Overview: Excavator Blade for Global Markets

INDUSTRIAL SPECIFICATION REPORT 2026

PRODUCT: Heavy-Duty Excavator Blade Assembly (Model: SL-HDB-750)
ISSUING AUTHORITY: SEA LION International Trade Co., Ltd. Engineering Division

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EXECUTIVE OVERVIEW

The SL-HDB-750 excavator blade represents a critical operational component engineered for extreme-duty applications across mining, bulk material handling (logistics), and large-scale earthmoving (construction). Validated through 18,000+ field hours in Tier-1 mining operations, this assembly delivers 22% longer service life versus industry benchmarks in high-abrasion environments (e.g., iron ore overburden, laterite clay, and crushed aggregate handling). Its modular design reduces changeout time by 35% compared to monolithic alternatives, directly minimizing fleet downtime—a decisive factor in high-utilization projects where operational continuity dictates project economics.

Regional market preference in Africa, Russia, and Southeast Asia is driven by three validated technical differentiators:

Region	Primary Application	Key Technical Advantage	Operational Impact
Africa	Open-pit mining (bauxite, copper)	AR450-grade wear plate + corrosion-resistant coating (ISO 9227:2017 Class 3)	40% reduction in blade replacement frequency in high-humidity, acidic soil conditions
Russia	Arctic logistics (frozen ore handling)	-40°C impact-tested manganese steel (GOST 19281-2014 compliant)	Zero brittle fracture incidents in Siberian winter operations (-35°C avg)
Southeast Asia	Flood-control infrastructure	Quick-coupler compatibility (SAE J2026) + variable pitch geometry	30% faster transition between dredging/embankment tasks on congested urban sites

SEA LION International’s 18-year specialization in heavy equipment export ensures this component aligns with the reliability expectations of SINOTRUK, SHACMAN, and XCMG platform operators. The SL-HDB-750’s standardized interface guarantees seamless integration with 95% of 30-50 ton class excavators deployed across target regions. Crucially, our global logistics infrastructure (RO-RO/Container) and certified refurbishment program enable 72-hour blade replacement cycles in remote operational zones—eliminating supply chain bottlenecks that typically incur $18,500/day in idle equipment costs. For fleet managers, this translates to quantifiable TCO reduction: 17% lower cost-per-cubic-meter moved versus non-optimized alternatives in 12-month lifecycle analysis.

SEA LION prioritizes long-term partnership through transparent specification adherence and component traceability. The SL-HDB-750 is not merely a consumable; it is a validated productivity multiplier for operations where terrain severity defines operational viability.

Technical Specifications & Parameters

Industrial Specification Report 2026

Prepared for Fleet Managers & Construction Companies
Component: Excavator Blade Assembly – Heavy-Duty Configuration

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This technical specification report outlines the core performance and mechanical attributes of the excavator blade system integrated into SEA LION International’s next-generation heavy-duty excavator platforms. Designed for high-cycle earthmoving, trenching, and grading applications in rugged terrain, the blade system is engineered for durability, precision, and fuel-efficient operation under sustained load.

The following table details the integrated powertrain and undercarriage specifications directly influencing blade performance, including engine output, transmission dynamics, load distribution, and tire compatibility.

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Technical Specifications – Excavator Blade System (2026 Model Series)

Parameter	Specification	Notes
Engine Model	WD615 (Weichai Power)	6-cylinder, inline, water-cooled diesel; Euro Stage V compliant
Engine Displacement	9.726 L	Optimized for high torque at low RPM
Rated Horsepower	290 hp @ 2,200 rpm	SAE J1995 gross power rating
Peak Torque	1,160 N·m @ 1,400–1,600 rpm	Enables rapid blade penetration and push force
Transmission	HW19710 – 10F/2R Synchromesh Manual	Heavy-duty gearbox with reinforced synchronizers; compatible with load-sensing hydraulics
Axle Load (Front)	8,500 kg (18,739 lbs)	Rated for full bucket + blade load; includes counterweight balance
Axle Load (Rear)	12,300 kg (27,117 lbs)	Driven axle with limited-slip differential
Tire Specifications	12.00R20, 20-ply (Load Range G), Radial	Off-road tread (E-4), cut- and wear-resistant compound; dual-fitment standard
Tire Inflation Pressure	75 psi (5.17 bar) – Loaded; 65 psi (4.48 bar) – Transport	Adjustable via central inflation system (optional)
Blade Type	Straight (S-Blade), Replaceable Cutting Edge	3.2 m width, 600 mm height; AR450 steel construction
Push Force (Max)	185 kN	Hydraulic cylinder-assisted; dual-ram configuration
Fuel Efficiency	18.3 L/h (avg. under 75% load)	Measured per ISO 9249; 5–8% improvement over 2023 baseline due to Weichai ECU tuning and reduced parasitic loss
Load Capacity (Blade)	3.8 m³ (loose material)	Based on ISO 7457; dependent on soil density and slope angle

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Fuel Efficiency Analysis

The WD615 engine, equipped with high-pressure common rail (HPCR) injection and variable geometry turbocharging (VGT), delivers optimized combustion efficiency across operational ranges. Real-world field data from 2025 pilot units indicates:

• Average fuel consumption: 16.7–19.4 L/h under mixed grading and trench backfill operations.
• Idle fuel savings: Auto-idle function reduces consumption by up to 15% during non-productive cycles.
• Eco-mode operation: Reduces engine speed to 1,900 rpm while maintaining 92% of hydraulic responsiveness, improving fuel economy by 7–10%.

The HW19710 transmission contributes to efficiency through precise gear engagement and minimal slippage, reducing drivetrain losses by approximately 4% compared to previous-generation synchromesh units.

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Load Capacity & Operational Performance

The excavator blade is engineered for maximum material displacement in compact to mid-size excavation fleets. Key load-related features include:

• Structural reinforcement: Blade frame integrates with main chassis via torsion-resistant box-section weldments.
• Dynamic load distribution: Front axle load is actively monitored via onboard sensors (standard on 2026 models), alerting operators to overloading conditions.
• Tire performance: The 12.00R20 radial tires provide a 30% larger footprint than bias-ply equivalents, reducing ground pressure to 0.85 kg/cm² under full load—critical for operation on soft or sensitive terrain.

Field testing confirms the system maintains blade accuracy and push force over 10,000+ hours with scheduled maintenance, including cutting edge replacement every 800–1,200 hours depending on abrasiveness of material.

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Conclusion: The 2026 excavator blade system, powered by the Weichai WD615 and mated to the HW19710 transmission, delivers a balanced profile of high load capacity, robust durability, and improved fuel efficiency. Ideal for fleet deployment in infrastructure, mining, and large-scale civil projects, this configuration supports lower TCO (Total Cost of Ownership) through extended service intervals and reduced fuel consumption.

Quality Control & Inspection Standards

SEA LION INTERNATIONAL

INDUSTRIAL SPECIFICATION REPORT: EXCAVATOR BLADE ASSEMBLY
REPORT ID: SL-EXB-QC-2026-001
EFFECTIVE DATE: 01 JANUARY 2026

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1. EXECUTIVE SUMMARY

This report details the manufacturing quality control (QC) protocols and Pre-Delivery Inspection (PDI) standards for SEA LION International excavator blades (Models EXB-20T to EXB-45T). Specifications address structural integrity under high-stress operational profiles, with explicit focus on chassis reinforcement for rough-terrain durability and powertrain compatibility. Data validates compliance with ISO 10218-1:2023 and SAE J1099.

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2. MANUFACTURING QUALITY CONTROL: CHASSIS & BLADE INTEGRATION

2.1. Structural Chassis Reinforcement

Chassis components undergo multi-stage hardening to withstand dynamic loads exceeding ISO 10218 operational limits. Key processes:

Parameter	Specification	Test Method	Acceptance Criteria
Base Material	ASTM A514 Grade F Steel (Quenched & Tempered)	Mill Cert + Spectro	Yield: ≥ 100 ksi (690 MPa)
Critical Weld Joints	Double-V Groove, Submerged Arc Welding (SAW)	Destructive Test (ASTM E8)	Min. Tensile: 750 MPa
Fatigue Life (Cycles)	500,000 cycles @ 120% rated load	FEA + Physical Rig Test (SAE J1099)	ΔStress ≤ 15% from baseline
Hardness Profile	380–420 HBW (Cutting Edge)	ASTM E10	Uniformity ±15 HBW across edge

Note: All chassis forgings utilize robotic welding with real-time X-ray monitoring (ISO 17636-2). Post-weld stress relief at 620°C ±10°C for 2 hours.

2.2. Abrasion Resistance & Edge Durability

Blade cutting edges employ AR400 steel with tungsten carbide inserts for high-abrasion environments:

Component	Hardness (HBW)	Impact Toughness (J @ -20°C)	Service Life (hrs)
Base Blade	400–440	≥ 27	1,800–2,200
Carbide Inserts (Tip)	1,500–1,800	N/A	3,000+
Wear Strip (Optional)	450–500	≥ 20	2,500–3,000

Validation: Accelerated wear testing per ASTM G65 (500 cycles @ 250 rpm, silica sand medium).

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3. POWERTRAIN DURABILITY INTEGRATION

3.1. Engine & Hydraulic System Compatibility

Blade operation directly impacts engine/transmission longevity. SEA LION blades are engineered to minimize parasitic load:

• Hydraulic Pressure Management: Blade curl/tilt circuits feature pressure-compensating valves (max. 5,060 psi / 350 bar) to prevent hydraulic shock during rock impact.
• Torque Load Reduction: Optimized blade geometry reduces peak torque demand by 18% vs. industry benchmark (verified via SAE J748 dynamometer testing).
• Cooling System Synergy: Blade PDI includes verification of hydraulic oil cooler bypass circuits to maintain engine coolant temps ≤ 105°C under continuous high-load cycling.

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4. PRE-DELIVERY INSPECTION (PDI) PROTOCOLS

4.1. Structural Integrity Verification

All units undergo 100% inspection prior to shipment:

Inspection Point	Method	Critical Failure Threshold
Chassis Weld Integrity	Ultrasonic Testing (ASTM E1961)	Porosity > 2% area; Cracks > 1.5 mm
Blade Alignment	Laser Theodolite (±0.5 mm tolerance)	Misalignment > 3 mm at pivot
Pin/Bushing Clearance	Dial Indicator Measurement	> 1.2 mm radial play
Hardness Verification	Portable Rockwell Tester (5 points)	Deviation > 20 HBW from spec

4.2. Operational Load Testing

Simulated rough-terrain validation (per ISO 10218 Annex B):

1. Dynamic Impact Test: 200 cycles of full-stroke blade penetration into compacted gravel (30% rock content).
2. Pass Criteria: Zero chassis deformation (>0.5 mm); hydraulic pressure spikes ≤ 10% nominal.
3. Continuous Load Test: 60 minutes at 110% rated load (curl/tilt).
4. Pass Criteria: Engine coolant temp stability (±5°C); no hydraulic fluid aeration.

4.3. Documentation Requirements

• Mill certificates for all structural steel (traceable to heat number)
• Weld procedure specification (WPS) and welder qualification records
• FEA validation report for customer-specified terrain profile (e.g., quarry, trenching)
• PDI checklist signed by certified QA technician (SEA LION Form QC-EXB-2026)

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5. CONCLUSION

SEA LION excavator blades achieve 22% higher fatigue life in rough-terrain applications versus ISO 10218 minimums, validated through accelerated field testing across 12 global sites. The integrated chassis-engine design reduces unplanned powertrain maintenance by 31% (based on 2025 fleet data). Strict adherence to the outlined QC and PDI protocols ensures operational readiness for high-utilization construction and mining environments.

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SEA LION International reserves the right to update specifications without notice. All data reflects standard production units; custom configurations subject to additional validation.
END OF REPORT

Shipping & Logistics Solutions

Industrial Specification Report 2026

Prepared for: Fleet Managers & Construction Companies
Subject: Logistics Solutions for Exporting Excavator Blades from China
Prepared by: SEA LION International – Senior Engineering Division
Date: April 5, 2026

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Executive Summary

This report evaluates three primary maritime transport methods—RO-RO (Roll-on/Roll-off), Bulk Cargo, and Flat Rack container shipping—for the export of excavator blades from manufacturing hubs in China (e.g., Xuzhou, Shandong, and Guangdong) to global construction markets. The analysis includes technical feasibility, cost-efficiency, handling requirements, and corrosion protection protocols, with specific emphasis on wax spraying as a preventive measure against seawater-induced degradation.

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Product Overview: Excavator Blade

Parameter	Specification
Material	High-strength low-alloy (HSLA) steel
Average Weight	800–2,500 kg per unit
Dimensions (L×W×H)	2.2 m × 1.0 m × 0.3 m (avg.)
Corrosion Risk	High (exposed steel, marine exposure)
Packaging Requirement	Wax-sprayed + shrink-wrapped
Handling Equipment	Forklift, crane, pallet jack

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Shipping Method Comparison

Criteria	RO-RO (Roll-on/Roll-off)	Bulk Cargo	Flat Rack Container
Loading Mechanism	Self-propelled or towed via ramps	Loosely stowed in hold	Secured onto open-sided container frame
Suitability for Blades	Moderate (if mounted on carrier)	Low (risk of shifting/damage)	High (secure, fixed positioning)
Protection from Elements	Limited (exposed decks)	Poor (direct hold exposure)	Good (weather cover optional)
Corrosion Risk	High (direct salt spray exposure)	Very High (humidity, condensation)	Moderate (with wax + tarpaulin)
Handling Efficiency	High (fast roll-on/off)	Low (requires grab/crane)	High (crane lift, secure lashings)
Cost (USD/unit)	$420–$580	$350–$480	$500–$650
Transit Time (China–EU)	28–35 days	30–40 days	26–33 days
Insurance Risk Rating	Medium	High	Low to Medium
Port Infrastructure	Requires RO-RO terminal	Standard bulk terminal	Standard container terminal
Stackability	Not stackable	Not applicable	Single layer only
Security	Moderate (open access)	Low (commingled cargo)	High (sealed, containerized)

Note: Pricing reflects Q1 2026 market averages for 40ft equivalent unit (TEU) or per-trip cost allocation.

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Corrosion Protection Protocol: Wax Spraying

To mitigate seawater-induced corrosion during transit, industrial-grade rust preventive wax spraying is strongly recommended for all export shipments.

Wax Spraying Specifications

Parameter	Requirement
Wax Type	Solvent-based, hydrophobic, self-healing
Coating Thickness	25–35 µm (microns)
Application Method	Automated spray booth or handheld nozzles
Drying Time	4–6 hours (ambient 25°C)
Coverage Area	Full blade surface, including edges
Salt Spray Test (ASTM B117)	>500 hours resistance
Post-Transit Removal	Biodegradable solvent wash or steam

Benefits:
– Forms hydrophobic barrier against chlorides and moisture
– Withstands temperature fluctuations (−10°C to +50°C)
– Compatible with steel substrates and common primers
– Non-toxic and compliant with IMO maritime safety standards

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Recommended Method: Flat Rack Container

Based on technical evaluation, Flat Rack containers are the optimal solution for excavator blade exports due to:

1. Structural Security: Blades are firmly lashed to a rigid frame, minimizing in-transit movement.
2. Environmental Protection: When combined with wax spraying and tarpaulin covers, corrosion risk is significantly reduced.
3. Global Interoperability: Compatible with standard container ports, rail, and inland logistics networks.
4. Traceability & Security: Containerized units allow for GPS tracking and tamper-evident seals.

RO-RO is viable only if blades are shipped as part of assembled machinery.
Bulk Cargo is not recommended due to high damage and corrosion risk.

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Operational Recommendations

1. Pre-Shipment Protocol:
2. Conduct surface degreasing prior to wax application.
3. Apply wax within 2 hours of final machining/packaging.

4. Use desiccant packs inside shrink wrap for added moisture control.

5. Loading & Lashing:

6. Secure blades using calibrated tension straps (min. 5,000 kg break load).

7. Position on timber dunnage to prevent direct steel-to-steel contact.

8. Documentation:

9. Include wax application certificate in shipping dossier.
10. Specify handling code “FORK-LIFT ONLY – BOTTOM ACCESS” on container labels.

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Conclusion

For reliable, corrosion-resistant export of excavator blades from China, Flat Rack container shipping with industrial wax spraying represents the most technically sound and logistically efficient solution. This method ensures structural integrity, regulatory compliance, and long-term asset preservation—critical for fleet managers and construction firms managing large-scale equipment procurement.

SEA LION International recommends integrating wax protection into OEM packaging standards and selecting logistics partners with certified Flat Rack handling capabilities.

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End of Report