The Wiki for Tale 6 is in read-only mode and is available for archival and reference purposes only. Please visit the current Tale 11 Wiki in the meantime.
If you have any issues with this Wiki, please post in #wiki-editing on Discord or contact Brad in-game.
Alliages
Overview
Les alliages sont fabriqués à partir de métaux fondus dans un Réacteur.
Le démarrage initial d'un lot d'alliage demande : 5 Charbon de bois, des métaux, et 1 résine d'arbre. Le type de résine dépend du type d'alliage. Après avoir travaillé sur le lot d'alliage jusqu'à sa cristalisation, vous pouvez prendre l'alliage produit, ou re-chauffer le lot. Vous souhaiterez re-chauffer le lot et recommencer tant que la quantité d'alliage produite n'est pas satisfaisante. Re-chauffer le lot coûte 3 Charbon de bois et 1 résine.
Types d'alliage et Coûts
If you update this list, please also update the table on the Reactory page.
Métallurgie avancée (1)
Laiton (100% = 8)
- 7 Cuivre, 1 Etain, 1 Résine:Palmier robuste, 5 Charcoal
Bronze (100% = 8)
Fer blanc (100% = 12)
Steel (100% = 8)
- 7 Fer, 1 Etain, 1 Résine:Grand palmier, 5 Charcoal
Advanced Metallurgy (2)
Acier lunaire (100% = 13)
Sun Steel (100% = 13)
Advanced Metallurgy (3)
Métal de Thot (100% = 15)
- 7 Acier, 4 Acier lunaire, 4 Acier solaire, 1 Résine:Folded Birch, 5 Charcoal
Water Metal (100% = 14)
- 7 Acier, 4 Acier lunaire, 3 Argent, 1 Résine:Pratyeka Tree, 5 Charcoal
Advanced Metallurgy (4)
Métal Bleu (100% = 21)
- 7 Acier, 5 Métal de Thot, 5 Métal aqueux, 4 Tungsten, 1 Résine:Cerulean Blue, 5 Charcoal
Advanced Metallurgy (5)
Alliage d'octet (100% = 21)
- 7 Acier, 5 Métal de Thot, 5 Métal aqueux, 4 Tungsten, 1 Résine:Oil Palm, 5 Charcoal
- Cannot reheat. The batch must be abandoned using the Utility menu.
Mechanism
The rules governing the behavior of the Reactory are as follows (more detail and historical information can be found in the discussion page):
- We define the active circle as the circle that has its center nearest your mouse click, that circle will not move (no matter if you click in overlaps or not).
- Circles overlapping with the active circle will move towards it like magnets, the nearer they are, the more they will move.
- If the click results in 2 or more circles congealing completely, the batch crystalizes. The crystalization percentage depends on the number of circles that congeal with the last active circle. So your last click is important: don't just click in the middle of the bright white blob, but try to attract the max number of circles with that last click.
- Estimate of when 2 circles congeal after a click: if a circle has center to center distance to active circle of less than half the circle radius, they will congeal and crystallization will be the result.
Output
A batch's percentage of crystallization is calculated as follows:
Crystallization = (N - 1) / (T - 1) N = number of circles perfectly overlapping after crystallization T = total number of circles
This number is shown as an integer, but likely keeps any fractional part for the purposes of calculating the output.
Output is calculated as follows:
Output (debens) = M * (X - F) / (100% - F) M = Total debens of metals put into the batch X = Crystallization percentage of the batch F = Floor crystallization percentage
The floor percentage is different for each metal, and its calculation method is unclear, but it appears to be determinable as the highest crystallization percentage at which no output is received (example, F=25% for steel, and F=33% for pewter).
Put plainly, the output is exactly 0 at or below the floor crystallization, equal to the sum of the input metals at 100% crystallization, and scales linearly between the two points.
Note that because fractions are kept internally, a larger batch from an upgraded Reactory will not necessarily produce an exact multiple of the output from a normal-sized batch at the same crystallization.
Guides
Here is a quick do and do not guide by wyked avoiding crystalization
Here is a beginner's guide to practical alloys by Daniels: Practical Beginning Alloys
Here is a youtube video guide for alloy by Daniels: Video Guide
