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Diesel engine NVH is an important characteristic of light and medium duty vehicles in today's market. Typical NVH related issues like idle gear clatter, gear whine and cab shake at low speed and load conditions are perceived as unpleasant and are unacceptable to the end customer. The root cause of many of these NVH concerns is frequently associated with powertrain structures and the excitation of different mechanical components within the engine. This paper focuses on development of robust and self-contained engine test stand which can help both for troubleshooting NVH concerns and for setting relevant targets at the subsystem levels to mitigate NVH risks. The motivation behind developing this unique test stand is given with examples and the advantages are demonstrated for relevant engine NVH testing applications.

Engine noise is one of the significant aspects of product quality for light and medium duty diesel engine market applications. Gear whine is one of those noise issues, which is considered objectionable and impacts the customer’s perception of the product quality. Gear whine could result due to defects in the gear manufacturing process and/or due to inaccurate design of the gear macro and micro geometry. The focus of this technical paper is to discuss gear whine considerations from the production plant perspective. This includes quick overview of the measurement process, test cell environment, noise acceptance criteria considerations. A gear whine case study is presented based on the data collected in the test cell at the engine plant. Gear whine data acquired on current product and next generation of prototype engines is analyzed and presented. This paper concludes by highlighting the lessons learned from the case study.

Due to increasing expectations for gasoline like sound quality, today's diesel engines for light and medium duty automotive markets needs to be carefully designed from NVH perspective. Typical engine operating conditions such as low idle, light tip in, tip out demand more attention as they are more prone to generating sound quality concerns. Any abrupt change in the noise signature may be perceived as a sign of malfunction and could have a potential to generate warranty claims. In this paper, an experimental investigation was carried out to determine the root cause of the transient oil pressure regulator buzz noise which occurred during no load transients at low engine speeds. The root cause of the objectionable noise was found to be associated with the impacts of the regulator plunger on the valve seat at certain engine speeds. Noise and vibration diagnostic tests confirmed that the plunger impacts at the seat caused the objectionable buzz noise.

NVH development of light duty diesel engines require significant collaboration with the OEM as compared to medium duty and heavy duty diesel engines. Typically, competitive benchmark studies and customer expectations define the NVH targets at the vehicle level and are subsequently cascaded down to the powertrain level. For engine manufacturing companies like Cummins Inc., it is imperative to work closely with OEM to deliver on the NVH expectations. In certain situations, engine level NVH targets needs to be demonstrated in the OEM or 3rd party acoustic test facility for customer satisfaction or commercial purposes. Engine noise tests across different noise test facilities may introduce some variation due to differences in the acoustic test facilities, test hardware, instrumentation differences, etc. In addition, the engine itself is a major source of variation.