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Advanced Manufacturing Technology Lab

EdNex uses innovation to drive the future of manufacturing and related logistic sectors. We embrace emerging technologies and applications to build well-equipped manufacturing technology labs for your organization. Our methods focus on enhancing output, increasing value and quality, reducing waste and emissions, and increasing the overall efficiency of your advanced manufacturing facilities.

We equip your next-gen facilities with 3D printers, CNC routers, and vacuum foaming, as well as laser cutting, welding, and casting machines. We customize our advance machining tools and manufacturing lab solutions to meet your organisation’s needs and offer great flexibility with no excessive capital investment. Our team has expertise in everything from concept to end-of-life considerations, giving you the technological edge needed to create the skilled workforce of tomorrow.

Autonomous Vehicles

The QBot 2e is an innovative open-architecture autonomous ground robot, equipped with built-in sensors, and a vision system. Accompanied by extensive courseware, the QBot 2e is ideally suited for teaching undergraduate and advanced robotics and mechatronics courses, surpassing capabilities of hobby-level robotic platforms. The open-architecture control structure allows users to add other off-the-shelf sensors and customize the QBot 2e for their research needs.

The QBot 2e is built on a two-wheel differential drive platform with built-in DC motors and sensors. It utilizes a wireless embedded computer to command motor velocity and measure the onboard sensors including bump, cliff, and RGBD. The embedded system also provides several I/O channels for interfacing additional digital and analog sensors. The integrated RGB camera and depth sensorsare capable of capturing RGB image data and 11-bit depth data and transmitting the data at a high frame rate. The QBot 2e operates using a host-target structure. Controllers are developed on the ground station host using QUARC for Simulink®. Real-time code is downloaded from the host to the QBot 2e embedded computer and allows users to run, modify and monitor code remotely from the host. The controllers on-board the QBot 2e are open-architecture and fully modifiable.

Virtual & Remote Labs: The Future Of Education 4.0

Virtual and remote labs have been around for almost 20 years and while they have been constantly gaining popularity since their appearance, the current Covid-19 Pandemic has brought to the fore the importance and the relevance of these labs as the most suitable and a permanent Solution for Future Engineering Labs. However, there are still many people in the Engineering education community who have very less information about these labs, their benefits, and which of these virtual and remote labs can be delivered for Engineering Education remotely and virtually.

Robotics Lab

Robotics and AI are indispensable when creating an integrated, inter-disciplinary approach for research and developing scientific methods. With EdNex Robotic Lab Solutions, you can equip your engineering students with the power to transform and update the traditional paradigms in robotics, mechatronics, and control systems.

EdNex takes considerable measures to integrate the most advanced robotics technology with your existing university-level curriculum. Our team works with you to design and build Robotics Labs that match your needs and train your teachers to ensure your students can make the most of these solutions.

Empower your students to explore, validate, and build key concepts in kinematics, dynamics, and control with the EdNex Robotics Lab setup. We provide universities with safe, efficient, and easy-to-use robotics tools for their engineering and robotics labs.

EdNex partners with technology leaders and world-class brands to bring the most suitable Robotics Tools for your lab. We aim to build a Robotics lab that aligns with your needs and objectives and supports your students in their learning, innovation, and invention.

Allcode Robot Arm Workcell

Technical Specifications

The Robot Arm covers 3 levels of teaching:

Technician Level

  • Investigating the workplace
  • Pendant Programming
  • G code programming

Production Engineer Level

  • Starting API programming
  • Simple production
  • Sorting & Pick and Place

Robot Designer Level

  • Kinematics calculations
  • Microcontroller programming

Robot Arm Overview

The robot arm production cell consists of a rugged stepper motor controlled 3 degrees of freedom arm bolted to a base plate and supplied with an activity mat that provides a range of exercises to replicate an industrial robot arm.

The free instructional guide includes worksheets in pendant, G code, API and microcontroller programming, sensors and actuators, kinematics and more. The user can connect the robot arm production cell to their hardware platform – Windows PC, Android mobile, Raspberry Pi/Linux device using USB, Bluetooth or Wi-Fi technology.

FAB Lab

Facilitate your student’s practical exposure to technology, experimentation, and prototyping with EdNex FAB Lab Solutions. Design and create a forward-thinking space that fosters innovative and efficient engineering projects- let students play, create, learn, and invent. Allow your students to learn and innovate with our advanced engineering lab solutions.

Our complete FAB Lab setup includes 3D Printers & Scanners, IoT & Electronics, Mechanical section with CNC Lathe, VMC & Laser cutting/ Engraving, Conventional Machines, Carpentry, Power Tools, Fabrication & Painting.

  • Design freedom
  • Lead times
  • Product customization
  • Product/Service cost scale
  • Material use
  • Supply chain decentralization

Metal One DMLS

We have created the smallest, most versatile and easiest to use metal powder 3D printer with DMLS technology.

It allows you to test your powders, start a print in just 15 minutes and have all the parameters at your disposal for any experiment or research.

  • TECHNOLOGY:   LPBF Laser Powder Bed Fusion Class 1 laser BS EN 60825-1:2014 + A11:2021
  • DIMENSIONS: 1050 x 600 x 1500 mm                             41.3 x 23.6 x 59.0 in
  • WEIGHT:  ca 315 kg (700 lb)
  • PRINTING VOLUME OPTIONS (max):
  • Small 65 x 65 x 100 mm  
              2.56 x 2.56 x 3.93 in
  • Big 100 x 100 x 100 mm  
              3.93 x 3.93 x 3.93 in
  • Z RESOLUTION: 30 microns (0.0012 in)
  • SPOT DIMENSION: 40 microns (0.0018 in)
  • LASER: Fiber (1064nm) – 300W, 500W or 1kW
  • GAS CONSUMPTION: 2.5 l/min (84.5 fl/oz/min)
  • GAS: Nitrogen – Argon
  • MINIMUM POWDER LOAD: 800 g (1.76 lb)
  • NETWORK CONNECTION

Some Characteristics May Change For Technical Reasons

  • Features
  • Open parameters
  • Remote control
  • Define laser movements with Gcode
  • Lan connectivity
  • Build in camera
  • Test mode for faster parameter search
  • Log file

Warranty one year
Technical support included for one year
Extended warranties and remote support option available

Snowwhite 2 Multi-Material

A new feature of SnowWhite2. With an update it is now possible to use two different materials for the creation of sintered objects (SLS).

Researchers will now have the possibility to control both the movement of the recoater and of each single powder distribution tank through intuitive and easy-to- manage commands, so from today they will have the possibility to test and create multi-material objects in a simple and intuitive way.

  • DIMENSIONS: 1500 x 600 x 600 mm
  • WEIGHT:  ca 120 Kg
  • PRINTING VOLUME: 100 x 100 x 100 mm (maximum)
  • Z RESOLUTION: 50 microns
  • XY RESOLUTION: 100 microns
  • LASER: CO2 (10640nm) – 14W
  • BUILDING SPEED (Z): up to 35 mm/h
  • SCAN SPEED: up to 3500 mm/s
  • HEATED CHAMBER: up to 190 °C
  • NETWORK CONNECTION
  • Some values may change for technical reasons

Metal One DMLS

We have created the smallest, most versatile and easiest to use metal powder 3D printer with DMLS technology.

It allows you to test your powders, start a print in just 15 minutes and have all the parameters at your disposal for any experiment or research.

  • Machine Specs and Features:
  • DIMENSIONS: 1500 x 600 x 600 mm
  • WEIGHT:  ca 150 Kg
  • PRINTING VOLUME: 50 x 50 x 50 mm (maximum)
  • Z RESOLUTION: 50 microns
  • XY RESOLUTION: 100 microns
  • LASER: CO2 (10640nm) – 14W
  • BUILDING SPEED (Z): up to 35 mm/h
  • SCAN SPEED: up to 3500 mm/s
  • POWDER BED: up to 350 °C
  • BUILD CYLINDER: up to 350 °C
  • LOAD CYLINDER: up to 350 °C
  • NETWORK CONNECTION

Some values may change for technical reasons

Stable temperature in build area
Designed for thermal camera installation
Temperature control for power and cylinders
Galvanometer system with f-Theta lens
All printing parameters are open
Log file available at the end of each process

Renewable Energy Lab

The world needs energy to function and progress. The widely-used non-renewable energy sources such as fossil, nuclear, and hydrocarbon are costly and nearby their end. It is time to transform into a new energy culture that embraces natural resources to produce and preserve energy that is non-pollutive and pocket-friendly. But where should the transformation begin? Building a society that is well aware of renewable energy possibilities is the first big step towards the successful migration to the renewable energy culture.

It is essential for students to learn about various renewable energy sources and the processes of harnessing them. Solar, wind, hydrogen cells, waves, tides, etc are the primary sources of renewable, sustainable, and clean energy. It is essential for an engineering student to be familiar with fundamental concepts of renewable energy, technologies that are being used to harvest and harness sustainable energy. Click here to download the technical presentation that will explain all the related devices and equipment along with its images to get a better perspective.

PCB Manufacturing System

  • Only machine which perform Drilling, Printing, Soldering and Reflow
  • It creates single & double sided PCB’S.
  • Build hardware faster
  • Print your own circuit boards (FR1, FR4, Kaplan or Polymer sheets)
  • It Loads the Gerber Files into V-One Software.
  • Dispenses Solder Paste on any Circuit Board
  • Quickly drill holes for vias and through holes components.
  • Print Area 128mm × 116mm
  • Minimum Trace Width 0.2mm

Make: VOLTERA, Model: NOVA

  • It Provides Pressure based dispensing.
  • Enables Inspection through integrated Vision System.
  • Print anything on everything.
  • Enhanced Material Flexibility.
  • Provides Software for everyone.
  • Has Modular Platform.
  • Print area 220 mm x 300 mm
  • Measurement resolution +/- 2.5μm (Z-axis step resolution)
  • Minimum tracewidth *100μm (0.10mm) using ACI FE3124 + 100μm nozzle
  • Print height resolution +/- 10μm (0.01 mm)
  • Minimum pin pitch 400μm (0.4mm)
  • Minimum passive 0201* Imperial
  • Inks ACI FE3124
  • Substrates PET, Kapton
  • Solder pastes Nordson T4 SnBiAg0.4

Double Sided PCB Mill & Engraving Machine:

Make: WEGSTR, Model : Wegstr CNC – PCB

  • It can perform Drilling, Milling and Engraving Etching.
  • It Provides Compact design and Precision Tooling.
  • Milling workspace : 140 mm (5.51 inch) (X) x 200 mm (7.87 inch) (Y) x 40 mm (1.58 inch) (Z)
  • Diameter of spindle: 3.175 mm (0.125 inch)
  • Connectivity: USB, USB cable length: 1.6 m (63 inch)
  • Repeatability: 0.02 mm
  • Spindle speed: 11 000 rpm
  • It provides Cut 2D software for PCB machining
  • It mills both soft and hard plastic, wood, aluminium, duralumin, PCB, balsa wood, MDF, Plexiglass, iron, copper, brass, bronze, gold, silver and more.
  • It is suitable for engineers, model makers, hobbyists, goldsmiths, jewellers, watchmakers, educational institutions and many others.

Multilayer Advanced PCB Printing Machine:

Make : BOTFACTORY, US

Model: SV2 – Starter, Enhanced, Professional

  • Capable of printing multilayer circuits ( 2- 4 Layers)
  • Dispensing paste onto pads,
  • Pick-and-place components to rapidly assemble your board, using multiple vacuum tips that are automatically interchanged.
  • It also uses a camera and computer vision to make adjustments and place the parts precisely.
  • Inkjet print low-resistivity conductive inks and dielectric insulating inks to make Printed Circuit Boar
  • Export your Gerber files from any PCB Design tool and import
  • Min Trace Width: 8 mil [200 microns]
  • Min Clearance: 8 mil [200 micron] – 16 mil (400 micron)
  • minimum pitch size = 0.4- 0.6mm

PCB - Vision Inspection System

  • PCB inspection is the act of mitigating errors or mistakes during Fabrication & Assembly Process.
  • Vision systems are capable of measuring parts, verifying parts are in the correct position, and recognizing the shape of parts.
  • Microscope has one HDMI port and two USB ports
  • Unique all-in-one Machine design.
  • Microscope has built in software to View, Capture the images & Record Videos and store it in a USB Disk
  • Measuring results can be sent to Excel.
  • Measuring Accuracy: within +_8 microns.

Flowcode Software

  • Flowcode is an advanced integrated development environment (IDE) for electronic and electromechanical system.
  • Flowcode targets microcontrollers such as Arduino, PIC and Raspberry Pi.
  • Non-programmer friendly
  • Choice of programming methods; flowcharts, blocks, pseudo, C
  • Multiple platform support and “code porting”
  • Advanced Simulation
  • Debugging systems – simulation debugging & code profiling

Laser Cutting Machine - C02:

  • High cutting precision and positional accuracy
  • Improved edge quality and surface finish
  • Higher repeatability
  • Advanced laser tools for material processing applications
  • Drilling and engraving in addition to cutting
  • Negligible work piece degradation
  • Cost-effectiveness
  • Minimal thermal stress zone
  • Shapes High Speed belt drive plotting unit with precise micro stepping drives
  • Red beam pointer
  • Z- Axis (Optional)

Structural Health Monitoring & Shake Table Lab

We offer designing technologies, products, and solutions for structural engineering and earthquake engineering.

TDG - researches, develops and offers innovative & high-quality data acquisition systems, sensors, servo-testing machines and earthquake simulators, that rapidly adapt and fit best to the requirements of customers on the global market.

Advanced Artificial Intelligence Labs

EdNex helps universities across India to build advanced AI Labs at your campus and offer structured courses in fundamentals of AI, machine learning, and IoT for your students.

At EdNex, we aim to empower learning and accelerate the adoption of AI in the industry with our innovative AI Lab setups for universities. We equip your AI labs with the latest technologies, allowing students to apply the advanced concepts of AI and machine learning to solve complex, real-world problems, thereby preparing them for successful careers.

  • Machine Learning – What is machine learning? – Types of machine learning – Machine learning algorithm
  • Practice Equipment Introduction
  • Raspberry Pi – Introduction and development environment setting
  • TensorFlow – Introduction to TensorFlow – Development environment to use TensorFlow – Using TensorFlow function – Implement algorithm using TensorFlow
  • Google Assistant – Introduction to G.A – G.A development environment setup and account setup – First conversation with G.A – Device control using speech recognition

IOT Lab Solutions

IoT is developing quickly and being adopted in many different areas and engineers need to know a variety of skills to design and implement an IoT system. Engineering schools and departments face the huge challenge of motivating and preparing their students for challenging technology careers and help them fully understand IOT applications, the mechanisms and their significance in the future.

In order to build a sustainable workforce for the future, and to train the current workforce on these emerging technologies, institutions must adapt their curricula to include these topics to effectively address this gap.

Autonomous Vehicle Lab

The QBot 2e is an innovative open-architecture autonomous ground robot, equipped with built-in sensors, and a vision system. Accompanied by extensive courseware, the QBot 2e is ideally suited for teaching undergraduate and advanced robotics and mechatronics courses, surpassing capabilities of hobby-level robotic platforms. The open-architecture control structure allows users to add other off-the-shelf sensors and customize the QBot 2e for their research needs.

The QBot 2e is built on a two-wheel differential drive platform with built-in DC motors and sensors. It utilizes a wireless embedded computer to command motor velocity and measure the onboard sensors including bump, cliff, and RGBD. The embedded system also provides several I/O channels for interfacing additional digital and analog sensors. The integrated RGB camera and depth sensorsare capable of capturing RGB image data and 11-bit depth data and transmitting the data at a high frame rate. The QBot 2e operates using a host-target structure. Controllers are developed on the ground station host using QUARC for Simulink®. Real-time code is downloaded from the host to the QBot 2e embedded computer and allows users to run, modify and monitor code remotely from the host. The controllers on-board the QBot 2e are open-architecture and fully modifiable.

Structural Health Monitoring Lab

This product is the most innovative & high-tech solution for seismic monitoring networks, developed by TDG. It includes an ultra low noise three component seismic internal accelerometer, which breaks the boundaries of conventional recorders. This digital system offers excellent noise performance and unmatched resolution, providing simultaneous sampled acceleration data through the ethernet interface. The product is equipped with an embedded linux powered single board computer system, easily handling all the connection, configuration, data processing, data transfer, event-handling and storage tasks. The unit offers the best price-performance ratio and the most innovative design of its class.

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