Integrated
Design and
Engineering

Complex buildings need more than discipline packages.
They need one coordinated design and engineering system.

TEBIN delivers multidisciplinary design and engineering for technically complex projects, combining architecture, structural, civil, mechanical, electrical, ICT, fire protection, and BIM coordination within one integrated team. We focus on clear interfaces, coordinated models, reliable calculations, buildable documentation, and practical construction support — from early concept to IFC packages and site coordination.

Disciplines8 in-house

DeliveryBIM-driven · ISO 19650

StagesConcept → Construction support

Best suited forData centers · Industrial · Logistics · Pharma · EV

Disciplines

ArchitectureStructuralCivilMechanicalElectricalICTFire ProtectionBIM Coordination

02 — The problems we solve

Complex projects fail
at the interfaces

Most engineering risks appear between disciplines, not inside a single one. TEBIN's integrated approach is built to prevent these gaps before they reach construction.

Late clashes between structure, MEP systems, and equipment
Missing or unclear responsibility at discipline interfaces
Drawings not aligned with BIM models or calculations
Calculations disconnected from layouts and equipment schedules
Incomplete tender or IFC documentation
Contractor RFIs caused by unclear or contradictory design intent
Design packages that are technically correct but difficult to build
Weak coordination between external utilities, building systems, and site infrastructure

03 — TEBIN approach

One design and engineering team.
One coordinated technical package.

TEBIN brings the main design and engineering disciplines into one production and coordination workflow — so technical decisions are checked across all disciplines before documentation is issued.

Interfaces managed, not assumed

We define and control interfaces between disciplines from the start — equipment spaces, technical rooms, shafts, MEP routes, penetrations, access zones, external connections, and utility interfaces.

BIM is part of engineering, not separate

Models are used to check geometry, access, installation logic, clashes, and document consistency — not created after design decisions are made.

Calculations and models work together

Engineering calculations are connected with real project geometry, selected equipment, routes, loads, and operational requirements — not produced in isolation.

Documentation prepared for construction

The goal is a clear, coordinated, buildable technical package — one that contractors can actually use on site, not just a set of drawings issued at the design stage.

04 — Eight disciplines

Eight disciplines delivered as one system

ARC

Architecture

Concept design, planning layouts, technical room coordination, building envelope interfaces, facade coordination, interior layouts, accessibility, and integration with engineering systems.

STR

Structural Engineering

Structural analysis and design, reinforced concrete, steel structures, foundations, structural BIM models, penetration coordination, support zones, and interface checks with MEP routes and equipment loads.

CVL

Civil Engineering

Site grading, earthworks, roads, external drainage, utilities, site infrastructure, utility corridors, connection points, and coordination between building systems and external networks.

MEP

Mechanical Engineering

HVAC, ventilation, heating, cooling, plumbing, sanitary systems, process HVAC interfaces, plant room layouts, hydraulic design, thermal coordination, and mechanical BIM models.

ELC

Electrical Engineering

MV/LV distribution, transformers, switchgear, UPS, generators, emergency power, lighting, earthing, lightning protection, cable routes, load calculations, and electrical BIM coordination.

ICT

ICT & Security

Structured cabling, network infrastructure, ICT rooms, security, access control, CCTV, communications, AV, IT/OT interfaces, cable containment, and coordination with electrical and architectural layouts.

FPS

Fire Protection & Life Safety

Sprinklers, suppression systems, fire detection and alarm, emergency lighting, smoke control, fire strategy coordination, compartment interfaces, and integration with architecture, MEP, and BMS.

BIM

BIM Coordination & Digital Delivery

BIM Execution Plans, model federation, clash detection, model quality checks, ISO 19650 workflows, CDE support, issue tracking, design review support, and digital handover packages.

05 — Project types

Design and engineering for buildings
with high coordination risk

TEBIN is strongest where technical complexity, reliability, and coordination quality matter.

Data Centers & Mission-Critical

Power, cooling, redundancy, controls, ICT, fire systems, and operational continuity coordinated as one integrated system.

Industrial & Production Facilities

Process interfaces, utilities, power supply, ventilation, safety systems, and structural or architectural constraints.

Logistics & Distribution Buildings

Civil works, MEP, external utilities, lighting, fire systems, ICT, security, and coordinated construction documentation.

EV Infrastructure & Advanced Mfg

High-current power, transformer substations, cable routes, civil layouts, drainage, lighting, and equipment interfaces.

Pharmaceutical & Life Sciences

Controlled environments, HVAC, cleanroom interfaces, utilities, power supply, fire safety, and compliance-driven documentation.

Complex Refurbishment Projects

Existing constraints, phased implementation, temporary systems, survey data, and careful construction sequencing.

06 — Delivery stages

From early concept
to construction support

TEBIN can deliver the full design and engineering lifecycle or defined project stages, depending on the required scope.

Strategic Definition

Understand project constraints, risks, and basic technical direction

Project brief and available documentation review
Site and utility constraints review
Preliminary technical options and risks
Discipline responsibility matrix
Initial BIM and coordination strategy

Concept Design

Define the main technical concept and key engineering decisions

Concept layouts and technical room planning
Main system concepts and utility connection concepts
Preliminary load assumptions and equipment space requirements
BIM Execution Plan and coordination principles
Initial risk and interface register

Design Development

Develop coordinated design and resolve main technical interfaces

Coordinated BIM models
Discipline development drawings and main calculations
Equipment layouts, shaft and route coordination
Clash detection reports and design review comments
Updated specifications and schedules

Tender / IFC

Issue a coordinated technical package for tendering or construction

IFC drawings, BIM models, and technical specifications
Equipment, cable, and system schedules
Calculation reports
Tender clarification support
Coordinated scope split and interface package

Construction Support

Support implementation and protect design intent during construction

RFI responses and shop drawing review
Contractor coordination and site issue clarification
Model updates and as-built support where agreed
Technical review of proposed design changes

07 — Typical deliverables

Clear engineering outputs
for decision, tender, and construction

Drawings & documentation

General arrangement drawings
Discipline plans, sections, and details
Technical room and equipment layouts
Schematics and single-line diagrams
External network layouts
Tender and construction packages

Models & coordination

Discipline BIM models
Federated coordination models
Clash detection and issue reports
Model quality check reports
BIM handover packages

Calculations & reports

HVAC and hydraulic calculations
Electrical power and cable calculations
Lighting and drainage calculations
System sizing and option comparison reports

Specifications & schedules

Technical specifications
Equipment and cable schedules
Duct and pipe schedules
Interface and responsibility matrices

08 — Coordination method

How we control design quality

Integrated engineering is not only about having many disciplines. It requires a controlled coordination method that keeps decisions visible, traceable, and aligned.

Coordination workflow

01 Define project scope, stage, and responsibilities
02 Confirm design basis and available input data
03 Set up BIM, CDE, naming, exchange, and review rules
04 Develop discipline models and calculations in parallel
05 Run regular interdisciplinary design reviews
06 Track issues, clashes, assumptions, and open decisions
07 Resolve interfaces before documentation is issued
08 Check drawings against coordinated BIM models
09 Issue packages with clear revision and status control
10 Support construction with RFI and clarification workflows

What we check

Spatial coordination and technical room capacity
Equipment access and maintainability zones
MEP route feasibility and structural openings
External utility interfaces and connections
Fire safety compartment interfaces
Electrical and mechanical load consistency
Specification and drawing consistency
BIM model quality before issue

09 — Why teams choose us

Complexity demands a single point of engineering responsibility

01 One responsibility

Single-team delivery with full accountability for every interface between disciplines

02 BIM as engineering

Models used to check geometry, access, installation logic, clashes, and document consistency

03 Complex projects

Data centers, industrial, logistics — where interfaces are critical and coordination failures are expensive

04 Buildability focus

Space, routes, access zones maintenance, installation logic, and documentation quality — designed in

05 International mindset

Works with international standards design stages, clients, and digital delivery requirements

06 Construction support

RFIs and clarifications resolved with engineering knowledge — not by looking up the drawing

Get in touch

Need integrated design and engineering
for a complex project?

Share your project stage, available documentation, required disciplines, BIM requirements, main technical risks, and expected delivery deadline. TEBIN will review the scope and explain how an integrated TEBIN team can deliver the required design and engineering scope.

Useful to include: project type and location · current design stage · available drawings or models · required disciplines · BIM and CDE requirements · main technical challenges

Start a conversation

7,000 m² Industrial Plant in Central Europe: Full-Scope BIM Delivery project by TEBIN

Industrial & Manufacturing · Central Europe

Integrated
Design and
Engineering

Complex projects fail
at the interfaces

One design and engineering team.
One coordinated technical package.