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جدا کننده لرزش سیم
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JGX-0958D-108A Wire Rope Vibration Isolator Pre-Validated FEA Models Reverse Engineering Support

JGX-0958D-108A Wire Rope Vibration Isolator Pre-Validated FEA Models Reverse Engineering Support

نام تجاری: Hoan
شماره مدل: JGX-0958D-108A
MOQ: 10 عدد
شرایط پرداخت: L/C، D/A، D/P، T/T، وسترن یونیون
اطلاعات جزئیات
محل منبع:
شانشی، چین
گواهی:
ISO 9001:2015, RoHS Compliant
مدل:
JGX-0958D-108A
نوع انزوا:
جدا کننده لرزش سیم
ساخت طناب سیمی:
7x19 فولاد ضد زنگ 304، قطر اسمی 6.4 میلی متر
بلوک های بستن:
آلیاژ آلومینیوم 6061-T6، روکش سخت آنودایز شده
پیکربندی سیم پیچ:
سیم پیچ مارپیچ 8 حلقه
ظرفیت بار استاتیک:
108 کیلوگرم در هر سوار (جهت فشرده سازی)
نسبت میرایی:
0.15-0.25 (وابسته به دامنه)
محدوده فرکانس طبیعی:
8-15 هرتز (وابسته به بار)
دمای عملیاتی:
-40 درجه سانتیگراد تا +200 درجه سانتیگراد مداوم
مقاومت در برابر خوردگی:
500+ ساعت نمک پاشی (ASTM B117)
نصب:
سوراخ های M10، الگوی پیچ 120 میلی متر در 80 میلی متر
وزن واحد:
تقریباً 0.85 کیلوگرم
برجسته کردن:

Pre-Validated FEA Models Available

,

Reverse Engineering Obsolete Isolators

,

Particle-Free Mechanical Dissipation

توضیحات محصول

JGX-0958D-108A Wire Rope Vibration Isolator: Engineering-Grade Vibration Control with Validated Simulation Models

What Is a Wire Rope Vibration Isolator and How Does It Work?

A wire rope vibration isolator is a passive mechanical device that attenuates vibration energy through the principle of Coulomb friction damping—dry friction generated between individual steel wire strands as the rope coil flexes under load. Unlike elastomeric (rubber) mounts that convert vibration energy into heat within the material matrix, the JGX-0958D-108A dissipates energy at the microscopic interface between its 133 individual wires (7 strands * 19 wires per strand), creating a maintenance-free, particle-free damping mechanism that does not degrade with age or temperature cycling.

The JGX-0958D-108A consists of three components: a helically wound 7*19 stainless steel 304 wire rope (6.4 mm nominal diameter, 8 active loops), upper and lower 6061-T6 aluminum alloy clamping blocks with a hard anodized surface finish, and four M10 stainless steel fastening bolts. When mounted between a vibration source and the protected structure, the wire rope coil flexes in response to input excitation, generating controlled inter-strand friction that converts kinetic energy into negligible heat while providing both stiffness (load support) and damping (energy dissipation) in a single compact element.

Pre-Validated FEA Models: Shorten Your Design Cycle by 2–3 Weeks

One of the persistent challenges in vibration isolator selection is the gap between catalog data and real-world installed performance. Static load ratings tell you whether the isolator can support the weight; they do not tell you how it will behave dynamically at your specific excitation frequency, mounting orientation, and attachment stiffness. Traditionally, closing this gap requires ordering samples, building test fixtures, running shaker table characterization, and iterating—a process that typically consumes 2–3 weeks per design cycle.

The JGX-0958D-108A addresses this with pre-validated FEA simulation models included as engineering collateral. Each model has been correlated against physical test data from a 6-DOF electrodynamic shaker table, achieving simulation-to-measurement accuracy within ±5% for these key outputs:

  • Static load-deflection curves in compression, tension, and shear loading directions
  • Dynamic stiffness (K*) and loss factor (η) as functions of excitation amplitude (0.1 mm to 2.0 mm peak-to-peak)
  • Transmissibility (T) across the 5 Hz to 500 Hz frequency range at rated load
  • Hysteresis loop shape and area—directly correlating to energy dissipation per cycle
  • Resonance amplification factor (Q) for the first three modal frequencies

These models are delivered in a format compatible with Ansys Mechanical, Abaqus, and COMSOL Multiphysics, allowing your structural dynamics team to drop the JGX-0958D-108A directly into a system-level model and evaluate isolation performance before committing to hardware procurement.

Reverse Engineering Service: A Systematic 4-Phase Methodology

When production machinery relies on vibration isolators that are no longer manufactured—because the original supplier discontinued the product line, changed their tooling, or went out of business—the equipment owner faces an unpalatable set of choices: accept degraded isolation performance from aging mounts, commission a costly custom re-design, or replace the entire machine. The JGX-0958D-108A platform offers a fourth option through its integrated reverse engineering service.

Phase 1: Metrology and Documentation (3–5 Business Days)

  • 3D laser scanning of the existing isolator to capture external envelope geometry with ±0.05 mm accuracy
  • Mounting interface measurement: bolt hole diameter, center-to-center spacing, thread specification, and counterbore depth
  • Material identification via XRF (X-ray fluorescence) analysis to determine wire rope alloy grade and clamping block composition
  • Photographic documentation of installation orientation, adjacent clearance zones, and any visible wear or corrosion patterns that inform the replacement design

Phase 2: Performance Characterization (5–7 Business Days)

  • Static load-deflection testing in all three loading axes on a universal testing machine with Class 0.5 load cell accuracy
  • Dynamic characterization on an electrodynamic shaker: swept-sine input from 5 Hz to 500 Hz, measuring transmissibility and phase angle
  • Shock response testing: half-sine pulse inputs at 15 g, 30 g, and 50 g to capture the isolator’s shock attenuation behavior
  • Hysteresis loop extraction at 0.5 mm, 1.0 mm, and 2.0 mm displacement amplitudes to quantify energy dissipation per cycle

Phase 3: FEA Correlation and Optimization (5–7 Business Days)

  • Construction of a high-fidelity FEA model tuned to match Phase 2 measurements to within ±5%
  • Parametric optimization of wire rope diameter (4.8–9.5 mm range), coil count (6–12 loops), and clamping geometry to achieve equivalent or improved performance within the same envelope
  • Fatigue life prediction using rainflow cycle counting and Miner’s rule, targeting a minimum 107 cycle endurance at rated load

Phase 4: Qualification and Delivery (10–15 Business Days)

  • Fabrication of 5 prototype JGX-0958D-108A units configured to the optimized specification
  • Back-to-back dynamic testing against the original isolator on the same shaker setup
  • Delivery of a qualification test report comparing original vs. replacement performance across all measured parameters
  • Final production run and shipment of certified replacement isolators with full material traceability documentation

Particle-Free Damping: Why Cleanroom Compatibility Changes the Selection Equation

ISO 14644-1 cleanroom classifications impose strict limits on airborne particulate concentration. A single elastomeric vibration mount in a Class 5 (ISO 5 / FED STD 209E Class 100) semiconductor fab can shed enough microscopic rubber particles over its 3–5 year service life to trigger particle count excursions during routine environmental monitoring. Wire rope isolators eliminate this failure mode at the component level.

The JGX-0958D-108A’s damping mechanism is purely mechanical: as the 133 individual stainless steel wires within the 7*19 rope construction slide against one another during flexure, they generate controlled friction without abrasion, without shedding, and without requiring lubrication. There are no elastomeric elements, no adhesive bonds, no coatings that can delaminate, and no organic materials that can outgas in vacuum environments. The hard anodized surface on the 6061-T6 aluminum clamping blocks provides wear resistance without generating aluminum oxide dust. This makes the JGX-0958D-108A suitable for:

  • Semiconductor manufacturing: Wafer steppers, CMP (chemical mechanical planarization) tools, ion implanters, and lithography track systems where sub-0.1 μm particle contamination can cause die yield loss
  • Pharmaceutical production: Aseptic filling isolators, lyophilizer tray stacks, tablet press vibration isolation, and clean-in-place (CIP) system mounts exposed to repeated washdown cycles
  • Optics and photonics: Laser interferometer tables, optical coating chambers, fiber optic draw towers, and telescope mount isolation where particulate settling on optical surfaces degrades transmission and increases stray light
  • Electron microscopy: SEM and TEM column isolation where vibration-induced image blur and particle-induced column contamination both degrade resolution
  • Precision metrology: Coordinate measuring machine (CMM) granite base isolation, roundness testers, surface profilometers, and gauge block calibration stations

JGX-0958D-108A Complete Technical Specification

Parameter Value Test Standard
Model Number JGX-0958D-108A
Isolator Type Wire Rope Vibration Isolator, Helical Coil
Wire Rope Construction 7 * 19 (7 strands, 19 wires per strand = 133 wires) ISO 2408
Wire Rope Material AISI 304 (UNS S30400) Stainless Steel ASTM A313
Wire Rope Diameter 6.4 mm ± 0.15 mm ISO 2408
Individual Wire Diameter 0.28 mm (center) + 0.26 mm (inner layer) + 0.22 mm (outer layer)
Clamping Block Material 6061-T6 Aluminum Alloy ASTM B211
Clamping Block Surface Hard Anodized, 25–50 μm thickness, 350–400 HV hardness MIL-A-8625 Type III
Active Coils 8 loops, symmetric helical winding
Rated Load – Compression (Z-axis) 108 kg (1,059 N)
Rated Load – Shear (X/Y-axis) 54 kg (530 N) per axis
Rated Load – Tension (Z-axis) 36 kg (353 N)
Static Deflection at Rated Load 2.5–3.5 mm (compression), 4.0–5.5 mm (shear)
Dynamic Stiffness (K*) at 0.5 mm, 20 Hz 380–420 N/mm (compression), 120–150 N/mm (shear) ISO 10846-2
Loss Factor (η) at 0.5 mm, 20 Hz 0.18–0.25 ISO 10846-2
Damping Type Coulomb (dry friction), amplitude-dependent
Natural Frequency at Rated Load 9.5–12.5 Hz (compression), 7.5–10.0 Hz (shear)
Resonance Amplification (Q) ≤4 (at resonance, compression mode)
Transmissibility at 25 Hz 0.25–0.35 (–12 to –9 dB isolation)
Transmissibility at 50 Hz 0.08–0.12 (–22 to –18 dB isolation)
Shock Attenuation (30 g, 11 ms half-sine) Peak response ≤15 g (attenuation ≥50%) IEC 60068-2-27
Operating Temperature Range -40°C to +200°C
Salt Spray Resistance 500+ hours, no red rust (passivated SS304) ASTM B117
Endurance Life ≥1 * 107 cycles at rated load, 10 Hz, ±1.5 mm
Mounting Bolts M10 * 1.5 mm pitch, A2-70 Stainless Steel (4 bolts) ISO 898-1
Bolt Torque 35–40 N·m
Mounting Pattern 120 mm * 80 mm (length * width, center-to-center)
Overall Dimensions 140 mm (L) * 95 mm (W) * 65 mm (H) ± 1.0 mm
Unit Mass 0.85 kg ± 0.03 kg
Certifications ISO 9001:2015, RoHS 2011/65/EU

How Does the JGX-0958D-108A Compare to Elastomeric Isolators?

Property JGX-0958D-108A Wire Rope Typical Elastomeric (NBR/CR) Mount
Damping mechanism Coulomb friction (inter-wire) Viscoelastic hysteresis (molecular)
Service life at 25°C 15+ years (no degradation) 3–5 years (oxidative aging)
Temperature range -40°C to +200°C -20°C to +80°C (typical)
Stiffness drift over 5 years ≤2% +15–40% (progressive hardening)
Damping drift over 5 years ≤3% -20–50% (loss of damping)
Oil and chemical resistance Excellent (SS304 + anodized Al) Poor to moderate (solvent swelling)
UV and ozone resistance Immune (all-metal) Poor (surface cracking)
Particulate generation Zero Moderate (rubber abrasion dust)
Outgassing in vacuum None (all-inorganic) Significant (plasticizers, cure residuals)
Fire resistance Non-flammable (melting point >1,400°C) Combustible (auto-ignition ~350°C)
End-of-life disposal 100% metal recycling (revenue) Mixed waste incineration/landfill (cost)
Damping at small amplitude (<0.1 mm) Lower (stiffer response) Higher (softer response)
Damping at large amplitude (>1.0 mm) Higher (friction activation) Lower (material saturation)

Frequently Asked Questions

What does the model number JGX-0958D-108A mean? The “JGX" prefix identifies the manufacturer’s wire rope isolator product family. “0958" is the size and configuration code for this envelope class. “D" designates the dual-clamp mounting configuration (two aluminum blocks capturing the wire rope coil). “108" is the rated compression load in kilograms. The “A" suffix indicates the standard configuration with SS304 wire rope and 6061-T6 aluminum blocks.

Can I use the FEA model with my existing simulation software? The pre-validated FEA models are delivered in a neutral file format importable into Ansys Mechanical (v2021 R2+), Abaqus (6.14+), COMSOL Multiphysics (5.6+), and Nastran (via bulk data deck). If your team uses a different solver, contact our applications engineering group for format conversion support.

What is the minimum information needed to start a reverse engineering project? We need the existing isolator’s envelope dimensions (a photograph with a scale reference is often sufficient for initial assessment), an estimate of the supported mass, and the dominant vibration frequency or operating speed of the machine. From these three inputs, our applications team can scope the project and provide a firm quotation within 2 business days.

Does the hard anodized surface wear off over time? The Type III hard anodize layer is 25–50 μm thick with a Vickers hardness of 350–400 HV. In normal industrial service, the clamping block surface that contacts the wire rope experiences negligible wear because the rope-to-block interface is static (no sliding motion)—all damping motion occurs within the wire rope coil itself.