Unique Pre-Form Design For Two-Step Forming Of Stainless Steel Fuel Cell Bipolar Plates

Abstract

A bipolar plate used in a fuel cell and a method of making a bipolar plate. The sheet is made from a ferritic or austenitic stainless steel, and defines an undulated surface pattern such that the patterned sheet may be formed into the bipolar plate. In one configuration, a stamping or related metal forming tool operation will further deform the patterned sheet into the bipolar plate shape such that the wall thickness is substantially uniform throughout the surface. In this way, there is a substantial reduction in stretching / thinning / necking at an intersection between bends and side walls that define the undulations of the pattern. In one form, the pattern defines a repeating serpentine shape. In a particular embodiment, the bends may include surface modifications to reduce the effects of sheet-to-tool misalignment.

Description

BACKGROUND OF THE INVENTION[0001]The present invention relates generally to a stainless steel alloy bipolar plate for use in a fuel cell environment that exhibits ease of manufacturability, and more particularly to such a bipolar plate that is easy and inexpensive to manufacture while preserving the best mechanical / structural properties possible.[0002]In many fuel cell systems, hydrogen or a hydrogen-rich gas is supplied through a flowpath to the anode side of a fuel cell while oxygen (such as in the form of atmospheric oxygen) is supplied through a separate flowpath to the cathode side of the fuel cell. An appropriate catalyst (for example, platinum) is typically disposed to form on these respective sides an anode to facilitate hydrogen oxidation and as a cathode to facilitate oxygen reduction. From this, electric current is produced with high temperature water vapor as a reaction byproduct. In one form of fuel cell, called the proton exchange membrane or polymer electrolyte membra...

AI Technical Summary

Benefits of technology

The present invention is about a method of making a stainless steel bipolar plate for a fuel cell. The method involves a two-step process of first shaping a flat sheet of stainless steel into an undulated sheet, using a pre-formation tool, to better define the shape of the final bipolar plate. This pre-formation tool ensures that the thickness of the sheet remains close to its original level, avoiding stretching or thinning that can occur with conventional forming methods. The resulting bipolar plate has flow channels and lands that are better defined, with reduced thickness deviation and less necking and stretching compared to conventional methods. This invention provides an improved method for making stainless steel bipolar plates for fuel cells.

Problems solved by technology

Because the bipolar plate operates in a high temperature and corrosive environment, conventional metals, such as plain carbon steel, may not be suitable for certain applications (such as in automotive environments) where long life (for example, about 10 years with 6000 hours of life) is required.

Nevertheless, their hardening curves are such that they are more susceptible to necking, stretching, thinning and consequent cracking when exposed to conventional stamping or related one-step metal-forming operations than their more conventional (for example, 304 stainless steel) counterparts.

These difficulties are especially prevalent in single-step deep-draw operations (for example, those involving relative large—such as between about 300 microns and 400 microns in depth—out-of-plane deformations) where significant side wall deformation may take place.

Moreover, current bipolar plate manufacturing accounts for high portion of overall fuel cell stack cost.

While using stamped stainless steel bipolar plates would be beneficial in addressing a significant portion of this cost, the low formability of stainless steel in general (and ferritic stainless steel in particular) is a significant challenge, especially for stamping very thin (for example, 0.100 millimeters or thinner) sheets that are possessive of the required channel strength and depth to satisfy functional requirements.

Nevertheless, such a process is slow, and requires expensive special equipment that would make it hard to meet either the required production rate or production cost Likewise, electro-magnetic forming could be used, but is a process that is still under development and not suitable for low-cost mass production.

Images