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How to Calculate and Solve for Depreciation Value | Declining Balance Method | Depreciation

The image above represents depreciation value.

To compute for depreciation value, three essential parameters are needed and these are Present Amount or Worth (P), Rate of Depreciation (α) and Number of Years of the Asset (t).

The formula for calculating depreciation value:

D = Pα(1 – α)^{(t – 1)}

Where:

D = Depreciation Value
P = Present worth or amount
t = Number of years of the asset
α = rate of depreciation

Let’s solve an example;
Find the depreciation value when the present amount or worth is 14, the rate of depreciation is 2 and the number of years of the asset is 10.

This implies that;

P = Present worth or amount = 14
t = Number of years of the asset = 10
α = rate of depreciation = 2

D = Pα(1 – α)^{(t – 1)}
D = 14(2)(1 – 2)^{(10 – 1)}
D = 14(2)(-1)⁹
D = 14(2)(-1)
D = -28

Therefore, the depreciation value is ₦ -28.

Calculating the Present Amount or Worth when the Depreciation Value, the Rate of Depreciation and the Number of Years of the Asset is Given.

P = ^D / _{α (1 – α)^{(t – 1)}}

Where;

P = Present worth or amount
D = Depreciation Value
t = Number of years of the asset
α = rate of depreciation

Let’s solve an example;
Find the present amount or worth when the depreciation value is 40, the rate of depreciation is 10 and the number of years of the asset is 9.

This implies that;

D = Depreciation Value = 40
t = Number of years of the asset = 9
α = rate of depreciation = 10

P = ^D / _{α (1 – α)^{(t – 1)}}
P = ⁴⁰ / _{10 (1 – 10)^{(9 – 1)}}
P = ⁴⁰ / _{10 (- 9)⁽⁸⁾}
P = ⁴⁰ / _{10 (- 43046721)}
P = ⁴⁰ / _{– 430467210}
P = 9.29e-8

Therefore, the present amount or worth is 9.29e-8.

Continue reading How to Calculate and Solve for Depreciation Value | Declining Balance Method | Depreciation

How to Calculate and Solve for Book Value | Declining Balance Method | Depreciation

The image above represents book value.

To compute for book value, three essential parameters are needed and these parameters are Present Amount or Worth (P), Rate of Depreciation (α) and Number of Years of the Asset (t).

The formula for calculating book value:

B = P(1 – α)^t

Where:

B = Book value of an asset
P = Present worth or amount
α = rate of depreciation
t = Number of years of the asset

Let’s solve an example;
Find the book value when the present amount or worth is 8, the rate of depreciation is 18 and the number of years of the asset is 10.

This implies that;

P = Present worth or amount = 8
α = rate of depreciation = 18
t = Number of years of the asset = 10

B = P(1 – α)^t
B = 8(1 – 18)¹⁰
B = 8(-17)¹⁰
B = 8 x 201
B = 1612

Therefore, the book value is ₦1612.

Calculating the Present Amount or Worth when the Book Value, the Rate of Depreciation and the Number of Years of the Asset is Given.

P = ^B / _{(1 – α)^t}

Where;

P = Present worth or amount
B = Book value of an asset
α = rate of depreciation
t = Number of years of the asset

Let’s solve an example;
Find the present amount or worth when the book value is 32, the rate of depreciation is 16 and the number of years of the asset is 10.

This implies that;

B = Book value of an asset = 32
α = rate of depreciation = 16
t = Number of years of the asset = 10

P = ^B / _{(1 – α)^t}
P = ³² / _{(1 – 16)¹⁰}
P = ³² / _{(- 15)¹⁰}
P = ³² / ₅₇₆₆
P = 0.00554

Therefore, the present amount or worth is 0.00554.

Continue reading How to Calculate and Solve for Book Value | Declining Balance Method | Depreciation

How to Calculate and Solve for Depreciation Value | Straight line Method | Depreciation

The image above represents depreciation value.

To compute for depreciation value, three essential value are needed and these parameters are Present Amount or Worth (P), Salvage Value (S) and Total Estimated Life of the Asset (N).

The formula for calculating depreciation value:

D = (P – S) / N

Where:

P = Present worth or amount
N = Total estimated life of an asset
S = Salvage value

Let’s solve an example;
Find the depreciation value when the present amount or worth is 9, the salvage value is 4 and the total estimated life of an asset is 10.

This implies that;

P = Present worth or amount = 9
N = Total estimated life of an asset = 10
S = Salvage value = 4

D = (P – S) / N
D = (9 – 4) / 10
D = 5 / 10
D = 0.5

Therefore, the depreciation value is ₦0.5.

Calculating the Present Amount or Worth when the Depreciation Value, the Total Estimated life of an Asset and the Salvage Value is Given.

P = (D x N) + S

Where;

P = Present worth or amount
D = Depreciation Value
N = Total estimated life of an asset
S = Salvage value

Let’s solve an example;
Find the present amount or worth when the depreciation value is 22, the total estimated life of an asset is 12 and the salvage value is 8.

This implies that;

D = Depreciation Value = 22
N = Total estimated life of an asset = 12
S = Salvage value = 8

P = (D x N) + S
P = (22 x 12) + 8
P = 264 + 8
P = 272

Therefore, the present amount or worth is 272.

Continue reading How to Calculate and Solve for Depreciation Value | Straight line Method | Depreciation

How to Calculate and Solve for Book Value | Straight line Method | Depreciation.

The image above represents book value.

To compute for book value, four essential parameters are needed and these parameters are present amount or worth (P), salvage value (S), total estimated life of the asset (N) and number of years of the asset (t).

The formula for calculating book value:

B = P – ((P – S)t / N)

Where;

B = Book value over a period of time
P = Present amount or worth
S = Salvage value
N = Total estimated life of an asset
t = Number of years of the asset

Let’s solve an example;
Find the book value when the present amount or worth is 12, the salvage value is 10, total estimated life of an asset is 8 and the number of years of the asset is 14.

This implies that;

P = Present amount or worth = 12
S = Salvage value = 10
N = Total estimated life of an asset = 8
t = Number of years of the asset = 14

B = P – ((P – S)t / N)
B = 12 – ((12 – 10)14 / 8)
B = 12 – ((2)14 / 8)
B = 12 – (28 / 8)
B = 12 – 3.5
B = 8.5

Therefore, the book value is ₦8.5

Calculating the Present Amount or Worth when the Book Value, the Salvage Value, the Total Estimated Life of the Asset and the Number of years of the Asset is Given.

P = – (^{B x N} / _t) – S

Where;

P = Present amount or worth
B = Book value over a period of time
S = Salvage value
N = Total estimated life of an asset
t = Number of years of the asset

Let’s solve an example;
Find the present amount or worth when the book value is 20, the salvage value is 10, the total estimated life of an asset is 5 and the number of years of the asset is 9.

This implies that;

B = Book value over a period of time = 20
S = Salvage value = 10
N = Total estimated life of an asset = 5
t = Number of years of the asset = 9

P = – (^{B x N} / _t) – S
P = – (^{20 x 5} / ₉) – 10
P = – (¹⁰⁰ / ₉) – 10
P = – 11.11 – 10
P = 1.11

Therefore, the present amount or worth is 1.11.

Continue reading How to Calculate and Solve for Book Value | Straight line Method | Depreciation.

How to Calculate and Solve for Time of Pouring | Design of Gating System

The image above represents time of pouring.

To compute for time of pouring, three essential parameters are needed and these parameters are Constant (P), Co-efficient used to Account for Wall Thickness (S) and Mass of Casting with Gates and Risers (G).

The formula for calculating time of pouring:

t = S√(2PG)

Where:

t = Time of Pouring
P = Constant
S = Co-efficient used to Account for Wall Thickness
G = Mass of Casting with Gates and Risers

Let’s solve an example;
Find the time of pouring when the constant is 0.62, the co-efficient used to account for wall thickness is 17 and the mass of casting with gates and risers is 21.

This implies that;

P = Constant = 0.62
S = Co-efficient used to Account for Wall Thickness = 17
G = Mass of Casting with Gates and Risers = 21

t = S√(2PG)
t = 17 x √(2 x 0.62 x 21)
t = 17 x √(26.04)
t = 17 x 5.10
t = 86.7

Therefore, the time of pouring is 86.7 s.

Calculating the Co-efficient used to Account for Wall Thickness when the Time of Pouring, the Constant and the Mass of Casting with Gates and Risers is Given.

S = ^t / _√(2PG)

Where;

S = Co-efficient used to Account for Wall Thickness
t = Time of Pouring
P = Constant
G = Mass of Casting with Gates and Risers

Let’s solve an example;
Find the co-efficient used to account for wall thickness when the time of pouring is 20, the constant is 0.62 and the mass of casting with gates and risers is 18.

This implies that;

t = Time of Pouring = 20
P = Constant = 0.62
G = Mass of Casting with Gates and Risers = 18

S = ^t / _√(2PG)
S = ²⁰ / _{√(2 x 0.62 x 18)}
S = ²⁰ / _√(22.32)
S = ²⁰ / _4.724
S = 4.23

Therefore, the co-efficient used to account for wall thickness is 4.23.

Calculating the Mass of Casting with Gates and Risers when the Time of Pouring, the Constant and the Co-efficient used to Account for Wall Thickness is Given.

G = (^t / _S)² x ¹ / _2P

Where;

G = Mass of Casting with Gates and Risers
t = Time of Pouring
P = Constant
S = Co-efficient used to Account for Wall Thickness

Let’s solve an example;
Find the mass of casting with gates and risers when the time of pouring is 12, constant is 0.62 and co-efficient used to account for wall thickness is 14.

This implies that;

t = Time of Pouring = 12
P = Constant = 0.62
S = Co-efficient used to Account for Wall Thickness = 14

G = (^t / _S)² x ¹ / _2P
G = (¹² / ₁₄)² x ¹ / _{2 x 0.62}
G = (0.85)² x ¹ / _1.24
G = 0.7225 x 0.806
G = 0.582

Therefore, the mass of casting with gates and risers is 0.582.

Nickzom Calculator – The Calculator Encyclopedia is capable of calculating the time of pouring.

To get the answer and workings of the time of pouring using the Nickzom Calculator – The Calculator Encyclopedia. First, you need to obtain the app.

You can get this app via any of these means:

Web – https://www.nickzom.org/calculator-plus

To get access to the professional version via web, you need to register and subscribe for NGN 1,500 per annum to have utter access to all functionalities.
You can also try the demo version via https://www.nickzom.org/calculator

Android (Paid) – https://play.google.com/store/apps/details?id=org.nickzom.nickzomcalculator
Android (Free) – https://play.google.com/store/apps/details?id=com.nickzom.nickzomcalculator
Apple (Paid) – https://itunes.apple.com/us/app/nickzom-calculator/id1331162702?mt=8
Once, you have obtained the calculator encyclopedia app, proceed to the Calculator Map, then click on Materials & Metallurgical under Engineering.

Now, Click on Foundry Technology under Material & Metallurgical

Now, Click on Design of Gating System under Foundry Technology

Now, Click on Time of Pouring under Design of Gating System

The screenshot below displays the page or activity to enter your values, to get the answer for the time of pouring according to the respective parameters which are the Constant (P), Co-efficient used to Account for Wall Thickness (S) and Mass of Casting with Gates and Risers (G).

Now, enter the values appropriately and accordingly for the parameters as required by the Constant (P) is 0.62, Co-efficient used to Account for Wall Thickness (S) is 17 and Mass of Casting with Gates and Risers (G) is 21.

Finally, Click on Calculate

As you can see from the screenshot above, Nickzom Calculator– The Calculator Encyclopedia solves for the time of pouring and presents the formula, workings and steps too.

How to Calculate and Solve for Total Cross-Sectional Area of Gates | Design of Gating System

The image above represents total cross-sectional area of gates.

To compute for total cross-sectional area of gates, three essential parameters are needed and these parameters are Mass of the Casting (G), Specific Speed of Pouring (K_s) and Time of Pouring (t).

The formula for calculating total cross-sectional area of gates:

F_s = ^G / _tKs

Where:

F_s = Total Cross-Sectional Area of Gates
G = Mass of the Casting
K_s = Specific Speed Of Pouring
t = Time of Pouring

Let’s solve an example;
Find the total cross-sectional area of gates when the mass of the casting is 10, specific speed of pouring is 18 and the time of pouring is 9.

This implies that;

G = Mass of the Casting = 10
K_s = Specific Speed Of Pouring = 18
t = Time of Pouring = 9

F_s = ^G / _tK_sF_s = ¹⁰ / _{9 x 18}
F_s = ¹⁰ / ₁₆₂
F_s = 0.0617

Therefore, the total cross-sectional area of gates is 0.0617 m².

Calculating the Mass of the Casting when the Total Cross-Sectional Area of Gates, Specific Speed of Pouring and the Time of Pouring is Given.

G = F_s x tK_s

Where:

G = Mass of the Casting
F_s = Total Cross-Sectional Area of Gates
K_s = Specific Speed Of Pouring
t = Time of Pouring

Let’s solve an example;
Find the mass of the casting when the total cross-sectional area of gates is 15, the specific speed of pouring is 7 and the time of pouring is 5.

This implies that;

F_s = Total Cross-Sectional Area of Gates = 15
K_s = Specific Speed Of Pouring = 7
t = Time of Pouring = 5

G = F_s x tK_s
G = 15 x 5(7)
G = 15 x 35
G = 525

Therefore, the mass of the casting is 525 m.

Continue reading How to Calculate and Solve for Total Cross-Sectional Area of Gates | Design of Gating System

How to Calculate and Solve for Volume Ratio | Design of Gating System

The image above represents volume ratio.

To compute for volume ratio, two essential parameters are needed and these parameters are Mass of the Liquid Metal filling the Mould Cavity, Gates and Risers (G) and Casting Volume (V).

The formula for calculating volume ratio:

K_v = ^G / _V

Where:

K_v = Volume Ratio
G = Mass of the Liquid Metal Filling the Mould Cavity,Gates and Risers
V = Casting Volume

Let’s solve an example;
Find the volume ratio when the mass of the liquid metal filling the mould cavity, gates and risers is 12 and the casting volume is 24.

This implies that;

G = Mass of the Liquid Metal Filling the Mould Cavity,Gates and Risers = 12
V = Casting Volume = 24

K_v = ^G / _V
K_v = ¹² / ₂₄
K_v = 0.5

Therefore, the volume ratio is 0.5.

Calculating the Mass of the Liquid Metal Filling the Mould Cavity, Gates and Risers when the Volume Ratio and the Casting Volume is Given.

G = K_v x V

Where;

G = Mass of the Liquid Metal Filling the Mould Cavity,Gates and Risers
K_v = Volume Ratio
V = Casting Volume

Let’s solve an example;
Find the mass of the liquid metal filling the mould cavity, gates and risers when the volume ratio is 15 and the casting volume is 10.

This implies that;

K_v = Volume Ratio = 15
V = Casting Volume = 10

G = K_v x V
G = 15 x 10
G = 150

Therefore, the mass of the liquid metal filling the mould cavity,gates and risers is 150.

Continue reading How to Calculate and Solve for Volume Ratio | Design of Gating System

How to Calculate and Solve for Co-efficient allowing for Friction | Design of Gating System

The image above represents co-efficient allowing for friction.

To compute for co-efficient allowing for friction, two essential parameters are needed and these parameters are Friction Co-efficient of the Gating System (μ₁) and Friction Co-efficient of the Mould (μ₂).

The formula for calculating co-efficient allowing for friction:

μ = μ₁ x μ₂

Where:

μ = Co-efficient allowing for Friction
μ₁ = Friction Co-efficient of the Gating System
μ₂ = Friction Co-efficient of the Mould

Let’s solve an example;
Find the co-efficient allowing for friction when the friction co-efficient of the gating system is 10 and the friction co-efficient of the mould is 14.

This implies that;

μ₁ = Friction Co-efficient of the Gating System = 10
μ₂ = Friction Co-efficient of the Mould = 14

μ = μ₁ x μ₂
μ = 10 x 14
μ = 140

Therefore, the co-efficient allowing for friction is 140.

Calculating the Friction Co-efficient of the Gating System when the Co-efficient Allowing for Friction and the Friction Co-efficient of the Mould is Given.

μ₁ = ^μ / _μ₂

Where;

μ₁ = Friction Co-efficient of the Gating System
μ = Co-efficient allowing for Friction
μ₂ = Friction Co-efficient of the Mould

Let’s solve an example;
Find the friction co-efficient of the gating system when the co-efficient allowing for friction is 45 and the friction co-efficient of the mould is 15.

This implies that;

μ = Co-efficient allowing for Friction – 45
μ₂ = Friction Co-efficient of the Mould = 15

μ₁ = ^μ / _μ₂
μ₁ = ⁴⁵ / ₁₅
μ₁ = 3

Therefore, the friction co-efficient of the gating system is 3.

Calculating the Friction Co-efficient of the Mould when the Co-efficient Allowing for Friction and the Friction Co-efficient of the Gating System is Given.

μ₂ = ^μ / _μ₁

Where;

μ₂ = Friction Co-efficient of the Mould
μ = Co-efficient allowing for Friction
μ₁ = Friction Co-efficient of the Gating System

Let’s solve an example;
Find the friction co-efficient of the mould when the co-efficient allowing for friction is 50 and the friction co-efficient of the gating system is 25.

This implies that;

μ = Co-efficient allowing for Friction = 50
μ1 = Friction Co-efficient of the Gating System = 25

μ₂ = ^μ / _μ₁
μ₂ = ⁵⁰ / ₂₅
μ₂ = 2

Therefore, the friction co-efficient of the mould is 2.

Continue reading How to Calculate and Solve for Co-efficient allowing for Friction | Design of Gating System

How to Calculate and Solve for Pouring Time for Medium-Sized and Large Casting up to 1000kg in Mass | Design of Gating System

The image above represents pouring time for medium-sized and large casting up to 1000kg in mass.

To compute for pouring time for medium-sized and large casting up to 1000kg in mass, three essential parameters are needed and these parameters are Co-efficient used to Account for Wall Thickness (S), Mass of Casting with Gates and Risers (G) and Thickness of the Casting (δ).

The formula for calculating pouring time for medium-sized and large casting up to 1000kg in mass:

t = S(Gδ)^1 / ₃

Where:

t = Pouring Time for Medium-Sized and Large Casting up to 1000kg in Mass
S = Co-efficient used to Account for Wall Thickness
G = Mass of Casting with Gates and Risers
δ = Thickness of the Casting

Let’s solve an example;
Find the pouring time for medium-sized and large casting up to 1000kg in mass when the co-efficient used to account for wall thickness is 9, mass of casting with gates and risers is 12 and thickness of the casting is 21.

This implies that;

S = Co-efficient used to Account for Wall Thickness = 9
G = Mass of Casting with Gates and Risers = 12
δ = Thickness of the Casting = 21

t = S(Gδ)^1 / ₃
t = 9 x (12 x 21)^1 / ₃
t = 9 x (252)^0.33
t = 9 x 6.31
t = 56.84

Therefore, the pouring time for medium-sized and large casting up to 1000kg in mass is 56.84 s.

Calculating the Co-efficient used to Account for Wall Thickness when the Pouring Time for Medium-Sized and Large Casting up to 1000kg in Mass, the Mass of Casting with Gates and Risers and the Thickness of the Casting is Given.

S = ³√(^t³ / _Gδ)

Where;

S = Co-efficient used to Account for Wall Thickness
t = Pouring Time for Medium-Sized and Large Casting up to 1000kg in Mass
G = Mass of Casting with Gates and Risers
δ = Thickness of the Casting

Let’s solve an example;
Find the co-efficient used to account for wall thickness when the pouring time for medium-sized and large casting up to 1000kg in mass is 30, mass of casting with gates and risers is 18 and the thickness of the casting is 20.

This implies that;

t = Pouring Time for Medium-Sized and Large Casting up to 1000kg in Mass = 30
G = Mass of Casting with Gates and Risers = 18
δ = Thickness of the Casting = 20

S = ³√(^t³ / _Gδ)
S = ³√(³⁰³ / _{18 x 20})
S = ³√(²⁷⁰⁰⁰ / ₃₆₀)
S = ³√(75)
S = 4.21

Therefore, the co-efficient used to account for wall thickness is 4.21.

Continue reading How to Calculate and Solve for Pouring Time for Medium-Sized and Large Casting up to 1000kg in Mass | Design of Gating System

How to Calculate and Solve for Pouring Time for thin-Walled Casting 450kg in Mass | Design of Gating System

The image above represents pouring time for thin-walled casting 450kg in mass.

To compute for pouring time thin-walled casting 450kg in mass, two essential parameters are Co-efficient used to Account for Wall Thickness (S) and Mass of Casting with Gates and Risers (G).

The formula for calculating pouring time for thin-walled casting 450kg in mass:

t = S√(G)

Where:

t = Pouring Time for Thin-Walled Casting 450kg in Mass
S = Co-efficient used to Account for Wall Thickness
G = Mass of Casting with Gates and Risers

Let’s solve an example;
Find the pouring time for thin-walled casting 450kg in mass when the co-efficient used to account for wall thickness is 20 and the mass of casting with gates and risers is 32.

This implies that;

S = Co-efficient used to Account for Wall Thickness = 20
G = Mass of Casting with Gates and Risers = 32

t = S√(G)
t = 20 x √(32)
t = 20 x 5.65
t = 113.13

Therefore, the pouring time for thin-walled casting 450kg in mass is 113.13 s.

Calculating the Co-efficient used to Account for Wall Thickness when the Pouring Time for Thin-Walled Casting 450kg in Mass and the Mass of Casting with Gates and Risers is Given.

S = ^t / _√(G)

Where;

S = Co-efficient used to Account for Wall Thickness
t = Pouring Time for Thin-Walled Casting 450kg in Mass
G = Mass of Casting with Gates and Risers

Let’s solve an example;
Find the co-efficient used to account for wall thickness when the pouring time for thin-walled casting 450kg in mass is 30 and the mass of casting with gates and risers is 25.

This implies that;

t = Pouring Time for Thin-Walled Casting 450kg in Mass = 30
G = Mass of Casting with Gates and Risers = 25

S = ^t / _√(G)
S = ³⁰ / _√25
S = ³⁰ / ₅
S = 6

Therefore, the co-efficient used to account for wall thickness is 6.

Continue reading How to Calculate and Solve for Pouring Time for thin-Walled Casting 450kg in Mass | Design of Gating System