How are the complications of the Astronomia achieved?
Jacob & Co. Astronomia Complications: A Complete Breakdown of "Mechanical Principles + Structural Implementation" Explaining in layman's terms: How are the four legendary functions—a three-dimensional orbital platform, a three-axis tourbillon, a dial always facing upwards, and the rotation of the Earth/celestial bodies—achieved step-by-step through gear architecture and transmission layout?
I. Understanding the Overall Underlying Architecture
Ordinary Watches: Planar layered structure, the movement lies flat, and all gears operate on a single plane.
Astronomia: Vertical Central Axis + Suspended Cross Rotating Platform
A main vertical central axis stands at the very center of the case.
A cross-shaped four-arm rotating bridge is mounted on the axis.
The entire cross bridge revolves around the central axis once every 20 minutes.
The four arms respectively hold: a three-axis tourbillon, hour and minute dials, a globe, and a sunburst diamond.
All complications are built upon this fundamental "global 20-minute revolution."
II. Core 1: How is the 20-minute global revolution achieved? The movement's bottom layer features a reduction gear train, receiving power from the mainspring. This power is reduced in speed through multiple gear sets, ultimately driving the central vertical main drive shaft. This main drive shaft then rotates the upper cross bridge at a uniform speed.
Transmission logic: Mainspring barrel ? Conventional gear train ? Multi-stage reduction gear set ? Central vertical shaft ? Cross bridge (one revolution every 20 minutes).
Challenges: Three-dimensional vertical transmission, axial force balance, and micro-backlash control; otherwise, the four cantilever arms would eccentrically vibrate.
replica Audemars Piguet watches
III. Core Feature 2: Tri-axis Tourbillon. How is this triple-axis combined rotation achieved?
This is its most crucial aspect: three rotating axes that are perpendicular to each other and move in superimposed motion:
1. First axis: Conventional tourbillon rotation (60 seconds/revolution).
Similar to a traditional one-minute tourbillon: The escapement and balance wheel inside the tourbillon frame rotate once around their own horizontal axis every 60 seconds, counteracting the gravitational positional difference.
2. Second Axis: Rotation of the Inclined Inner Frame (5 minutes/revolution)
The tourbillon is not fixed to the cantilever, but rather mounted in a tilting, oscillating second support. A dedicated gear train drives this second support, rotating once every 5 minutes around the inclined axis, increasing spatial dimension to compensate for gravity.
3. Third Axis: Revolving with the Bridge (20 minutes/revolution)
The entire tourbillon assembly revolves around the vertical axis at the center of the dial every 20 minutes, along with the cross-shaped bridge.
Implementation Principle: Three independent gear trains + differential planetary gear sets, each driving an orthogonal axis, superimpose the three layers of motion: rotation ? tilting ? revolution. All power comes from the same mainspring, relying on precisely distributed transmission ratios.
IV. Core 3: How is the dial always 12 o'clock facing upwards during revolution achieved? (The smartest mechanical design)
Contradiction: With the dial mounted on the rotating bridge, without compensation, the scale will remain crooked during the 20-minute revolution, making it impossible to read the time.
Implementation Solution: Planetary Differential Reverse Rotation System
A planetary differential gear mechanism is built into the lower part of the hour and minute dial.
The bridge rotates the dial clockwise every 20 minutes.
The differential gear train gives the dial a counter-clockwise rotation.
The mechanical transmission ratio is precisely matched: revolution angular velocity = counter-rotation angular velocity.
Result: The dial always remains horizontal relative to the table, with 12 o'clock always facing upwards. The rotation is imperceptible to the naked eye; only the entire support rotates around it.
This is Astronomia's most essential patented mechanical structure.
V. Core Feature 4: Globe and Sun Diamond Independent Rotation – How is this achieved?
In addition to the tourbillon and hour and minute dials, the four cantilever arms also feature:
A miniature enamel globe: rotating once every 24 hours
A 288-facet Jacobian-cut sunburst: rotating once every 60 seconds
Implementation: Multiple hidden vertical drive shafts branch off from the central main shaft
Each shaft has its own small reduction/increase gear train
Matching different speed ratios for 24 hours and 60 seconds
All are hidden inside the hollow cross-shaped bridge arms; the gears are not visible from the outside, only the elegant rotation of the celestial body is visible.
Challenges: Ultra-miniature gears, transmission through hollow cantilever arms, multiple gear trains operating independently without interference, and balanced power distribution.
VI. How does the overall power and layout of the movement withstand such complexity?
Dedicated custom movement JCAM10 / JCAM19: Hundreds of precision parts, all redesigned with a three-dimensional structure; a generic movement cannot be modified.
Unified power input, multi-path distribution: A single mainspring barrel outputs power through multi-layer differential and planetary gear trains to: global revolution, three-axis tourbillon, dial compensation, Earth rotation, and diamond rotation—all functions.
Three-dimensional bridge plate + suspended bridge structure: The traditional solid mainplate is eliminated, replaced by a hollowed-out aerospace-grade alloy and gold bridge, reducing weight while maintaining rigidity and preventing rotational deformation.
In a succinct summary:
All the complications of the Astronomia are achieved through four key mechanical structures:
Multi-stage reduction gear train ? drives the entire dial's 20-minute three-dimensional revolution
Three sets of orthogonal independent gear trains + planetary gears ? stacked to create a triple-axis tourbillon rotation
Differential counter-rotation mechanism ? cancels out the revolution, ensuring the hour and minute dials are always upright and readable
Multi-path hidden transmission gear trains built into the bridge ? allow the Earth and Sun diamonds to rotate independently for timing.
It's like compressing a complete miniature solar system mechanical astronomical instrument into the watch case, achieved entirely through pure mechanical gear differentials, speed ratios, and spatial orthogonal structures, without any electronic assistance.