1 от 1

Mitsubishi Electric Q03UDVCPU MELSEC Q Series CPU Module

Mitsubishi Electric Q03UDVCPU MELSEC Q Series CPU Module

Only 10 item(s) left in stock
  • Manufacturer: Mitsubishi Electric

  • Product No.: Q03UDVCPU

  • Country of origin:Съединени щати

  • Product Type: PLC CPU Modules

  • Payment: T/T, Western Union

  • Weight: 1200g

  • Dimensions: 27.4 mm x 98 mm x 115 mm

  • Shipping port: Xiamen

  • Warranty: 12 months

Количество
Покажи пълните подробности

Description

Engineered for high-speed sequence execution and seamless plant network integration, the Mitsubishi Electric Q03UDVCPU serves as a high-performance central processing unit within the MELSEC Q Series automation platform. This universal high-speed CPU is designed to meet the rigorous demands of complex manufacturing systems, delivering an ultra-fast instruction execution speed of 1.9 ns for basic LD operations. With its built-in RJ45 Ethernet port, the module enables robust device-level communication, diagnostic telemetry, and programming access without requiring dedicated network interfaces. Its architecture supports a substantial 30K step program capacity, alongside dual-slot scalability via standard SD/SDHC cards, making it an ideal choice for data-intensive logging and precision motion control coordination across modern industrial architectures.

Features

  • Ultra-High-Speed Processing: Achieves a 1.9 ns execution time for basic LD instructions and 3.9 ns for MOV instructions to minimize controller scan times.
  • Integrated Ethernet Interface: Built-in 10/100 Mbps RJ45 port supports up to 16 simultaneous socket connections, MC Protocol, and MELSOFT connections.
  • Flexible Memory Architecture: Features 120 KB program capacity and 192 KB standard RAM, expandable using extended SRAM cassettes.
  • Onboard SD/SDHC Support: Native card slot supports standard storage media up to 32 GB for secure data logging, recipe handling, and automated system backups.
  • Multi-Language Programming: Fully compatible with structured text (ST), function blocks, SFC (MELSAP 3), and traditional ladder logic.

Applications

  • High-speed multi-axis synchronized packaging systems.
  • Automotive assembly line tracking and component handling cells.
  • Distributed water treatment infrastructure utilizing telemetry systems.
  • Precision semiconductor thermal processing and indexing machinery.

Technical Specifications

Parameter Specification Value
Manufacturer Mitsubishi Electric
Model Code Q03UDVCPU
Control Method Stored program iteration operation
Program Capacity 30K steps (120 KB)
LD Instruction Speed 1.9 ns
Physical I/O Points 4096 points
Standard RAM / ROM 192 KB / 1025.5 KB
Internal Current Consumption (5 VDC) 0.58 A (Base Unit) / 0.60 A (with SRAM Cassette)
Supported Storage SD/SDHC memory card (up to 32 GB)
Built-in Ports RJ45 Ethernet, Mini-USB, SD Card Slot
Operating Ambient Temperature 0 to 55 degC
Net Weight 0.20 kg
Dimensions (W x H x D) 27.4 mm x 98 mm x 115 mm
Shipping Weight (Calculated) 1.20 kg

Empirical Engineering Insights

Alternative Models & Compatibility

The Q03UDVCPU represents the high-speed universal evolution of the older Q03UDECPU. When upgrading existing legacy systems, note that the V-series uses an integrated SD/SDHC card slot rather than the legacy CompactFlash or PCMCIA card options. To ensure system logic and task allocation compile correctly, your engineering team must update the target PLC type to 'Q03UDV' within GX Works2 (version 1.98C or higher) or GX Works3 before performing a code download.

Application Pitfalls & Engineering Notes

While the program memory is non-volatile, retaining latched parameters, registers (D, W), and internal system clock data relies on the Q6BAT lithium backup battery. In environments with ambient operating temperatures consistently exceeding 45 degC, the battery decay curve accelerates. It is highly recommended to monitor special register SD8005 (Battery Low Flag) via your SCADA system or local HMI to schedule preventative maintenance before data loss occurs.

Commissioning & Wiring Tips

For reliable Ethernet connectivity, ensure the RJ45 industrial cabling is shielded (S/FTP) and routed away from high-voltage inverter output cables. When configuring the built-in Ethernet parameters in your GX programming suite, double-check that the IP address range does not conflict with active IP routes on your company's network. In addition, you should always connect the base unit's functional ground (FG) terminal directly to a low-impedance earth ground to protect against high-frequency transient switching noise.

Installation Guidelines

CRITICAL SAFETY WARNING

Always isolate all main electrical power supplies feeding the backplane assembly (such as the Q38B or Q312B main bases) before inserting or removing the Q03UDVCPU module. Attempting hot-swapping or handling the CPU while the power supply unit is active will lead to immediate damage of the backplane bus interface and potential failure of neighboring I/O modules.

1
Ensure the main power supply module installed on the base unit is fully powered off and verified using a calibrated voltmeter.
2
Align the lower hook of the Q03UDVCPU with the module guide hole located on the slot 0 position of the MELSEC Q series base unit.
3
Push the top of the module firmly toward the backplane until the upper latch securely snaps into position, then tighten the module fixing screw (M3) to a torque rating of 0.36 to 0.48 N-m.
4
Insert the SD card if required, verify memory card lock is engaged, and connect your shielded RJ45 communication cable into the built-in Ethernet port before restoring control power.

What is the primary difference between the Q03UDVCPU and the older Q03UDECPU?

The Q03UDVCPU features a significantly faster processor (1.9 ns instruction execution vs 9.5 ns on the Q03UDECPU) and replaces the legacy memory card interfaces with an integrated SD/SDHC card slot supporting up to 32 GB.

Does the Q03UDVCPU retain program code when the battery is completely discharged?

Yes, the main ladder program and parameter configurations are written directly to the non-volatile standard ROM, which does not require power. However, standard latch registers, clock settings, and standard RAM variables require a functional Q6BAT battery to remain retentive during power-downs.

Which software is required to program this CPU module?

The Q03UDVCPU is programmed using Mitsubishi's GX Works2 (version 1.98C or later) or GX Works3. Programming can be done via the integrated USB Mini-B port or through the built-in RJ45 Ethernet port.

What is the maximum number of physical I/O points supported by this CPU?

The Q03UDVCPU supports a maximum of 4096 physical input/output points directly connected to the local or extension backplanes, with a total device addressable space of up to 8192 points.

Глобална експресна доставка

  • Стандартна доставка: 4-6 работни дни чрез DHL, FedEx и UPS.
  • Експресна изпращане: Изпращане в същия ден за налични поръчки, направени преди 14:00 ч. (GMT+8).
  • Глобално покритие: Обслужваме над 150 държави, включително бърза доставка до Саудитска Арабия и ОАЕ.

Връщания и гаранция

  • 30-дневна гаранция: Връщания се приемат за налични продукти в оригинална, фабрично запечатана опаковка.
  • 12-месечна гаранция: Всеки индустриален компонент е подкрепен с нашата професионална техническа гаранция.

Поръчките се обработват и доставят от понеделник до петък (с изключение на официалните празници).


За пълна информация относно допустимост, такси за презареждане и международни връщания, моля, разгледайте нашия официален Политика за възстановяване и връщане .

TECHNICAL SPECIFICATIONS

Country of origin
Съединени щати

Наскоро разгледани продукти

Технически знания

Електрически задвижващи механизми, проектирани да заменят хидравлични и пневматични системи: Практическо ръководство за индустриална автоматизация

Тази статия обяснява как интегрираните електрически задвижвания, като серията e-Actuator на SMC, трансформират индустриалното управление на движението, като заменят традиционните пневматични и...

Математически операции с OpenPLC за индустриални автоматизационни приложения

Тази статия обяснява как PLC системите изпълняват основни математически операции като събиране, изваждане, умножение, деление, модуло и степенуване в индустриалната автоматизация. Показва как тези...

Разширена булева логика с FBD PLC програмиране: Практически индустриални приложения отвъд основната логика

Статията обяснява няколко усъвършенствани булеви логически функции, използвани в програмирането на PLC, извън основните операции AND, OR и NOT. Тя разглежда как инструменти като таблици на...

Булева логика в програмирането на PLC: Разбиране на логическите врати в FBD

Булевата логика е основата на всяка програма за PLC. От прости машинни управления до сложни индустриални автоматизационни системи, логическите врати определят как контролерите реагират на променящите...

Подробно ръководство за индустриални защитни стени и сегментиране на OT мрежи

Индустриалните защитни стени играят ключова роля в киберсигурността на OT, като защитават мрежите PLC, DCS и SCADA чрез сегментация, контрол на входящия/изходящия трафик и интеграция на IDS/IPS в...

Ръководство за роботизирани захвати: от деликатно боравене до тежка автоматизация

Съвременните роботизирани захвати се развиват отвъд традиционните механични челюсти. От системи с лепкави повърхности, вдъхновени от геконите, и меки захвати за хранителни продукти до инструменти за...