The present disclosure relates to production of polar plates of fuel cells, and more particularly to a method for forming a flow channel on a metal bipolar plate of a fuel cell.
Bipolar plate is a vital component of a fuel cell, and is mainly made of metal, graphite or composite material. The graphite bipolar plate has advantages of low density and great corrosion resistance. Unfortunately, a low porosity, low mechanical strength and high brittleness of graphite result in a large volume and mass of the graphite bipolar plate. Moreover, the composite bipolar plate has large contact resistance and high cost. By comparison, the metal bipolar plate has advantages of great electrical conductivity, corrosion resistance and processability. Whereas, the current stamping process fails to enable the continuous production of metal bipolar plates, and it also struggles with high machining power, imprecise machining shape and large difficulties in controlling warpage and rebound. In view of this, it is necessary to provide a novel method for manufacturing a metal bipolar plate to realize high-precision batch production, as well as increase the flow channel depth and reduce the thickness change of the metal bipolar plate after forming.
An object of the present disclosure is to provide a method for forming a flow channel on a metal bipolar plate of a fuel cell to overcome the defects in the prior art, in which a shape design model of a roller used in the rolling of a metal bipolar plate of a fuel cell by two pre-forming and one truing. The forming method with two pre-forming and one truing increases the flow channel depth and reduces the thickness change of the metal bipolar plate after forming. Moreover, it has efficient and simple operation, and is suitable for the continuous production of the metal bipolar plate of a fuel cell.
The technical solutions of the present disclosure are described as follows.
The disclosure provides a method for forming a flow channel on a metal bipolar plate of a fuel cell, comprising:
pre-treating a metal polar plate;
subjecting the metal polar plate to low-temperature heating;
forming a flow channel on the metal polar plate by rolling;
cutting a gas inlet, a gas outlet, a cooling liquid inlet and a cooling liquid outlet on the metal polar plate;
subjecting the metal polar plate to surface treatment;
bonding the metal polar plate with another metal polar plate treated by the above steps to form a metal bipolar plate; and
trimming the metal bipolar plate;
wherein the step of “forming a flow channel on the metal polar plate by rolling” is performed through steps of:
performing pre-forming twice on the metal polar plate sequentially using a pair of first rollers and a pair of second rollers; and
performing truing once using a pair of truing rollers to form the flow channel on the metal polar plate;
design parameters of a first punch and a first die of each of the pair of first rollers used in a first pre-forming and design parameters of a second punch and a second die of each of the pair of second rollers used in a second pre-forming are determined through the following steps:
(1) determining an inclination length l11, a draft angle β11 and a depth h11 of the first punch by a first calculation model:
wherein r11 is an arc radius of the first punch; α11 is half of an arc included angle of the first punch; t is a thickness of the metal polar plate; and k1 is a ratio of a thickness of the metal polar plate after the first pre-forming to a thickness of the metal polar plate before the first pre-forming, and 0<k1<1; and determining an inclination length l12, a draft angle β12, a depth h12 and a horizontal length l1 of the first die by a second calculation model:
wherein r12 is an arc radius of the first die; α12 is an arc included angle of the first die; t is the thickness of the metal polar plate; and k1 is the ratio of the thickness of the metal polar plate after the first pre-forming to the thickness of the metal polar plate before the first pre-forming, and 0<k1<1; and
(2) determining an inclination length l21, an arc radius r21, a draft angle β21 and a depth h21 of the second punch by a third calculation model:
wherein r11 is the arc radius of the first punch; α11 is half of the arc included angle of the first punch; α21 is half of an arc included angle of the second punch; t is the thickness of the metal polar plate; k1 is the ratio of the thickness of the metal polar plate after the first pre-forming to the thickness of the metal polar plate before the first pre-forming, and 0<k1<1; and k2 is a ratio of a thickness of the metal polar plate after the second pre-forming to the thickness of the metal polar plate after the first pre-forming, and 0<k2<1; and
determining an inclination length l22, an arc radius r22, a draft angle β22, a depth h22 and a horizontal length l1 of the second die by a fourth calculation model:
wherein r12 is the arc radius of the first die; α12 is the arc included angle of the first die; α22 is an arc included angle of the second die; t is the thickness of the metal polar plate; k1 is the ratio of the thickness of the metal polar plate after the first pre-forming to the thickness of the metal polar plate before the first pre-forming, and 0<k1<1; and k2 is the ratio of the thickness of the metal polar plate after the second pre-forming to the thickness of the metal polar plate after the first pre-forming, and 0<k2<1.
In some embodiments, design parameters of a third punch and a third die of each of the pair of truing rollers are determined through the following steps:
determining an inclination length l31, an arc radius r31, a draft angle β31 and a depth h31 of the third punch by a fifth calculation model:
wherein r21 is the arc radius of the second punch; α21 is half of the arc included angle of the second punch; α31 is half of an arc included angle of the third punch; s is an inclination length of the third punch and the third die for elongating the metal polar plate; c is a horizontal length of the third punch and the third die for elongating the metal polar plate; t is the thickness of the metal polar plate; k2 is the ratio of the thickness of the metal polar plate after the second pre-forming to the thickness of the metal polar plate after the first pre-forming, and 0<k2<1; and k3 is a ratio of a thickness of the metal polar plate after the truing to the thickness of the metal polar plate after the second pre-forming, and 0<k3<1; and determining an inclination length l32, an arc radius r32, a draft angle β32, a depth h32 and a horizontal length l3 of the third die by a sixth calculation model:
wherein r22 is the arc radius of the second die; α22 is the arc included angle of the second die; α32 is an arc included angle of the third die; s is the inclination length of the third punch and the third die for elongating the metal polar plate; c is the horizontal length of the third punch and the third die for elongating the metal polar plate; t is the thickness of the metal polar plate; k2 is the ratio of the thickness of the metal polar plate after the second pre-forming to the thickness of the metal polar plate after the first pre-forming, and 0<k2<1; and k3 is the ratio of the thickness of the metal polar plate after the truing to the thickness of the metal polar plate after the second pre-forming, and 0<k3<1.
In some embodiments, a model for calculating a depth h, a width d, a spine width w and a fillet angle r of the flow channel of the metal polar plate is shown as follows:
wherein r21 is the arc radius of the second punch; α21 is half of the arc included angle of the second punch; α31 is half of an arc included angle of a punch of each of the pair of truing rollers; s is an inclination length of the punch and a die of each of the pair of truing rollers for elongating the metal polar plate; c is a horizontal length of the punch and the die of each of the pair of truing rollers for elongating the metal polar plate; t is the thickness of the metal polar plate; k2 is the ratio of the thickness of the metal polar plate after the second pre-forming to the thickness of the metal polar plate after the first pre-forming, and 0<k2<1; and k3 is a ratio of a thickness of the metal polar plate after the truing to the thickness of the metal polar plate after the second pre-forming, and 0<k3<1.
Compared to the prior art, the disclosure has the following beneficial effects.
In the method provided herein, the flow channels are formed on the metal bipolar plate by means of two pre-forming processes and one truing process. As a consequence, the method of the disclosure can realize the continuous production, and in the method, the machining power is significantly reduced, the rebound and warpage can be effectively controlled. In addition, models for calculating the design parameters of the rollers used in the pre-forming and truing are also provided herein, which facilitates the manufacture of the rollers, rendering the flow channels manufactured by roll forming superior to those manufactured by micro-stamping forming in the quality and precision, so as to improve a power density of the fuel cell and promote the installation of a fuel cell stack.
In the drawings, 1, straightening and feeding metal polar plate; 2, thinning the metal polar plate; 3, straightening the metal polar plate; 4; cleaning the metal polar plate; 5, detecting thickness of the metal polar plate; 6, low-temperature heating the metal polar plate; 7, rolling the metal polar plate; 8, cutting the metal polar plate; 9, performing surface treatment on the metal polar plate; 10, bonding two metal polar plates to form a metal bipolar plate; and 11, trimming the metal bipolar plate.
The disclosure will be clearly described below with reference to the accompanying drawings and embodiments.
As shown in
As show in
As shown in
(1) An inclination length l11, a draft angle β11 and a depth h11 of the first punch are determined by a first calculation model:
where r11 is an arc radius of the first punch; α11 is half of an arc included angle of the first punch; t is a thickness of the metal polar plate; and k1 is a ratio of a thickness of the metal polar plate after the first pre-forming to a thickness of the metal polar plate before the first pre-forming, and 0<k1<1.
An inclination length l12, a draft angle β12, a depth h12 and a horizontal length l1 of the first die are determined by a second calculation model:
where r12 is an arc radius of the first die; α12 is an arc included angle of the first die; t is the thickness of the metal polar plate; and k1 is the ratio of the thickness of the metal polar plate after the first pre-forming to the thickness of the metal polar plate before the first pre-forming, and 0<k1<1.
(2) An inclination length l21, an arc radius r21, a draft angle fill and a depth h21 of the second punch are determined by a third calculation model:
where r11 is the arc radius of the first punch; α11 is half of the arc included angle of the first punch; α21 is half of an arc included angle of the second punch; t is the thickness of the metal polar plate; k1 is the ratio of the thickness of the metal polar plate after the first pre-forming to the thickness of the metal polar plate before the first pre-forming, and 0<k1<1; k2 is a ratio of a thickness of the metal polar plate after the second pre-forming to the thickness of the metal polar plate after the first pre-forming, and 0<k2<1.
An inclination length l22, an arc radius r22, a draft angle β22, a depth h22 and a horizontal length l1 of the second die are determined by a fourth calculation model:
where r12 is the arc radius of the first die. α12 is the arc included angle of the first die; α22 is an arc included angle of the second die; t is the thickness of the metal polar plate; k1 is the ratio of the thickness of the metal polar plate after the first pre-forming to the thickness of the metal polar plate before the first pre-forming, and 0<k1<1; k2 is the ratio of the thickness of the metal polar plate after the second pre-forming to the thickness of the metal polar plate after the first pre-forming, and 0<k2<1.
As shown in
An inclination length l31, an arc radius r31, a draft angle β31 and a depth h31 of the third punch are determined by a fifth calculation model:
where r21 is the arc radius of the second punch; α21 is half of the arc included angle of the second punch; α31 is half of an arc included angle of the third punch; s is an inclination length of the third punch and the third die for elongating the metal polar plate; c is a horizontal length of the third punch and the third die for elongating the metal polar plate; t is the thickness of the metal polar plate; k2 is the ratio of the thickness of the metal polar plate after the second pre-forming to the thickness of the metal polar plate after the first pre-forming, and 0<k2<1; and k3 is a ratio of a thickness of the metal polar plate after the truing to the thickness of the metal polar plate after the second pre-forming, and 0<k3<1.
An inclination length l32, an arc radius r32, a draft angle β32, a depth h32 and a horizontal length l3 of the third die are determined by a sixth calculation model:
where r22 is the arc radius of the second die; α22 is the arc included angle of the second die; α32 is an arc included angle of the third die; s is the inclination length of the third punch and the third die for elongating the metal polar plate; c is the horizontal length of the third punch and the third die for elongating the metal polar plate; t is the thickness of the metal polar plate; k2 is the ratio of the thickness of the metal polar plate after the second pre-forming to the thickness of the metal polar plate after the first pre-forming, and 0<k2<1; and k3 is the ratio of the thickness of the metal polar plate after the truing to the thickness of the metal polar plate after the second pre-forming, and 0<k3<1.
As shown in
where r21 is the arc radius of the second punch; α21 is half of the arc included angle of the second punch; α31 is half of the arc included angle of the third punch; s is the inclination length of the third punch and the third die for elongating the metal polar plate; c is a horizontal length of the third punch and the third die for elongating the metal polar plate; t is the thickness of the metal polar plate; k2 is the ratio of the thickness of the metal polar plate after the second pre-forming to the thickness of the metal polar plate after the first pre-forming, and 0<k2<1; and k3 is the ratio of the thickness of the metal polar plate after the truing to the thickness of the metal polar plate after the second pre-forming, and 0<k3<1.
A metal anode plate and a metal cathode plate with straight flow channels or S-shaped flow channels can be manufactured by the forming method provided herein.
Number | Date | Country | Kind |
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201910834814.8 | Sep 2019 | CN | national |
This application is a continuation of International Patent Application No. PCT/CN2020/111920, filed on Aug. 27, 2020, which claims the benefit of priority from Chinese Patent Application No. 201910834814.8, filed on Sep. 5, 2019. The content of the aforementioned applications, including any intervening amendments thereto, is incorporated herein by reference in its entirety.
Number | Date | Country | |
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Parent | PCT/CN2020/111920 | Aug 2020 | US |
Child | 17530063 | US |