Intakes
Contents
Description
(description of mechanism)
Design Considerations
Touch It, Own It
"Touch it, own it" is a concept used to describe an effective intake, although it is not a measurable metric. The moment a "touch it, own it" intake comes in contact with a game piece, it is "owned" by the robot such that it will never lose grip, fall out, or be stolen by another robot. It can be seen as somewhat of a buzzword.
Effective Intake Area
The effective intake area is the size of the area in front of the robot where reliable intaking can happen. The larger the effective intake area, the more easily game pieces can be acquired and scored. For a tank drive robot, measuring the width of the intake (parallel to the front bumper) is more important than measuring its length (perpendicular to the front bumper). For a swerve drive, the critical measurement is the total ground area under the intake where reliable intaking happens.
Speed
Assuming that a roller intake is being used (as it almost always should), the surface speed of the roller(s) should be fast enough that the robot can pick up a game pieces when driving forward at full speed. For "single-contact" intake designs like the Top Roller, that means that the surface speed of the roller should be 2-4x the top speed of the robot. For "dual-contact" designs like the Top and Bottom Roller and Side Rollers, each roller's surface speed should be 1-2x the robot's top speed.
A simple equation to calculate an intake's rotational speed is:
Where:
Ω = The intake's rotational velocity
Vs = The intake's surface speed (1-4 times The robot's maximum driving speed, depending on the type of intake used)
r = The intake's radius
Deployment
All parts of an FRC robot are typically required to start within the robot's frame perimeter. With few exceptions, an intake is unable to acquire game pieces from inside the frame perimeter. This means that intakes have to actuate outwards in order to fuction effectively. It is not always strictly necessary to be able to retract an intake, although game rules sometimes make it advantageous to do so, and parts outside the frame perimeter are always more succeptable to damage than parts protected by the bumpers.
This deployment typically happens with a linear slide, pivot, or four bar. Intake deployment is an ideal use for pneumatics as most intakes have only two positions, stowed and deployed. Deploying an intake with a motor is useful in some cases where pneumatics aren't present on the robot (such as the 2021 Robot (Oreo)), or when the intake's exact position needs to be controlled (such as the 2019 Robot (Flip)).
Durability
Because intakes are often the only part of a robot extending past the frame perimeter, they need to be designed to take more abuse than most other robot parts. Compliant mounting and flexible parts are a popular way to keep intakes from taking damage when deployed. A robot should be able to drive into a wall at full speed without breaking any parts.
Major Types
Over Bumper
Description
When to Use
Notable Examples
Link to Info | Link to Info | Link to Info |
Through Bumper
Description
When to Use
Notable Examples
Link to Info | Link to Info | Link to Info |
Top and Bottom Roller
Description
When to Use
Notable Examples
Link to Info | Link to Info | Link to Info |
Top Roller
Description
Dustpans
When to Use
Notable Examples
Link to Info | Link to Info | Link to Info |
Side Rollers
Description
Dustpans
When to Use
Notable Examples
Link to Info | Link to Info | Link to Info |
Pinchers
Description
Dustpans
When to Use
Notable Examples
Link to Info | Link to Info | Link to Info |