Thermodynamics Calculator beta

Model A → B environmental transitions, dew point & condensation (psi), and desiccant sizing with packet helpers.

Module 1 — Air Properties

State A (current) vs State B (target / bound)

State A current

Temperature Air at A

Relative humidity %RH at A

Pv (psi) —

Pg(T) (psi) —

Absolute humidity (g/m³) —

Dew point (°F) —

State B target / bound

Temperature Storage / fridge / case

Relative humidity %RH goal in B

Pv (psi) —

Pg(T) (psi) —

Absolute humidity (g/m³) —

Dew point (°F) —

Air volume (optional) Used to convert humidity drop into grams of water

Module 2 — A → B Transition

Drying requirement + condensation check

Moisture to remove (air-only)

—

Condensation check

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Δ( Dew point − T₍B₎ )

—

We assume you cool/condition air from State A until its absolute humidity matches State B. Then we scale by volume to estimate grams of water that must be captured. This does not yet include moisture emitted by paper, sleeves, backing boards, etc.

Module 3 — Desiccant Sizing

Usable capacity %

e.g., silica gel ≈ 10–12%, molecular sieve ≈ 20%

Safety factor

Standard pack size (g)

Required desiccant mass —

Summary —

Packs needed —

Module 4 — Dew Point & Condensation

Condensation occurs when the water-vapor partial pressure at the current state equals the saturation vapor pressure at the bounding surface’s temperature: Pv(current) = Pg(T_bounding).

Pv(current) — psi

Pg(T_bounding) — psi

Example: cup at A taken to B — if Pv(A) ≥ Pg(T_B) you’ll see fog on the cooler surface.

Module 5 — Time to Reach Target (Concentration-Based)

Computes time using absolute humidity (vapor density, g/m³) at the final storage temperature. Internally it solves: C(t)=C_des+(C0−C_des)·e^(−t/τ) with τ=V/(A·h_m). State A and B are pulled from Module 1 (no local overrides).

Used for RH⇄AH conversions.

Desiccant equilibrium RH (%)

Regenerated silica ≈ 0–5%; spent gel may be 30–50%.

Volume V

Mass-transfer coef h_m (m/s)

Exposed desiccant area A (m²)

Use total area if multiple packs are used.

Area helper: total exposed area = #packs × area per pack.

# of packs

Area per pack (m²)

Total area (m²) 0.01

Calculation details — concentration-based core

The transient is modeled as a well-mixed volume exchanging vapor with a desiccant surface at the final storage temperature.

Governing form: C(t) = C_des + (C₀ − C_des) · e^−t/τ
Time constant: τ = V / (A · h_m)
Target time: t = −τ · ln[(C* − C_des)/(C₀ − C_des)]
90% approach: T90 = 2.302585 · τ

Conversions at final T

Absolute humidity (g/m³): C = 216.7 · e / T(K), where e = RH · e_sat(T) and e_sat from Magnus-Tetens.
RH from AH: RH = 100 · C / C_sat(T), with C_sat(T) = 216.7 · e_sat(T) / T(K).

Variables

V — chamber volume (m³)
A — exposed desiccant area (m²). For N packs, use total area = N × area/pack.
h_m — air-side mass-transfer coefficient (m/s)
C_0 — initial vapor density at final T (from State A converted to final T)
C_des — desiccant baseline vapor density at final T (from RH_des)
C* — target vapor density at final T (from RH or AH target)
G(t) — grams removed: G(t) = (C_0 − C_des) (1 − e^−t/τ) · V

Final-T absolute humidity C₀ —

Desiccant baseline C_des —

Target C* —

Time constant τ —

T₉₀ (≈ 2.3·τ) —

Grams removed at time t G(t) = (C₀−C_des)(1−e^{−t/τ})·V

Note on saturation: As desiccant loads, its effective RH (and C_des) rises, shrinking the driving force and increasing T₉₀. Regenerate or add capacity as you approach the Module 3 capacity limit.

Appendix — Worked Example (Small Box, step-by-step)

Scenario: State A = 70°F & 50% RH, State B = 50°F & 50% RH, desiccant baseline RH_des = 10% at 50°F; geometry V = 0.02 m³, A = 0.01 m², h_m = 0.001 m/s.

Convert temperatures
70°F → T_A = (70 − 32)·5/9 = 21.1°C; 50°F → T_B = 10.0°C.
Saturation vapor pressure (Magnus–Tetens)
e_sat(T) = 6.112·exp(17.62·T/(243.12+T)) [hPa].
e_sat(21.1) ≈ 24.9 hPa; e_sat(10.0) ≈ 12.3 hPa.
Absolute humidity (g/m³): C = 216.7·e/T_K, where e = RH·e_sat and T_K=T+273.15.
- C_A = 216.7·(0.50·24.9) / (21.1+273.15) = 216.7·12.45/294.25 ≈ 9.2 g/m³.
- C* = 216.7·(0.50·12.3) / (10+273.15) = 216.7·6.15/283.15 ≈ 4.7 g/m³.
- C_des = 216.7·(0.10·12.3) / 283.15 = 216.7·1.23/283.15 ≈ 0.94 g/m³.
Initial at final T
C_sat(10°C) = 216.7·12.3/283.15 ≈ 9.4 g/m³ → C₀ = min(C_A, 9.4) = 9.2 g/m³.
Time constant
τ = V/(A·h_m) = 0.02/(0.01·0.001) = 0.02/0.00001 = 2000 s (33.3 min).
Time to reach C*
t = −τ ln( (C* − C_des)/(C₀ − C_des) ) = −2000·ln( (4.7−0.94)/(9.2−0.94) )
(4.7−0.94) = 3.76; (9.2−0.94) = 8.26; ratio = 0.455; ln = −0.788 → t ≈ 1576 s (26.3 min).
90% approach to baseline
T₉₀ = 2.302585·τ = 2.302585·2000 ≈ 4605 s (76.8 min).
Grams removed vs time
G(t) = (C₀−C_des)(1 − e^−t/τ)·V. At T₉₀:
(C₀−C_des) = 9.2−0.94 = 8.26 g/m³. The exponential term at T₉₀ is ~0.1, so (1−e^−t/τ) ≈ 0.9.
G(T₉₀) ≈ 8.26·0.90·0.02 ≈ 0.15 g.