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Comparative Tracking Index

The Comparative Tracking Index (CTI) is a standardized that quantifies the relative resistance of solid electrical insulating materials to the formation of conductive surface tracks—known as tracking—under the combined effects of electrical stress and aqueous contamination. This index represents the maximum voltage (typically between 100 V and 600 V) at which the material can withstand a specified without exhibiting tracking, defined as a sustained of 0.5 A for at least 2 seconds or significant surface erosion. The test simulates real-world conditions of moisture and pollutants on insulators, providing a rapid assessment of material performance for applications in electrical and electronic equipment. The CTI is determined through an accelerated laboratory procedure outlined in international standards, primarily IEC 60112, which specifies the method for proof and comparative tracking indices of insulating materials, and its technical equivalent ASTM D3638. In the test, an electrolyte solution (typically with a of about 395 Ω·) is applied in drops to a flat specimen between platinum electrodes, with AC voltages applied incrementally up to 600 V in steps as specified in the standard, until tracking is observed. This method ensures comparability across materials and is not intended to predict long-term service behavior but rather to characterize inherent properties for design purposes. The CTI value plays a critical role in electrical insulation coordination, influencing minimum creepage distances and pollution degrees in standards such as IEC 60664-1 for low-voltage systems. Materials are classified into groups based on their CTI, which dictates their suitability for different environmental and voltage conditions, particularly in printed circuit boards (PCBs), enclosures, and isolation barriers. Higher CTI values indicate better resistance to tracking, allowing closer spacing of conductors without risk of breakdown. This grouping helps engineers select materials to mitigate risks of surface arcing or , ensuring safety and reliability in devices operating up to 1000 V AC or 1500 V DC.

Fundamentals

Definition

The Comparative Tracking Index (CTI) measures the resistance of solid insulating materials to electrical tracking, which is the formation of conductive carbonized paths on the material's surface due to the combined effects of electrical discharge, , and contamination. This phenomenon can lead to unintended current flow between conductors, potentially causing failure in electrical equipment. CTI is defined as the maximum voltage, expressed in volts, at which an insulating material withstands the application of 50 drops of a 0.1% electrolyte solution without exhibiting tracking. Tracking failure occurs when a leakage of ≥0.5 A persists for more than 2 seconds across the test surface or if a persistent flame exceeding 2 seconds is observed. To determine the CTI value, five specimens are tested at voltage levels in 25 V increments (starting from 100 V and increasing) to find the highest voltage at which all five pass the 50-drop test without failure; the CTI is then the highest such voltage, confirmed by an additional 100-drop endurance test at 25 V below that level. The basic principle of the CTI test simulates real-world conditions of surface contamination and voltage stress on insulating materials, providing a comparative assessment of their relative resistance to surface breakdown and tracking erosion. This evaluation focuses on the material's inherent properties rather than specific device geometries, aiding in the selection of insulators for electrical applications.

Historical Development

The Comparative Tracking Index (CTI) test emerged in the mid-20th century as part of broader efforts to standardize electrical insulation testing, driven by the rapid expansion of the electrical industry following World War II. The post-war boom in electrical appliances, power distribution, and industrial equipment heightened concerns over insulation failure due to surface tracking under moist conditions, prompting international collaboration to develop reliable assessment methods for solid insulating materials. This need for standardization was addressed through the International Electrotechnical Commission (IEC), which laid the groundwork for quantitative evaluation of tracking resistance. The foundational standard, IEC 60112, was first published in 1959 as "Recommended method for determining the and proof tracking indices of solid insulating materials under moist conditions," marking the shift from earlier qualitative observations of tracking phenomena to a structured, voltage-based indexing . Subsequent revisions refined the : the 1971 edition updated procedural details, the 1979 third edition incorporated enhanced test criteria, and the 2003 fourth edition clarified and failure definitions to improve . These updates evolved the test from rudimentary assessments toward precise, repeatable measurements, enabling evaluation across materials. Parallel developments in the United States influenced global adoption, with introducing ASTM D3638 in 1977 as a standard test method for the comparative tracking index of electrical insulating materials at low voltages (up to 600 V). This standard provided an equivalent approach to IEC 60112, facilitating harmonization in North American applications. In the 1970s, Underwriters Laboratories (UL) integrated CTI testing into its polymeric materials evaluation framework through the first edition of UL 746B in 1975, which assessed long-term properties including tracking resistance for electrical equipment safety. This incorporation supported and material certification in consumer and industrial products. Recent milestones reflect ongoing adaptations to modern challenges, with the IEC 60112 fifth edition in 2020 introducing a new contaminant solution C (a surfactant-based aligned with IEC 60587) to enhance test . The standard's sixth edition, published in 2025, further consolidates these revisions with minor technical updates, such as terminology adjustments, ensuring the CTI remains a vital tool for quantifying tracking resistance.

Test Methodology

Procedure

The procedure for determining the Comparative Tracking Index (CTI) begins with , where test specimens are conditioned at 23 ± 5 °C and 50 ± 10 % relative for at least 24 hours to ensure consistent content. The surface of the material is cleaned mechanically without the use of solvents to remove any contaminants that could affect the test results. In the setup phase, two electrodes, each with a contact area of 5 mm × 2 mm, are positioned in a V-shape forming a 60° angle with the material surface, with a spacing of 4.0 mm between their inner edges, ensuring firm contact under controlled pressure. An solution is prepared according to the , and drops of 0.02 ml (20 mm³) each are applied between the electrodes every 30 seconds using a calibrated . Voltage application commences at 100 V AC, with increments of 25 V applied sequentially up to a maximum of 600 V, while maintaining the test environment at 23 °C ± 5 °C and relative humidity between 40% and 75%. At each voltage level, the test continues for 50 drops or until failure is detected, with the voltage increased only after confirming no tracking at the previous level. Five specimens are tested at each voltage level. If one of the five fails, five additional specimens are tested; the voltage level is acceptable if no more than one of the ten specimens tracks. The CTI is the highest such voltage, verified by testing five specimens with 100 drops at 25 V below that level, where they must all pass. Failure is defined as tracking when the current exceeds 0.5 A for 2 seconds, indicating the formation of a conductive . Following the test, a is performed on the material surface to identify any carbon tracks, erosion, or signs of , with documentation of any observed damage for reporting purposes.

Equipment and Standards

The Comparative Tracking Index (CTI) test apparatus consists of specialized equipment designed to simulate electrical tracking under controlled contamination and voltage stress. Core components include electrodes, an supply, a precision drop dispenser for delivery, and an for measurement. These elements ensure consistent evaluation of insulating materials' resistance to surface tracking. The electrodes are constructed from with a purity of at least 99%, featuring a rectangular cross-section of 5 mm × 2 mm, a edge angled at 30° ± 2°, and a flat end face with a thickness of 0.01 mm to 0.1 mm. They are arranged to form an included angle of 60° ± 5° and spaced 4.0 ± 0.1 mm apart, applying a downward force of 1.00 ± 0.05 N to the test specimen, conforming to the specified in international standards for reproducible contact. The power supply provides adjustable AC voltage from 100 V to 600 V at a of 48 Hz to 62 Hz, with a minimum of 0.6 kVA to deliver a sinusoidal with accuracy of ±1.5%. It incorporates an over-current protection mechanism that activates at 0.50 ± 0.05 A for a duration of 2.00 ± 0.20 s upon detection of tracking. The drop dispenser is calibrated to release individual drops of approximately 20 mg (equivalent to 0.02 ml) of solution from a height of 35 ± 5 mm above the specimen surface, at regular intervals of 30 ± 5 s, via a with an outer of 0.9 mm to 3.45 mm. The total mass for 50 drops must fall between 0.997 g and 1.147 g to verify dispensing accuracy. Current monitoring is performed using an with an accuracy of ±3% to measure short-circuit currents up to 1.0 ± 0.1 A, enabling detection of leakage or failure events during the test. Auxiliary equipment supports safe and precise testing, including a conditioning chamber that maintains 23 ± 5 °C and 50 ± 10% relative for specimen preparation, adjustable sample holders accommodating flat or curved surfaces, and safety interlocks to isolate high-voltage components and prevent operator exposure. An is often integrated to remove fumes generated during testing. Calibration procedures ensure equipment reliability: electrodes are inspected for flatness and restored to shape if deformed, with force and separation verified periodically; the electrolyte solution's resistivity is confirmed at 3.95 ± 0.05 Ω·m using a 0.1% (NH₄Cl) preparation in at 23 ± 2 °C. The governing international standard is IEC 60112:2020, which details the apparatus and procedures for determining CTI and Proof Tracking Index (PTI) values, including amendments for solution variations like Solution C (0.2% NH₄Cl with for lower surface tension). In the U.S., ASTM D3638-21e01 adapts this method for low-voltage applications up to 600 V, specifying similar and electrode requirements. UL 746A employs the IEC 60112 CTI protocol for assessing polymeric materials' tracking resistance in electrical equipment, integrating it into broader safety evaluations. IEC 60112 outlines two primary test methods: Method A for PTI, applying 50 drops at a fixed voltage to assess failure probability, and Method B for CTI, identifying the highest voltage withstood by 50 drops across multiple specimens, followed by verification with 100 drops at 25 V below that level.

Classification

Material Groups

The Comparative Tracking Index (CTI) classifies insulating materials into standardized groups based on their resistance to surface tracking under electrical stress, as defined in international and industry standards. The (IEC) standard IEC 60112 establishes the testing methodology, while classifications into material groups are typically applied in related standards such as IEC 60664-1 for coordination. These groups are I, , IIIa, and IIIb, with higher groups indicating superior tracking resistance and allowing for reduced creepage distances in electrical designs. Under the IEC classification, materials are categorized as follows: Group I materials exhibit CTI values of 600 V or greater, demonstrating excellent resistance suitable for high-voltage applications; examples include ceramics and (PTFE). Group II materials have CTI values between 400 V and less than 600 V, offering good resistance, such as certain resins. Group IIIa covers CTI values from 175 V to less than 400 V, providing fair resistance, while Group IIIb spans 100 V to less than 175 V for moderate resistance. Materials with CTI below 100 V are generally not recommended for electrical insulation applications and may be assumed to fall under Group IIIb for conservative design purposes per IEC 60664-1. The Underwriters Laboratories (UL) standard UL 746A employs a similar grouping system aligned with IEC 60112 testing, but incorporates Performance Level Categories (PLC) from 0 to 4 corresponding to the voltage ranges: PLC 0 (≥600 V, Group I), PLC 1 (400–599 V, Group II), PLC 2 (250–399 V, Group IIIa), PLC 3 (175–249 V, Group IIIa), and PLC 4 (100–174 V, Group IIIb). In UL contexts, post-2008 revisions discontinued the distinct IIIb designation for some polymeric materials, merging lower ranges into broader Group III considerations, though IEC standards retain the IIIa/IIIb distinction. This alignment ensures compatibility with safety evaluations for polymeric materials in electrical equipment. Material group assignment relies on the lowest CTI value obtained from multiple test determinations to ensure conservative reliability. According to IEC 60112, a minimum of five specimens must be tested for CTI determination; the material passes if at most one of ten total specimens (including any retests) fails at the specified voltage, with the final CTI reported as the highest voltage where no tracking occurs after 50 drops of electrolyte solution, verified by 100 drops at 25 V below that level. This process accounts for variability in material composition, surface conditions, and fabrication, requiring at least three valid determinations per material variant in practice for robust classification. Representative examples illustrate these groups in practical contexts. printed circuit board (PCB) laminate, a common epoxy-glass composite, typically achieves CTI values of 175–250 V, placing it in Group IIIa for general applications. In contrast, PTFE exceeds 600 V, qualifying for Group I in demanding RF and high-insulation environments. Ceramics often surpass 600 V, enabling their use in Group I for robust industrial insulators, while select epoxy formulations reach 400–600 V for Group II in molded components. Threshold implications of these groups directly influence design and . Materials in Group IIIb (CTI 100–<175 V) are restricted to low-voltage applications (typically below 50 V) under safety codes like IEC 60950 and UL 60950, as they require larger creepage distances to prevent tracking failures in polluted environments; higher groups permit denser layouts with reduced spacing, enhancing efficiency in high-voltage systems while maintaining safety margins.

Result Interpretation

The Comparative Tracking Index (CTI) is calculated as the highest voltage level, expressed as a multiple of 25 V, at which five test specimens withstand 50 drops of the electrolyte solution without tracking failure (sustained current ≥0.5 A for >2 s) or persistent ; erosion may be noted separately for the degree observed. Testing proceeds in 25 V increments following an initial screening phase, where failure at a given voltage V results in the CTI being assigned as V minus 25 V, reflecting the preceding successful level. To confirm the value, an additional 100 drops are applied at this CTI voltage minus 25 V on the same or equivalent specimens. Statistical evaluation in CTI determination follows a binary pass-fail criterion rather than continuous metrics: if one of five specimens fails at the candidate voltage, five additional specimens are tested, and the level passes only if no more than one failure occurs across the total of ten. For batch or production testing, results from multiple valid trials may be averaged to assess consistency, with outliers discarded if they deviate by more than 20% from the mean, though the standard emphasizes the primary CTI as the deterministic highest passed voltage. Confidence intervals can be derived for larger sample sets in to quantify variability, but these are not part of the core IEC procedure. Key limitations of CTI values include their role as a relative measure of tracking resistance under simulated contamination, not an absolute predictor of material lifetime or long-term performance in real-world applications. The test is insensitive to creepage distances exceeding 3 mm, as it evaluates short-path tracking with fixed spacing, potentially underestimating risks in wider gaps. Variability arises from factors such as sample thickness, which must exceed 3 mm to ensure reliable results—thinner specimens can lead to artificially lower CTI values due to increased vulnerability—and surface finish, where irregularities like scratches may alter drop behavior and tracking initiation. In comparative assessments, higher CTI values indicate greater resistance to tracking under contaminated conditions, allowing for reduced minimum creepage distances in design; for instance, materials with CTI ≥600 V permit closer conductor spacing than those below 175 V. However, CTI should be paired with complementary tests, such as the Relative Temperature Index (RTI), to fully evaluate insulation integrity across thermal and electrical stresses.

Influencing Factors

Material Properties

The Comparative Tracking Index (CTI) of a material is significantly influenced by its , particularly its resistance to carbonization under electrical stress. Polymers containing carbon atoms are susceptible to forming conductive paths through caused by partial discharges, but materials with inherently stable molecular structures, such as polyimides, exhibit superior resistance compared to those like , which degrade more readily into conductive residues. Inorganic fillers, such as or alumina trihydrate (), enhance CTI in polymer composites by promoting erosion resistance and interrupting carbon path formation, outperforming unfilled pure polymers that lack such mechanical reinforcement. Surface properties play a critical role in CTI performance by affecting how electrolytes interact with the during testing. Hydrophobic and , non-porous surfaces limit the spreading of conductive liquids, thereby reducing the likelihood of tracking ; for instance, surface treatments that increase hydrophobicity can elevate CTI values by minimizing and leakage current paths. stability is another key intrinsic factor, where materials possessing high temperatures above 150°C, like certain polyimides, better endure the localized heat from electrical arcs without softening or degrading, preserving integrity. Additives incorporated into polymers can either bolster or compromise CTI, depending on their . Halogen-free flame retardants, while environmentally preferable, often prove hygroscopic and thus lower CTI by facilitating and electrolyte conduction. Crosslinking in thermoset polymers, such as epoxies reinforced with , improves tracking resistance by creating a rigid network that hinders the propagation of continuous carbonized tracks. Representative examples illustrate these effects: achieves CTI values >600 V due to its tendency to erode cleanly without forming conductive carbon paths, whereas polyimides like Kapton® typically have CTI values around 150 V, despite their thermal resilience, likely due to greater surface wetting by electrolytes.

Environmental and Test Variables

The Comparative Tracking Index (CTI) test is sensitive to the type of contaminant used, with the standard electrolyte solution of 0.1% (NH₄Cl) in simulating surface , but real-world contaminants such as dust, salts, or electrolytic residues often exhibit higher conductivity, thereby reducing the apparent CTI by promoting faster and tracking paths. For instance, electrolytic surface has been shown to significantly lower CTI values by enhancing ionic along the material surface. In contrast, less conductive pollutants may overestimate material resistance compared to harsh industrial environments. Relative humidity plays a critical role in CTI outcomes, as levels exceeding 50% facilitate moisture absorption and ionic conduction on the insulator surface, increasing tracking risk by up to several hundred volts in susceptible materials. Standard tests are conducted at controlled humidity to minimize variability, but elevated humidity accelerates dry-band arcing and leakage currents, particularly in hygroscopic polymers. conditions also influence results; the IEC 60112 specifies testing at 23 ± 5 °C to ensure reproducibility, yet higher temperatures during or prior to testing enhance mobility and thermal degradation, accelerating failure and potentially lowering CTI in materials like polybutylene terephthalate (PBT). Surface temperatures above 150 °C during tracking further promote , reducing overall resistance. Electrode configuration is standardized with a fixed spacing of 4.0 mm ± 0.1 mm between electrodes to maintain consistent strength, as narrower gaps could overestimate tracking propensity while wider ones might underestimate it. Voltage application follows a stepwise rather than a continuous ramp, but variations in ramp speed—such as faster increments—can lead to underestimation of resistance by not allowing full development of tracking paths. Sample preparation significantly affects CTI, with molded specimens generally yielding higher values than polished or machined surfaces due to the latter introducing micro-contaminants or irregularities that can reduce . residues, such as release agents or , can further degrade surface integrity, emphasizing the need for clean, uncontaminated preparation to avoid artificially low results. Aging under environmental stressors like UV exposure or progressively degrades surface properties, leading to a drop in CTI over time; for example, UV breaks molecular bonds in polymers like , increasing hydrophilicity and leakage currents, thereby reducing CTI over time. Hydrolytic aging similarly causes embrittlement and cracking, heightening tracking susceptibility in materials such as polyimides, with degradation accelerating under combined moisture and thermal stress.

Applications and Implications

Industrial Uses

In the field of (PCB) and electronics manufacturing, the Comparative Tracking Index (CTI) plays a pivotal role in selecting insulating substrates to ensure reliability in high-density designs. Standard materials, with a CTI rating of 175-250 V, are commonly used for where environmental stresses are moderate, allowing for adequate without excessive spacing requirements. In contrast, automotive applications demand higher CTI values, such as 400-599 V (Material Group II), often achieved with specialized high-CTI or CEM-3 laminates, to withstand vibrations, temperature fluctuations, and potential contamination that could lead to tracking failures in high-density boards. This selection enables tighter creepage distances, supporting compact layouts while maintaining electrical integrity in harsh operating conditions. In power systems, CTI is essential for insulating materials in and enclosures, particularly those exposed to outdoor elements. Materials with CTI greater than 400 V, classified in Groups I or II (≥400 V), are required to prevent surface tracking and under humidity, pollution, and , ensuring long-term operational safety in medium- and high-voltage applications. For instance, outdoor insulators must meet these thresholds to resist conductive path formation from environmental contaminants, thereby minimizing downtime and maintenance needs in utility infrastructure. For household appliances, CTI guides the choice of wiring insulation materials to mitigate risks in moisture-prone settings. Low-CTI materials (below 175 V, Group IIIb) are avoided in devices like refrigerators or washing machines, where humid environments could promote tracking along insulation surfaces; instead, higher-CTI variants (≥175 V) are selected to maintain dielectric strength and prevent unintended current leakage. This approach ensures durable performance in everyday appliances subjected to condensation and spills. The material selection process incorporates CTI alongside standards like IPC-2221 to optimize creepage and clearance distances in PCB layouts. By categorizing materials into Performance Level Categories (PLCs) based on CTI—such as PLC 2 (250-399 V) for general use or PLC 0 (>600 V) for extreme high-voltage needs—designers can calculate minimum spacings that balance safety and board density, as outlined in IPC-2221B for generic printed board requirements. This integration, often verified through UL 746A testing, facilitates reliable designs across voltage classes without over-engineering. In (EV) systems, advancements in CTI have enhanced performance, particularly post-2020 developments in high-voltage components. For example, Covestro's Bayblend® FR3015 CTI and Makrolon® FR6019 CTI polycarbonates achieve a CTI of 600 V, enabling robust insulation for Li-ion housings and while supporting compact designs with reduced creepage distances. Similarly, Envalior's high-CTI materials for HV connectors extend tracking resistance to 900 V, improving safety in 800 V architectures by minimizing potential failure points in s exposed to thermal and electrical stresses. These innovations have contributed to more reliable systems.

Safety and Regulatory Aspects

A low Comparative Tracking Index (CTI) in insulating materials increases the risk of surface tracking, where conductive paths form on the material surface under electrical stress and contamination, potentially leading to arcing, short circuits, electric shock, or fire hazards in electrical equipment. In printed circuit boards (PCBs), tracking failures can contribute to short circuits as a common failure mode, particularly in humid or polluted environments, compromising device reliability and user safety. Regulatory frameworks incorporate CTI values to ensure adequate insulation coordination and prevent such hazards. Under IEC 60664-1, materials are classified into groups based on CTI, with Group IIIa (CTI 175–400 V) or higher often required for creepage distances in pollution degree 2 environments typical of indoor IT equipment, aligning with safety standards like IEC 62368-1 that superseded IEC 60950-1. The EU's RoHS Directive (2011/65/EU) restricts certain halogenated flame retardants, such as polybrominated biphenyls (PBB) and polybrominated diphenyl ethers (PBDE). Halogen-free alternatives have been developed, some offering higher CTI values compared to formulations with halogenated retardants. Certification processes rely on CTI testing to verify material suitability. UL recognition under UL 746A evaluates short-term electrical properties, including CTI, assigning performance levels that inform safe use in end products, with higher CTI values allowing reduced creepage distances. For European market access, CTI compliance supports under the Directive (2014/35/EU), as harmonized standards like EN IEC 60664-1 require CTI-based material grouping to demonstrate conformity with essential safety requirements. In , CTI plays a key role in determining degrees and failure modes. For indoor applications ( degree 2, non-conductive with occasional condensation), a CTI of at least 175 V is typically specified to minimize tracking risks, whereas outdoor or industrial settings ( degree 3, conductive ) demand higher CTI values and larger creepage distances to mitigate in hazard and operability (HAZOP) analyses. Recent developments address evolving environmental challenges, including impacts. In May 2025, UL published Outline of Investigation UL 2597 for surface tracking tests up to 900 V, extending beyond the 600 V limit of ASTM D3638 and IEC 60112, to support climate-resilient, high-voltage materials for electric vehicles amid rising and from .

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