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TEMPERATURE RISE CALCULATIONS
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CUSTOMER NAME
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txtClientName
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PROJECT NAME
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txtProjectName
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BOARD NAME
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txtBoardName
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MBB RATING : txtMBBRating A
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MBB SIZE : txtNosets x txt_rem_Space_betn_2 x txtMBBHeight x txtMBBT mm2
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FAULT LEVEL : txtFault_level kA for txt_fduration sec.
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TEMP.RISE : txtTemp_Rise oC
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Inputs:
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Data/Assumptions
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Value Selected
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Unit of Measurement
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Remark
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MBB Rating
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txtMBBRating
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A
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txt_rem_MBBRating
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Bus bar material
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txtBusBarMaterial
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txt_rem_BusBarMaterial
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MBB size / area
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t = txtMBBT & h = txtMBBHeight
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mm2
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txt_rem_MBBSA
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No.of bus bars per phase
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txt_Nbb
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txt_rem_Nbb
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No. of phases
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txtNo_Of_Phase
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txt_rem_No_Of_Phase
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Fault level
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txtFault_level
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kA
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txt_rem_Faultlevel
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Ambient temp
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txtAmbientTemp
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oC
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txt_rem_AmbientTemp
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Ambient temp at installation site
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txtAmbient_Temp_at_installation_site
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oC
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txt_rem_Ambient_Temp_at_installation_site
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Temp. rise
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txtTemp_Rise
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oC
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txt_rem_Temp_Rise
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End temp
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txtEnd_Temp
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oC
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txt_rem_End_Temp
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(Degree Of Protection) IP
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txtIP
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txt_rem_IP
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MBB enclosure dim./area
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D = txtMBB_Enclosure_dim & H = txtMBB_Enclosure_area
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mm2
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txt_rem_MBBendimarea
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MBB Insulation
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txtMBB_sleeving
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txt_rem_MBBsleeving
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MBB Ventilation
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txtMBB_ventilation
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txt_rem_MBBventilation
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A. The continuous current carrying capacity (i.e. value
of DC current rating) for Bus bar having above details & temp. conditions is given
by –
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ldc = 24.9 x A0.5 x P0.39 x O0.61 =
txtDC_Current_Rating A
√ sqrt( [1+{R x O} ] x S)
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where A = cross
sectional area of one bus bar in sq.cm.
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P = Perimeter of one bus bar in cm.
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O = Temperature Rise = difference between end temp. & ambient
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R = Resistance temperature co-efficient at txtAmbientTemp oC ambient
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S = Specific Resistance in micro ohms cm.
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B. De-rating due to Skin Effect:
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To obtain the A.C. rating, the
D.C. rating is divided by a factor called ‘SKIN EFFECT RATIO’, as given below :
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lac = ldc / sqrt( Rac/Rdc)
= txtDC_Current_Rating / √sqrt( 1.11 ) = txtDe_Rating_Due_To_Skin A
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where Rac/Rdc
is the Skin effect ratio
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C. De-rating due to Temp factor :
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Applying temp. correction factor
to account for site amb. Temp condition, we get de-rating factor as -
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[(T2) / (T1)]1/1.7 = txtDe_Rating_Due_To_Temp
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where T2 is the ambient temp. as
per manufacturer in oC, & T1 is the installation site amb. temp. in
oC
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De-rated A.C current carrying capacity
after the temp. correction factor = txtDe_Rating_Due_To_Skin x txtDe_Rating_Due_To_Temp
= txtDe_Rating_At_Temp A
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D. De-rating due to Enclosure :
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Total Area of Bus bars / Total area of Enclosure = (txtNo_Of_Phase
x txt_Nbb x txtMBBHeight x txtMBBT) / (txtMBB_Enclosure_area
x txtMBB_Enclosure_dim) = txtderatingdata1 / txtderatingdata2 = txtDe_Rating_Due_To_Enclosure = txtDe_Rating_Due_To_EnclPer
%
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Thus, the A.C rating of the MBB
after enclosure de-rating factor = txtDe_Rating_At_Temp x txtDe_Rating_For_DeRatting
= txtDe_Rating_At_Encolsure A
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E. De-rating due to proximity effect :
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De-rating factor due to txt_Nbb no. of
bus bars per phase = txtidratingproxy_E
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The A.C rating of the MBB after
proximity factor = txtDe_Rating_At_Encolsure x txtidratingproxy_E = txtDe_Rating_At_Proximity A
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F. De-rating due to bus bar insulation :
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De-rating factor due to bus bar
insulation = txtidratingBB_insulation_F
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The A.C rating of the MBB with
selected insulation factor = txtDe_Rating_At_Proximity x txtidratingBB_insulation_F = txtDe_Rating_At_Insulation A
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G. De-rating due to Ventilation of bus bar :
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De-rating factor due to
txtMBB_ventilation = txtidratingBB_ventilation_G
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A.C rating of the MBB with
txtMBB_ventilation = txtDe_Rating_At_Insulation x txtidratingBB_ventilation_G = txtDe_Rating_At_Ventilation A
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H. Expected Temperature rise above the site ambient
for the rated current is given by -
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[(T1)/(T2)]0.61 = (l1)/(l2)
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Where I1 is the final de-rated
current obtained, I2 is the rated current, T1 is the ambient temp. in oC,
and T2 is the temp. rise expected
above the site installation ambient temp.
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[txtMBBRating/txtDe_Rating_At_Ventilation]1/0.61 x txtAmbientTemp = txtExp_Above_The_Amb oC
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The calculated end temp.= txtFinalExpAbovesitetempforG oC, which tempIsorNot within the permissible temp.rise limit.
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Thus, we conclude that the selected bus bar size tempIsorNot sufficient to carry the rated current.
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