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Motor Control Center (MCC) Data

This dialog box includes the following areas and tabs:

Database Dialog Box Toolbar
Connection Information
Specifications Tab
Incoming Tab
Description Tab
Summary Tab
Short Circuit Tab
Power Flow Tab
Equipment Elevation Tab
Harmonics Tab
Arc Flash Hazard Tab
Accessories Tab

See Common Tabs for information on the Location, Comments, Hyperlinks, Media Gallery, or Collected Data tabs.

Figure 1: MCC Data Dialog Box

Connection Information

Option	Description
ID Name	Uniquely identifies the equipment item. The program automatically assigns a name, but you can change it, if needed. The name can be up to 16 characters long. For MCCs, the program automatically assigns the names MCC-1, MCC-2, MCC-3, and so on.
Base kV	The base kV of the MCC. MCC’s are modeled like a bus in many ways. You can connect cables, busways or transformers to it, and perform fault calculations.
Spreadsheet View and Configure	See Spreadsheet View for information about these options.
Lock Auto-Sizing	When this check box is selected, this item cannot be automatically sized using SmartDesign™ (the auto-design feature).

Specifications Tab

These are the specifications for the MCC including the bus.

Option	Description
Service	Select the service for the MCC. Your options are 3 Phase-3 Wire or 3 Phase-4 Wire.
Unit	Select either U.S., Metric, or CSA.
Bus Rating These are all user-defined fields.
Mfr	Use this text field to describe the MCC manufacturer.
Type	Use this text field to further describe the MCC manufacturer model.
Bus SC Rating (kA)	The rating of the bus used in calculating the Short Circuit duties for SmartDuty™.
Horz Bus Rating (A)	The current rating of the horizontal bus.
Vert Bus Rating (A)	The current rating of the vertical bus.
Bus Data
Area	Area numbers are used to uniquely define different areas of the electrical system. These areas can then be used for creating specific text reports from analysis operations that represent subsets of the system. For example, typical paper plant areas may be the power house (Area 1), caustic plant (Area 2), pulp mill (Area 3), and paper machine (Area 4). Area numbers are positive integers between 1 and 999.
Zone	A zone number is simply a sub-area. This enables even more specific reporting. You may want to define the pulp mill as Area 3 and the digester electrical equipment as Zone 2. Specific reports can then be generated for this combination without including the entire pulp mill or the other digesters.

Description	Use this text field to describe the particular MCC.
Device Code	You can type letters or numbers to describe the device code for the equipment item. The information can be converted and printed as a QR code on arc flash labels.
Fed By	Use this field to indicate the transformer or the power supply source feeding the MCC.
Last Updated	The date and time the MCC data was last updated is displayed here.
Header Comment	Use this field for any comment on the MCC.

Incoming Tab

Figure 2: Incoming Tab

Option	Description
Incoming Device Type	You can select the type of incoming protective device type for the MCC. The choices available are: Main Lug Only: No protective device is present. Main Breaker: An LV breaker protects the MCC bus. Select the breaker using Incoming Device Settings. Main Fuse: A fuse protects the MCC bus. Select the fuse using Incoming Device Settings.
Incoming Branch	Select the incoming branch equipment such as cables, transformers or busways. All the branches connected to the MCC in the one-line are displayed.
Incoming Device Settings	Opens the data dialog for the main fuse or main breaker specified as the incoming device type. See Low Voltage Breaker Data or Fused Switch Data for more information.

Option

Description

Incoming Device Type

You can select the type of incoming protective device type for the MCC. The choices available are:

Main Lug Only: No protective device is present.
Main Breaker: An LV breaker protects the MCC bus. Select the breaker using Incoming Device Settings.
Main Fuse: A fuse protects the MCC bus. Select the fuse using Incoming Device Settings.

Incoming Branch

Select the incoming branch equipment such as cables, transformers or busways. All the branches connected to the MCC in the one-line are displayed.

Incoming Device Settings

Opens the data dialog for the main fuse or main breaker specified as the incoming device type. See Low Voltage Breaker Data or Fused Switch Data for more information.

Description Tab

This is a spreadsheet listing similar to the Device Library. When you place a new MCC on the one-line, the first time you open its database dialog and click on the Description tab, EasyPower displays the MCC Spreadsheet Creation Wizard which enables you to select the number of rows you want. Clear the check box at the bottom of the Wizard dialog if you don't want it to appear with each new MCC. You can insert or append new rows in the spreadsheet if you need them later.

Figure 3: MCC Spreadsheet Creation Wizard Dialog Box

Figure 4: Description Tab of MCC Data Dialog Box

Note: When you click on the Description tab, additional buttons become available on the MCC Data dialog box toolbar. Some of these buttons are the same as those in the Device Library (see EasyPower Device Library) and they offer another way to add rows if the Wizard is not used.

Option	Description
MCC Library	The list contains all of the same schedules as the Device Library. To enter a listing other than those contained in the list, create a new page in the MCC section of the Device Library. See EasyPower Device Library for more information.
Schedule	This list enables you to specify which Device Library Schedule your chosen Library Load spreadsheet is located in. To enter a listing other than those contained in the list, create a new page in the MCC section of the Device Library. See EasyPower Device Library for more information.
Export	The spreadsheets can be exported to metafiles (.WMF) or delimited database text files (.CSV). Export is beside the Print button on the MCC/Panel dialog box toolbar when the viewing the Description tab.

Spreadsheet

Note: The Section Space and Equipment Name are not necessary for calculation purposes but are used to match the way they are organized in the MCC.

Option	Description
Section Space	Enter the location of the individual bucket in the MCC. Typical entries would be 1A, 1B, 2A, 2B, 2C, and so on.
Equipment Name	Enables you to identify each piece of equipment.
Library Load	This list corresponds directly to the Library Load column in the Device Library. After you have made selections in the MCC Library, Schedule and Library Load fields, all of the data cells that follow are automatically filled in when you click on another cell. You can also double-click on the cell to enter something different than what is listed.
Status	The third column is a toggle "On/Off" to indicate if this particular item is currently connected to the MCC schedule. This affects the power flow and short circuit current contribution.
Load Type	You can select different kinds of loads such as motors, loads, or sub-MCC/panel. Based on the load type selected, various analysis are possible. When you select a load type, the cells in the row that do not apply become unavailable. You might see a Data button indicating you need to enter data specific to the load type. Cells highlighted in red require data in order to perform any analysis. The following load types are available: Motor: The motor data required for analysis are usually Motor HP, Motor X/R, and the X/R Ratio in the short circuit tab. The required data fields are highlighted in red. If you do not know the motor X/R ratio, you can calculate typical X/R ratio for the motor based on size by selecting the cell for Motor X/R and clicking Calculate in the toolbar or by pressing F9 on the keyboard. A motor contributes to the short circuit current. You can enter other data in the row, such as cable description, protective device, starter description and capacitor data. When you select Motor as a load type, you can plot its curves on the TCC plot. Note: Motor FLA for 3-phase motors is calculated as follows. For U.S. units, the NEC table FLA values are used. For metric units, motor FLA is calculated as Motor kW/(Motor Eff * Motor power factor * Base kV * SQRT3). Load: The load data is entered in the columns Static kW and Static kVAR. Other data entries are optional. You cannot plot curves for devices in the TCC plot. Sub-MCC: This means the current MCC is feeding another MCC. You need to specify the sub-MCC ID name and the cable connecting the two MCCs. You also need to enter the protective device data for the sub-MCC. You can plot the protective device curve on a TCC. Sub-Panel: This is similar to a sub-MCC type, except it is used when connecting the MCC to a sub-panel. Motor w/ TCC: The load type is motor. However, you can plot the cable damage curve, protective device trip curve and the motor starting curve on a TCC plot. You need to specify the motor data, protective device data and the cable data. Load w/ TCC: You can plot the curves for cable and protective device on a TCC plot. The load is specified in kW and kVARs. <50 HP Lump: This is to model a group of motors all of which are under 50 HP rating. No TCC plot is obtained for this type of load. >50 HP Lump: This is to model a group of motors all of which are larger than 50 HP rating. No TCC plot is obtained for this type of load.

The rest of the fields correspond directly to those in the Device Library. MCCs are validated upon creation. That means that if you create an MCC and do not input any data, you can still go into an analysis focus without receiving an error message. However, after you create a row in this spreadsheet, you will not be able to enter an analysis focus until all required data is input. The cells which require data for analysis are highlighted in red.

If you are making a custom entry, you will notice that many of the data cells contain lists of items. Some of the cells have bold headings, and when they are selected the Calculate button becomes active. Clicking it calculates the data for those cells. You can select several cells at a time before clicking Calculate. For instance, clicking on the header itself selects the entire column.

Because the MCC is a library, along with the Calculate button, all of the other editing features are identical to those listed in the customizing section for the Device Library. See Customizing the Device Library for more information.

Spreadsheet View

Use Spreadsheet View to configure the columns that appear in the spreadsheet. You can create new configurations that display only selected columns.

To create a new configuration, click Configure. In the Database Print Config dialog box, type the new configuration name in the Configuration box, and select the desired column headings in the Columns pane.

Use the Select All check box to include all the columns, or Clear All to clear all columns and select only those you want to see.

Use Delete to remove the selected configuration.

Close saves your changes and closes the dialog box.

Figure 5: Database Print Config Dialog Box

If you have multiple configurations saved, you can display the desired configuration by selecting it in the Spreadsheet View list.

Export an MCC or Panel Schedule

To export an MCC or panel schedule, click Export in the toolbar of the MCC or panel data dialog box. This opens a new dialog box where you can specify location and file name of the file you are exporting, and you can select whether all MCCs and panels are to be exported, or only the selected one.

Figure 6: Export Dialog Box for an MCC or Panel Schedule

Option	Description
Save as type	You can save the schedule as a CSV (spreadsheet) file or as a WMF (picture) file.
Print Range	Choose one of the following. All: Prints all of the possible columns from the Description tab. Current Configuration: Prints only the columns that appear in the current configuration.
Export All MCCs/Panels	When clear, only this MCC or panel is exported. When this check box is selected, all the MCC and Panels are exported.

Option

Description

Save as type

You can save the schedule as a CSV (spreadsheet) file or as a WMF (picture) file.

Print Range

Choose one of the following.

All: Prints all of the possible columns from the Description tab.
Current Configuration: Prints only the columns that appear in the current configuration.

Export All MCCs/Panels

When clear, only this MCC or panel is exported. When this check box is selected, all the MCC and Panels are exported.

Summary Tab

The Summary tab of MCC Data dialog box provides the total load on the MCC and the load that must be used in designing.

Figure 7: Summary tab of MCC Data Dialog Box

Option	Description
Calculate Downstream Load	Calculates the total load on the MCC, taking into account the connected load, demand factors, and NEC code factors.
Override with User Values	This check box enables you to enter data in the Total Downstream Load – kVA column.

Spreadsheet

The spreadsheet has two sections – MCC Load and Including Downstream Load.

Option	Description
MCC Load This spreadsheet section provides the summary of the loads fed by the feeders of the MCC. The loads from the sub-MCC and sub-panels are not included in this section.
Total kVA	This is the aggregate load.
Total FLA	Total load in amps.
Motor HP	The total HP for the items with "On" in the Status column of the Description section.
Motor kVA >= 50 HP	The total KVA for connected items equal to or greater than 50HP.
Motor kVA < 50 HP	The total KVA for connected items less than 50HP.
Static kVA	Total kVA of the loads.
Capacitor kVAR	Total kVARs of all the capacitors
(Calculations)
Connected	Connected kVA = [(SkW)² + (SkVAR)²]^1/2
Demand	Demand kVA = [S(kW * DF)² + S(kVAR * DF)²]^½ Where DF is the individual demand factor of each MCC circuit.
Code Factors	Code Factors kVA = [(kW_L + SkW)2 + (kVAR_L + SkVAR)2]1/2 Where, kW_L = Code Mult Factor * kW for largest motor in MCC. KVAR_L = Code Mult Factor * kVAR for largest motor in MCC. kW and kVAR are for the rest of the loads. The code multiplying factor is specified in Tools > Options > Equipment.
Design	Design kVA = Code Factors kVA * Design Factor The Design Factor is specified in Tools > Options > Equipment.
Including Downstream Load This provides the sum of the loads fed by feeders inside the MCC and the sub-MCC and sub-panels.
kVA	Total kVA load calculated. You can enter your own values in these fields by selecting the check box for Override with User Values.
FLA	Total FLA load calculated. You can enter your own values in these fields by selecting the check box for Override with User Values.

Short Circuit Tab

Figure 8: Short Circuit Tab of MCC Data Dialog Box

Option	Description
kVA >50Hp	Total kVA of the motors which are greater than 50Hp.
X"dv or Xlr	Is set at the default value for >50Hp. You can enter your own value and it applies to all the motors greater than 50Hp.
X/R Avg	Calculate fills this field using values from the spreadsheet. You can enter your own X/R average.
KVA <50Hp	Total kVA of the motors which are less than 50Hp.
X"dx or Xlr	Is set at the default value for <50Hp but you can change this. You can enter your own value and it applies to all the motors less than 50Hp.
X/R Avg	Calculate fills this field using values from the spreadsheet. You may enter your own X/R average.
Calculate	Click to calculate the X/R averages for motors greater than and less than 50 HP.

Power Flow Tab

Figure 9: Power Flow Tab of MCC Data Dialog Box

Option	Description
Load Model	Enables you to select the motor kVA from the MCC Specifications data or from SCADA (Supervisory Control and Data Acquisition) data. SCADA data can be read in by clicking File > Import.
MCC Specifications	kVA: Select the method used to determine the kilovolt-ampere for power flow analysis. Choose between: Connected: The kVA is determined by the load defined on the Description tab of the MCC. Demand: The kVA is determined by the demand factor. Demand factor is calculated as the maximum loading conditions divided by the total connected load. This is specified on the Description tab of the MCC. Code: The kVA is determined by the code factors. Code factors are derived from the factors set up in the database File Properties on the Code Factors tab which reference NFPA 70E (NEC) article 220.40. You can view or edit the codes on the Description tab of the MCC. Design: The kVA is determined by the design factor in combination with the code factors. Design factor is set up in Tools > Options on the Equipment tab. You can view or edit the design factor on the Description tab of the MCC.
Load Type	Motors can be modeled for the power flow solution in several different ways. Constant kVA - This is the most common model. It is conservative, and results in slightly lower voltage values than would be measured on an actual system. Constant Current - This model is generally not used in motor modeling. It more closely matches an induction motor's characteristics in the reactive component than other models, but is technically incorrect because kW is relatively constant throughout the voltage range for an induction motor. Constant Impedance - This model is used for starting induction and synchronous machines, and closely matches motor characteristics during low voltages. kW + j Current - This model is a combination of the above models and more closely matches actual motor characteristics within normal operating voltages.
Scaling Factor	Provides an easy way of adjusting the total motor load used in determining power flows. By changing the scaling factor, the actual Hp (total connected value) entered in the Hp field can remain static. This reduces modeling errors and eliminates multiple databases for different contingencies.
SCADA Model SCADA data is derived from real time, or metered data, and converted to an ASCII format which can be read into EasyPower. SCADA data is read in as a 100% scaling factor load. The load value is multiplied by the user-defined scaling factor. This provides a way to adjust SCADA loads to form new cases.
kW	The kW value as read in from the SCADA ASCII file.
kVAR	The kVAR value as read in from the SCADA ASCII file.
Load Type	SCADA data can be modeled in the power flow solution in several different ways. SCADA load type is set in the ASCII file, but can be changed by you. Constant kVA - This is the most common model. It is conservative, and results in slightly lower voltage values than would be measured on an actual system. Constant Current - This model is generally not used in motor modeling. It more closely matches an induction motor's characteristics in the reactive component than other models, but is technically incorrect because kW is relatively constant throughout the voltage range for an induction motor. Constant Impedance - This model is used for starting induction and synchronous machines, and closely matches motor characteristics during low voltages. kW + j Current - This model is a combination of the above models and more closely matches actual motor characteristics within normal operating voltages.
Scaling Factor	Provides an easy way of adjusting the total SCADA load used in determining power flows. By changing the scaling factor, the actual kW +j kVAR read in from the ASCII file remains static, however the load used in the power flow is adjusted by this factor.

Equipment Elevation Tab

See MCC Elevation for information about this tab.

Harmonics Tab

Use the Harmonics tab to indicate whether this equipment item is introducing harmonics into your power system.

Figure 10: Harmonics Tab

Option

Description

Load Type

The default is Linear, indicating the equipment does not produce harmonics. Choosing Harmonic makes the item an harmonic source and makes other fields in this tab available to edit.

Note:
For an adjustable frequency drive (AFD), the Load Type is always Harmonic.
For motors, the Load Type is Harmonic if the With Adjustable Frequency Drive (AFD) check box is selected on the Specifications tab of the motor; otherwise, it is always Linear.

Fundamental Amps

Use to set the fundamental amps. The options are as follows:

Equipment Rating sets Fundm Amps to the equipment rating of the item described in the Specifications tab.
User Specified activates the Fundm Amps field, enabling you to specify a value.

To use fundamental current calculated by power flow, select Calculated from Power Flow in the Summation Fundamental Voltage area of the Harmonics Options > Control dialog box.

Harmonic Spreadsheet

Use the spreadsheet to enter the harmonic spectrum produced by this item. You can enter up to 30 different harmonics in each equipment item. In the spreadsheet, enter the Harmonic Number (such as 5 for the 5^th harmonic), the Harmonic Current in percent of the Fundamental Amps, and the Current Angle. By indicating the current angle, you can simulate transformer phase shift effects on rectifiers so appropriate canceling can take place. The harmonic may be integer or non-integer.

Library Load

Common harmonic spectra may be entered from the device library. For instructions on how to enter your own spectra information, see Harmonics with Spectrum™. After selecting a particular device library spectrum from the Mfr and Type lists, click Import, and that spectrum is entered into the harmonic spreadsheet.

Resistance Factor

EasyPower offers two methods for calculating R_H:

Resistance varying with a power of the harmonic (R-EXP):

R_H = R_Fund * H ^R-EXP

Resistance varying with a percent eddy current factor (%ECF):

R_H = R_Fund * (1+ECF*H²)/(1+ECF)

EasyPower defaults all skin effect correction to R-EXP and a value of 0.5.

Typical Resistance Correction Factors
	R-EXP	%ECF
Transformer	0.5-1.0	1.0-3.0
Utility	0.0-0.8	-
Generator	0.3-0.6	-
Line/Cable	0.5	-
Reactor	0.5-1.0	0.8-3.0
Motor	0.2-0.4	-

Arc Flash Hazard Tab

Figure 11: Arc Flash Hazard tab of MCC Data

Since the MCC can be analyzed like a bus, you can also obtain arc flash hazard assessment results for MCC. The arc flash tab is similar to that of bus data. However, the equipment type is forced to MCC/Panel, since an MCC cannot be another type. You can specify the trip time as available in the default library, enter the incident energy or you can enter the trip times in the fields. For detailed descriptions see Arc Flash Hazard Tab.

Accessories Tab

Figure 12: Accessories Tab

Option	Description
Accessories Description	The accessories for distribution equipment types can be specified in the panel, MCC, and bus dialog boxes. You can add or delete the accessory items as needed per equipment. Only the selected items are displayed in the schedule outputs.
Meter Data
Note	An accessory note of up to 1,024 characters.
Maximum Demand	The maximum demand load at this equipment.
Power Factor	The power factor for the equipment.
Reading Date	The date the meter was read or the information was gathered.
kVA
Safety Factor	Percentage above the kVA that will be multiplied to calculate the new safety factor load.
Load with Safety Factor	Load amount after calculating the safety factor.
Added (New) Demand Load	User-specified load amount to add to the equipment.
Total New Demand Load	Total of the load with safety factor and the added demand load.
Total Amps	Amps based on the total demand load.

Other Tabs

See Common Tabs for information on the Location, Comments, Hyperlinks, Media Gallery, or Collected Data tabs.

More Information

Database Technical Reference	Common Tabs
Media Gallery


	www.easypower.com EasyPower, LLC 7730 SW Mohawk St. Tualatin, OR 97062 (503)655-5059	techsupport@easypower.com feedback@easypower.com EasyPower knowledge base EasyPower Version 9.8 Copyright © 2017 EasyPower, LLC. All Rights Reserved. Help was last updated on 7/10/2017

www.easypower.com

EasyPower, LLC

7730 SW Mohawk St.

Tualatin, OR 97062

(503)655-5059

techsupport@easypower.com

feedback@easypower.com

EasyPower knowledge base

EasyPower Version 9.8

Help was last updated on 7/10/2017