millironx/UNIFAC.jl
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Add nitroethane groups

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Thomas A. Christensen II 2020-03-08 15:23:30 -07:00
parent 3003655025
commit e34c1153d4
Signed by: millironx
GPG key ID: 139C07724802BC5D
3 changed files with 18 additions and 13 deletions
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3
.vscode/settings.json vendored Normal file
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@ -0,0 +1,3 @@
{
"julia.environmentPath": "c:\\Users\\cclea\\source\\repos\\UNIFAC.jl"
}

2
Project.toml
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@ -1,4 +1,4 @@
name = "UNIFAC" name = "UNIFAC"
uuid = "49c32154-e3b1-44a0-88e7-ff6c176fd7d7" uuid = "49c32154-e3b1-44a0-88e7-ff6c176fd7d7"
authors = ["Thomas A. Christensen II <25492070+MillironX@users.noreply.github.com>"] authors = ["Thomas A. Christensen II <25492070+MillironX@users.noreply.github.com>"]
version = "0.1.0" version = "0.1.1"

24
src/UNIFAC.jl
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@ -8,14 +8,14 @@ export unifac
function unifac(ν, x, T) function unifac(ν, x, T)
# unifac takes three arguments: # unifac takes three arguments:
# ν (that's the Greek lowercase nu) is a 42 x n Integer array where n is the # ν (that's the Greek lowercase nu) is a 56 x n Integer array where n is the
# number of species in the system. The number at ν[k,i] indicates how many # number of species in the system. The number at ν[k,i] indicates how many
# instances of subgroup k are present in a single molecule of species i # instances of subgroup k are present in a single molecule of species i
# x is a 1 x n Float64 array that contains the liquid species mole fractions # x is a 1 x n Float64 array that contains the liquid species mole fractions
# T is the temperature of the system in Kelvins # T is the temperature of the system in Kelvins
# Declare the UNIFAC subgroup parameters # Declare the UNIFAC subgroup parameters
R = Array{Float64}(undef, 42, 1) R = Array{Float64}(undef, 56, 1)
R[1] = 0.9011 R[1] = 0.9011
R[2] = 0.6744 R[2] = 0.6744
R[3] = 0.4469 R[3] = 0.4469
@ -35,8 +35,9 @@ function unifac(ν, x, T)
R[34] = 0.9795 R[34] = 0.9795
R[41] = 1.8701 R[41] = 1.8701
R[42] = 1.6434 R[42] = 1.6434
R[56] = 1.7818
Q = Array{Float64}(undef, 42, 1) Q = Array{Float64}(undef, 56, 1)
Q[1] = 0.848 Q[1] = 0.848
Q[2] = 0.540 Q[2] = 0.540
Q[3] = 0.228 Q[3] = 0.228
@ -56,9 +57,10 @@ function unifac(ν, x, T)
Q[34] = 0.624 Q[34] = 0.624
Q[41] = 1.724 Q[41] = 1.724
Q[42] = 1.416 Q[42] = 1.416
Q[56] = 1.560
# Declare the subgroup interaction parameters # Declare the subgroup interaction parameters
a = zeros(42, 42) a = zeros(56, 56)
a[1:4, 10] .= 61.13 a[1:4, 10] .= 61.13
a[1:4, 12:13] .= 76.50 a[1:4, 12:13] .= 76.50
a[1:4, 15] .= 986.50 a[1:4, 15] .= 986.50
@ -153,7 +155,7 @@ function unifac(ν, x, T)
end end
# Calculate e # Calculate e
e = zeros(42, size(ν, 2)) e = zeros(56, size(ν, 2))
for i in 1:size(ν,2 ) for i in 1:size(ν,2 )
e[:, i] = (ν[:, i] .* Q) ./ q[i] e[:, i] = (ν[:, i] .* Q) ./ q[i]
end end
@ -162,22 +164,22 @@ function unifac(ν, x, T)
τ = exp.(-a ./ T) τ = exp.(-a ./ T)
# Calculate beta # Calculate beta
β = zeros(42, size(ν, 2)) β = zeros(56, size(ν, 2))
for i in 1:size(ν, 2) for i in 1:size(ν, 2)
for k in 1:42 for k in 1:56
β[k, i] = sum(e[:, i] .* τ[:, k]) β[k, i] = sum(e[:, i] .* τ[:, k])
end end
end end
# Calculate Theta # Calculate Theta
Θ = zeros(42, 1) Θ = zeros(56, 1)
for k in 1:42 for k in 1:56
Θ[k] = sum(x .* q .* e[k, :]') / sum(x .* q) Θ[k] = sum(x .* q .* e[k, :]') / sum(x .* q)
end end
# Calculate s # Calculate s
s = zeros(42, 1) s = zeros(56, 1)
for k in 1:42 for k in 1:56
s[k] = sum(Θ .* τ[:, k]) s[k] = sum(Θ .* τ[:, k])
end end