SHAPE
THE UN-
DEFINED

We take ambiguous ideas and engineer them into precise, manufacturable products. Structured mechanical thinking at every stage — from first sketch to production handover.

50+
Products designed
DFM
First delivery ready
0
Decoration. Only function.
280.00 mm 120.00 mm M3×0.5 THRU PARTING LINE AMORPHIX TECH DWG: AMX-004-B REV: 03 — AL6061-T6 ISO — ENCLOSURE BODY — SW 2024
// Active engineering
CAD
3D & detailed drawings
FEA
Validated before prototype
Mechanical Design Design for Manufacturing GD&T Drawings FEA Analysis Tolerance Stack-up Robotics & Automation Opto-Mechanical Systems Mechanical Design Design for Manufacturing GD&T Drawings AFEA Analysis Tolerance Stack-up Robotics & Automation Opto-Mechanical Systems
01 —
Mechanical Product Design
From concept sketch to production-ready CAD. Robust designs focused on function, reliability, and manufacturability.
02 —
CAD & Detailed Engineering
3D models, assemblies, drawings, GD&T, and tolerance stack-ups. Ready for manufacturing partner handover.
03 —
Design for Manufacturing
DFM & DFA optimization. Reduce cost, simplify assembly, and ensure smooth production — from the first design.
04 —
Engineering Analysis
Structural, thermal, and motion analysis via FEA. Validate performance before you cut a single prototype.
// Who we are
We believe good design is
not decoration.
It is clarity, performance,
and accountability.

Amorphix Technologies is a product design and engineering firm focused on transforming undefined ideas into precise, manufacturable products. We work at the critical stage where concepts are still forming and engineering decisions matter the most.

The name Amorphix comes from amorphous — something without a fixed form. Our work is about giving shape, structure, and purpose to ideas that are still undefined.

3D CAD · Assemblies
Complex surfaces
FEA · Thermal · CFD
2D drawings · GD&T
// How we work
THE PROCESS

Structured engineering thinking — from ambiguous brief to manufacturable product.

01 —
Problem Understanding
Requirements, constraints, and real-world use cases clearly defined before any geometry is created.
02 —
Concept Development
Multiple directions evaluated for manufacturability risk and performance trade-offs.
03 —
Detailed Design
Full CAD models, exploded assemblies, engineering drawings and BOM.
04 —
Validation
FEA structural, thermal, motion analysis. Design refinement before prototype spend.
05 —
Production Support
Engineering support during manufacturing, assembly, and first-article inspection.
// Engineered proof
VISUAL
PROOF
CAD renders, section views, thermal analysis, and annotated drawings — not stock images.
260.00 mm AMX-004-B
Electronics enclosure — AMX-004
Isometric render · AL6061-T6 · DFM Ready
18°C 94°C STEADY STATE
Thermal analysis
ANSYS Steady State · 94°C peak
Ø52.00 B — B SECTION VIEW
Section cut B-B
Bore detail · wall analysis
// Who we work with
OUR CLIENTS
Startups
First-generation product companies
We help founders turn a napkin sketch into a manufacturable product without an in-house engineering team.
Robotics & Automation
Robotics & automation companies
Structural frames, joint assemblies, actuator housings — designed for repeatability and ease of maintenance.
Industrial
Industrial product companies
Robust designs for harsh environments. Material selection, thermal management, and fatigue analysis.
R&D Teams
R&D and innovation teams
We integrate into existing engineering teams to accelerate development and add mechanical depth.
Opto-Mechanical
Opto-mechanical systems developers
Precision mounts, kinematic platforms, and enclosures for optical systems and laser instrumentation.
Electronics
Electromechanical development firms
Housings, connectors, cable management, and thermal designs that complement electronics development.
// Let's build something
WHATEVER
YOU NEED —
WE'LL BUILD IT.

Tell us about your project. We'll review it and get back with an honest assessment of what we can do and how.

Address
16-6-201/301, 3rd Floor
Osmanpura, Chaderghat
Hyderabad 500024, Telangana
Email
info@amorphix.in
Phone
+91 9059979215
// What we do
ENGINEERING
SERVICES

End-to-end mechanical product design and engineering — from the first undefined concept to a fully documented, manufacturable product ready for production.

⏥ 0.05 A Ra 1.6 A 140.00 ± 0.05 140.00 AMORPHIX · AMX-009-C · BRACKET · REV 02 · 3RD ANGLE
01
Mechanical Product Design

From early concept to detailed CAD — we develop robust mechanical designs focused on functionality, reliability, and manufacturability. We start by understanding the problem deeply before touching any geometry.

Concept sketches & feasibility study
3D CAD model (SolidWorks / CATIA)
Design review documentation
Risk register per revision
02
CAD & Detailed Engineering

3D modeling, assemblies, drawings, GD&T, and tolerance stack-ups prepared for real-world manufacturing. Every drawing is checked against your manufacturing partner's capabilities.

Fully detailed 3D models & assemblies
2D engineering drawings (ASME Y14.5)
GD&T callouts & datum references
Bill of Materials (BOM)
03
Design for Manufacturing

DFM & DFA optimization to reduce cost, simplify assembly, and ensure smooth production handover. We design with your manufacturing process — machining, casting, injection moulding — in mind from day one.

DFM analysis report per part
DFA assembly sequence optimization
Material & process selection rationale
Cost reduction recommendations
04
Engineering Analysis

Structural, thermal, and motion analysis to validate performance before prototyping or production. We use FEA to find failure modes, hot spots, and stress concentrations — before you spend on a prototype.

Static & fatigue structural FEA
Thermal steady-state & transient analysis
Motion & kinematics simulation
Analysis report with recommendations
// Tools & software
WHAT WE USE
SolidWorks
Primary CAD · 3D & assemblies
CATIA V5
Complex surfaces & aerospace
Fusion 360
Rapid concept modeling
AutoCAD
2D drawings & GD&T
ANSYS Mechanical
Structural FEA
ANSYS Thermal
Heat transfer analysis
KeyShot
Photorealistic rendering
GD&T Advisor
Tolerance verification
// Why choose us
WHY AMORPHIX
Engineering first. Aesthetics second.
We don't start with the shape — we start with the problem. Function, reliability, and manufacturability drive every decision. The form follows.
DFM on first delivery.
We don't hand you a beautiful model that can't be made. Every drawing is production-ready from revision one, reviewed against your manufacturing process.
No black boxes.
Every design decision is documented and explained. You understand why each constraint exists — and can make informed changes as requirements evolve.
Structured uncertainty.
Most engineering firms want a clear brief. We work best when the problem is still undefined — bringing structure and logic to the fuzzy front end of product development.
Validation before prototype.
FEA analysis is built into our process — not an optional add-on. We validate structurally and thermally before you spend money on a physical prototype.
Long-term support.
We provide engineering support through manufacturing, first-article inspection, and production ramp-up — not just until we hand over files.
// Engineered proof
CASE
STUDIES
04

Four detailed project breakdowns. Problem → engineering process → outcome.

Electronics EnclosureDFM · CNC · Die Cast
IP67-rated Electronics Enclosure for Embedded Control Unit

A robotics OEM needed a fully sealed, thermally managed enclosure for an outdoor embedded controller — cast aluminium, IP67, with integrated cable gland bosses and EMI shielding slots.

±0.05
mm tolerance
Rev 03
DFM frozen
8wk
Timeline
Read Case Study
AMX-004-B · AL6061
RoboticsFEA · Weldment · Structural
6-DOF Robotic Arm Structural Frame — Fatigue Analysis

A robotics startup needed a structural frame for a 6-DOF cobot arm capable of 5kg payload at full reach. Required fatigue-life validation for 1M cycles and minimised mass-to-stiffness ratio.

1M
Cycle fatigue target
-18%
Mass reduction
6wk
Timeline
Read Case Study
σ_max 142 MPa AMX-007 · 6DOF COBOT STRUCTURAL — FEA VALIDATED
Opto-MechanicalKinematic · Precision · Laser
Kinematic Lens Mount for Industrial Laser System

A laser instrumentation company needed a kinematic mount for a 60mm objective lens — sub-micron repeatability, minimal thermal drift, and compatible with their existing 60mm C-mount thread.

<1μm
Repeatability target
SS316
Material selected
4wk
Timeline
Read Case Study
M60×1.0 K1 K2 K3 AMX-011 · KINEMATIC MOUNT
IndustrialThermal · Sheet Metal · DFM
Thermal Management Chassis for High-Power Industrial Drive

A drives manufacturer needed a chassis redesign for a 22kW VFD to improve heat dissipation and reduce assembly time. Existing design had 32-screw assembly and a thermal hotspot at 108°C peak.

-14°C
Peak temp reduction
32→8
Assembly fasteners
10wk
Timeline
Read Case Study
94°C 42°C AMX-014 · VFD CHASSIS · 22kW
Back to Case Studies
Electronics EnclosureDFM · Die Cast · CNC
IP67-rated Electronics Enclosure

A fully sealed, thermally managed housing for an outdoor embedded controller — designed for die casting in AL6061-T6 with integrated EMI bosses and IP67-rated cable gland bosses.

AMX-004-B · REV 03 · AL6061-T6 · IP67

The Problem

A robotics OEM was developing an outdoor autonomous platform. Their existing embedded controller was housed in a commercial off-the-shelf ABS box that couldn't meet IP67, had no EMI mitigation, and was running 18°C above the controller's maximum ambient specification at 40°C outdoor temperature.

They needed a custom housing designed for die casting in aluminium — IP67 sealed, with integrated heat spreader features, cable gland bosses, and EMI shielding slots — within 8 weeks to meet their pilot build schedule.

Engineering Approach

We started with a thermal model using ANSYS Steady-State Thermal to establish the heat flux path from the PCB through the housing to ambient. This drove the placement of cast-in fin features on the base and the selection of AL6061-T6 for its thermal conductivity (167 W/m·K).

For IP67 sealing, we designed a precision machined groove on the lid parting line for a silicone O-ring (shore A 70), with a compression ratio of 18–22% — verified against Parker O-ring design guidelines. Cable gland bosses were designed with a 2° draft for casting and a secondary CNC op for the M20 PG thread.

EMI shielding was achieved through four interlocking boss features at the corners of the lid seam, providing a continuous conductive path when torqued to specification. GD&T datum scheme was set to the machined base face (Datum A) and two tooling holes.

Outcome

The design passed IP67 ingress testing on first-article. Peak PCB temperature reduced from the OEM's existing 62°C to 44°C in 40°C ambient — an 18°C improvement. The casting was first-time good from the tool, with no ECOs required after initial sampling. Total design to production-ready drawing: 7.5 weeks.

Project specs
Client type
Robotics OEM
Material
AL6061-T6
Process
Die cast + CNC
Tolerance
±0.05 mm
IP rating
IP67
Timeline
8 weeks
Revision
Rev 03 — Frozen
Tools used
CAD
Thermal FEA
Thermal
GD&T
ASME Y14.5-2018
Rendering
Key results
Temp reduction
−18°C
IP rating achieved
IP67 ✓
First-article
Pass — 0 ECOs
Back to Case Studies
RoboticsFEA · Weldment · Structural
6-DOF Robotic Arm Structural Frame

Structural frame design for a 6-DOF collaborative robot arm — 5kg payload, 1 million cycle fatigue life, 18% mass reduction from baseline concept through topology-informed redesign and FEA validation.

σ_max 142 MPa AMX-007 · 6DOF · 5kg PAYLOAD

The Problem

A robotics startup was developing a 6-DOF collaborative robot arm for light industrial pick-and-place. Their baseline concept — a welded mild steel frame — passed static load cases but the fatigue simulation showed failure at 280,000 cycles against a 1M cycle target. The frame was also 3.2kg overweight for the payload-to-weight ratio requirement.

Engineering Approach

We performed a full ANSYS Static Structural analysis of the baseline design under worst-case loading — maximum payload at full reach at 90° from vertical. Stress concentration at the joint between link 2 and the shoulder was identified as the primary failure location (σ_max = 248 MPa, SF = 0.82 against endurance limit).

Redesign focused on three areas: gusset geometry at the shoulder joint to redistribute load; wall thickness optimisation through parametric sweep to reduce mass while maintaining stiffness; and material upgrade from mild steel to 4130 CrMo for the primary links — improving fatigue strength from 310 MPa to 460 MPa.

Outcome

Final design achieved σ_max = 142 MPa with a fatigue safety factor of 1.62 at 1M cycles. Total frame mass reduced by 18% (580g) relative to baseline. All weld joints designed to AWS D1.1 standards with full penetration specification on primary load paths.

Project specs
Client type
Robotics startup
Material
4130 CrMo steel
Process
Weldment + machining
Payload
5 kg at full reach
Fatigue target
1,000,000 cycles
Timeline
6 weeks
Key results
Mass reduction
−18% (580g)
Fatigue SF
1.62 @ 1M cycles
σ_max
142 MPa
Back to Case Studies
Opto-MechanicalKinematic · Precision
Kinematic Lens Mount — Laser System

Sub-micron repeatability kinematic mount for a 60mm objective lens in an industrial laser system — three-ball kinematic coupling, low-drift SS316, C-mount compatible.

K1 K2 K3 M60×1.0 AMX-011 · KINEMATIC MOUNT · SS316

The Problem

A laser instrumentation company needed to replace a friction-clamped lens mount that showed 4–8μm position drift after each removal and reinstallation. Their process required frequent lens swaps, and the drift was introducing misalignment in their beam path.

Engineering Approach

The solution was a three-ball kinematic coupling — a classic precision engineering approach where three balls seat against three V-grooves to provide deterministic, repeatable location. We designed the mount in SS316L for low thermal expansion and corrosion resistance, with the ball-groove geometry calculated to achieve the theoretical repeatability of under 0.5μm.

The outer thread was designed as a standard M60×1.0 to match the company's existing C-mount infrastructure. Spring preload was selected to ensure positive seating under vibration without inducing Hertzian contact stress beyond 40% of material yield.

Outcome

Measured repeatability on first prototype: 0.3μm RMS over 50 removal/reinstallation cycles. The customer reported zero beam path realignment required after lens swaps — eliminating a 25-minute recalibration step from their process.

Project specs
Client type
Laser instruments
Material
SS316L
Process
Precision CNC
Thread
M60×1.0 C-mount
Timeline
4 weeks
Key results
Repeatability
0.3μm RMS
vs. target
<1μm ✓
Recal. time
25 min → 0 min
Back to Case Studies
IndustrialThermal · Sheet Metal · DFM
Thermal Management Chassis — 22kW VFD

Chassis redesign for a 22kW variable-frequency drive — reduced peak thermal hotspot by 14°C, cut assembly fastener count from 32 to 8, fully DFM-optimised for sheet metal folding.

94°C 42°C AMX-014 · VFD CHASSIS · 22kW

The Problem

A drives manufacturer's existing 22kW VFD chassis had two critical issues: a thermal hotspot at 108°C on the IGBT mounting interface (8°C above the component's maximum junction temperature derating point), and a 32-screw assembly that was adding 14 minutes to their production line cycle time.

Engineering Approach

Thermal redesign focused on the IGBT mounting surface — replacing a flat bolted interface with an integrated cold-plate channel design that directs airflow across the component. Fin geometry was optimised for the available 80mm fan airflow using CFD analysis, adding 340cm² of effective surface area.

DFA rationalisation replaced 24 M3 screws with a snap-fit rail system requiring only 8 M4 captive screws for final torque-critical connections. The snap-fit geometry was designed for 10,000 cycle fatigue life and 3mm deflection during assembly without permanent set.

Outcome

Peak IGBT interface temperature reduced from 108°C to 94°C — 14°C improvement, well within the derating threshold. Assembly time reduced from 22 minutes to 8 minutes. The sheet metal design was fully DFM-checked for laser cutting and brake pressing with zero secondary ops required.

Project specs
Client type
Drives manufacturer
Material
Galv. steel 2mm
Process
Laser cut + brake press
Power
22kW VFD
Timeline
10 weeks
Key results
Temp reduction
−14°C
Fastener count
32 → 8 screws
Assembly time
22 → 8 minutes
// Who we are
AMOR-
PHIX
From amorphous — without fixed form.
We give shape, structure, and purpose to ideas that are still undefined.

Amorphix Technologies is a product design and engineering firm in Hyderabad. We work at the critical front end of product development — where concepts are still forming, requirements are unclear, and engineering decisions matter most.

Hyderabad, Telangana Est. 2022 B2B Engineering Services
// Our philosophy
HOW WE THINK
Understand the problem — not the shape
Most design firms start sketching immediately. We spend the first phase interrogating the requirements, constraints, and real-world use cases before touching any geometry. The shape comes last.
Engineer concepts, not decorations
Every feature on a product must earn its place. If it doesn't improve function, reliability, or manufacturability — it doesn't belong. We design for performance, not aesthetics.
Freeze only when manufacturable
A design isn't done when it looks right. It's done when we've verified it can be made — by checking against your manufacturing process, tolerances, and assembly sequence.
Define constraints and real-world conditions
What temperature range? What load cycle? What happens in the worst case? We define the envelope first, then design to it — not the other way around.
Validate through analysis and iteration
FEA is not optional. We validate structurally and thermally before any prototype spend. Iterations in simulation cost ₹0. Iterations in metal cost everything.
Accountability at every stage
Every decision is documented. Every revision is tracked. You should always know why a constraint exists and what it would cost to relax it.
// Work with us
READY TO
DEFINE
YOUR PRODUCT?

We'd love to hear about your project. Tell us what you're building and we'll come back with an honest assessment of the engineering challenge.

Address
16-6-201/301, 3rd Floor
Osmanpura, Chaderghat
Hyderabad 500024, Telangana
Email
info@amorphix.in
Phone
+91 9059979215
// Project intake
START A
PROJECT

Fill out the brief below. We'll review it and respond within 48 hours with an honest assessment — what we can do, what it will take, and whether we're the right fit for your project.

// What happens next
01
We review your brief and assess the engineering complexity
02
We respond faster with questions or a scoping call invite
03
30-minute scoping call to align on requirements and constraints
04
Proposal with scope, deliverables, timeline, and fixed price
01 — Contact details
02 — Tell us about the project
Brief received.

Thank you for reaching out. We've received your project brief and will review it within 48 business hours. If we need to clarify anything, we'll email you directly.

Office address
16-6-201/301, 3rd Floor
Osmanpura, Chaderghat
Hyderabad 500024
Telangana, India
Industries we serve
Robotics Automation Industrial Opto-Mech Electronics Startups R&D Teams Manufacturing
Response guarantee
We review every brief personally. You'll hear from an engineer — not a sales team.
Not sure if we're a fit?
Drop us a note anyway. We're happy to point you in the right direction even if we can't take the project.