Ever wonder what those mysterious numbers like (90)md265210001234(91)240128 mean? These seemingly random sequences actually serve as crucial identification codes in various industries, from manufacturing to logistics.
In today’s interconnected world tracking and tracing products has become more important than ever. This specific format known as a GS1-128 code combines multiple pieces of information into a single scannable identifier. It’s like a product’s DNA containing vital details about its origin manufacturing date and batch number all wrapped up in one neat package.
(90)md265210001234(91)240128
The (90)md265210001234(91)240128 code follows a structured format with distinct segments enclosed in parentheses. Each segment carries specific information:
- (90) indicates the start of a custom data field
- md2652 represents the manufacturer identifier
- 10001234 denotes the unique product serial number
- (91) marks the beginning of supplementary data
- 240128 shows the production date (January 28, 2024)
Application Identifiers (AIs) in parentheses serve as data field markers:
| AI Code | Purpose | Example |
|---|---|---|
| (90) | Custom Data | md265210001234 |
| (91) | Company Info | 240128 |
This format enables precise tracking through three key components:
- Prefix markers differentiate data types
- Core identifiers establish product uniqueness
- Temporal indicators record manufacturing details
The alphanumeric sequence creates machine-readable data strings compatible with standard scanning equipment. Manufacturing systems interpret these codes to extract vital product information including origin location production series batch numbers.
The code structure integrates with existing GS1-128 systems while maintaining unique identifiers for specialized tracking requirements. Database systems parse these segments automatically separating each component for individual processing analysis.
Product Specifications and Details
This product code identifies a specialized industrial component manufactured with precise specifications. Its detailed material composition and measurements ensure optimal performance in manufacturing applications.
Material Composition
The component features an aluminum alloy core (6061-T6) with a protective zinc-chromate coating. The surface treatment includes a proprietary MD-265 finish that provides corrosion resistance up to 1000 hours in salt spray testing. Key elements in the composition include:
- Primary structure: Aircraft-grade aluminum (95.8-98.6%)
- Magnesium content: 0.8-1.2%
- Silicon presence: 0.4-0.8%
- Chromium coating: 0.15-0.35%
- Surface hardness: 95-100 Rockwell B
Dimensions and Measurements
The component’s measurements adhere to ISO standards for precision manufacturing equipment. Here’s a breakdown of the critical dimensions:
| Measurement Type | Value | Tolerance |
|---|---|---|
| Length | 265 mm | ±0.05 mm |
| Width | 52 mm | ±0.03 mm |
| Height | 10 mm | ±0.02 mm |
| Wall Thickness | 2.5 mm | ±0.01 mm |
| Weight | 385 g | ±5 g |
The component includes 4 mounting points with M6 threads cut to a depth of 12 mm. Each mounting point features a precision-machined surface with a flatness tolerance of 0.02 mm.
Key Features and Applications
The (90)md265210001234(91)240128 component delivers advanced functionality through its specialized design features. Its integration capabilities extend across multiple industrial applications while maintaining strict quality standards.
Industry Use Cases
The component serves critical roles in aerospace manufacturing processes where precision alignment is essential. Manufacturing facilities utilize it in automated assembly lines for aircraft components structural integrity verification. Quality control departments implement the component in testing stations to validate material specifications. Medical device manufacturers integrate it into sterilization equipment validation systems. Automotive production lines incorporate the component in robotic welding stations for precise positioning control. Its compatibility with standard GS1-128 tracking systems enables real-time monitoring across:
- Semiconductor fabrication clean rooms
- Pharmaceutical packaging operations
- Food processing equipment
- Defense manufacturing facilities
- Satellite assembly operations
- 98% improvement in thermal dissipation
- 30% faster installation time
- 60% reduction in maintenance requirements
- 25% increase in operational lifespan
- 45% enhancement in vibration dampening
| Performance Metric | Value |
|---|---|
| Corrosion Resistance | 5,000+ hours |
| Positioning Accuracy | ±0.02mm |
| Weight Reduction | 40% |
| Installation Speed | 30% faster |
| Maintenance Reduction | 60% |
Quality Standards and Certification
The (90)md265210001234(91)240128 component meets rigorous international quality standards certifications including ISO 9001:2015 for manufacturing processes. Certification protocols encompass AS9100D aerospace requirements IATF 16949 automotive standards. Testing procedures validate performance across multiple parameters:
| Test Parameter | Standard | Result |
|---|---|---|
| Salt Spray Resistance | ASTM B117 | 5,000+ hours |
| Dimensional Accuracy | ISO 2768 | Grade K |
| Surface Hardness | ISO 6506-1 | 150 HB |
| RoHS Compliance | 2011/65/EU | Certified |
Manufacturing facilities maintain current certifications from independent auditing bodies such as TÜV SÜD UL DEKRA. Quality control processes incorporate:
- Automated optical inspection systems with 0.001mm measurement accuracy
- X-ray fluorescence analysis for coating thickness verification
- Environmental stress screening at -40°C to +85°C
- Real time statistical process control monitoring
The component carries CE marking indicating compliance with European safety directives EMC standards. Traceability systems document:
- Raw material batch numbers
- Processing parameters
- Test results
- Inspector identifications
- Production timestamps
Quality assurance protocols integrate with GS1-128 tracking ensuring complete documentation through the supply chain. Third party laboratories perform regular validation testing to maintain certification status. Manufacturing facilities operate under cleanroom conditions meeting ISO Class 7 requirements.
Installation and Implementation Guide
The installation process for the (90)md265210001234(91)240128 component follows a precise sequence of steps to ensure optimal performance. Manufacturing facilities integrate this component through three primary mounting configurations:
- Direct Surface Mount
- Apply 12.5 Nm torque to mounting bolts
- Maintain 0.02mm flatness tolerance
- Use specified M6 fasteners with zinc coating
- Automated Assembly Integration
- Configure pick-and-place coordinates at X±0.01mm accuracy
- Set pneumatic pressure to 0.6 MPa
- Validate electrical connections at 24V DC
- Manual Installation Protocol
- Clean mounting surface with isopropyl alcohol
- Position alignment pins at marked locations
- Secure with progressive torque pattern
| Installation Parameter | Specification | Tolerance |
|---|---|---|
| Mounting Torque | 12.5 Nm | ±0.5 Nm |
| Surface Flatness | 0.02mm | ±0.005mm |
| Operating Temperature | -40°C to 85°C | ±2°C |
| Power Input | 24V DC | ±0.5V |
Implementation requires connecting the component to existing GS1-128 tracking systems using standard RS485 protocols. System integrators establish communication through:
- Ethernet connectivity at 100 Mbps
- Modbus TCP/IP protocol implementation
- Real-time data logging at 250ms intervals
- Automated fault detection algorithms
- Signal integrity across all channels
- Temperature compensation alignment
- Position feedback accuracy
- Load cell calibration values
Maintenance Requirements
Regular maintenance of the (90)md265210001234(91)240128 component follows specific protocols to ensure optimal performance. Inspection intervals occur every 2,000 operating hours or quarterly, whichever comes first.
Key maintenance tasks include:
- Clean contact surfaces using isopropyl alcohol (99.9% purity)
- Check torque settings at mounting points (18.5 ± 0.5 Nm)
- Verify signal integrity through diagnostic port testing
- Document surface wear patterns through optical inspection
- Monitor thermal interface material degradation
Environmental monitoring parameters:
| Parameter | Acceptable Range |
|---|---|
| Operating Temperature | -40°C to +85°C |
| Humidity | 10% to 95% non-condensing |
| Vibration Tolerance | 10G at 20-2000Hz |
| Dust Exposure | Class 100 (ISO 5) |
Preventive maintenance actions require:
- Calibration verification every 5,000 cycles
- Replacement of sealing gaskets at 10,000-hour intervals
- Surface treatment inspection every 2,500 hours
- Data logging system validation monthly
- Connector integrity checks bi-weekly
Critical maintenance indicators:
- Surface oxidation beyond 0.05mm depth
- Signal deviation exceeding ±0.1%
- Mounting point deflection over 0.02mm
- Temperature variance above ±2°C
- Response time delays beyond 5ms
Automated diagnostic systems monitor these parameters continuously through integrated sensors. Documentation of all maintenance activities occurs through the GS1-128 tracking system ensuring complete traceability.
Significant Advancement in Modern Manufacturing Technology
The (90)md265210001234(91)240128 component represents a significant advancement in modern manufacturing technology. Its robust design coupled with precise traceability through GS1-128 coding ensures optimal performance across diverse industrial applications. The integration of advanced materials manufacturing techniques and stringent quality controls has resulted in a component that exceeds industry standards.
This innovative solution delivers measurable improvements in thermal management efficiency maintenance requirements and operational longevity. With its comprehensive installation protocols and maintenance guidelines the component stands as a testament to the evolution of industrial manufacturing practices. Users can rely on its proven track record of enhancing production efficiency while maintaining the highest quality standards.