This tutorial provides a brief description of EasyPower panel schedules.
Figure 1: One-line View of a Panel Schedule
Depending on your settings, you may need to click Panel Schedule again or click the Select arrow to return to the pointer.
In the Panel Data dialog box, note that there are several tabs. The Specifications tab contains entry fields for panel information. Most of these are not required for analysis calculations. For this tutorial, assume that units are set to US, not Metric.
Note: You can resize the Panel Data dialog box window by dragging its edges. You can also maximize the dialog box on your screen by clicking the Maximize button.
Figure 2: Panel Schedule Spreadsheet
Figure 3: The Panel Spreadsheet Toolbar
The spreadsheet has its own scroll bars to use for moving around. You can also use the tabs (shown in Panel Spreadsheet Sections) at the bottom of the spreadsheet to move to different sections of the spreadsheet.
Figure 4: Panel Spreadsheet Sections
Typical panelboard circuits are lined up in two columns: one on the left side of the panelboard and one on the right. The EasyPower panel spreadsheet is laid out in the same manner (see Panel Schedule Spreadsheet). Each spreadsheet row represents two circuit poles—one on the left and one on the right.
To model a two-phase or three-phase load in panels, simply specify the number of poles in the CB/Fuse Poles column.
The next two rows on the left spreadsheet are no longer available as shown in Panel Spreadsheet Loads. Each row on the left side represents a pole or phase. The load data for the two disabled rows (phases) are specified in the first row.
Only one extra row gets disabled as shown on the right in Panel Spreadsheet Loads. The load data for the disabled row can be entered in the row above it.
Figure 5: Panel Spreadsheet Loads
Cells that have inadequate data for analysis purposes are highlighted in red. There are no red cells displayed here since by default the panel spreadsheets already contain the minimum data required to run analysis calculations.
Cells that can be calculated (using the button) are indicated by bold column headers. For example, the Int kA cell in the Protective Device section can be calculated as shown in Calculable Cells With Bold Headers. To calculate this field, the other protective device information for that row must be entered.
Figure 6: Calculable Cells With Bold Headers
You can enter protective device and conductor information, but the data is not required for analysis calculations.
In Panel Schedule Spreadsheet, you will notice a Library Load column. This is for advanced panel spreadsheet users who want to enter typical panel circuits in their user-editable device library. After predefining a Library Load in Stdlib.mdb (the device library), selecting that Library Load in the panel spreadsheet automatically fills in the rest of the cells for that entire circuit.
Figure 7: The Panel Summary
Note that there is also a Total column in the Including Downstream Load section. When you click Calculate Downstream Load, EasyPower automatically traverses your system to add up downstream load.
There are no generators in this system yet, so the downstream load is not calculated in this example. In the traversing algorithm, EasyPower uses generators to determine upstream branch direction.
The Connected kVA is the vector sum of all the connected VA values converted to kVA units. You have the option of using Demand, Code Factors, or Design kVA values as well.
If you are an advanced EasyPower user, you can add a cable, a bus and a utility as shown in Performing Short Circuit Calculations on a Panel and have EasyPower perform short circuit, power flow and harmonics calculations on this small system.
Figure 8: Performing Short Circuit Calculations on a Panel
This has been a brief overview of EasyPower’s panel schedule equipment. The EasyPower User Guide and Help documentation cover this topic in greater depth.