Boom Aerial Work Vehicle Lower Arm Hydraulic Cylinder

The lower arm cylinder is the heaviest, longest, and most powerful hydraulic cylinder on a boom aerial work vehicle. It is the actuator that rotates the entire main boom from stowed (horizontal) to maximum elevation — lifting the boom structure, the telescopic sections or articulating knuckle joints, the jib, the platform basket, and the personnel standing in it against gravity through an arc of 60–80°. With a Φ100 bore, Φ80 rod, and 1,458 mm stroke, the GTHZ210C-620400-000 generates the highest sustained force of any cylinder in the Korea Ever-Power aerial work vehicle range. This is the cylinder that defines the boom lift’s working height.

Boom Lift · Main Boom Rotation · Lower Arm · Heaviest Cylinder on the Machine

Boom Aerial Work Vehicle
Lower Arm Hydraulic Cylinder

Every cylinder on a boom lift serves a specific function — steering turns the wheels, the floating cylinder levels the platform, and the upper arm cylinder articulates the jib. But the lower arm cylinder does the heaviest work on the machine: it lifts the entire boom assembly from its stowed position against gravity and holds it there, at full extension, with personnel in the basket, for hours at a time. At Φ100 bore and 1,458 mm stroke, this is the largest-bore, longest-stroke, and heaviest single cylinder in the Korea Ever-Power aerial work vehicle range — and it is the cylinder whose failure takes the entire boom lift out of service immediately.

Φ100
Bore (mm)
Φ80
Rod (mm)
1,458
Stroke (mm)
21 MPa
Pressure
137 kg
Weight

Technical Specification — GTHZ210C Lower Arm Cylinder

Boom Aerial Work Vehicle Lower Arm Hydraulic Cylinder Dimension 1

Cylinder Name Drawing Number Bore (D) Rod (d) Stroke (S) Install Dist (L) Pressure Ports (M) Weight
Lower arm cylinder GTHZ210C-620400-000 Φ100 Φ80 1458 1899 21 MPa 2-Φ9 137 kg
Function Main boom rotation — raises and lowers the entire boom assembly
Acting Type Double-acting (raise & lower under hydraulic control)
Rod-to-Bore Ratio 0.80 — extreme column load specification
Port Style 2-Φ9 banjo fitting ports (high-flow)
Body Material 20# / 45# / Q345B steel
Seal Options Parker, NOK, Hallite, Busak Shamban
Certification ISO 9001:2015, ISO 14001, ISO 45003
Quality 100% proof pressure tested (31.5 MPa) + leakage test
MOQ / Warranty 1 piece / 1 year

Why the Lower Arm Cylinder Is the Largest on the Boom Lift

The lower arm hydraulic cylinder mounts between the turntable (the rotating base) and the main boom section. Every kilogram of the entire boom structure — the lower boom, the upper boom, the telescopic sections, the jib, the platform basket, and the personnel — hangs from this cylinder. The further the boom extends horizontally, the greater the moment arm, and the greater the force the lower arm cylinder must produce to hold the boom at angle.

Boom Aerial Work Vehicle Lower Arm Hydraulic Cylinder 1

Parameter Lower Arm (this product) Steering Floating
Bore Φ100 Φ63 Φ63
Stroke 1,458 mm 320 mm 60 mm
Weight 137 kg 13 kg 16 kg
Piston area 7,854 mm² 3,117 mm² 3,117 mm²
Force at 21 MPa ~165 kN (16.5 tonnes) ~65 kN ~78 kN (25 MPa)
165 kN in context:
The lower arm cylinder produces approximately 165 kN (16.5 tonnes-force) at its 21 MPa rated working pressure. This is enough force to lift a fully loaded boom assembly at the boom pivot point. The cylinder must hold this force continuously — sometimes for hours — while personnel work on the elevated platform. Any internal seal bypass that allows the boom to drift downward is a critical safety failure that requires immediate cylinder replacement.

The Φ80 Rod — Engineered for Extreme Column Loading

The lower arm cylinder has a rod-to-bore ratio of 0.80 — the highest in the entire aerial work vehicle cylinder range. A standard cylinder of this bore would use a Φ50–Φ60 rod. The GTHZ210C uses Φ80. This is not over-engineering; it is a direct response to the column loading condition that the lower arm cylinder operates under.

When the boom is at low elevation angles (10–30° from horizontal — the most common working range for building maintenance and infrastructure inspection), the lower arm cylinder is nearly horizontal. The massive push force acts along the rod axis as a compressive column load. At 1,458 mm of exposed rod length at full extension, even a small lateral deflection can initiate Euler buckling. The Φ80 rod increases the second moment of area (the geometric property that resists buckling) by 4.5× compared to a Φ50 rod — providing a critical safety margin against rod buckling at the low boom angles where the cylinder force is highest and the rod extension is longest.

Induction-Hardened + Hard Chrome

The Φ80 rod is C45 steel, induction-hardened to HRC 55–62 across the surface layer, then hard-chrome plated to 20 μm minimum. On a lower arm cylinder that operates outdoors on construction sites — exposed to rain, mud splatter, abrasive dust, and occasional impact from swinging loads — the chrome layer is the primary defense against rod surface damage. Any scratch or pit in the chrome that reaches the steel substrate will corrode and destroy the rod seal within weeks. The 20 μm chrome thickness provides the wear reserve needed for 6,000–10,000 hours of outdoor operation.

2-Φ9 Banjo Ports — High Flow Capacity

The lower arm cylinder uses 2-Φ9 banjo-style port connections rather than threaded ports. Banjo fittings allow the hose to connect at any rotational angle around the port axis — critical on the lower arm cylinder because the hose routing must accommodate the cylinder's angular movement as the boom rotates. The Φ9 port bore provides the flow cross-section needed for the high oil volume that fills and empties the Φ100 bore during boom raise and lower cycles. At typical boom speeds, the lower arm circuit flows 30–50 L/min — far more than the 5–10 L/min through the steering or floating circuits.

Replacing the Lower Arm Cylinder — The Largest Job on a Boom Lift

Replacing the lower arm cylinder is the most complex and physically demanding cylinder replacement on a boom aerial work vehicle. The cylinder weighs 137 kg, mounts deep inside the turntable structure, and requires the boom to be fully lowered and supported on a cribbing stack before the cylinder can be disconnected. A crane or overhead hoist is typically required to handle the cylinder weight during extraction and insertion.

Step 1: Support the boom

Fully lower and retract the boom. Place timber cribbing or steel trestles under the boom to support its weight independently of the lower arm cylinder. Verify the boom is stable before disconnecting any hydraulic lines. On a boom lift, the boom assembly is heavy — it must be safely supported before the cylinder that holds it is removed.

Step 2: Disconnect and extract

Disconnect the two banjo fittings and cap all ports immediately. Remove the pin retainers at both ends of the cylinder. Use a crane sling or hoist rated for at least 200 kg (cylinder weight plus tooling) to support the cylinder before removing the final pin. Extract the cylinder from the turntable — this may require rotating the turntable to align the cylinder with the extraction opening.

Step 3: Install and commission

Hoist the new GTHZ210C-620400-000 lower arm cylinder into position. Align the pin bores and insert both mounting pins. Reconnect the banjo fittings — torque to specification. Bleed the boom circuit by cycling the boom slowly from stowed to approximately 30° elevation, 5–10 times. Check the hydraulic fluid level after bleeding — the Φ100 × 1,458 mm bore holds approximately 11.4 litres of oil that must be displaced from the reservoir. Total replacement time: 4–8 hours depending on machine access and crane availability.

hydraulic-cylinder-workshop-1

Lower Arm Cylinder vs Upper Arm Cylinder — Different Roles on the Same Boom

On an articulating boom lift, two separate arm cylinders work in sequence. The lower arm cylinder raises the main boom from its turntable pivot — controlling the primary elevation. The upper arm cylinder extends from the knuckle joint, articulating the jib section to position the platform over or around obstacles. They are different cylinders with different sizes, different forces, and different failure patterns.

Boom arm hydraulic cylinder

Key distinction:
The lower arm cylinder handles the heaviest load (entire boom + platform + personnel) and has the largest bore (Φ100). The upper arm cylinder handles a lighter load (jib + platform + personnel only — no main boom weight) and uses a smaller bore. Both are critical for safe operation, but the lower arm cylinder is the more expensive replacement and the longer downtime event.

Lower Arm Cylinder — Technical Questions

The boom drifts down slowly when holding at angle — is this always the lower arm cylinder?

Not always. Boom drift can originate from the lower arm cylinder (internal piston seal bypass), from the holding valve (counterbalance valve not fully seating), or from the control valve (spool not centring properly). The diagnostic procedure is to cap the cylinder hoses at the holding valve and repeat the drift test. If the boom holds with the hoses capped, the leak is upstream (valve or control circuit). If it still drifts, the lower arm cylinder has internal bypass and needs replacement.

How long does a boom lift lower arm cylinder typically last?

Under normal operating conditions, 5,000–10,000 hours. The lower arm cylinder cycles less frequently than the steering or floating cylinders (the boom is raised and lowered a few times per work shift, not continuously), but each cycle involves very high forces and the rod is exposed to outdoor contamination for extended periods. The primary wear mechanism is not cycle count but environmental exposure — construction dust, rain, and UV degradation of the rod seal over years of outdoor service.

Can I rebuild the lower arm cylinder instead of replacing it?

If the bore and rod surfaces are in good condition, yes — but the economics are different at this cylinder size. A seal kit for a Φ100 bore cylinder costs significantly more than for smaller cylinders, and the disassembly and reassembly of a 137 kg cylinder requires workshop hoist equipment and experienced technicians. If the bore is scored or the rod chrome is damaged, the re-machining cost (re-honing a Φ100 bore + re-chroming a Φ80 rod) can approach 60–70% of a new replacement cylinder. Contact Korea Ever-Power for a new cylinder quotation before committing to a rebuild.

What equipment do I need to replace the lower arm cylinder on site?

At minimum: a mobile crane or overhead hoist rated for 200+ kg lift capacity, a sling set rated for the cylinder weight, timber cribbing or steel trestles to support the boom during removal, hydraulic hose caps or plugs, and standard hydraulic tools (torque wrench for banjo fittings, pin punch set for clevis pins). Two technicians minimum — one to guide the cylinder and one to operate the crane. Allow 4–8 hours total including bleeding and commissioning. If workshop access is available, the replacement is faster because the boom lift can be positioned under a fixed overhead crane.

Customer Reviews

Tom W.
Verified Purchase · May 2025
★★★★★

This was the biggest hydraulic cylinder I've ever handled — 137 kg is no joke. Needed a 2-tonne overhead crane to install it. But the quality is excellent: the Φ80 rod chrome was flawless, the banjo ports threaded cleanly, and the pin bores aligned perfectly with the turntable mountings on our GTHZ210C boom lift. We ran a full drift test — 450 kg on the platform, boom at 45°, held for 15 minutes with zero measurable descent. The old cylinder was leaking about 2° per hour at the same load. Massive improvement. Delivery took 4 weeks but for a cylinder this size that's reasonable.

Atlas MEWP Services GmbH
Verified Purchase · March 2025
★★★★★

We service boom lifts for construction and industrial access across Germany. The lower arm cylinder is our most expensive single-item replacement — the OEM quotes €4,500+ with 10-week lead time. The Ever-Power replacement was approximately 40% less and arrived in 25 days. We've installed 3 units on different boom models over the past 6 months, all performing at OEM level. The 25 MPa proof test certificate that comes with each cylinder satisfies our TÜV inspection requirements. This is now our standard source for lower arm cylinder replacements.

Santos R.
Verified Purchase · January 2025
★★★★☆

Good cylinder, correct dimensions, works well. Took one star for the packaging — a 137 kg cylinder arrived on a pallet with strapping, which is fine, but the rod end was protected with only a plastic cap and some tape. For a cylinder this heavy, the rod cap should be a bolted metal protection plate. The rod chrome was undamaged, so no real harm done, but during shipping a 137 kg cylinder bouncing on a pallet could easily damage an exposed rod end. Suggest upgrading the rod protection for heavy cylinders.

Pacific Heights Access Ltd
Verified Purchase · June 2025
★★★★★

We tried rebuilding a lower arm cylinder in-house once — never again. Re-honing a Φ100 bore and re-chroming a Φ80 rod cost us more in machining fees than the Ever-Power replacement costs complete. Plus we had the cylinder out of service for 5 weeks during the rebuild. Now we order the full replacement from Ever-Power, install it in a day, and send the old one for scrap metal credit. Faster, cheaper, and we get a warranty. Third lower arm cylinder we've bought from them — consistent quality every time.

Other Boom Lift Cylinders

Upper arm cylinder

Upper Arm Cylinder

Jib articulation cylinder — smaller bore, lighter load than the lower arm.

Floating cylinder

Floating & Steering Cylinders

Platform levelling and front-axle steering for boom lifts.

Scissor lift cylinders

Scissor Lift Cylinders

Lifting and steering for scissor-type aerial work platforms.

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