Inquire: Call 0086-755-23203480, or reach out via the form below/your sales contact to discuss our design, manufacturing, and assembly capabilities.
Quote: Email your PCB files to Sales@pcbsync.com (Preferred for large files) or submit online. We will contact you promptly. Please ensure your email is correct.
Notes: For PCB fabrication, we require PCB design file in Gerber RS-274X format (most preferred), *.PCB/DDB (Protel, inform your program version) format or *.BRD (Eagle) format. For PCB assembly, we require PCB design file in above mentioned format, drilling file and BOM. Click to download BOM template To avoid file missing, please include all files into one folder and compress it into .zip or .rar format.
IPC-9504: Preconditioning & Process Simulation Guide for Non-IC Components
Here’s a scenario that plays out more often than anyone likes to admit: you’ve qualified a new passive component supplier, run incoming inspection, everything checks out—then three months later, you’re seeing field failures on assemblies using those parts. The root cause? Those components couldn’t actually survive your soldering process, but nobody tested for that specifically.
This is exactly the problem IPC-9504 was designed to solve. Officially titled “Assembly Process Simulation for Evaluation of Non-IC Components (Preconditioning Non-IC Components),” this standard provides the test methodology to verify that passive components will survive your manufacturing processes without reliability degradation. If you’re qualifying capacitors, resistors, inductors, or any non-IC component for production, IPC-9504 is the standard that tells you how to simulate your factory conditions and evaluate whether those parts will hold up.
IPC-9504 establishes standardized manufacturing process simulations for evaluating non-IC electronic components. Published by IPC in June 1998, this 27-page standard provides a systematic approach to answer one fundamental question: will these components work with your process?
The standard defines preconditioning sequences that simulate real-world factory conditions including moisture exposure, thermal stress from soldering operations, chemical exposure from fluxes, and cleaning processes. By subjecting components to these controlled simulations before reliability testing or production use, you can identify process compatibility issues before they become field failures.
The Core Objective of IPC-9504
The primary purpose of IPC-9504 is straightforward: ensure that passive components meet expected reliability requirements after exposure to factory assembly processes. This isn’t about optimum assembly conditions—it’s about survivability. The standard helps you determine:
Can these components handle your reflow profile without damage?
Will wave soldering cause thermal shock failures?
Do the components tolerate exposure to your flux chemistry?
Will cleaning processes degrade component performance?
Without this type of qualification testing, you’re essentially gambling that components will survive processes they were never specifically validated against.
IPC-9504 vs IPC-9501: Understanding the Key Differences
One of the most common points of confusion is the relationship between IPC-9504 and IPC-9501. Both standards address assembly process simulation, but they target fundamentally different component types.
Component Scope Comparison
Aspect
IPC-9501
IPC-9504
Target Components
Integrated circuits (ICs)
Non-IC components (passives)
Package Types
Plastic IC packages, BGAs, QFPs
Capacitors, resistors, inductors, connectors
Failure Modes
Die attach delamination, wire bond damage, popcorning
Cracking, parameter drift, termination damage
Related MSL Standard
J-STD-020
IPC-9503
Publication Date
July 1995
June 1998
Why Separate Standards Exist
Integrated circuits and passive components have fundamentally different constructions and failure mechanisms. An IC package contains semiconductor die, wire bonds, die attach material, and mold compound—all of which respond differently to thermal and moisture stress compared to, say, a multilayer ceramic capacitor or a wound inductor.
IPC-9504 was developed specifically because the test vehicles, thermal profiles, and evaluation criteria needed for passive components differ from those appropriate for ICs. A ceramic capacitor doesn’t have wire bonds to damage, but it can experience thermal shock cracking. A tantalum capacitor won’t delaminate like a plastic IC package, but moisture can affect its dielectric properties.
Components Covered by IPC-9504
IPC-9504 applies to a broad range of non-IC electronic components used in PCB assembly. The standard is intentionally comprehensive to cover the diversity of passive component technologies.
Primary Component Categories
Component Type
Examples
Key Process Concerns
Ceramic Capacitors
MLCCs, disc capacitors, chip caps
Thermal shock cracking, flex cracking
Film Capacitors
Polyester, polypropylene, PPS
Temperature limits, moisture absorption
Electrolytic Capacitors
Tantalum, aluminum polymer
MSL sensitivity, parameter shift
Resistors
Chip resistors, networks, potentiometers
Termination damage, value drift
Inductors
Chip inductors, power inductors, beads
Core damage, winding damage
Transformers
SMD transformers, pulse transformers
Insulation breakdown, delamination
Connectors
SMD connectors, headers
Housing damage, contact degradation
Crystals/Oscillators
Crystal units, ceramic resonators
Frequency shift, seal damage
Thermistors
NTC, PTC devices
Resistance drift, cracking
Filters
EMI filters, LC filters
Parameter degradation
The standard applies to both surface-mount (SM) and through-hole (TH) components, covering reflow soldering, wave soldering, and hand soldering applications.
IPC-9504 Preconditioning Test Procedures
The heart of IPC-9504 lies in Section 10, which defines the specific preconditioning test procedures. These procedures simulate the environmental and process exposures components experience during storage and assembly.
Preconditioning Flow Overview
The IPC-9504 preconditioning sequence follows a structured flow designed to replicate worst-case manufacturing conditions:
Step
Procedure
Purpose
1
Initial Inspection
Baseline visual and electrical verification
2
Moisture Exposure
Simulate storage and handling conditions
3
Component Placement Simulation
Replicate pick-and-place thermal stress
4
Soldering Process Exposure
Reflow or wave solder thermal simulation
5
Chemical Exposure
Flux and cleaning agent compatibility
6
Final Evaluation
Post-process inspection and electrical test
Moisture Exposure Simulation
Moisture preconditioning simulates the humidity exposure components experience during storage and factory floor handling. The procedure involves:
Temperature and Humidity Conditions: Components are exposed to controlled temperature and humidity environments based on their target moisture sensitivity level. Typical conditions include 30°C/60% RH for specified durations matching floor life requirements.
Soak Duration: The moisture soak time depends on the MSL classification being simulated. For example, MSL 3 components would be soaked for 168 hours (7 days) at 30°C/60% RH to simulate maximum allowed floor life exposure.
Pre-Bake Option: Components may be baked prior to moisture soaking to establish a known dry baseline condition, typically at 125°C for 24 hours.
Soldering Process Exposure
IPC-9504 defines thermal profiles for both reflow and wave soldering simulations. These profiles represent typical manufacturing conditions that components must survive.
Reflow Soldering Profile Parameters
Parameter
SnPb Process
Lead-Free Process
Preheat Rate
1-3°C/second
1-3°C/second
Soak Temperature
150-200°C
150-200°C
Soak Time
60-120 seconds
60-120 seconds
Peak Temperature
225-235°C
245-260°C
Time Above Liquidus
60-90 seconds
60-90 seconds
Cooling Rate
2-4°C/second max
2-4°C/second max
Number of Cycles
3 (typical)
3 (typical)
The three-cycle requirement simulates double-sided assembly (two reflow passes) plus one rework cycle—a reasonable worst-case for production components.
Wave Soldering Profile Parameters
IPC-9504 defines separate wave solder profiles for through-hole and surface-mount components:
Parameter
Through-Hole
Surface-Mount
Preheat Temperature
100-150°C topside
100-150°C topside
Preheat Rate
≤3°C/second
≤3°C/second
Solder Pot Temperature
250-260°C (SnPb) / 260-270°C (Lead-free)
250-260°C (SnPb) / 260-270°C (Lead-free)
Wave Contact Time
3-5 seconds
2-4 seconds
Temperature Differential
≤150°C (preheat to wave)
≤130°C (preheat to wave)
Chemical Exposure Testing
IPC-9504 addresses component compatibility with flux chemistries and cleaning processes commonly used in PCB assembly.
Flux Exposure Procedure
The standard defines flux exposure testing to verify component compatibility with corrosive (water-soluble) fluxes:
Flux Application: Components are immersed in activated water-soluble flux at room temperature for a minimum of 10 seconds
Dwell Time: Flux remains on components for a specified duration before cleaning
Cleaning: Multiple agitated deionized water rinses remove flux residues
Drying: Components are dried at room temperature before evaluation
Cleaning Process Compatibility
Components are evaluated for compatibility with common cleaning agents including:
Aqueous cleaning solutions
Semi-aqueous cleaners
Saponifiers
Solvent-based cleaners (where applicable)
The evaluation focuses on physical damage, marking integrity, and electrical parameter stability after cleaning exposure.
Acceptance Criteria and Evaluation Methods
IPC-9504 Section 10.5 defines the acceptance criteria for evaluating components after preconditioning. The evaluation is multi-faceted, examining both physical and electrical performance.
Electrical testing verifies that preconditioning hasn’t degraded component performance:
Component Type
Key Parameters
Typical Limits
Capacitors
Capacitance, DF, DCL, ESR
Per manufacturer specification
Resistors
Resistance value, TCR
Per manufacturer specification
Inductors
Inductance, DCR, Q-factor
Per manufacturer specification
Crystals
Frequency, ESR
Per manufacturer specification
Components failing visual or electrical criteria after preconditioning indicate process incompatibility and should not be used in production without process modifications or component changes.
Process Compatibility Matrix
IPC-9504 Section 11 provides a soldering process compatibility matrix that helps users select appropriate test conditions based on their actual manufacturing processes.
Component Classification System
The standard classifies components based on their process compatibility requirements:
Classification
Description
Applicable Processes
Class A
Full reflow compatible
Multiple reflow cycles, wave, hand solder
Class B
Limited reflow
Single reflow, wave, hand solder
Class C
Wave/hand solder only
Wave and hand solder processes
Class D
Hand solder only
Manual soldering operations
This classification helps procurement and engineering teams match component capabilities to assembly requirements during design and sourcing phases.
Implementing IPC-9504 in Your Qualification Program
Practical implementation of IPC-9504 requires integrating the preconditioning requirements into your component qualification and incoming quality programs.
Supplier Qualification Testing
When qualifying new passive component suppliers, request IPC-9504 compliance data that matches your specific assembly processes:
Define Your Process Parameters: Document your actual reflow profile, wave solder settings, flux chemistry, and cleaning process
Request Matching Test Data: Ask suppliers for preconditioning data using profiles that match or exceed your process conditions
Evaluate Results: Review visual and electrical data against your acceptance criteria
Gap Analysis: Identify any areas where supplier test conditions don’t match your requirements
Internal Qualification Testing
For critical applications or when supplier data is unavailable, perform internal IPC-9504 testing:
Equipment Requirements:
Reflow oven or reflow simulator capable of controlled profiles
Wave solder equipment or thermal simulation capability
Temperature profiling equipment with thermocouple capability
Controlled temperature/humidity chamber for moisture soaking
Electrical test equipment appropriate for component type
Sample Size Considerations: The standard recommends sufficient sample sizes for statistical validity. For initial qualification, 20-30 pieces per test condition is typical. For ongoing monitoring, smaller sample sizes may be appropriate based on risk assessment.
Documentation Requirements
Maintain complete records of IPC-9504 testing including:
Component identification (manufacturer, part number, lot/date code)
Preconditioning conditions used (moisture soak, thermal profiles)
Pre- and post-conditioning electrical data
Visual inspection results with photographs of any anomalies
Several independent test laboratories offer IPC-9504 preconditioning services for companies without internal testing capability. Key capabilities to look for include:
Programmable reflow simulation equipment
Wave solder simulation capability
Controlled environment chambers for moisture soaking
C-SAM (acoustic microscopy) for internal defect detection
Major passive component manufacturers often provide process compatibility data in their datasheets or application notes. Key sources include technical documentation from Murata, TDK, KEMET, Vishay, Panasonic, and other Tier 1 suppliers. When supplier data references IPC-9504 or equivalent preconditioning, you can have higher confidence in process compatibility.
Common Challenges and Solutions
Challenge: Supplier Data Doesn’t Match Your Process
Problem: Component supplier provides IPC-9504 data based on different thermal profiles than your actual assembly process.
Solution: Request testing at your specific conditions, or perform internal qualification testing. If the supplier’s peak temperature exceeds yours, their data may still be valid (conservative). If your process is more aggressive, additional testing is warranted.
Challenge: Limited Testing Resources
Problem: Your facility lacks the equipment for full IPC-9504 preconditioning.
Solution: Partner with an independent test laboratory for qualification testing. Alternatively, invest in a benchtop reflow simulator—these compact systems can perform J-STD-020 compliant reflow cycles for component qualification at relatively low cost.
Challenge: Legacy Components Without Documentation
Solution: Perform retroactive qualification testing on a sample basis, prioritizing components with known field issues or high-risk applications. Document results to build a component qualification database.
Frequently Asked Questions About IPC-9504
What’s the difference between IPC-9504 and JESD22-A113?
JESD22-A113 (Preconditioning of Plastic Surface Mount Devices Prior to Reliability Testing) is the JEDEC equivalent for IC packages, similar to how IPC-9501 addresses ICs in the IPC framework. IPC-9504 specifically addresses non-IC components (passives) which have different failure modes and test requirements. The procedures are conceptually similar—moisture soak followed by reflow simulation—but the specific parameters and evaluation criteria differ based on component construction. For passive components, IPC-9504 is the appropriate standard.
How many reflow cycles should I use for IPC-9504 preconditioning?
The standard typically specifies three reflow cycles for qualification testing. This represents a reasonable worst-case scenario: two passes for double-sided board assembly plus one rework cycle. For components that will only see single-sided assembly with no anticipated rework, fewer cycles might be justified, but three cycles provides margin for process variation and is the accepted industry practice for qualification purposes.
Do all passive components require IPC-9504 qualification?
Not all passive components are equally sensitive to assembly processes. Standard chip resistors and smaller MLCCs are generally robust and may not require extensive qualification testing beyond supplier verification. However, larger packages, specialty materials (tantalum, aluminum polymer capacitors), precision components, and any parts for critical applications should undergo IPC-9504 preconditioning to verify process compatibility. When in doubt, testing is always preferred over assumptions.
Can I use IPC-9504 for lead-free process qualification?
Yes, IPC-9504 applies to both SnPb and lead-free assembly processes. When qualifying for lead-free, use appropriate peak temperatures (typically 245-260°C versus 225-235°C for SnPb) and ensure your thermal profiles match your actual production conditions. The higher temperatures of lead-free processing make preconditioning qualification even more critical, as thermal stress on components is significantly increased.
How does IPC-9504 relate to incoming inspection?
IPC-9504 qualification testing is typically performed during initial component qualification, not as part of routine incoming inspection. Once a component is qualified per IPC-9504 for your process, incoming inspection focuses on verifying lot-to-lot consistency through sampling rather than repeating full preconditioning. However, any significant changes in component construction, supplier manufacturing location, or your assembly process may warrant re-qualification per IPC-9504.
Conclusion: Making IPC-9504 Work for Your Organization
IPC-9504 provides the structured methodology to verify that passive components will survive your assembly processes without reliability degradation. While it requires investment in testing capability or laboratory partnerships, the cost of qualification testing is minimal compared to the consequences of field failures from process-incompatible components.
The key takeaways for implementing IPC-9504 effectively are straightforward. First, understand your actual assembly conditions—your reflow profile, wave solder parameters, flux chemistry, and cleaning process define what you need to qualify against. Second, require IPC-9504 compliant data from suppliers, and verify that their test conditions match or exceed yours. Third, establish internal testing capability for critical components or when supplier data is unavailable. Finally, document everything—qualification data is only valuable if it’s traceable and retrievable.
For most passive components in non-critical applications, supplier-provided qualification data combined with incoming inspection provides adequate assurance. For critical applications, high-reliability products, or new component technologies, direct IPC-9504 testing gives you the confidence that your components will perform reliably through assembly and throughout product life.
The investment in proper process simulation and preconditioning pays dividends in reduced field failures, lower warranty costs, and confidence that your products will meet customer expectations. IPC-9504 isn’t just another standard to comply with—it’s a practical tool for building reliability into your products from the component level up.
For official specifications and current requirements, obtain IPC-9504 directly from IPC at shop.ipc.org. This article provides general guidance and should be used in conjunction with the official standard documentation.
Inquire: Call 0086-755-23203480, or reach out via the form below/your sales contact to discuss our design, manufacturing, and assembly capabilities.
Quote: Email your PCB files to Sales@pcbsync.com (Preferred for large files) or submit online. We will contact you promptly. Please ensure your email is correct.
Notes: For PCB fabrication, we require PCB design file in Gerber RS-274X format (most preferred), *.PCB/DDB (Protel, inform your program version) format or *.BRD (Eagle) format. For PCB assembly, we require PCB design file in above mentioned format, drilling file and BOM. Click to download BOM template To avoid file missing, please include all files into one folder and compress it into .zip or .rar format.
