MRI installation and deinstallation Service

Installing or removing an MRI system is a complex operation that involves magnetic, mechanical, and cryogenic handling. Rumo Tech provides safe installation and deinstallation services for GE, Siemens and Philips MRI systems, ensuring the magnet and components are protected throughout the entire process.

MRI systems cannot be treated as standard medical equipment. The superconducting magnet, shielding components, gradients, and cryogenic systems require controlled procedures to prevent damage, helium loss, or safety hazards. A properly planned installation or deinstallation avoids costly repairs and reduces downtime during relocation or resale. MRI shimming is the process of restoring magnetic field homogeneity, allowing the system to operate within manufacturer specifications and produce consistent, diagnostic-quality images. This condition is commonly observed in superconducting MRI systems from manufacturers such as GE Healthcare, Siemens Healthineers and Philips.

When Is MRI installation or deinstallation required?

Facilities require these services whenever an MRI system is being relocated, replaced, sold, or newly installed. The magnet must be prepared, secured, and handled using procedures different from conventional equipment removal. In many cases, the system must be ramped down, stabilized, and disconnected before transport. Improper removal may lead to helium loss, internal movement of components, or quench events during transport or handling. Installation procedures are equally critical, as the magnet must be positioned, reconnected, stabilized, and prepared for ramping and calibration before operation.

What is involved in MRI install and deinstall?

Magnetic field instability usually develops gradually. MRI systems are extremely sensitive to environmental and cryogenic variations, and even small changes can affect homogeneity and calibration stability

Magnet ramp down

The magnetic field is safely reduced to allow handling and transport.

Cryogenic stabilization

Helium levels and cooling conditions are controlled to protect the magnet.

Mechanical disassembly

Gradients, patient table, panels, and external components are removed and secured for transport.

Positioning, preparation and operation

After installation, the magnet is positioned, stabilized, and prepared for ramping and calibration.

Our MRI installation and deinstallation procedure

Following installation, additional services such as helium refill, ramping and shimming are commonly required before the system can return to clinical operation.

Step 1 — Site preparation and system disassembly

We coordinate with the facility and logistics team to prepare access routes, protect the magnet, disconnect components, and safely remove the system.

Step 2 — Installation, Stabilization and System Readiness

After positioning at the new site, the system is reassembled, cryogenic conditions are verified, and the magnet is prepared for ramping and calibration.

MRI systems and platforms we service

Our engineers support a wide range of superconducting MRI systems. Below are some of the platforms we frequently service.

Siemens

Siemens Magnetom Altea
Siemens Magnetom Aera
Siemens Magnetom Amira
Siemens Magnetom Avanto
Siemens Magnetom C!
Siemens Magnetom Espree
Siemens Magnetom Essenza
Siemens Magnetom Sempra
Siemens Magnetom Skyra
Siemens Magnetom Sola
Siemens Magnetom Symphony
Siemens Magnetom Verio

GE Healthcare

Signa HDxt
Signa Excite
Signa Voyager
Signa Creator
Optima MR360
Optima MR450w
Signa Brivo
Discovery MR750
Signa Architect

Philips

Why specialized MRI handling is necessary

An MRI magnet weighs several tons and contains superconducting components suspended inside the cryostat. Improper lifting, vibration, or tilting may cause internal displacement or cryogenic imbalance. Helium loss, magnet damage, or transport quench events are often the result of incorrect handling procedures rather than shipping distance. Proper preparation significantly reduces these risks.

Helium loss
Quench risk
Damages
Transport quench
Coil alignment

Risks of improper MRI removal or installation

Unresolved magnetic field instability affects clinical reliability, workflow efficiency and operational performance.

Helium Loss

Improper handling can disturb the cryogenic system and cause helium loss requiring refill.

Internal Magnet Damage

Shock or tilt may move internal components, affecting field homogeneity and requiring repair.

Transport quench

Incorrect preparation may trigger a quench during transport, making the system inoperable.

Plan your MRI relocation safely

If you are planning to move, sell, install or remove an MRI system, early coordination is essential.

Response typically within one business day.

Frequently Asked Questions About MRI Install and deinstall

What is included in a complete MRI installation service?

A full installation includes ramping up, cryogenic stabilization, coil and gradient checks, shimming, tuning, image quality verification, and OEM-compliant safety testing.

How is an MRI safely de-installed?

De-installation requires controlled ramping down, magnet discharge, system securing, component disconnection, and safe removal following OEM instructions and facility guidelines.

How long does MRI installation or removal take?

Time varies depending on OEM, facility layout, and logistics, but most standard installations or de-installations take 1–3 days, plus ramping and calibration phases.

Can you relocate MRI systems to another facility?

Yes. We handle complete MRI relocation services, including de-installation, transport preparation, logistics coordination, and full re-installation at the new site.

Do you support Siemens, GE, Philips, and Canon MRI systems?

Yes. Our engineers have extensive hands-on experience with all major MRI manufacturers and follow each OEM’s technical standards and procedures.

Why is ramping up and ramping down important during installation?

Proper ramping protects the magnet from thermal and electrical stress, prevents quench events, and ensures a stable superconducting field before system commissioning.