Ebod 917 Fix Jun 2026

The video stars Himari Nozaki (also credited as Himari Nosaki). At the time of this release, Nozaki was a rising solo actress known for her slender frame coupled with a natural, larger-than-average bust measurement, fitting squarely into E-BODY’s target casting archetype.

EBOD-917 is part of a long-running numerical series. As of 2025, this specific title is considered a back-catalog item. It is not a compilation or "best-of" disc; it features original, exclusive footage. The title is region-coded for Japan (NTSC, Region 2 for DVD) but is widely available via licensed digital JAV distribution platforms globally.

| Register | Function | Description | Typical Value | |----------|----------|-------------|---------------| | 40001‑40004 | Input Registers | Raw 16‑bit ADC values for Channels 1‑4 | 0–65535 | | 40101 | Holding Register | Channel 1 scaling factor (e.g., 1000 = 1 V) | 1000 | | 40102 | Holding Register | Channel 2 scaling factor | 1000 | | 40110‑40113 | Holding Registers | Zero‑offset correction per channel | 0 | | 40200 | Coil | Module “Reset” (1 = reset) | 0/1 | | 40201‑40204 | Coils | Channel enable (1 = active) | 1 | | 40300 | Input Register | Status word (bit‑0 = fault, bit‑1 = over‑range, …) | – | ebod 917

| Category | Key Points | |----------|------------| | | The EBOD‑917 is a compact, 4‑channel, isolated analog input module used primarily in industrial automation and data‑acquisition systems. It is designed to accept voltage or current signals and feed them to a PLC, DCS, or PC‑based monitoring platform. | | Typical Applications | • Process monitoring (temperature, pressure, flow) • Remote sensor interfacing • Laboratory data acquisition • Energy‑metering front‑ends | | Physical Specs | • Dimensions: 120 mm × 80 mm × 30 mm (H × W × D) • Weight: ~250 g • Mounting: DIN‑rail or panel‑mount (screw holes M3) | | Electrical Specs | • Input Types: Voltage (±10 V, 0‑10 V) or current (4‑20 mA) selectable per channel • Isolation: 1500 V dc (per IEC 61010‑1) • Supply: 24 V DC ± 10 % (max 150 mA) • Resolution: 16‑bit ADC (≈0.305 mV per LSB on a ±10 V range) | | Communications | • Primary Interface: Modbus‑RTU (RS‑485) up to 115.2 kbps • Optional: Ethernet‑TCP (via add‑on converter) • Addressing: 1‑247 (configurable via dip‑switches) | | Environmental Ratings | • Operating Temp: –25 °C to +70 °C (industrial) • Storage Temp: –40 °C to +85 °C • Ingress Protection: IP20 (non‑sealed) – use a protective enclosure for harsh environments | | Safety & Compliance | • CE, UL, IECEx (explosion‑proof version available) • Built‑in short‑circuit and over‑voltage protection (clamps at 12 V/24 mA) | | Typical Wiring | 1. Power: Connect 24 V DC to V+ and V‑ terminals, observing polarity. 2. Signal: For a 4‑20 mA loop, connect sensor + to I+ and sensor – to I‑ (or use a shunt resistor for voltage mode). 3. Ground: The module chassis ground may be tied to the system ground if isolation requirements allow. | | Common Setup Steps | 1. Power up the module and verify the status LED (green = OK, amber = warning, red = fault). 2. Set the Modbus address using the dip‑switches (refer to the user manual for binary mapping). 3. Configure channel type (V or I) via the onboard switch or through a configuration tool (if the firmware supports it). 4. Map the channels in your PLC/DCS software (e.g., assign registers 40001‑40004 for the four inputs). | | Typical Troubleshooting | • No data / dead LED – Check 24 V supply polarity and continuity. • Random spikes – Verify proper shielding of sensor cables; add a 120 Ω termination at the RS‑485 line. • Incorrect scaling – Confirm the channel mode (V vs. I) matches the sensor type and that the correct calibration factor is applied in software. • Isolation fault – Measure the isolation resistance (>1 MΩ is expected). If it’s low, the module may have been exposed to a surge. | | Maintenance Tips | • Periodically inspect connector pins for corrosion, especially in humid or salty environments. • Keep the module’s ventilation openings clear; dust can affect heat dissipation. • Perform a firmware check annually—new releases often include improved noise filtering. | | Useful Resources | • User Manual (PDF) – includes wiring diagrams, dip‑switch tables, and register map. • Quick‑Start Guide – 2‑page PDF for “plug‑and‑play” installation. • Firmware Update Utility – Windows‑based tool (v1.3.4). • Technical Support – Email: support@ebod‑tech.com, Phone: +1‑800‑555‑0199 (8 am–5 pm EST). |

Just point me to the area that matters most to you, and I’ll dive deeper! The video stars Himari Nozaki (also credited as

EBOD-917 Studio: E-BODY (a label of WANZ FACTORY) Release Date: September 2021 (Standard DVD release)

The chassis has also undergone significant revisions, featuring Saleen's proprietary suspension, braking, and tire packages to ensure optimal handling and grip. These enhancements result in a more responsive, more agile driving experience, especially when pushed beyond the limits of a standard production Mustang. Additional features, such as a modified interior with leather and aluminum trim, as well as unique Saleen badging, complete the package. As of 2025, this specific title is considered

The EBOD 917 is an offshoot of the popular Saleen Mustang program, which began in the 1990s and aimed to create high-performance, bespoke versions of Ford's iconic muscle car. The program's name, "EBOD," is an acronym for "Engineered by Saleen, Optimized by DiMarco," referring to the partnership between Saleen Automotive and DiMarco Engineering. Born from this collaboration, the EBOD 917 represents the pinnacle of Saleen's Mustang creations, boasting an impressive array of upgrades to push the boundaries of performance and handling.

The current market price of an EBOD 917 can range anywhere from $150,000 to over $250,000, depending on the condition of the vehicle, mileage, and overall authenticity. These prices reflect the car's rarity, the level of craftsmanship that went into each unit, and the value placed on the Saleen brand.

– With up to 247 devices on the same RS‑485 network, a simple spreadsheet listing each module’s address, location, and channel assignments saves a lot of head‑scratching later.