Forta H-Series - the attractive non-magnetic material for EV motors

The fully austenitic stainless steel grade offers an important new alternative for automotive electrical engineering.

Outokumpu’s new Forta H-Series grade of ultra-high strength stainless steel is fast gaining interest in the automotive industry where it helps designers to create strong, durable and lightweight vehicle structures. However, its capabilities do not end there. Forta H-Series also offers a cost-effective alternative to aluminum in electric vehicle (EV) motors and other applications that require a high performance non-magnetic material. The reason is that this fully austenitic grade has a completely stable, non-magnetic microstructure even after extensive forming, machining and joining.

Why are non-magnetic materials important for EV motors?

In simple terms, an EV’s electric motor converts a current flowing in a magnetic field into the rotational force that drives the wheels. The efficiency of the motor hinges on shaping and focusing the electric motor’s magnetic field to achieve the maximum output. That means certain key components, such as the support rings and protective casing, should ideally be made of a non-magnetic material. This minimizes the influence on the magnetic field. 
 
The degree to which the material is non-magnetic is also very important – using a material that is 99 percent non-magnetic, as opposed to 97 percent, can have a very significant impact on the overall efficiency of the EV motor. Many other factors such as the motor’s design and construction also have a significant influence on efficiency.
 

Magnetic and non-magnetic stainless steel

To understand the advantages of Forta H-Series it is useful to consider the microstructures of different stainless steel grades which influence why some are magnetic and others are non-magnetic. 

Pure iron exists normally in one of two main kinds of crystal structure: alpha-iron with a body-centered-cubic (bcc) lattice – forming a material known as ferrite, and a gamma-iron face-centered-cubic (fcc) lattice – forming austenite - see Figure 1.

At room temperature, pure iron exists as ferrite. It transforms into austenite at temperatures above 911°C. However, special alloying elements called austenite formers - like nickel, manganese, cobalt or nitrogen – enable austenite to exist at room temperature. Because of their characteristic fcc microstructure, austenitic steels show different properties to ferritic steels, especially in terms of corrosion resistance. 

The most crucial difference when it comes to electrical engineering is that ferritic steels are ferromagnetic – they are attracted to magnets, while austenitic steels are paramagnetic – they are non-magnetic.

There is a further crystal structure that is important – martensite. The fcc structure of austenite at high temperatures allows carbon atoms to fit easily into the spaces between the iron atoms. In the bcc ferrite structure there is much less space for carbon atoms. Therefore, if a hot steel is cooled very quickly (quenched), the carbon atoms become trapped in the ferrite. The result is a distorted crystal structure that forms martensite. This is important as martensite is very hard and is a significant factor in the strengthening of steel. And it is also ferromagnetic. Ferritic cubic structure (BCC-lattice) versus austenitic cubic structure (FCC-lattice) Figure 1 – Pure iron can exist in two main crystalline forms – magnetic ferrite and non-magnetic austenite.  
 

Forta H-Series – always non-magnetic because it never forms martensite

A key challenge in using conventional austenitic steels in applications requiring a non-magnetic material is that they tend to form martensite during forming, machining and welding. The magnetic martensite then impairs their non-magnetic properties.

This is where the new Forta H-Series offers a significant advantage. The closely controlled addition of austenite-forming elements gives it a fully-austenitic microstructure. Crucially, it does not harden by forming martensite. Instead, it relies on a hardening process characterized by an effect called TWIP (Twinning Induced Plasticity). This gives the steel a high instantaneous hardening rate (n-value) as it is worked, with the microstructure becoming increasingly fine.

Forta H-Series retains its stable and fully austenitic microstructure without transforming into martensite during forming and machining processes, such as drilling, turning, milling, stamping and welding. That means, it always remains non-magnetic. Figures 2 to 5 provide a summary of the main properties of Forta H-Series that are important for electrical engineering.
 
Electrical conductivity [m/(Ω*mm2)]
Copper 58
Aluminum alloys 28-36
Iron 10
Steel alloys 3.5-8.6
Graphite 3
Forta H-Series 1.24
Figure 2. The electrical conductivity of different materials.
 

Physical properties - Forta H-Series
Density  ρ = 7.78 kg/dm3
Young's modulus  E = 200 GPa
Thermal expansion
(coefficient at 100 °C)
 α = 16.27 10-6/°C
Thermal conductivity  λ = 12.5 W/(m*K)
Figure 3. The physical properties of Outokumpu Forta H-Series. Comparison of Forta H-Series with other automotive materials Figure 4. Yield strength vs. elongation curves.
 
Material Yield strength Rp0.2 [MPa] Tensile strength Rm [Mpa] Elongation after fracture A80 [%]
   Typical values
 Forta H500  530 900 51
 Forta H800  800 1000 31
 Forta H1000 1000 1200 13
Figure 5. Forta H-Series’ mechanical properties.  
 

How non-magnetic is Forta H-Series?

The magnetic property of a material is measured by its magnetic permeability, which indicates how well it supports the development of a magnetic field. This permeability is normally quoted as a relative value compared to air or vacuum – which is given the nominal value of 1.

Forta H-Series has a relative permeability of just 1.006 – for comparison, typical figures for carbon steel are 100 and for pure iron 5,000.
 

Where can Forta H-Series be applied in an electric motor?

In addition to its non-magnetic properties, Forta H-Series offers high strength and price stability as it contains no nickel. It also retains its strength at high temperatures well above the 300 to 350°C that might be experienced in an EV motor. That means that Forta H-Series offers an important high-performance cost-effective alternative to aluminum alloys. Areas where the material might be used are illustrated in Figure 6. These include the main housing. end shields, flange end shields and support disks. E-engine exploded view Figure 6. Electric motor components where Forta H-Series could offer improved performance.
 
There are other electrical applications for Forta H-Series. For example, the fast acting solenoid valves that are now being used in large numbers on vehicles in components like seats, window lifters and wing mirrors.
 

The EMC factor

In addition to being non-magnetic, Forta H-Series can also be a useful material in helping key electrical components meet the increasingly stringent standards now being applied for electromagnetic compatibility (EMC). This means that critical onboard components are shielded so that they do not emit radio frequency interference (RFI) that can affect other vehicles, while also ensuring they themselves are immune to RFI. EMC is especially important to ensure safety and reliability as the market moves towards semi-automated and fully autonomous vehicles.

Forta H-Series has a low electrical conductivity of 1.24 m/(Ω·mm²), which for EMC applications is 29 times lower than aluminum - 28-36 m/(Ω·mm²). Because radiated power is governed by a square law, shielding with Forta H-Series is more effective than aluminum by a factor of 841 (29 squared).
 

Forta H-Series - the important new alternative for automotive electrical engineering 

Forta H-Series retains a fully austenitic non-magnetic, low electrical conductivity microstructure no matter how it is formed or joined. That makes it ideal for:
  • EV motor components
  • Fast acting solenoid valves
  • EMC shielding
Other benefits of Forta H-Series include:
  • High strength, lightweight material
  • Excellent crash resistance
  • Good corrosion resistance associated with stainless steel
  • Price stability due to its zero-nickel content
  • Full recyclability
  • Expert support by Outokumpu
  • Global supplier for the automotive industry for decades
  • Worldwide availability
  • Deep understanding of the automotive industry and its supply chain
  • State-of-the-art research and development centers
Please contact us for a free consultation with one of our automotive experts to see how Forta H-Series could enhance the efficiency of your automotive electrical engineering project.
 

Listen to the webinar recording

Webinar title: "How non-magnetic stainless steels are driving the electric era of mobility" presented by Stefan Lindner. Duration 56 min.

See the recording

Recommended content

Designer's guide

Take the fast lane to the forefront of automotive manufacturing with stainless steel

Article

Stainless steel offers surprising flexibility for automotive manufacturing

Article

What if a car fuel tank was made from stainless?

Case STILRIDE – Carbon footprint LCA

STILRIDE motors ahead with sustainable stainless steel

Article

Outokumpu’s new high-temperature, price-stable Therma 4622Nb™ grade ready to roll

White paper

Can stainless steel overtake aluminum for constructing low carbon vehicles?

Article

Stainless steel stacks up for fuel cell bipolar plates

Articolo

Indicare un'impronta di carbonio specifica per prodotto per i clienti del settore ...

Article

Sustainable stainless steel fuel tanks for hybrid and ICE vehicles