Temperatures stay low, clocks stay high, and fans behave.
Then the simulator runs for two hours.
And everything changes.
Short answer
Benchmark cooling measures short-term heat removal.
Sustained load cooling reveals how a system behaves over time.
Simulators expose weaknesses that benchmarks rarely reach.
What cooling benchmarks actually measure
Most cooling benchmarks are short and controlled.
They apply load, capture peak temperatures,
and end before thermal equilibrium is reached.
Benchmarks typically show:
- Initial temperature response
- Peak cooling capacity
- Short-term boost behavior
They do not reflect long-session behavior.
What sustained load looks like in simulation
Simulator workloads ramp up and stay active.
There are few pauses and no reset points.
Sustained load means:
- Continuous CPU and GPU utilization
- Heat accumulation in the case and components
- Cooling systems operating at steady state
This is where real behavior appears.
Thermal equilibrium changes everything
Thermal equilibrium occurs when heat input
equals heat dissipation.
Many systems look stable before equilibrium.
After equilibrium:
- Clocks may settle lower
- Fan speeds stabilize or increase
- Small inefficiencies become visible
Benchmarks often stop before this point.
CPU behavior under sustained thermal pressure
CPUs adjust frequency based on temperature and power.
Under sustained load, boost behavior changes.
This can lead to:
- Lower sustained clocks
- Timing variation
- Reduced consistency in simulation workloads
These effects rarely appear in short tests.
GPU cooling under continuous rendering
GPUs in simulators often render continuously.
Over time, heat saturates the cooling system.
Sustained GPU load can cause:
- Clock drift
- Power limit behavior
- Increased noise levels
Benchmark runs usually end before this happens.
Fan behavior over time
Cooling benchmarks often show smooth fan curves.
Sustained load reveals reality.
Over long sessions:
- Fans may ramp higher than expected
- Noise becomes less predictable
- Small temperature changes trigger audible shifts
Acoustic stability matters in simulation.
Case heat saturation and airflow limits
Under sustained load, the entire case heats up.
Air entering the system is warmer.
This reduces cooling efficiency and can cause:
- Gradual temperature rise
- Thermal cycling
- Long-term component stress
Why benchmark cooling results can be misleading
Benchmarks reward peak performance.
Simulators punish instability.
A system that looks excellent in benchmarks
may struggle to maintain consistent behavior
during long simulation sessions.
What simulator cooling should be optimized for
Simulator systems should be designed for endurance.
Key priorities include:
- Thermal equilibrium under sustained load
- Stable CPU and GPU clocks over time
- Predictable fan behavior
- Quiet operation during long sessions
Final thought
Benchmarks show potential.
Sustained load shows reality.
In simulation, cooling success
is defined by how the system behaves
after the first hour, not the first minute.
Simulator Platforms We Support
RBS systems are designed for the most common simulator platforms used today.
Golf simulators
TrackMan · Uneekor · Foresight
Racing simulators
iRacing · Assetto Corsa · rFactor
Flight simulators
MSFS · X-Plane · Prepar3D
