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Superconducting vector magnet 3D Superconducting Coil

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Description

Overview

The 3D superconducting coil generates a three-dimensional vector magnetic field with arbitrary rotation of the field direction. It supports continuous-current operation and is engineered for high magnetic-field uniformity (especially along Z) and excellent field stability.

Key features

Provides a three-dimensional vector magnetic field with freely rotatable direction.
Capable of continuous-current operation (DC mode).
Designed for high magnetic-field uniformity along Z and strong field stability.
Compatible with dilution refrigerators and other cryogenic systems for integrated setups.
Lightweight mechanical design; mechanical and dimensional options customizable to customer requirements.

Available configurations

Configuration 9 T / 1 T / 1 T — Magnetic field: Z 9 T, X/Y 1 T; cold bore diameter: 90 mm (customizable); magnetic field uniformity (design): Z <0.1%, X/Y <0.5%; magnetic field stability: ≤10 ppm/h; magnet weight: <34 kg (indicative).
Configuration 3 T / 3 T / 3 T — Magnetic field: Z 3 T, X/Y 3 T; cold bore diameter: 90 mm (customizable); magnetic field uniformity (design): Z ≤10 ppm, X/Y <0.5%; magnetic field stability: ≤10 ppm/h.
Configuration 6 T / 2 T / 2 T — Magnetic field: Z 6 T, X/Y 2 T; cold bore diameter: 90 mm (customizable); magnetic field uniformity (design): Z <0.1%, X/Y <0.5%; magnetic field stability: ≤10 ppm/h.
Configuration 6 T / 1 T / 1 T — Magnetic field: Z 6 T, X/Y 1 T; cold bore diameter: 90 mm (customizable); magnetic field uniformity (design): Z <0.1%, X/Y <0.5%; magnetic field stability: ≤10 ppm/h.
Configuration 4 T / 1 T / 1 T — Magnetic field: Z 4 T, X/Y 1 T; cold bore diameter: 90 mm (customizable); magnetic field uniformity (design): Z <0.1%, X/Y <0.5%; magnetic field stability: ≤10 ppm/h.
Additional configuration examples:

0.5 T / 0.1 T / 0.1 T — Magnetic field: Z 0.5 T, X/Y 0.1 T; cold bore diameter: 110 mm; magnet weight: <25 kg; magnetic field uniformity (design): Z <0.05%, X/Y <1%; magnetic field stability: ≤10 ppm/h.
1 T / 1 T / 1 T — Magnetic field: Z/X/Y 1 T; cold bore diameter: 80 mm; magnetic field uniformity (design): Z ≤0.1%, X/Y <1%; magnetic field stability: ≤10 ppm/h.
0.6 T / 0.6 T / 0.6 T — Magnetic field: Z/X/Y 0.6 T; cold bore diameter: 80 mm; magnetic field uniformity (design): Z ≤0.1%, X/Y <1%; magnetic field stability: ≤10 ppm/h.
7 T / 2 T / 2 T — Magnetic field: Z 7 T, X/Y 2 T; cold bore diameter: 80 mm; magnetic field uniformity (design): Z ≤0.1%, X/Y <1%; magnetic field stability: ≤10 ppm/h.
3 T / 1.5 T / 1.5 T (parameter row indicates Z 4 T, XY 1.5 T) — Cold bore diameter: 90 mm or 100 mm options; magnet weight: <42 kg; magnetic field uniformity (design): Z ≤0.1%, X/Y <1%; magnetic field stability: ≤10 ppm/h.

Technical specifications

Magnetic field stability (typical design): ≤10 ppm/h.
Magnetic field uniformity (design values vary by configuration): examples include Z <0.1% with X/Y <0.5% for high-field configurations, Z ≤10 ppm for specific configurations, and Z <0.05% for some low-field optimized configurations.
Cold bore diameters: commonly 80 mm, 90 mm (customizable), 100 mm and 110 mm depending on configuration.
Magnet weight: indicative ranges such as <25 kg, <34 kg, <42 kg depending on configuration.
Supports integration with dilution refrigerators and other cryogenic systems; mechanical design optimized for lightweight integration.

Compatibility & customization

Designed for integration in low-temperature experimental setups and compatible with standard dilution refrigerators (cryostats).
Cold bore diameter, weight targets and mechanical interfaces can be customized to meet specific experimental or installation constraints.
Electrical and cryogenic connectors, mounting fixtures and vacuum interfaces can be adapted on request.