the mainspring arbor ''(C)'', so it makes one turn during the clock's running period. The force of the spring arm against the cam exerts a retarding force on the mainspring, reducing its torque, which varies with the thickness of the cam. When the mainspring is fully wound up, the arm presses against the wide part of the cam. Since it is far from the axis, the retarding force it exerts is maximum. As the clock runs and the mainspring unwinds, the cam rotates and the spring bears against the narrower parts of the cam, reducing the retarding force gradually, to compensate for the declining force of the mainspring. At the end of the running period there was often a steep depression in the cam that the roller pressed against, so the force of the stackfreed spring aided the weakened mainspring. Often (as shown at right) a solid uncut section in the cam's ''(E)'' gear teeth also functioned as ''stopwork'', limiting the mainspring so it stopped before it was wound up all the way, and stopped before it unwound all the way. This restricted the mainspring to the center part of its range, further reducing force variation.

Advantages and disadvantages

The stackfreed was a very inefficient device. Since it worked by exerting an opposing friction force on the mainspring, it required more powerful mainsprings and higher gear ratios in watches, which may have introduced more variation in drive force. The

, the other mainspring compensation device, was much more efficient. The only advantages of the stackfreed were that it was easier to make and much thinner than the fusee, which, combined with the fact that it was located in unused space on the outside of the back plate, allowed stackfreed watches to be flatter. With the development of narrower, more compact fusees, the stackfreed disappeared from timepieces around 1630.

References

{{Authority control Timekeeping components

History

How it works

Advantages and disadvantages

See also

References