CHANNEL FORMING SYSTEM OF FUEL CELL SEPARATOR

Abstract

A channel forming system of fuel cell separator is provided. The channel forming system includes a composite molded body of graphite or graphite and resin that comprises the fuel cell separator; and a channel forming tool with rotary drive for the composite molded body. The channel forming tool includes a cylindrical body; and a grooving tool. The grooving tool includes machining blades in the shape of groove which are manufactured as workpiece shape of the channel and regularly arranged in lines on the external circumferential surface along the major axis of the cylindrical body, and as the channel forming tool rotates against the composite molded body, channels are created on the whole surface of one side of the composite molded body.

Claims

1. A channel forming system of fuel cell separator comprising: a composite molded body of graphite or graphite and resin that comprises the fuel cell separator; and a channel forming tool with rotary drive for the composite molded body, wherein the channel forming tool comprises a cylindrical body; and a grooving tool, wherein the grooving tool includes machining blades in a shape of groove which are manufactured as workpiece shape of the channel and regularly arranged in lines on an external circumferential surface along a major axis of the cylindrical body, and as the channel forming tool rotates against the composite molded body, channels are created on a whole surface of one side of the composite molded body.

2. The channel forming system of claim 1, wherein a length of a line including machining blades that comprise the grooving tool which is longer than a width of the composite molded body of the fuel cell separator.

3. The channel forming system of claim 1, wherein the lines including machining blades are located on the external circumferential surface of the cylindrical body with specific distance along a central angle.

4. The channel forming system of claim 3, wherein the cylindrical body rotates at a speed of 2,000 rpm to 20,000 rpm and is transferred with contact on the composite molded body at the feeding speed of 50 mm/sec to 200 mm/sec.

5. The channel forming system of claim 1, wherein shape of channel is formed with 1.0 mm to 2.0 mm of width and 0.3 mm to 1.0 mm of depth and the machining blades includes 100 to 200 grooves.

6. A channel forming tool of fuel cell separator comprising: a cylindrical body; and a grooving tool, wherein the grooving tool includes machining blades in a shape of groove which are manufactured as workpiece shape of the channel and regularly arranged in lines on the external circumferential surface along a major axis of the cylindrical body, and as the channel forming tool rotates against the composite molded body, channels are created on a whole surface of one side of the composite molded body.

7. The channel forming system of claim 6, wherein the lines including machining blades are located on the external circumferential surface of the cylindrical body with specific distance along a central angle.

8. The channel forming system of claim 6, wherein shape of channel is formed with 1.0 mm to 2.0 mm of width and 0.3 mm to 1.0 mm of depth and the machining blades includes 100 to 200 grooves.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0018] The picture of FIG. 1 shows the channel forming tool of this invention in the holder.

[0019] FIG. 2 is a magnified picture of the grooving tool of the channel forming tool in FIG. 1.

[0020] FIG. 3 shows the channel forming tool of FIG. 1 installed on the driving part and the actual picture showing how the channels are formed.

DETAILED DESCRIPTION

[0021] The following is a detailed description of correct examples of this invention implemented referring to the attached drawings.

[0022] FIG. 1 shows how the channel forming tool (100) of this invention is located in the holder.

[0023] The grooving tool (20) is located along the cylindric body (10) lengthwise, and the grooving tool (20) is shown in the magnified image of FIG. 2 with more details.

[0024] The above grooving tool (20) is built with a line (linear array) with regularly aligned grooving blades along the longitudinal direction of the body, and that grooving tool (20) includes many parallel lines at certain central angles on the circumference surface. For example, lines of grooving blades located at each angle of 45 degrees orienting from the center of the cylindric body place 4 grooving blade lines on the whole surface of the body. Many grooving blade lines at regular central angles with the same orientation to center, which may make 4 to 8 lines. In the example attached, 6 lines of grooving tool (20) are made.

[0025] Taking advantage of the grooving tool which have many grooving blades regularly aligned along the composite molding body of graphite or graphite and resin that comprises the separator, channels can be formed on the whole surface or one whole side of the fuel cell separator with a run.

[0026] The above body (10) and the grooving tool (20) of the channel forming tool (100) are made of hard metal or tool metal.

[0027] The grooving tool (20) manufactured following the workpiece shape of the channels to be formed on the separator consists of an array of grooving tools, which becomes the channel forming tool of fuel cell separator that can form many channels simultaneously by creating many grooves on the bar-shaped tool material.

[0028] In other words, the grooving tool can form many channels at the same time by making bar-type lines at each certain central angles on the cylindric body (10) and creating many grooves right on the bar-type lines.

[0029] The grooving tool (20) is fixed on the circumferential surface of the cylindric body (also called as an assembly of holder, jig, or grooving tool) with a length longer than the width of the separator, and it can create many grooves simultaneously by cutting method as the body (10) is rotating and transferred with contact on the surface of the separator. Since it has multiple lines of grooving tools (20), subsequent channel cutting is carried out as the body (10) rotates and sticking of the cut material like sand burning never occurs.

[0030] The shape of each channel to be formed is as wide as 1.0 to 2.0 mm and as deep as 0.3 to 1.0 mm, and 100 to 200 of the grooves on the tool are made in the workpiece shape of the channel, leaving etching 100 to 200 grooves on the surface.

[0031] The cylindric body (10) above rotates at the speed of 2,000 to 20,000 rpm when the diameter of the bottom is 150 mm, and transferred with contact on the separator at the feeding speed of 50 to 200 mm/sec, creating all channels on one side of the separator within several seconds (in 10 seconds or less). The diameter of the bottom of the cylinder can be 100 to 200 mm.

[0032] FIG. 3 shows the channel forming tool of FIG. 1 installed on the driving part and how it actually creates channels. One end of the cylindric body of the channel forming tool is fixed on the driving part to rotate the cylindric body and makes channels on the molded body of the fuel cell separator. Therefore, the construction of the equipment is simple because one single driving part is used to make channels on the whole surface of the molded body at the same time.

[0033] The actual channel forming process is carried out in the atmospheric environment of room temperature. However, it is ideal to keep the temperature constant because the composite molded body of graphite or graphite and resin is very sensitive to thermal expansion. The process can be done in a thermo-hygrostat or under controlled room temperature using an air conditioner or a heater.

[0034] The rights of this invention is defined by the scope of the claims, not limited to the examples of implementation explained above, and it is apparent that persons with ordinary skill in the art to which the invention pertain may implement various alterations and manufacturing within the scope of the rights written.