Answer:
The appropriate solution is:
(a) 2828 cases each time
(b) $4005656.85
(c) $3609800
Explanation:
The given values are:
Annual demand,
D = 200,000 cases
Per case cost,
C = $20
Carrying host,
H = [tex]10 \ percent\times 20[/tex]
= $[tex]2[/tex]
Ordering cost,
S = $40
(a)
The economic order quantity will be:
⇒ [tex]Q^*=\sqrt{(\frac{2DS}{H} )}[/tex]
On substituting the values, we get
[tex]=\sqrt{[\frac{(2\times 200000\times 40)}{2} ]}[/tex]
[tex]=\sqrt{\frac{16000000}{2} }[/tex]
[tex]=2828[/tex]
(b)
According to the question,
The annual ordering cost will be:
= [tex](\frac{D}{Q^*}) S[/tex]
= [tex](\frac{200000}{2828}) 40[/tex]
= [tex]2828.85[/tex] ($)
The annual carrying cost will be:
= [tex](\frac{Q^*}{2})H[/tex]
= [tex](\frac{2828}{2} )2[/tex]
= [tex]2828[/tex] ($)
The annual purchase cost will be:
= [tex]D\times C[/tex]
= [tex]200000\times 20[/tex]
= [tex]4000000[/tex] ($)
Now,
The total inventory cost will be:
= [tex]2828.85+2828+4000000[/tex]
= [tex]4005656.85[/tex] ($)
(c)
According to the question,
Order quantity,
Q = 10000 cases
Per case cost,
C = $18
Carrying cost,
H = [tex]10 \ percent\times 18[/tex]
= [tex]1.8[/tex]
The annual ordering cost will be:
= [tex](\frac{D}{Q} )S[/tex]
= [tex](\frac{200000}{10000} )40[/tex]
= [tex]800[/tex] ($)
The annual carrying cost will be:
= [tex](\frac{Q}{2} )H[/tex]
= [tex](\frac{10000}{2} )1.8[/tex]
= [tex]9000[/tex] ($)
The annual purchase cost will be:
= [tex]D\times C[/tex]
= [tex]200000\times 18[/tex]
= [tex]3600000[/tex]
Now,
The total cost of inventory will be:
= [tex]800+9000+3600000[/tex]
= [tex]3609800[/tex] ($)
