Patent Application
20190275760
The present disclosure relates generally to friction clutches and plates used in torque converters and motor vehicle transmissions and more specifically to wet friction material.
The friction material in wet-type friction clutches generally operates in an oil submerged environment and is often paper-based material used to form friction material rings. It is known to spray or sprinkle diatomaceous earth sold under the trade name CELITE on top of the base materials directly during the paper making process in a Fourdrinier machine at the wet end of the machine when the paper base material is being moved along a conveyor. This process is good for very high volume papers, but there is large waste during initial set up, so it is not practical for smaller volume production.
U.S. Pat. No. 6,013,696 discloses using a laser to form pores in a cured, resin-impregnated friction material.
U.S. Pat. No. 6,318,534 discloses friction material having micro-pockets formed on the surface.
U.S. Pub. 2017/0089415 discloses friction material including a bottom layer and a top layer forming a paper composite, with pores being created by a laser in the top surface.
U.S. Pub. 2017/0261057, U.S. Pub. 2006/0008635, U.S. Pub. 2017/0335913 and U.S. Pat. No. 9,499,759 disclose friction material including two or more layers.
A method of making a wet friction material is provided. The method includes providing an outer layer on a base layer to form the wet friction material. The base layer includes a proportion of first fiber material and a proportion of first filler material and the outer layer includes a proportion of second fiber material and a proportion of second filler material. The proportion of second fiber material is less than the proportion of first fiber material and the proportion of second filler material is greater than the proportion of first filler material. The method also includes forming a plurality of orifices passing through the outer layer.
According to embodiments of the method, the base layer has a first thickness, the outer layer has a second thickness, the wet friction material may have a total thickness equaling the first thickness plus the second thickness and the second thickness may be 10% to 30% of the total thickness. The orifices may have a maximum diameter of 50 μm to 200 μm. The orifices may represent 10% to 30% of a total surface area of an outer surface of the outer layer. The first filler material and the second filler material may be each formed by one or more fillers from a group consisting of diatomaceous earth and/or clay. The first fiber material and the second fiber material may be each formed by one or more fibers from a group consisting of aramid fibers, organic fibers and/or carbon fibers. The proportion of first fiber material may be between 35 to 60% of the base layer and the proportion of second fiber material may between of 5 to 25% of the outer layer. The proportion of first filler material may be between 15 to 50% by percentage weight of the base layer and the proportion of second filler may be between of 45 to 75% by percentage weight of the outer layer. The providing of the outer layer on the base layer to form the wet friction material may include laminating the outer layer on the base layer. At least one of the base layer and the outer layer may include a binder. The laminating of the outer layer on the base layer may include applying heat and pressure to the outer layer to fix the outer layer and the base layer together via the binder.
A clutch assembly is also provided including a metal part and the wet friction material fixed on the metal part.
A wet friction material is also provided. The wet friction material includes a base layer; and an outer layer on the base layer. The base layer includes a proportion of first fiber material and a proportion of first filler material and the outer layer includes a proportion of second fiber material and a proportion of second filler material. The proportion of second fiber material is less than the proportion of first fiber material and the proportion of second filler material is greater than the proportion of first filler material. The outer layer includes a plurality of orifices passing through the outer layer.
According to embodiments of the wet friction material, the base layer has a first thickness, the outer layer has a second thickness, the wet friction material may have a total thickness equaling the first thickness plus the second thickness and the second thickness may be 10% to 30% of the total thickness. The orifices may have a maximum diameter of 50 μm to 200 μm. The orifices may represent 10% to 30% of a total surface area of an outer surface of the outer layer. The first filler material and the second filler material may be each formed by one or more fillers from a group consisting of diatomaceous earth and/or clay. The first fiber material and the second fiber material may be each formed by one or more fibers from a group consisting of aramid fibers, organic fibers and/or carbon fibers. The proportion of first fiber material may be between 50 to 80% of the base layer and the proportion of second fiber material may be between of 5 to 30% of the outer layer. The proportion of first filler material may be between 15 to 50% by percentage weight of the base layer and the proportion of second filler may be between of 45 to 75% by percentage weight of the outer layer.
The present disclosure is described below by reference to the following drawings, in which:
The present disclosure provides embodiments of wet friction material that are able to provide a sufficient friction at high slip speed while also maintaining porosity. Adding a friction modifier layer to the top surface improves the friction performance, but clogs the pores of the underlying wet friction material. The present disclosure provides small orifices in the friction modifier layer increase the porosity and the performance in high slip speed.
Base layer 10 is a wet friction material formed of fibers, filler material and a binder. The fibers can be aramid fibers, organic fibers, carbon fibers and/or fiberglass. The organics fibers include cellulose fibers or cotton fibers. The fillers can be diatomaceous earth and/or clay. The binder can be a phenolic resin, a latex or a silane. Optionally a friction modifier such as graphite may also be included in base layer 10.
Outer layer 12 includes fibers, filler material and a binder. The fibers can be aramid fibers, organic fibers, carbon fibers and/or fiberglass. The organic fibers include cellulose fibers or cotton fibers. The fillers can be diatomaceous earth and/or clay. The binder can be a phenolic resin, a latex or a silane. Optionally a friction modifier such as graphite may also be included in outer layer 12. The composition of outer layer 12 includes a higher ratio of filler material and a lower ratio of fibers than base layer 10, such that outer layer 12 is less porous and more dense than base layer 10, has a higher coefficient of friction than base layer 10 and a higher wear resistance than base layer 10. The fibers of layers 10 and 12 have a mean diameter of 45 to 55 microns and a mean length of 1 to 2 millimeters.
In one preferred embodiment, base layer 10 includes, by percentage weight, 35 to 60% fibers, 15 to 40% filler material and 20 to 30% binder. In another preferred embodiment, base layer 10, by percentage weight, 35 to 55% fibers, 15 to 40% filler material and 20 to 30% binder. More specifically, in one preferred embodiment, base layer 10 includes, by percentage weight, 30 to 55% aramid and organic fibers and 5 to 10% carbon fibers, 15 to 40% filler material and 20 to 30% binder. In another preferred embodiment, base layer 10 includes, by percentage weight, 40 to 60% aramid and organic fibers and 5 to 10% carbon fibers, 15 to 40% filler material and 20 to 30% binder.
In one preferred embodiment, outer layer 12 includes, by percentage weight, 5 to 25% fibers, 45 to 75% filler material and 20 to 30% binder.
After the forming of wet friction material 16, a plurality of orifices 18 are formed in outer layer 12 by a laser 20. Orifices 18 extend from outer surface 12a to inner surface 12b such that orifices 18 extend through outer layer 12 to undercover the porous matrix of base layer 10. Orifices 18 thus allow fluid at outer surface 12a of outer layer 12 to access the porous matrix of base layer 10. Laser 20 is moved in a controlled manner over surface 12a of outer layer 12 and repetitively pulsed to form orifices 18. In one preferred embodiment, orifices 18 are formed in outer layer 12 each have a maximum diameter of 50 μm to 200 μm and represent 10% to 30% of the total surface area of outer surface 12a of outer layer. Maximum diameter is defined as the greatest distance between two edge points of an orifice as measured from outer surface 12a. Total surface area means the surface area of outer surface 12a before orifices 18 are added, i.e., the surface area of outer surface 12a after orifices 18 are added, plus the surface area removed by the formation of orifices 18.
In the preceding specification, the disclosure has been described with reference to specific exemplary embodiments and examples thereof. It will, however, be evident that various modifications and changes may be made thereto without departing from the broader spirit and scope of disclosure as set forth in the claims that follow. The specification and drawings are accordingly to be regarded in an illustrative manner rather than a restrictive sense.
10 base layer
10a outer surface
10b lower surface
12 outer layer
12a outer surface
12b inner surface
14 heat plate
14a plate surface
16 wet friction material
18 orifices
20 laser
22 metal part
22a surface
30 clutch plate
32 lockup clutch assembly
34 torque converter
36 piston
38 front cover
38a inside surface
40 impeller
42 turbine
44 damper assembly
46 output hub
