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TO-252
TO-252
TO-252
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Power MOSFET (Advanced Power Electronics AP9870GH)

TO-252, also known as DPAK[1] or Decawatt Package, is a semiconductor package developed by Motorola[2] for surface mounting on circuit boards.[3] It represents a surface-mount[4] variant of TO-251 package, and smaller variant of the D2PAK package. It is often used for high-power MOSFETs and voltage regulators.

Variants

[edit]
Variant with 5 pins: a dual input dropout regulator (Globaltech GS1581D)

Package can have 3 pins with 90 mils (2.3 mm) pitch or 5 pins with 45 mils (1.1 mm) pitch. The middle pin is usually connected to the tab. The middle pin is sometimes omitted.

See also

[edit]

References

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

TO-252

View on Grokipedia
from Grokipedia
The TO-252, also known as DPAK, is a surface-mount device (SMD) package standardized by for medium-power components, featuring a molded plastic body with an exposed thermal pad for efficient heat dissipation. It is designed primarily for applications requiring low on-resistance and high-speed switching, such as in MOSFETs, diodes, and power transistors.

Physical Characteristics

The TO-252 package typically measures approximately 6.1 mm in length, 6.58 mm in width, and 2.29 mm in height, with two gullwing-style leads spaced at a 2.3 mm pitch and an exposed tab for the third terminal, enabling surface-mount assembly on printed circuit boards (PCBs). The body is constructed from flame-retardant epoxy molding compound (UL 94V-0 rated), and the leads are matte tin-plated copper alloy for solderability, while the exposed pad connects directly to the die attach for thermal management. Variants exist with 2 or 3 terminals, and the package supports reflow soldering up to 260°C for 30 seconds per JEDEC J-STD-020 guidelines.

Applications and Key Features

Commonly used in power supply circuits, DC-DC converters, motor drivers, and , the TO-252 enables compact designs with power handling up to around 80 W (depending on PCB thermal vias and copper area). Its key advantages include an exposed drain tab that serves as a when soldered to the PCB, reducing thermal resistance, and compatibility with high-volume automated assembly via tape-and-reel . Modern versions often incorporate lead-free (Pb-free) and halogen-free materials to meet environmental standards.

Overview

Definition and Purpose

The TO-252 is a three-lead surface-mount package standardized by , also referred to as DPAK (Discrete Power Package) or Decawatt Package, specifically designed for housing medium-power discrete semiconductors such as MOSFETs, Schottky diodes, and linear voltage regulators. This package features gullwing-shaped leads for reliable PCB attachment and an exposed tab that serves as the primary thermal interface, making it suitable for applications requiring compact integration of power-handling components like motor drivers and DC-DC converters. The primary purpose of the TO-252 is to provide efficient thermal management in surface-mount designs, where the exposed tab directly contacts the PCB to dissipate heat, enabling the board itself to function as an effective . This configuration supports power dissipation levels of up to several watts, depending on PCB layout and copper thickness, while maintaining a low profile that minimizes overall device height. A key design intent of the TO-252 is to facilitate the shift from traditional through-hole mounting to , allowing for automated high-volume assembly and accommodating higher-power devices in space-constrained electronics without substantially expanding board footprint.

Development History

The TO-252 package, also known as DPAK or Decawatt Package, originated with Semiconductor in the mid-1980s as a response to the growing demand for (SMT) in power applications. It was designed to enable compact packaging for medium-power devices, facilitating the transition from through-hole to surface-mount designs in electronics manufacturing. This development aligned with the broader industry shift toward SMT, which allowed for higher component density on printed circuit boards, particularly in and emerging automotive systems requiring efficient power handling. Motorola's initial release of the TO-252 occurred circa 1987-1988, addressing the need for a robust, high-power surface-mount alternative to traditional packages in applications demanding up to several watts of dissipation. By this time, the package had gained traction for its ability to support power transistors and regulators in space-constrained environments, marking a key advancement in packaging efficiency. Standardization efforts followed shortly thereafter, with the package adopted into the JEDEC outline as TO-252 under issue B in September 1988, formalizing its dimensions and specifications for industry-wide compatibility. This registration in the late 1980s paved the way for broader adoption, leading to widespread use by the mid-1990s in devices such as power MOSFETs and linear regulators across consumer and automotive sectors. The evolution of the TO-252 was deeply influenced by overarching SMT trends, which emphasized and automated assembly processes, ultimately positioning it as a direct replacement for the older through-hole package in many high-volume applications. This shift not only reduced board space but also improved throughput, solidifying the TO-252's role in the proliferation of compact power electronics by the late 1990s.

Physical Specifications

Dimensions and Materials

The TO-252 package, standardized under outline TO-252AA (JESD95, Issue F), features a compact body with dimensions of approximately 6.0 mm in width (D: 5.97–6.22 mm) and 6.5 mm in length (E: 6.35–6.73 mm), excluding mold flash, which is limited to 0.127 mm per side. The overall height measures 2.18–2.39 mm (A), with a seated height of up to 0.13 mm (A1), enabling low-profile surface-mount applications. The footprint occupies roughly 6.5 mm × 9.5 mm, including an exposed tab (D1: minimum 5.21 mm × E1: minimum 4.32 mm) designed for heat sinking to the PCB. The package includes three leads—typically configured for , source, and drain in MOSFETs—with a thickness of 0.64–0.89 mm (b), a nominal pitch of 2.29 mm (e), and bent gull-wing shapes for surface mounting. Lead lengths vary, with the inner leads at 1.40–1.78 mm (L) and the tab extension providing additional mounting surface (b3: 4.95–5.46 mm). Construction utilizes a molded body for electrical insulation and , meeting UL flammability rating 94V-0. The internal leadframe and exposed tab consist of for high conductivity, often with in wire-bonding areas. External leads are matte-tin plated over for enhanced and resistance, with pure tin finishes common in lead-free variants. The typical weight of the TO-252 package is approximately 0.3 grams, facilitating efficient reel-to-reel handling in automated assembly processes. This lightweight design, combined with the exposed tab, supports effective to the underlying board.

Thermal Management Features

The TO-252 package facilitates heat dissipation primarily through its exposed metal tab, which is soldered to copper pours on the (PCB) to serve as the main , conducting thermal energy away from the device junction via direct contact with the PCB substrate. This mechanism leverages the tab's low thermal impedance, with junction-to-case thermal resistance (RθJC) typically ranging from 1 to 2 °C/W, as reported in manufacturer datasheets for devices in this package. Effective PCB integration is crucial for optimizing thermal performance, requiring a area of at least the size, approximately 50 mm², with 1 oz (35 µm) thickness to provide adequate spreading; larger areas, such as 50 mm² or more, further reduce thermal resistance. Incorporating thermal vias beneath the tab—often in arrays of 6x6 with 0.3 mm —enhances conduction to inner PCB layers or the board's underside, potentially lowering junction-to-ambient thermal resistance (RθJA) by up to 50% in multi-layer designs. Power dissipation in the TO-252 package is limited to 2-5 , varying with ambient temperature, airflow, and PCB configuration, with typically from 25°C ambient to prevent junction temperatures from exceeding safe limits (often 150°C). The maximum allowable power PP is determined by the equation P=TjmaxTaRθJA,P = \frac{T_{j_{\max}} - T_a}{R_{\theta JA}}, where TjmaxT_{j_{\max}} is the maximum , TaT_a is the ambient temperature, and RθJAR_{\theta JA} represents the junction-to-ambient resistance, generally 50-80 °C/ without supplementary heatsinking.

Electrical and Mounting Details

Pin Configuration

The TO-252 package, also known as DPAK, features a standard three-pin layout for N-channel MOSFETs, with Pin 1 (left) designated as the , Pin 2 (middle) as the Source, and Pin 3 (right, connected to the tab) as the Drain. The tab is electrically connected to the Drain, providing an additional low-inductance path for high-current applications. In this configuration, the Gate pin receives the control signal to switch the on or off, the Source serves as the reference or ground connection, and the Drain connects to the high-power load. Typical devices in this package support voltage ratings up to 60 V and current ratings up to 30 A, enabling efficient power switching in compact designs. Device orientation is determined by viewing the package with the tab facing down, where pins are numbered from left to right; the top side bears markings such as the device code for identification. For other components like diodes or voltage regulators, pin assignments vary: diodes typically use the pins for and connections (with the tab often as ), while regulators assign pins to , and ground (with the tab commonly tied to ground or output).

Soldering and Assembly Guidelines

is the preferred surface-mount process for TO-252 components, adhering to J-STD-020 guidelines with a peak of 260°C for a maximum of 10 seconds to ensure reliable joints without package damage. This profile includes preheating at 150–200°C for 60–120 seconds, a ramp-up rate not exceeding 3°C/s, and a time above 217°C of 60–150 seconds, limited to three reflow cycles total. is feasible for TO-252 but requires robust PCB land patterns, with an additional 0.2 mm added to the land dimensions to accommodate wave dynamics and prevent bridging or insufficient wetting. The recommended land pattern for TO-252 follows IPC-7351 standards, featuring lead pads of approximately 1.1 mm width by 2.6 mm length to match the 1.27 mm lead pitch and promote uniform fillet formation. The central tab pad is significantly larger at approximately 5.6 mm by 10.7 mm, incorporating thermal relief cutouts to minimize stress during while facilitating heat dissipation to the PCB. These dimensions ensure compatibility with automated assembly equipment and allow for inspection of joints post-reflow. Handling precautions are essential to maintain TO-252 integrity; leads should not be bent beyond 90 degrees or subjected to excessive mechanical , as this can crack the molded or misalign internal connections. The package carries a (MSL) of 1 per J-STD-033, permitting unlimited floor life under ambient conditions (30°C/85% RH) but recommending storage in dry environments (5–30°C, 40–70% RH) to avoid moisture absorption that could lead to during high-temperature processing. Solder joint reliability for TO-252 in demanding environments, such as automotive applications, is enhanced by IPC-7351-compliant pad designs that optimize fillet and standoff height, supporting long-term performance in vehicle .

Variants

Standard TO-252 Configurations

The TO-252AA represents the standard JEDEC-registered variant of the TO-252 surface-mount package, characterized by a compact footprint measuring approximately 6.5 mm in width by 9.5 mm in length, enabling efficient board space utilization in high-density designs. This configuration features a molded body with exposed metal tab for enhanced thermal dissipation, making it the baseline form widely adopted for discrete semiconductors. Standard configurations include both 2-lead and 3-lead versions; the 2-lead variant (TO-252-2) is commonly used for diodes and rectifiers, while the 3-lead version is typical for transistors like MOSFETs. The standard pin configuration for the 3-lead version consists of three leads with a nominal pitch of 2.29 mm, typically designated as , source, and drain for N-channel MOSFETs, while the central tab serves as a fourth electrical and , internally connected to the drain terminal to facilitate heat sinking directly to the PCB. This arrangement supports straightforward integration in automated assembly processes and is prevalent in applications requiring moderate power handling. For manufacturing efficiency, the TO-252AA is supplied in tape-and-reel packaging, utilizing 8 mm wide embossed carrier tape compatible with standard pick-and-place machines, with each 330 mm diameter reel containing 2,500 units to optimize handling and reduce waste in (SMT) lines. This format adheres to EIA-481 standards for embossed tape, ensuring reliable component orientation and protection during transport and feeding. Compliance with environmental regulations is integral to the TO-252AA, with lead-free (Pb-free) construction using matte tin plating on leads and tab, meeting RoHS Directive 2002/95/EC requirements since the mid-2000s following the directive's implementation in July 2006. This shift eliminated hazardous substances like lead in solderable surfaces, aligning with global standards without compromising electrical or thermal performance.

Extended Variants

Extended variants of the TO-252 package include modifications that expand functionality or improve performance for specific applications, such as precision sensing or higher power density requirements. One such adaptation is the TO-252-5, a five-terminal configuration with four leads plus the central tab, which provides additional connectivity options compared to the standard three-lead design. This variant is employed in circuits where extra pins facilitate functions like , as seen in certain ICs that incorporate sensing for accurate by minimizing voltage drops across sense paths. Evolutions toward smaller footprints have led to packages like Vishay's PowerPAK series, which offer reduced dimensions while maintaining or enhancing electrical performance. For instance, the PowerPAK SO-8 measures 5 mm × 6 mm, representing a footprint approximately 52% smaller and a profile 50% thinner than the traditional DPAK (TO-252), enabling higher component density on circuit boards. The related PowerPAK 8x8L, at 8.1 mm × 8.25 mm × 1.9 mm, provides a comparable footprint to the DPAK but utilizes advanced clip bonding technology to achieve lower on-resistance (Rds(on)) and reduced parasitic , supporting efficient switching in space-constrained designs. Similarly, DirectFET variants, such as the DirectFET Medium Can, provide a 54% smaller footprint than DPAK while optimizing thermal and electrical characteristics for high-frequency applications. Related packages derived from the TO-252 lineage include the D2PAK (), a larger sibling designed for elevated power handling. The D2PAK features a broader body, typically supporting up to 100 W power dissipation—roughly double the capability of standard DPAK components—due to its increased surface area for heat dissipation and compatibility with larger die sizes. This makes it suitable for applications demanding higher currents and voltages, such as up to 100 V and 50 A in automotive and industrial power modules. In , the SOT-428 serves as the EIAJ-equivalent nomenclature for the DPAK (TO-252), sharing identical dimensions (6 mm × 6.6 mm × 2.3 mm body) and lead pitch (2.285 mm) for seamless interoperability in global manufacturing. These extended variants gained prominence in the , driven by the need for higher integration on densely populated boards in and automotive systems. Innovations like copper clip interconnects in DPAK and D2PAK, introduced around 2011 by manufacturers such as , further enhanced thermal performance and , allowing support for demanding specifications including 100 V operation and currents approaching 50 A in optimized configurations.

Applications

Common Use Cases

The TO-252 package, also known as DPAK, is extensively utilized in power management circuits due to its ability to handle moderate power levels in a compact surface-mount form factor. It is commonly employed in switch-mode power supplies (SMPS) for efficient voltage conversion and regulation, DC-DC converters for stepping down or up voltages in portable systems, and linear regulators for stable output in low-to-medium current applications up to 40 V. For example, N-channel PowerTrench MOSFETs in TO-252 configuration are optimized for DC-DC conversion, providing low on-resistance to minimize power losses during switching operations. Similarly, monolithic adjustable voltage regulators like the series are packaged in TO-252 (DPAK) to deliver precise regulation in space-constrained power supply designs. In , TO-252 devices are qualified to AEC-Q101 standards, ensuring robustness against extremes, , and typical of environments. These packages are prevalent in motor drivers for electric windows and fans, LED modules for interior and exterior illumination, and battery management systems (BMS) for monitoring and balancing lithium-ion cells in electric vehicles. Power MOSFETs in TO-252, such as those rated for 60 V and 90 A, support high-current switching in automotive applications while meeting reliability requirements. AEC-Q101-compliant diodes and transistors in this package also facilitate efficient power distribution in 12 V and 24 V systems. Consumer devices leverage the TO-252 package for its balance of thermal performance and board space efficiency in everyday . It appears in audio amplifiers for driving speakers in home theater systems and portable music players, portable chargers for USB power delivery, and white goods such as washing machines for and power regulation. NPN power transistors in TO-252 enable high-current amplification in audio output stages, supporting continuous collector currents up to 6 A. In battery-powered consumer gadgets, these packages regulate charging circuits to prevent and ensure safe operation. Industrial applications benefit from the TO-252's reliability in demanding control systems, where it drives for switching high loads and controls in pneumatic and hydraulic actuators within equipment. Power MOSFETs in this package handle the inductive loads of relay coils and solenoid drivers, offering fast switching to minimize energy dissipation in setups. These components are integrated into programmable logic controllers (PLCs) and industrial power supplies for precise operation in 24 V DC environments.

Performance Advantages and Limitations

The TO-252 package offers significant performance advantages in compact, surface-mount applications, particularly for medium-power devices handling 1-10 W . Its smaller enables denser circuit layouts compared to through-hole packages like the , without compromising electrical performance. Additionally, the TO-252 is cost-effective for automated assembly processes, as its surface-mount design minimizes handling and soldering complexity relative to larger packages. When paired with appropriate PCB heatsinking, such as pours, it achieves good thermal performance, supporting reliable operation in space-constrained environments like DC-DC converters. Despite these benefits, the TO-252 has notable limitations, including higher junction-to-ambient thermal resistance (RθJA typically >50 °C/W on standard PCBs) than many through-hole alternatives, which can limit heat dissipation in high-ambient conditions. It is not ideal for applications exceeding 10 W without additional cooling, as excessive power leads to elevated junction temperatures and reduced reliability. Mechanical stress from lead bending during handling or mounting can also introduce risks of cracking or fatigue in the package. In comparisons, the TO-252 excels over the SO-8 for medium-power needs, offering lower RθJA (around 40-96 °C/W) and higher dissipation capacity, though the SO-8 supports more pins in lower-power, multi-device configurations. Relative to the , the TO-252 provides similar thermal efficiency on PCB heatsinks but occupies less board space, while the is preferable for high-power scenarios (>10 W) due to easier attachment to external heatsinks. The D2PAK () variant scales similarly to the TO-252 but handles higher dissipation (up to 20-50 W) with a larger footprint and lower RθJA (20-40 °C/W), making it suitable for more demanding thermal loads. To mitigate these limitations, designers can employ thermal pads or vias under the drain tab to enhance to inner PCB layers or external sinks, effectively extending the package's power-handling capabilities beyond 10 W. Extended variants, such as those with enhanced tab designs, may further address thermal constraints in specific high-power needs.

References

  1. https://www.jedec.org/sites/default/files/TOINDEX.pdf
  2. https://www.infineon.com/package-family/PG-TO252
  3. https://amkor.com/packaging/power-discrete/to-252/
  4. https://www.diodes.com/assets/Package-Files/TO252-DPAK.pdf
  5. https://www.topdiodes.com/topdiode-the-dpak-to-252-package-used-for-medium-power-mosfets-and-linear-power-regulators/
  6. https://fscdn.rohm.com/en/products/databook/applinote/ic/power/linear_regulator/to252_thermal_resistance_information_an-e.pdf
  7. https://madpcb.com/glossary/dpak/
  8. https://www.arrl.org/files/file/Technology/tis/info/pdf/8710015.pdf
  9. https://www.ic-components.com/blog/understanding-the-to252-package-thermal-management-and-design-efficiency.jsp
  10. https://www.tortai-tech.com/wp-content/uploads/2023/09/IPC-SM-782.pdf
  11. https://anysilicon.com/semiconductor-packaging-history-trends/
  12. https://www.vishay.com/docs/95016/dpak252a.pdf
  13. https://www.mouser.com/datasheet/2/115/TO252-DPAK-1140976.pdf
  14. https://amkormarcomexternal.blob.core.windows.net/amkordotcom/wp-content/uploads/2019/12/DPAK-TO-252-DS414-.pdf
  15. https://fscdn.rohm.com/en/techdata_basic/ic/package/Jisso_TO252-3-1-2_Rev004s_E2%28MSL1%29.pdf
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  17. https://www.analog.com/en/resources/design-notes/exposed-pads-a-brief-introduction.html
  18. https://www.onsemi.com/pdf/datasheet/fdd2572_f085-d.pdf
  19. https://www.diodes.com/datasheet/download/DMJ70H600HK3.pdf
  20. https://www.ti.com/lit/an/slvae85/slvae85.pdf
  21. https://product.torexsemi.com/files/packages/to-252-pd.pdf
  22. https://www.st.com/resource/en/datasheet/std16nf06.pdf
  23. https://assets.wolfspeed.com/uploads/2023/10/Wolfspeed_C4D02120E_data_sheet.pdf
  24. https://www.ti.com/lit/ds/symlink/lm78m05-mil.pdf
  25. https://www.ablic.com/en/doc/package/solder/NOS_TO252.pdf
  26. https://www.diodes.com/assets/Package-Files/TO252-Standard.pdf
  27. https://www.nisshinbo-microdevices.co.jp/en/design-support/package/to-252-3-l1.html
  28. https://www.protoexpress.com/blog/features-of-ipc-7351-standards-to-design-pcb-component-footprint/
  29. https://www.circuitinsight.com/uploads/2/voids_smt_solder_joints_trends_automotive_electronics_ipc.pdf
  30. https://www.infineon.com/package/PG-TO252-2-1
  31. https://manuals.plus/asin/B092V8FN8P
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  35. https://www.analog.com/media/en/quality/RoHS_Compliance_General_Info.pdf
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  41. https://madpcb.com/glossary/d2pak/
  42. https://www.nexperia.com/packages/SOT428.html
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  49. https://www.onsemi.com/pdf/datasheet/fdd6670a-d.pdf
  50. http://www.ctksemi.com/news/industry-information/hot-selling-to-252-mosfet-selection.html
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  52. https://www.onsemi.com/pdf/datasheet/fdb86569_f085-d.pdf
  53. https://www.ti.com/lit/pdf/slva158
  54. https://www.onsemi.jp/download/application-notes/pdf/eb201-d.pdf
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