This truck part is made by Cummins®. We guarantee that all of our parts are from the OEM (original equipment manufacturer), ensuring a proper fit and quality manufacturing.
We honor the warranty provided by the original equipment manufacturer.
Introduction
The Cummins 4927763 Water Transfer Tube is a component designed for use in heavy-duty trucks. It plays a role in the engine cooling system by facilitating the movement of coolant between the engine and the radiator, contributing to the overall efficiency and reliability of the vehicle. Understanding its purpose and operation is key to maintaining optimal engine performance.
Basic Concepts of Water Transfer Tubes
A Water Transfer Tube is a part of the engine cooling system that facilitates the movement of coolant between the engine and the radiator. Its operation is fundamental to maintaining the engine’s temperature within a safe range. By circulating coolant, it helps dissipate heat generated during engine operation, ensuring the engine does not overheat 1.
Purpose of the Cummins 4927763 Water Transfer Tube
The Cummins 4927763 Water Transfer Tube enables the efficient transfer of coolant, which is vital for regulating engine temperature. This transfer allows heat to be carried away from the engine and dissipated through the radiator. Proper coolant circulation is necessary for preventing engine overheating and ensuring consistent performance 2.
Key Features
The Cummins 4927763 Water Transfer Tube is constructed from materials that offer durability and resistance to the corrosive effects of coolant. Its design includes features that enhance its performance, such as precise fittings for secure attachment and smooth internal passages for unimpeded coolant flow. These attributes contribute to the tube’s effectiveness in the cooling system 3.
Benefits of Using the Cummins 4927763 Water Transfer Tube
Incorporating the Cummins 4927763 Water Transfer Tube into a truck’s cooling system can lead to improved cooling efficiency. This enhancement helps reduce the risk of engine overheating, which can cause damage and decrease performance. Additionally, the tube’s robust construction and design contribute to the engine’s longevity by ensuring reliable coolant circulation.
Installation Considerations
When installing the Cummins 4927763 Water Transfer Tube, it is important to follow proper procedures to ensure a secure and effective fit. This may involve preparing the installation area, using appropriate tools, and carefully aligning the tube with its connections. A correct installation is necessary for the tube to function as intended within the cooling system.
Troubleshooting Common Issues
Issues such as leaks or blockages can occasionally occur with the Cummins 4927763 Water Transfer Tube. Diagnostic procedures may include visual inspections and pressure tests to identify problems. Solutions can range from tightening connections to replacing the tube if damage is detected. Addressing these issues promptly helps maintain the efficiency of the cooling system.
Maintenance Tips
To prolong the lifespan of the Cummins 4927763 Water Transfer Tube, routine maintenance is recommended. This includes regular inspections for signs of wear or damage, cleaning the tube and its connections to prevent buildup, and following manufacturer guidelines for replacement intervals. Consistent maintenance practices contribute to the tube’s durability and the cooling system’s reliability.
Cummins Overview
Cummins Inc. is a well-established company in the automotive and heavy-duty truck industries, known for its wide range of products and strong reputation. With a history of innovation and quality, Cummins offers a variety of components and systems designed to enhance vehicle performance and efficiency. The company’s commitment to excellence is reflected in its product offerings, including the Cummins 4927763 Water Transfer Tube.
Water Transfer Tube (Part 4927763) Compatibility with Cummins Engines
The Water Transfer Tube (part number 4927763) is a component in the cooling system of various Cummins engines. This part is designed to facilitate the transfer of water or coolant between different parts of the engine, ensuring efficient heat dissipation and maintaining optimal operating temperatures.
QSK60 and CM850 Engines
The QSK60 and CM850 engines are part of Cummins’ heavy-duty engine lineup, known for their robust performance and reliability in demanding applications. The Water Transfer Tube (4927763) is specifically engineered to fit seamlessly within these engines, providing a reliable pathway for coolant flow. This ensures that the engine maintains its operational efficiency and longevity, even under strenuous conditions.
MCRS Engines
The MCRS engines, another segment of Cummins’ extensive engine portfolio, also benefit from the precise engineering of the Water Transfer Tube (4927763). This part is integral to the cooling system of these engines, ensuring that the coolant is distributed evenly and effectively. The design of the tube allows for minimal resistance to flow, which is crucial for maintaining the engine’s performance and preventing overheating.
Grouping by Application
While the Water Transfer Tube (4927763) is compatible with the QSK60, CM850, and MCRS engines, it is essential to note that its application may vary slightly depending on the specific engine model and configuration. Cummins engineers have ensured that this part meets the stringent requirements of each engine type, providing a reliable and efficient solution for coolant transfer.
Role of Part 4927763 Water Transfer Tube in Engine Systems
The 4927763 Water Transfer Tube is a component in the efficient operation of engine systems, particularly within the auxiliary cooling system. This tube facilitates the movement of coolant between various parts of the engine, ensuring that all components remain within optimal temperature ranges.
In the auxiliary cooling system, the water transfer tube connects the main coolant passages to the auxiliary cooling circuits. This allows for the distribution of coolant to areas that may not be adequately covered by the primary cooling system, such as turbochargers, aftercoolers, or other high-heat components. By maintaining a consistent flow of coolant, the tube helps prevent overheating and ensures the longevity and performance of these critical engine parts.
Additionally, the tube plays a role in the overall thermal management of the engine. It assists in dissipating heat away from sensitive components, thereby contributing to the stability and reliability of the engine’s operation. The effective circulation of coolant through the water transfer tube also aids in maintaining the viscosity of the lubricants, which is vital for reducing friction and wear within the engine.
Conclusion
The Cummins 4927763 Water Transfer Tube is integral to the auxiliary cooling system, enhancing the engine’s thermal efficiency and protecting its components from excessive heat. Proper installation, maintenance, and understanding of its role within the engine system are essential for ensuring optimal engine performance and longevity.
-
Hick, H., Kupper, K., & Sorger, H. (2021). Systems Engineering for Automotive Powertrain Development. Springer.
↩ -
Khajepour, A. (2023). Synthesis Lectures on Advances in Automotive Technology. Springer.
↩ -
Awari, G.K., Kumbhar, V.S., & Tirpude, R.B. (2011). Automotive Systems Principles and Practice. CRC Press.
↩
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.
; %7D .b %7B fill: none; stroke: %23fff; stroke-miterlimit: 10; stroke-width: 11px; %7D %3C/style%3E%3ClinearGradient id='a' x1='23.8' x2='129.71' y1='37.23' y2='139.74' gradientTransform='matrix(.29182 0 0 .29182 43.5 40.5)' gradientUnits='userSpaceOnUse'%3E%3Cstop stop-color='%23f36d2b' offset='0'/%3E%3Cstop stop-color='%23ee323a' offset='1'/%3E%3C/linearGradient%3E%3Cfilter id='b' x='0' y='0' width='257' height='257' filterUnits='userSpaceOnUse'%3E%3CfeOffset dy='3' input='SourceAlpha'/%3E%3CfeGaussianBlur result='c' stdDeviation='14.5'/%3E%3CfeFlood flood-opacity='.169'/%3E%3CfeComposite in='SourceGraphic' in2='result1'/%3E%3C/filter%3E%3C/defs%3E%3Cg transform='translate(-88,2)'%3E%3Cg class='c' transform='translate(46.5,-40.5)'%3E%3Ccircle class='a' cx='68.305' cy='65.305' r='24.805' style='fill:url(%23a);stroke-width:.29182'/%3E%3C/g%3E%3Cg transform='matrix(.29182 0 0 .29182 104.3 14.299)'%3E%3Ccircle class='b' cx='36' cy='36' r='36'/%3E%3Cpath class='b' transform='translate(-1993.9 -1555.3)' d='m2030 1572v22.852h18.516'/%3E%3C/g%3E%3C/g%3E%3C/svg%3E%0A){kind=small}
; %7D .b %7B fill: none; stroke: %23fff; stroke-miterlimit: 10; stroke-width: 10px; %7D%0A%3C/style%3E%3ClinearGradient id='a' x1='23.8' x2='129.71' y1='37.23' y2='139.74' gradientTransform='matrix(.29182 0 0 .29182 43.5 40.5)' gradientUnits='userSpaceOnUse'%3E%3Cstop stop-color='%23f36d2b' offset='0'/%3E%3Cstop stop-color='%23ee323a' offset='1'/%3E%3C/linearGradient%3E%3Cfilter id='b' x='0' y='0' width='257' height='257' filterUnits='userSpaceOnUse'%3E%3CfeOffset dy='3' input='SourceAlpha'/%3E%3CfeGaussianBlur result='c' stdDeviation='14.5'/%3E%3CfeFlood flood-opacity='.169'/%3E%3CfeComposite in='SourceGraphic' in2='result1'/%3E%3C/filter%3E%3C/defs%3E%3Cg transform='translate(2,2)'%3E%3Cg class='c' transform='translate(-43.5,-40.5)'%3E%3Ccircle class='a' cx='68.305' cy='65.305' r='24.805' style='fill:url(%23a);stroke-width:.29182'/%3E%3C/g%3E%3Cg transform='matrix(.29182 0 0 .29182 15.648 15.86)'%3E%3Cpath class='b' transform='translate(-1735.3 -1357)' d='m1751 1384.5 10.419 10.419 20.453-20.452'/%3E%3Cpath class='b' transform='translate(-2778 -1743)' d='m2838.7 1743c0 41.7 7.358 46.734-30.046 69.422-37.405-22.688-30.047-27.726-30.047-69.422z'/%3E%3C/g%3E%3C/g%3E%3C/svg%3E){kind=small}
; %7D .b %7B fill: none; stroke: %23fff; stroke-miterlimit: 10; stroke-width: 11px; %7D %3C/style%3E%3ClinearGradient id='a' x1='23.8' x2='129.71' y1='37.23' y2='139.74' gradientTransform='matrix(.29182 0 0 .29182 43.5 40.5)' gradientUnits='userSpaceOnUse'%3E%3Cstop stop-color='%23f36d2b' offset='0'/%3E%3Cstop stop-color='%23ee323a' offset='1'/%3E%3C/linearGradient%3E%3Cfilter id='b' x='0' y='0' width='257' height='257' filterUnits='userSpaceOnUse'%3E%3CfeOffset dy='3' input='SourceAlpha'/%3E%3CfeGaussianBlur result='c' stdDeviation='14.5'/%3E%3CfeFlood flood-opacity='.169'/%3E%3CfeComposite in='SourceGraphic' in2='result1'/%3E%3C/filter%3E%3C/defs%3E%3Cg transform='translate(-1137 -1)'%3E%3C/g%3E%3Cg%3E%3Cellipse class='a' transform='translate(-41.5 -38.5)' cx='68.305' cy='65.305' rx='24.805' ry='24.805' style='fill:url(%23a);stroke-width:.29182'/%3E%3Cpath class='b' transform='matrix(.29182 0 0 .29182 16.683 28.431)' d='m26.284 0-26.284 17.551m42.284-17.551 26.284 17.551m-25.284-21.551a9 9 0 0 1-9 9 9 9 0 0 1-9-9 9 9 0 0 1 9-9 9 9 0 0 1 9 9zm31.5-0.391a40.5 40.5 0 0 1-40.5 40.5 40.5 40.5 0 0 1-40.5-40.5 40.5 40.5 0 0 1 40.5-40.5 40.5 40.5 0 0 1 40.5 40.5z' style='fill:none;stroke-miterlimit:10;stroke-width:11px;stroke:%23fff'/%3E%3C/g%3E%3C/svg%3E){kind=small}