QET uses an algorithmic approach to wire routing. To simulate G-Force: Select the tool.
Choose "Align to Top" or "Align to Center." This simulates a downward gravitational pull, bringing all elements to a uniform horizontal plane instantly. 4. Advanced Tip: The "Momentum" of Custom Elements
In the context of QET, "G-Force" refers to the and Force-vector positioning of elements. Unlike static CAD tools, QET allows for dynamic snapping and auto-leveling of components, ensuring that your wires aren't just lines, but logically flowing connections that "pull" into place. 2. Setting Up Your Workspace g force qelectrotech tutorial
If components are "flying" away or snapping incorrectly, your grid scale is likely too large. Reduce the grid size to 5px.
Select a group of disorganized components (e.g., a row of contactors). Use the tool (Force-Alignment). QET uses an algorithmic approach to wire routing
Set your grid to a standard metric or imperial offset (typically 10px or 2.5mm). G-Force snapping relies on a clean grid to calculate the "pull" of a component.
Enable this in the View menu. This allows components to act like magnets, a fundamental requirement for the G-Force effect. 3. Step-by-Step Tutorial: Implementing Dynamic Alignment Phase A: Defining the Anchor For G-Force to work, you need a fixed point. Place your Power Supply or Main Busbar symbols first. you can define the "Hotspot."
By treating your components as objects with "weight" and your wires as "tension lines," you can master the G-Force workflow in QElectroTech. This doesn't just make your schematics look better—it makes the drafting process significantly faster.
Lock these elements using the "Lock" property in the right-hand panel. These act as your gravitational center. Phase B: Applying the "Pull" (Wiring)
When creating your own symbols in the , you can define the "Hotspot."