Clean Snowmobile Challenge Muffler

The goal of this project is to design a muffler that significantly reduces emissions and noise output compared to the stock muffler without noticeably reducing engine performance or increasing weight. We must have a fully assembled muffler before the Clean Snowmobile Competition, held in March. The muffler must be tested pre-competition with relative data that can be presented in the team’s technical paper and presentation.

Background
For the past 15 years, the University of Idaho has had a team compete in the SAE Clean Snowmobile Challenge. This challenge is based on making modifications to stock snowmobiles in order to reduce noise and emissions while increasing fuel economy, so that the snowmobile industry has less effects on the environment. This year, the UI CSC senior design team will be re-designing the muffler on the snowmobile in order to further address two aspects of the competition - Noise and Emissions.

Deliverables

 * Background research on various sound reduction technologies
 * CAD models and flow simulations of different sound reducing technologies and their effects on backpressure
 * Assembled muffler

Design Development
Although the UICSC team has made noise a focus for development in the past, it has remained a problematic area. To further address this issue, the team developed new testing apparatuses and procedures to better understand snowmobile sound production and mitigation. This includes determining sources of noise as well as controlled testing of various noise attenuation devices. All final sound reductions on chassis were found using the J1161 sound test.

Anechoic Sound Box
To improve understanding of sound attenuation, the UICSC team manufactured an anechoic sound box testing apparatus, referred to as the UI sound box (UISB). The initial design of the UISB was based on an existing design, which was used to test the acoustic effectiveness of quarter-wave and Helmholtz resonators [10]. The anechoic sound box was designed to emit pure frequencies through a waveguide (pipe) without interference. The box contains amplified speakers and tweeters acting as a sound source directed into the UISB. The housing was built using 1.91 cm (0.75 in) high density fiber board internally lined with the studio-foam. Attached to the sound box is the waveguide, which extends to the environment with a removable center section. This section in the center of the pipe is removable for the purpose of testing individual acoustic components. The component length was held constant so the waveguide spanned the same distance for each test. Four microphones were placed along the pipe at the specified locations from the outlet of the UISB. The microphone’s signals were analyzed using a Digilent electronics explorer board.

Muffler Design
The following strategies contributed to the largest reduction in sound: expansion chambers with larger cross-sectional areas, ordering expansion volumes from small to large in series, and “V”-shaped geometric interference plates of the same size. Solidworks was used to simulate fluid flow and back pressure of the muffler components. A flow bench with variable flow rate was used to compare back pressure values to simulations. The average difference between the Solidworks simulations and flow bench measurements was 58%. This was due to the simulations being calculated based on steady flow while the flow bench utilizes vacuum motors that create pulses. The UICSC muffler design is called Red Dawn (AM)2. Using this information, the UICSC team designed four mufflers that were simulated through Solidworks for fluid flow and back pressure, while Sidlab was used for transmission loss.

Results
The Red Dawn (AM)2 muffler performed better than stock at higher frequencies, which are weighted higher in the A-weighted scale [16]. All testing assumed 56.3 kph (35 mph) at 30% throttle. This gives an accurate representation of typical cruising speeds. The results for the Sidlab simulations are shown in the Figure.