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We honor the warranty provided by the original equipment manufacturer.
Introduction
The 4983279 Oil Transfer Connection is a component designed to facilitate the efficient transfer of oil within the lubrication system of commercial trucks. Manufactured by Cummins Inc., a renowned name in the automotive and heavy-duty truck industry, this component exemplifies the brand’s commitment to quality and innovation.
Basic Concepts of Oil Transfer Connection
An Oil Transfer Connection is a conduit that allows oil to move between various components within a truck’s lubrication system. Its primary function is to maintain a steady flow of oil, which is vital for reducing friction, dissipating heat, and protecting engine parts from wear and tear 1. By facilitating the transfer of oil, it ensures that all moving parts receive the necessary lubrication to operate smoothly and efficiently.
Purpose of the 4983279 Oil Transfer Connection
This Cummins part plays a role in the operation of a truck by ensuring that oil is distributed effectively throughout the engine. This distribution is crucial for maintaining proper lubrication, which in turn helps in preserving engine performance and longevity 2. By ensuring that oil reaches all critical components, this connection aids in the overall efficiency and reliability of the truck’s engine.
Key Features
The 4983279 Oil Transfer Connection is characterized by several design elements that enhance its performance and durability. It is constructed from high-quality materials that are resistant to corrosion and wear, ensuring longevity in harsh operating conditions. The design includes precise fittings and seals that prevent oil leaks, maintaining the integrity of the lubrication system. Additionally, its robust construction allows it to withstand the high pressures and temperatures typical in commercial truck engines 3.
Benefits
The use of the 4983279 Oil Transfer Connection offers several advantages. It contributes to improved lubrication efficiency, ensuring that all engine components receive adequate oil supply. This enhanced lubrication protects the engine from excessive wear, potentially extending its operational life. Furthermore, by maintaining consistent oil flow, it helps in dissipating heat more effectively, which is crucial for engine performance under demanding conditions 4.
Installation Process
Installing the 4983279 Oil Transfer Connection involves several steps to ensure proper setup. Begin by ensuring the engine is cool and the oil system is depressurized. Locate the connection points within the lubrication system and clean them to remove any debris. Align the connection with the fittings and secure it using the appropriate tools. It is important to follow the manufacturer’s guidelines to ensure a proper seal and prevent leaks. After installation, check for any signs of leakage and ensure that the connection is firmly in place.
Maintenance Tips
To ensure the longevity and optimal performance of the 4983279 Oil Transfer Connection, regular maintenance is recommended. Inspect the connection periodically for signs of wear or damage. Clean the area around the connection to prevent the accumulation of dirt and debris, which could affect its performance. Additionally, check the seals and fittings for any signs of leakage and replace them if necessary. Adhering to these maintenance practices will help in maintaining the efficiency of the lubrication system.
Troubleshooting Common Issues
Common issues with the 4983279 Oil Transfer Connection may include oil leaks, reduced oil flow, or connection failure. To address these problems, first, inspect the connection for any visible damage or wear. If a leak is detected, check the seals and fittings for proper alignment and integrity. In case of reduced oil flow, ensure that there are no obstructions within the connection or the lubrication system. If the connection fails, it may need to be replaced following the manufacturer’s guidelines for installation.
Cummins Overview
Cummins Inc. is a global power leader that designs, manufactures, and distributes a wide range of power solutions, including engines, filtration, and emission solutions. With a strong reputation in the commercial truck industry, Cummins is known for its commitment to quality, innovation, and customer satisfaction. The company’s extensive product range and dedication to advancing technology make it a trusted name among professionals in the automotive and heavy-duty truck sectors.
Cummins Oil Transfer Connection 4983279 Compatibility
The Cummins Oil Transfer Connection part number 4983279 is designed to integrate seamlessly with a variety of Cummins engines, ensuring efficient oil transfer and system integrity. This part is compatible with the following engines:
ISF2.8 CM2220 F129
The ISF2.8 CM2220 F129 engine benefits from the precise engineering of the 4983279 Oil Transfer Connection. This component ensures that oil is effectively transferred between the engine’s various systems, maintaining optimal lubrication and performance.
QSF2.8 CM2880 Series
The 4983279 Oil Transfer Connection is also compatible with the QSF2.8 CM2880 engines, which include the following variants:
- QSF2.8 CM2880 F104
- QSF2.8 CM2880 F105
- QSF2.8 CM2880 F114
These engines, known for their robust design and reliability, are enhanced by the precise fit and function of the 4983279 part. It ensures that oil flow is maintained at the required levels, preventing potential engine damage due to insufficient lubrication.
R2.8 CM2220 R101B
The R2.8 CM2220 R101B engine is another beneficiary of the 4983279 Oil Transfer Connection. This part ensures that the engine’s oil systems operate smoothly, contributing to the engine’s overall efficiency and longevity.
By integrating the 4983279 Oil Transfer Connection into these engines, users can expect enhanced performance, reliability, and longevity of their engine systems.
Role of Part 4983279 Oil Transfer Connection in Engine Systems
The 4983279 Oil Transfer Connection is an integral component in the efficient operation of various engine systems. Its primary function is to facilitate the seamless transfer of oil between different parts of the engine, ensuring optimal lubrication and performance.
Integration with Plumbing Systems
In the context of engine plumbing, the 4983279 Oil Transfer Connection acts as a vital link. It connects the oil supply lines to critical engine components, ensuring a consistent flow of lubricant. This connection is essential for maintaining the integrity of the oil circulation system, which is responsible for reducing friction, dissipating heat, and preventing wear on moving parts.
Interaction with Turbocharger Systems
When integrated with turbocharger systems, the 4983279 Oil Transfer Connection plays a significant role. Turbochargers require a steady supply of oil to lubricate their bearings and maintain efficient operation. The connection ensures that oil is delivered to the turbocharger oil inlet, which is crucial for the turbocharger’s performance and longevity.
Specific Role in Turbocharger Oil Inlet Connection
At the turbocharger oil inlet connection, the 4983279 Oil Transfer Connection ensures that oil is supplied at the correct pressure and flow rate. This is important for the turbocharger’s internal components, such as the turbine and compressor, which operate at high speeds and temperatures. Proper lubrication at these points prevents overheating and mechanical failure, contributing to the overall efficiency and reliability of the turbocharger.
Conclusion
In summary, the 4983279 Oil Transfer Connection is a key component in maintaining the lubrication needs of complex engine systems, particularly in high-performance applications like turbocharged engines. Its role in connecting and facilitating oil flow between various engine components underscores its importance in ensuring smooth and efficient engine operation.
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Fehan, D. R. (2013). Design of Racing and High-Performance Engines 2004-2013. SAE International.
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Bonnick, A., & Newbold, D. (2011). A Practical Approach to Motor Vehicle Engineering and Maintenance, Third Edition. Elsevier Ltd.
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ElGindy, M., & ElSayegh, Z. (2023). Road and Off-Road Vehicle Dynamics. Springer Nature.
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Goodnight, N., & Van Gelder, K. (2018). Automotive Braking Systems. Jones & Bartlett Learning.
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SPECIFICATIONS
RECOMMENDED PARTS
* Variable geometry turbocharger and electronic actuator repairs are not eligible to be claimed as over-the-counter under New or ReCon parts warranty for parts installed after October 1, 2018.
* Diesel Oxidation Catalyst (DOC), Diesel Particulate Filter (DPF), Selective Catalyst Reduction (SCR) catalyst, and Electronic Control Module (ECM) repairs are not eligible to be claimed as over-the-counter under New or ReCon parts warranty for parts installed after January 1, 2020.
* These restrictions are only applicable to New parts and ReCon parts coverages for the components listed above sold to a customer in the US or Canada. All other coverages are excluded. All other regions are excluded.
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