our expertise

We are a multidisciplinary team of experts, bringing together mechanical, electrical, material, and production engineers alongside embedded hardware, software, and cybersecurity specialists. Our team consists of engineers, scientists and researchers blending deep academic knowledge with hands-on industry experience.

TIZ Glagol is a rapidly growing development hub with strong engineering, design and manufacturing knowledge and the fastest working team you’ll work with.

services

mechanical engineering

  • extremely rapid mechanical prototyping
  • structure design and analysis
  • DFM – design for manufacturing
  • vehicle engineering and design
  • pneumatic and electric machine design
  • sheetmetal forming tool design
  • high-level surface design
  • micro-machines and assemblies 
development

materials engineering

  • examination of physical and chemical properties of materials
  • targeting specific characteristics
  • characterization of materials
  • mechanical, chemical, electrical, thermal, optical, magnetic properties
  • processing of materials
  • metals, ceramics, polymers, composites
  • multifunctional materials
  • recycling

electrical engineering

  • PCB design (schematic, PCB layout)
  • power electronics design
  • high speed layout
  • design for mass production
  • system wide simulations (electronics, thermal, control loop)
  • component obsolescence management
  • EMC / Safety compliance consulting
  • test automation platforms
  • functional safety for HW
  • requirements management

for embedded engineering, software development and cybersecurity visit quarksteam.com

mechanical engineering capacities

  • 3D printing (any material any size)
  • Sheetmetal forming 
(all small series processes)
  • Vacuum plastic forming 
(1500x1500mm, ~5mm thickness)
  • TIG/MIG welding
  • Composite parts manufacture
  • QC and measuring station
  • Product assembly lines
  • Electrical testing
  • Machining of all types
  • Laser cutting of sheetmetal and 
profiles
  • Powdercoating

success stories

bespoke designer e-bikes

Goal
Transform a startup-level project into a fully developed engineering initiative and launch small-scale production.

Activities and Technologies

  • Complete Digitalization: Convert all existing parts and drawings into an integrated, structured CAD project.
  • Design Optimization: Refine the bike’s design and develop new components and assemblies.
  • Tooling & Manufacturing Setup: Design and produce welding jigs and specialized tooling.
  • Small-Series Production of Designer E-Bikes, including:
    • Full preparation for production.
    • Precision manufacturing of complex steel tube components.
    • Welding and post-processing of all frames and parts.
    • Fabrication of intricate components using SLA resin 3D printing.

Results
Production and delivery of the first units within four months of project initiation.

firefighter vision-through-smoke system

Goal
Design and manufacture the complete housing for a specialized thermal vision device, integrating an externally mounted helmet camera and an internal AR lens for real-time video playback.

Activities and Technologies

  • Comprehensive Digitalization: Convert all existing parts and drawings into a structured CAD project.
  • Iterative Design Process: Develop multiple design solutions, refining over 30 iterations to optimize user field of view, comfort, and reliability.
  • Prototyping & Manufacturing:
    • Produce prototypes using FDM and SLA 3D printing.
    • Vacuum form the helmet visor to seamlessly accommodate new components.

Results
The project is ongoing, with positive user feedback so far.

power metering solution

Goal
Develop a versatile power metering solution for mobile equipment and machinery, capable of:

  • Power control (on/off switching).
  • User identification and per-user power consumption tracking.
  • Ensuring safety features for reliable operation.
  • OCPP communication to generate reports and invoices.

Activities & Technologies

  • End-to-end development, covering:
    • Housing design for durability and compactness.
    • Electronics engineering for precise metering and control.
    • Firmware development for seamless device operation and OCPP integration.

Results

  • A compact, reliable power metering device.
  • Prototypes completed, with final product details under NDA until the official announcement.

six-axis phone testing robot

Goal
Execute a two-phase project:

  • Phase 1 – Production and assembly of 25 units based on the client’s existing design.
  • Phase 2 – Complete redesign of the machine for optimized medium-series production.

Phase 1 activities

  • Establishment of a production and assembly line.
  • In-house 3D printing of:
    • 150+ kg of standard plastic components.
    • 20+ kg of high-strength resin parts.
  • Manufacturing and testing of low-voltage cables.
  • Ad-hoc design improvements during production.
  • Quality control, testing, and delivery of 25 units.

Phase 2 activities

  • Full machine redesign, transitioning to manufacturing methods suited for medium-series production:
    • Laser cutting.
    • Sheet metal forming.
    • Vacuum forming.
  • Extensive prototyping and testing.
  • Final optimized solution delivered to the client.

Results

  • ~10x reduction in total part count.
  • 50% cost reduction per unit.
  • Production time per unit reduced from 30 hours to just 7 hours.

electric cars battery testing

Goal
Collaborate with the Institute of General and Physical Chemistry to develop lithium battery technology for the automotive industry. The project, conducted under NDA, focuses on material design and testing in both laboratory and field conditions.

Activities and Technologies

  • Material Design: Development and refinement of battery materials.
  • Equipment Development: Designing and manufacturing specialized testing equipment.
  • Testing & Validation:
    • Laboratory experiments to analyze performance.
    • Field testing at a dedicated proving ground.
  • Data Analysis: Logging, interpreting, and refining results to optimize battery performance.

Results

  • Successful collaboration with positive client feedback.
  • Strong test results, leading to an upcoming next phase.
  • One of the largest and most complex projects undertaken so far.

bmw 1 race suspension

Goal
Develop a new, adjustable inboard pushrod-rocker suspension to enhance track performance, incorporating feedback from professional racers.

 

Activities and Technologies

  • 3D Scanning & Digitization: Capture and extract all relevant vehicle geometry.
  • Suspension Analysis: Evaluate the existing system using multi-body dynamic simulations.
  • Advanced Suspension Design:
    • Implement cutting-edge design techniques, rarely utilized in Serbia.
    • Optimize geometry for improved handling and performance.
  • Structural Calculations & Simulations: Ensure optimal strength-to-weight ratio.
  • Prototyping & Testing:
    • Iterative development with real-world vehicle testing.
    • Manufacturing in-house (machining & welding).
    • Final installation and track testing with the client.

Results

Testing is currently in progress.

racing peugeot system upgrade

Goal

Design and manufacture completely new wheel uprights and optimize the steering system for enhanced racing performance.

 

Activities & Technologies

  • 3D Scanning & Digitization: High-precision scanning of the car segment, converted into a detailed CAD model.
  • Suspension & Steering Analysis: Extracting and analyzing critical geometry to optimize performance.
  • Topology Optimization:
    • Redesigning the wheel uprights for maximum strength and minimal weight.
    • Preparing components for CNC milling.
  • Manufacturing & Testing:
    • Precision machining and assembly.
    • On-track testing to fine-tune the steering system.

Results

  • New uprights are 2× lighter and stronger than the originals.
  • Steering system optimized for peak racing performance.

composite wing for audi tt

Project Goal
Design and develop a high-performance, regulation-compliant composite rear wing for an Audi TT, tailored to the client’s specifications.

 

Activities & Technologies

  • CAD Design & Simulations: Optimizing aerodynamics and structural integrity.
  • Composite Engineering: Developing a lightweight yet durable wing using advanced composite materials.

Results
The final product was technically successful.

simulations

testing and validation

our expertise

We are a multidisciplinary team of experts, bringing together mechanical, electrical, material, and production engineers alongside embedded hardware, software, and cybersecurity specialists. Our team consists of engineers, scientists and researchers blending deep academic knowledge with hands-on industry experience.

TIZ Glagol is a rapidly growing development hub with strong engineering, design and manufacturing knowledge and the fastest working team you’ll work with.

services

mechanical engineering

  • Extremely rapid mechanical prototyping
  • Structure design and analysis
  • DFM – design for manufacturing
  • Vehicle engineering and design
  • Pneumatic and electric machine design
  • Sheetmetal forming tool design
  • High-level surface design
  • Micro-machines and assemblies 
development

materials engineering

  • examination of physical and chemical properties of materials
  • targeting specific characteristics
  • characterization of materials
  • mechanical, chemical, electrical, thermal, optical, magnetic properties
  • processing of materials
  • metals, ceramics, polymers, composites
  • multifunctional materials
  • recycling

electrical engineering

  • PCB design (schematic, PCB layout)
  • power electronics design
  • high speed layout
  • design for mass production
  • system wide simulations (electronics, thermal, control loop)
  • component obsolescence management
  • EMC / Safety compliance consulting
  • test automation platforms
  • functional safety for HW
  • requirements management

for embedded engineering, software development and cybersecurity visit quarksteam.com

mechanical engineering capacities

  • 3D printing (any material any size)
  • Sheetmetal forming 
(all small series processes)
  • Vacuum plastic forming 
(1500x1500mm, ~5mm thickness)
  • TIG/MIG welding
  • Composite parts manufacture
  • QC and measuring station
  • Product assembly lines
  • Electrical testing
  • Machining of all types
  • Laser cutting of sheetmetal and 
profiles
  • Powdercoating

success stories

bespoke designer e-bikes

Goal
Transform a startup-level project into a fully developed engineering initiative and launch small-scale production.

Activities and Technologies

  • Complete Digitalization: Convert all existing parts and drawings into an integrated, structured CAD project.
  • Design Optimization: Refine the bike’s design and develop new components and assemblies.
  • Tooling & Manufacturing Setup: Design and produce welding jigs and specialized tooling.
  • Small-Series Production of Designer E-Bikes, including:
    • Full preparation for production.
    • Precision manufacturing of complex steel tube components.
    • Welding and post-processing of all frames and parts.
    • Fabrication of intricate components using SLA resin 3D printing.

Results
Production and delivery of the first units within four months of project initiation.

firefighter vision-through-smoke system

Goal
Design and manufacture the complete housing for a specialized thermal vision device, integrating an externally mounted helmet camera and an internal AR lens for real-time video playback.

Activities and Technologies

  • Comprehensive Digitalization: Convert all existing parts and drawings into a structured CAD project.
  • Iterative Design Process: Develop multiple design solutions, refining over 30 iterations to optimize user field of view, comfort, and reliability.
  • Prototyping & Manufacturing:
    • Produce prototypes using FDM and SLA 3D printing.
    • Vacuum form the helmet visor to seamlessly accommodate new components.

Results
The project is ongoing, with positive user feedback so far.

power metering solution

Goal
Develop a versatile power metering solution for mobile equipment and machinery, capable of:

  • Power control (on/off switching).
  • User identification and per-user power consumption tracking.
  • Ensuring safety features for reliable operation.
  • OCPP communication to generate reports and invoices.

Activities & Technologies

  • End-to-end development, covering:
    • Housing design for durability and compactness.
    • Electronics engineering for precise metering and control.
    • Firmware development for seamless device operation and OCPP integration.

Results

  • A compact, reliable power metering device.
  • Prototypes completed, with final product details under NDA until the official announcement.

six-axis phone testing robot

Goal
Execute a two-phase project:

  • Phase 1 – Production and assembly of 25 units based on the client’s existing design.
  • Phase 2 – Complete redesign of the machine for optimized medium-series production.

Phase 1 activities

  • Establishment of a production and assembly line.
  • In-house 3D printing of:
    • 150+ kg of standard plastic components.
    • 20+ kg of high-strength resin parts.
  • Manufacturing and testing of low-voltage cables.
  • Ad-hoc design improvements during production.
  • Quality control, testing, and delivery of 25 units.

Phase 2 activities

  • Full machine redesign, transitioning to manufacturing methods suited for medium-series production:
    • Laser cutting.
    • Sheet metal forming.
    • Vacuum forming.
  • Extensive prototyping and testing.
  • Final optimized solution delivered to the client.

Results

  • ~10x reduction in total part count.
  • 50% cost reduction per unit.
  • Production time per unit reduced from 30 hours to just 7 hours.

electric cars battery testing

Goal
Collaborate with the Institute of General and Physical Chemistry to develop lithium battery technology for the automotive industry. The project, conducted under NDA, focuses on material design and testing in both laboratory and field conditions.

Activities and Technologies

  • Material Design: Development and refinement of battery materials.
  • Equipment Development: Designing and manufacturing specialized testing equipment.
  • Testing & Validation:
    • Laboratory experiments to analyze performance.
    • Field testing at a dedicated proving ground.
  • Data Analysis: Logging, interpreting, and refining results to optimize battery performance.

Results

  • Successful collaboration with positive client feedback.
  • Strong test results, leading to an upcoming next phase.
  • One of the largest and most complex projects undertaken so far.

bmw 1 race suspension

Goal
Develop a new, adjustable inboard pushrod-rocker suspension to enhance track performance, incorporating feedback from professional racers.

Activities and Technologies

  • 3D Scanning & Digitization: Capture and extract all relevant vehicle geometry.
  • Suspension Analysis: Evaluate the existing system using multi-body dynamic simulations.
  • Advanced Suspension Design:
    • Implement cutting-edge design techniques, rarely utilized in Serbia.
    • Optimize geometry for improved handling and performance.
  • Structural Calculations & Simulations: Ensure optimal strength-to-weight ratio.
  • Prototyping & Testing:
    • Iterative development with real-world vehicle testing.
    • Manufacturing in-house (machining & welding).
    • Final installation and track testing with the client.

Results

Testing is currently in progress.

racing peugeot system upgrade

Goal

Design and manufacture completely new wheel uprights and optimize the steering system for enhanced racing performance.

 

Activities & Technologies

  • 3D Scanning & Digitization: High-precision scanning of the car segment, converted into a detailed CAD model.
  • Suspension & Steering Analysis: Extracting and analyzing critical geometry to optimize performance.
  • Topology Optimization:
    • Redesigning the wheel uprights for maximum strength and minimal weight.
    • Preparing components for CNC milling.
  • Manufacturing & Testing:
    • Precision machining and assembly.
    • On-track testing to fine-tune the steering system.

Results

  • New uprights are 2× lighter and stronger than the originals.
  • Steering system optimized for peak racing performance.

composite wing for audi tt

Project Goal
Design and develop a high-performance, regulation-compliant composite rear wing for an Audi TT, tailored to the client’s specifications.

 

Activities & Technologies

  • CAD Design & Simulations: Optimizing aerodynamics and structural integrity.
  • Composite Engineering: Developing a lightweight yet durable wing using advanced composite materials.

Results
The final product was technically successful.

simulations

testing and validation