Photochemical etching is the perfect choice for metal component production in the quickly changing alternative powertrain supply chain. Its versatility and accuracy permit the fabrication of different prototypes, even in shape memory alloys, no matter how many design iterations.
Reduction of weight is an essential part of the EV revolution, a goal that can be achieved through etching, suitable applications including alkaline battery connectors and busbars. Additionally, two sides of a plate can be etched simultaneously. Cooling plates for battery management systems can be formed from steel, titanium, or aluminum, and bipolar plates for fuel cell stacks are possible too with these same metals.
The EV revolution
New and sustainable mobility technologies are in high demand due to the increasing drive for alternative powertrains fuelled by initiatives in Europe and the United States.
In the EU, the European Commission has set a target of having at least 30% of new cars sold to be electric by 2030. To help reach this goal, several financial incentives are available, including grants for buying electric vehicles and installing charging points. The Commission is also working on developing a comprehensive network of charging infrastructure across Europe.
In the United States, the federal government offers a tax credit of up to $7,500 for purchasing an electric vehicle. Several states also have incentive programs. In addition, the US Department of Energy is investing over $4 billion to develop a nationwide network of fast-charging stations.
As a precision metal part fabrication process, PCE is well suited to the production of some of the critical EV components such as bipolar plates used in fuel cells, making them in a cost-effective, precise, and speedy fashion, while at the same time stimulating innovation by providing design freedom
PCE is a subtractive metal processing method that involves selectively removing metal from a flat metal surface with the use of a chemical reagent to produce desired shapes or patterns. The process captures CAD drawings in transparent photo tools, then converts them into a negative image which is developed on a photoresist covering the metal surface.
The process has several benefits, as it produces intricate parts, with complex patterns or varied opening profiles in thin metallic sheets ranging from dozens of microns to around 2 millimeters thick. It outperforms other methods, like traditional metal cutting and stamping.
Etching can be employed to work on a wide range of metals, from stainless steels to copper and nickel to aluminum, not forgetting clad materials and shape memory alloys. Every metal has its etching traits, and the expertise of your chosen PCE specialist will tailor etchant chemistries to the precise metal being processed to get optimal performance and excellent results.
PCE & BI-polar plate manufacture
With the global fuel cell market expected to reach $25 billion by 2025, international pressure on energy diversification has generated a keen investment atmosphere towards alternative energy sources — of which fuel cells are close to being the most effective.
The requirement for fuel cells to be increasingly efficient and cost-effective is having a major impact on the materials used and the manufacturing methods chosen.
Historically, CNC-machined graphite has been the material of choice for producing bipolar fuel cell plates. Unfortunately, it is rather expensive and suffers from excessive permeability, making it unsuitable for mass production. Metal alloys such as stainless steel and titanium are gaining popularity due to their cost-effectiveness and simple manufacturability. Moreover, stainless steel offers many great benefits for fuel cell applications, including remarkable strength, chemical stability, and durability.
Fuel cells are made up of intricately machined plates with grooves or channels to allow gas and liquid flow, but the scalability and ability of CNC-machining, hydroforming, and stamping techniques are questionable.
Stamping and hydroforming are common metalworking techniques, however, these processes can cause planarity issues, as well as stress and burrs. Additionally, single-point machining processes and presswork tooling can be both time-consuming and expensive, particularly during research and development.
PCE provides manufacturers with a viable means of producing complex components, such as bipolar fuel cell plates, with noteworthy benefits.
Utilizing digital tooling instead of hard tooling, PCE offers the significant benefit of being cost-effective and allows designs to be readily customized. This is hugely advantageous in terms of optimizing without incurring excessive expenses.
The process facilitates quick scale-up from a prototype to high-volume production, with almost no limit on the complexity of components - ideal for fuel cell plates that must be free of imperfections to successfully bond the stack. It does not affect the temper or properties of metals, is suitable for all grades of steel, and accuracy is ensured at ±0.025 mm; all done in days instead of months.
PCE is a versatile technology that allows for the simultaneous removal of metal. This enables complex patterns and channels to be etched to an accuracy of 0.025mm on both sides of the plate, with features such as headers, collectors, or ports easily achievable at no extra cost.
At the micrometal Etching Group, we can also produce these components in certain exotic and hard-to-machine metals, such as titanium, for lighter weight and superior protection from corrosion in high-temperature fuel cell applications.
The PCE process is a compelling option for the manufacture of complex sheet metal parts across multiple applications, due to its versatility. This approach can stimulate innovation, removing barriers inherent in traditional manufacturing technologies and hence providing design engineers with more freedom.
PCE offers flexibility and cost-effectiveness for the production of bipolar plates, enabling the speedy manufacture of various designs. Additionally, with the capability to etch stainless steel, nickel-based alloys, copper, aluminum, titanium, and other alloys, its potential is amplified.
Related Glossary Terms
Substances having metallic properties and being composed of two or more chemical elements of which at least one is a metal.
- computer-aided design ( CAD)
computer-aided design ( CAD)
Product-design functions performed with the help of computers and special software.
- flat ( screw flat)
flat ( screw flat)
Flat surface machined into the shank of a cutting tool for enhanced holding of the tool.
- hard tooling
Tooling made for a specific part. Also called dedicated tooling.
Any manufacturing process in which metal is processed or machined such that the workpiece is given a new shape. Broadly defined, the term includes processes such as design and layout, heat-treating, material handling and inspection.
- stainless steels
Stainless steels possess high strength, heat resistance, excellent workability and erosion resistance. Four general classes have been developed to cover a range of mechanical and physical properties for particular applications. The four classes are: the austenitic types of the chromium-nickel-manganese 200 series and the chromium-nickel 300 series; the martensitic types of the chromium, hardenable 400 series; the chromium, nonhardenable 400-series ferritic types; and the precipitation-hardening type of chromium-nickel alloys with additional elements that are hardenable by solution treating and aging.