9 hours ago
Introduction: When a Skid Steer Refuses to Stay Put
The CASE 85XT skid steer is a rugged and reliable compact loader, but like many hydrostatically driven machines, its parking brake system is a critical safety feature that can quietly fail. In this article, we explore a real-world case involving a 2005 CASE 85XT with a malfunctioning parking brake that allowed the machine to roll on inclines—even when the brake was engaged. We’ll break down the system’s design, explain why hydraulic pressure matters, and offer practical steps for diagnosis and repair.
Terminology Note: Understanding the Brake System
- ROPS (Roll-Over Protective Structure): A safety system that includes seat bar sensors and interlocks to prevent unintended movement.
- NORS Switch (Neutral Override Release Switch): Confirms hydraulic pressure and system readiness for brake engagement.
- Spring-Applied Hydraulic-Release Brake: A fail-safe design where springs engage the brake when hydraulic pressure is absent.
- Drive Motors: Integrated units that include the brake assemblies and power the wheels.
The Problem: Brake Light On, But Machine Still Rolls
After restoring the ROPS safety system and replacing all safety switches, the operator found that the machine correctly entered neutral when the seat bar was lifted. The brake light illuminated, indicating hydraulic pressure at the NORS switch. However, when parked on a hill and the brake button was pressed, the machine still rolled slowly downhill. Even disconnecting the hydraulic feed line to the brake assemblies didn’t stop the movement—suggesting the brakes weren’t engaging mechanically.
System Behavior and Expectations
In a spring-applied hydraulic-release brake system:
In Washington State, a CASE 85XT used in a logging yard began rolling downhill during loading operations. The operator had assumed the brake was engaged, but a worn disc and broken spring allowed the machine to creep forward. After a near-miss with a trailer, the machine was pulled from service. A full teardown revealed both brake assemblies were worn beyond spec. Rebuilding the units restored full holding power—and reinforced the importance of incline testing after brake repairs.
Preventive Measures and Long-Term Strategies
The CASE 85XT’s parking brake failure was ultimately mechanical—not hydraulic. Despite correct system signals and pressure, worn discs and broken springs prevented engagement. This case highlights the importance of understanding how hydraulic and mechanical systems interact—and why visual confirmation of brake function is essential. In compact equipment, safety isn’t just about stopping—it’s about staying stopped when it matters most.
The CASE 85XT skid steer is a rugged and reliable compact loader, but like many hydrostatically driven machines, its parking brake system is a critical safety feature that can quietly fail. In this article, we explore a real-world case involving a 2005 CASE 85XT with a malfunctioning parking brake that allowed the machine to roll on inclines—even when the brake was engaged. We’ll break down the system’s design, explain why hydraulic pressure matters, and offer practical steps for diagnosis and repair.
Terminology Note: Understanding the Brake System
- ROPS (Roll-Over Protective Structure): A safety system that includes seat bar sensors and interlocks to prevent unintended movement.
- NORS Switch (Neutral Override Release Switch): Confirms hydraulic pressure and system readiness for brake engagement.
- Spring-Applied Hydraulic-Release Brake: A fail-safe design where springs engage the brake when hydraulic pressure is absent.
- Drive Motors: Integrated units that include the brake assemblies and power the wheels.
The Problem: Brake Light On, But Machine Still Rolls
After restoring the ROPS safety system and replacing all safety switches, the operator found that the machine correctly entered neutral when the seat bar was lifted. The brake light illuminated, indicating hydraulic pressure at the NORS switch. However, when parked on a hill and the brake button was pressed, the machine still rolled slowly downhill. Even disconnecting the hydraulic feed line to the brake assemblies didn’t stop the movement—suggesting the brakes weren’t engaging mechanically.
System Behavior and Expectations
In a spring-applied hydraulic-release brake system:
- Hydraulic pressure keeps the brake disengaged during operation
- When pressure is removed (e.g., engine off or brake button pressed), springs should engage the brake
- If the machine rolls with no hydraulic pressure, the brake assembly is likely worn or damaged
- Worn Brake Discs
- Over time, the friction material on the brake discs wears down, reducing holding capacity. This is especially common in machines with high hours or frequent hill work.
- Broken or Weak Return Springs
- The springs responsible for engaging the brake when hydraulic pressure is lost can fatigue or break, preventing full engagement.
- Contaminated or Damaged Brake Assemblies
- Hydraulic fluid contamination, corrosion, or mechanical damage inside the drive motor brake assembly can impair function.
- Incorrect Hydraulic Pressure
- Over time, the friction material on the brake discs wears down, reducing holding capacity. This is especially common in machines with high hours or frequent hill work.
- If pressure at the brake assembly is too low or inconsistent, the system may not fully release or engage the brake.
- Confirm hydraulic pressure at the brake feed line using a pressure gauge
- Disconnect hydraulic feed and observe brake engagement behavior
- Remove drive motors and inspect brake assemblies for wear or damage
- Check for broken springs, worn discs, or contaminated components
- Verify ROPS system is functioning correctly and not interfering with brake logic
- Hydraulic release pressure: Typically 250–300 psi
- Brake disc thickness: Refer to CASE service manual; replace if below minimum spec
- Spring tension: Should be uniform across all springs; replace if visibly deformed
- Drive motor removal torque: Use proper lifting equipment; motors are heavy and integrated
- Replace brake discs and springs as a complete set to ensure balanced engagement
- Clean and inspect all components for corrosion or fluid contamination
- Use OEM parts or high-quality aftermarket kits for rebuild
- Reinstall drive motors with proper torque and alignment
- Test brake function on incline before returning to service
- Document repair and hours for future maintenance planning
In Washington State, a CASE 85XT used in a logging yard began rolling downhill during loading operations. The operator had assumed the brake was engaged, but a worn disc and broken spring allowed the machine to creep forward. After a near-miss with a trailer, the machine was pulled from service. A full teardown revealed both brake assemblies were worn beyond spec. Rebuilding the units restored full holding power—and reinforced the importance of incline testing after brake repairs.
Preventive Measures and Long-Term Strategies
- Inspect brake assemblies every 1,000 hours or annually
- Avoid bypassing safety systems like ROPS; they protect against unintended movement
- Train operators to test brake function on slight inclines before heavy use
- Keep spare brake kits in fleet maintenance inventory
- Log all brake-related repairs and monitor for recurring issues
The CASE 85XT’s parking brake failure was ultimately mechanical—not hydraulic. Despite correct system signals and pressure, worn discs and broken springs prevented engagement. This case highlights the importance of understanding how hydraulic and mechanical systems interact—and why visual confirmation of brake function is essential. In compact equipment, safety isn’t just about stopping—it’s about staying stopped when it matters most.
