Assistive CPR Device

CPR is an acronym for Cardiopulmonary Resuscitation, an emergency procedure that is used to preserve brain function through artificially circulating the blood through the body. Conducting CPR is a physically demanding procedure that requires special training. The purpose of this project is to make CPR simpler and less physically demanding, allowing for our physically challenged client to successfully perform CPR. Eventually, we hope that this device can be adapted or inspire future iterations that would allow others with disabilities to perform this life saving technique.

Background
CPR is an important life saving technique for victims who can not breath as well as those suffering from cardiac arrest. In statistics posted by the American Heart Association, having a bystander who can perform CPR improves the victims survival rate by almost 45 percent.

For this project, 120CCs were recruited to design a device that would assist a medical student with a disability conduct CPR. With a final goal of helping them pass their CPR examination to further progress into the medical field, as well as empower them and others with similar ailments to pursue their dreams in the medical field.

120CCs design team has acquired a CPR training mannequin to use for testing both prototype and final designs. Additionally, 120CCs will be using a volunteer to test if the design will provide mechanical assistance for physically challenged individuals.

Specifications
The Assistive CPR device needs to meet several design specifications in order to be both practical and usable for emergency medical situations.


 * The Device must be compliant with American Heart Association Guidelines.
 * The Device must be able to compress the chest a minimum of 5 cm to a maximum of 6 cm.
 * The device should use a force multiplication system to help physically weaker individuals apply the necessary force and pressure to compress the chest a minimum and maximum depth.
 * The Device should be portable and easily stored for quick access/use during a medical emergency.
 * The Device must fit an average human as well as be easily maneuverable to apply compressions to the proper location on the sternum.
 * The Device must withstand 1,000 hours of use without structural damage.
 * The Device must be lightweight and easily deployable with a mechanized wheelchair.

=Design Developments=

Initial Designs and Project Expectations
Project Description: “...The WWAMI Medical Program at the University of Idaho is interested in developing a device that people with minimal physical strength can use to provide necessary chest compression. The device would be used on people suffering from cardiac events, in locations such as assisted care facilities and rest homes We envision that someone in a wheelchair could move and position the device, then add the force required…”

With this in mind 120CCs began the project with designing devices usable from a wheelchair. Dr. Crepeau also provided an initial prototype to help guide the team on the right track.

Baseboard Lever Design
Dr. Crepeau provided an initial prototype to help guide the team on the right track. The initial design although effective, did not work with CPR test requirements of not moving the mannequin to be placed ontop of the base board. Fortunately Abdulrahman created a second iteration of the device that would work without the base board. The design also, in theory, was to be exceptionally portable with its simplicity.

Dual Fulcrum Design
One of the initial iterations of the project was the dual fulcrum design created via Solid Works by 120CCs team member Ahmed shown to the left. The second fulcrum would provide the force necessary for the patient to receive the necessary compression while maintaining a lever arm that could be extended and thus accessible to a person in a wheelchair. The simplicity of the design also lends to the ability to break down and be stored effectively or carried by disassembling the lever from the compression arch.

Revision of Design and Project Expectations
After receiving knowledge of our clients full capabilities, our previous designs were scraped and the team went back to the drawing board. Intent on creating design specific to our clients personal strengths. We at 120CCs, interviewed our client and discussed they were capable and comfortable in doing, as well as taking measurements of their wheel chair and ability of strength.

Wheel Chair Box Lever Design
During a meeting with the WWAMI medical student, they mentioned that they use a mechanism in their car to lock their wheelchair into place behind the steering wheel to allow them to safely drive their car. This system, is colloquially called the EZ-Lock System. It is used widely to allow for operation of a vehicle from a wheel chair. We thought this device could be a good base for integrating the Rotating Arm Device into the student's wheel chair. If all goes according to plan this will allow the student to "dock" into the Assistive CPR Device and subsequently manipulate it with their wheel chair.

This design met all requirements of storage limitations, maneuverability as well as lightness and ease of use for the client. The device also provided enough mechanical advantage to apply approximately 100-120 lbf to the sternum of the mannequin.

2nd Prototype
Inspired by the Q-Straint locking mechanism, the 120CCs moved forward to create the body of the mechanism. Given the success of the “wheel chair box lever design” in initial tests, few modifications were necessary to to create a device that would assist our client.

For the secondary prototype 120CCs turned to the manufacturer of 80/20 to supply them with material both rigid and adaptable enough to create the design. 80/20 Manufacturing site states that the material has the following mechanical properties.

Each piece of 80/20 is made up of annealable 6105-T5 aluminum alloy, and has earned the moniker of “the industrial erector set” because of its versatility. This versatility of the material has allowed the team to address a consistent question of adjustability. With at little as a slide the mechanism can be raised and lowered to suit different widths of the patient and applicator. Although this is not a perfect emergency situation level adjustment, it does place the group in the right direction. For the second prototype, a Y-axis hinge was attached to the compression lever, in order to help maintain full lateral energy when performing compressions on the dummy.

Prototype Testing
Prototype 1.2 had the extension of a angled plate to both bring the force applicator closer to our client, as well as preserve her lateral force when performing compressions on the dummy. Additionally prototype 1.0 and 1.2 were tested with our client using a front facing position and a right side mounted position.

Design 1: The front facing position had the benefit of our client compressing with both arms instead of just the right side. Additionally, mounting will be easier and have less torsional stresses over mounting from the side.

Design 2: Side mounting it was easier for the client to line up the applicator to the proper location on the dummy, but only one arm was able to apply the force, lending to quicker fatigue during the 1 minute period of consistent compressions.

Design Validation
File:Design Validation Plan.pdf

=Team Members=

=Additional Documentation=

Project Schedule

Meeting Minutes

Budget

Presentations



Client Interview