
Typical applications for transmission oil pumps
Where TPV engineering supports stable oil pressure, lubrication, cooling, and hydraulic control in modern transmission systems.

Transmission System Integration
We adapt pump architecture, gear set, housing, and hydraulic interfaces to your transmission layout, oil circuit, and operating strategy.
Why choose Transmission Oil Pumps?
Transmission oil pumps must deliver stable pressure and flow for lubrication, cooling, and hydraulic actuation while meeting strict NVH and packaging requirements.
From requirements to validated prototypes
A clear workflow tailored to your application, covering concept development, simulation, prototyping, validation testing, and series ramp-up with production partners.
Requirements
Kick-off & application review
Requirement specification + application targets
Concept
System layout & gear set design
3D design + initial drawings
Simulation
Hydraulic calculations & CFD
Hydraulic performance data + simulation results
Prototyping
Prototype manufacturing
Functional prototypes for test bench validation
Validation
Prototype test rig optimization
Validated pump system ready for production preparation
Series
Ramp-up with production partners
Series-ready production setup with established partners
Validated Quality
Every prototype is optimized on our prototype test rig for hydraulic stability, low pressure pulsation, low noise behavior, and reliable flow delivery. Transmission oil pump prototypes are typically available within 3–4 months after design freeze and are 100% tested with full test reports.
FAQs
Quick answers to practical engineering questions about transmission oil pump development, hydraulic stability, NVH, pressure pulsation, and integration into AT, DCT, and CVT systems.
Typical drivers include pressure instability, excessive pulsation, NVH issues, packaging limits, higher cooling demand, efficiency targets, or the need to adapt an existing pump concept to a new AT, DCT, or CVT architecture.
Yes. The development process is consistent, but the hydraulic targets differ. AT systems often focus on reliable pressure and lubrication, DCT systems on rapid pressure build-up and clutch cooling, and CVT systems on stable high-pressure supply.
Ideally before the pump envelope and hydraulic interfaces are fully frozen. Early involvement makes it easier to optimize suction conditions, gear set design, pressure behavior, packaging, and NVH before costly layout constraints are fixed.
Useful inputs include pressure and flow targets, speed range, oil temperature range, transmission type, circuit layout, suction conditions, packaging envelope, drive interface, NVH limits, and known pulsation or pressure-control issues.
Often, yes. TPV can evaluate the available space, gear geometry, leakage gaps, suction path, and pressure behavior to identify improvement potential within the existing housing or interface constraints.
Prototype systems can be tested for flow delivery, pressure stability, pulsation, NVH behavior, leakage, power consumption, and relief valve behavior before the concept is prepared for series production with partner manufacturers.


