|Place of Origin:||China|
|Brand Name:||TEI Racing|
|Model Number:||Carbon Ceramic|
Payment & Shipping Terms:
|Minimum Order Quantity:||1|
|Packaging Details:||42*42*42cm Brand Box|
|Payment Terms:||T/T, Western Union, MoneyGram,Paypal|
|Supply Ability:||50 kits per month|
|Fit Car:||BMW Farreri Mclaren Porshce GTR 2021 Audi R8||Meterial:||Cerbon Ceramic|
|Size:||378*32 405*34||Wheel:||19inch 20inch 21inch 220inch|
Audi R8 Carbon Ceramic Brake Rotors,
1420 Degree Carbon Ceramic Brake Rotors,
Audi R8 Car Racing Disc
Automotive Carbon Ceramic Brake Rotors Sport Car Racing Disc Farreri GTR McLaren Porsche 2021 Audi R8
Automotive carbon ceramic brake rotors
Advantages of the next-generation of carbon ceramic brake discs
Up to 70% weight savings (typically 20kg of unsprung weight), compared with steel rotors
Improved handling and driveability
Better NVH (less noise, vibration and harshness)
Improved performance (in both wet and dry conditions)
Reduced brake wear – longer lifespan
Outstanding performance, even from cold
Higher temperature resistance, without brake fade
Increasing the driving mileage of your electrical vehicles
We supply both carbon ceramic rotors and carbon carbon brake rotors. They can all be used for racing. But customers prefer to use carbon carbon brakes for racing only, and use carbon ceramic rotors on both track and street running.
Extremely long life time
Service life 300,000-400,000Kms steel brake disc only 50,000-700,000kms
Upgrade long carbon Fiber
Shorter Braking distance by 20%-30%
The braking force remains stable under extreme conditions
The carbon ceramic brake disc weight only 1/4 of steel disc
High Temperature Resistance
Carbon ceramic brake discs can stand highest temperature 1420 Degree , Steel brake disc stand 600 degree
Excellent chemical stability and corrosion resistance
We have two kinds of different brake pads. They are carbon carbon (C/C )pads and semi-metallic pads. The carbon carbon brake pads are the best option to work with the carbon carbon brake rotors. But for carbon ceramic brake discs, we can use both the C/C pads and the semi-metallic pads. These brake pads can work the carbon ceramic brake discs for track and street use. And our semi-metal pads are also siutable to work with other brands carbon ceramic brake rotors, such as Brembo and SGL.
Both the brake rotors and brake pads can be customized, don’t forget to inquiry.
Currently, the best option brake pads for carbon ceramic discs are organic compounds made, which are similar to be used with traditional iron brake discs but different. These are pads are more low-metal or semi-metal pads. Our carbon ceramic brake discs can be used with Pagid Racing RSC series pads, and Pagid Racing RSL29 pads. But these are not available for every shapes now. We have developed our own low-metal pads, covering any shapes of pads. These brake pad compound are speciality developed for carbon ceramic brakes.
Light weight, saving as much as 70% mass versus steel
Stable CoF, Coefficient of Friction
No heat fading
Shorter braking distance
No thermal shock nor expansion
Longer life-span than previous gen CCBs
3D needle- punched carbon fiber structure
Higher intensity, retain structural integrity up to 1800⁰ C
We made the carbon ceramic discs in 3 steps. First, the carbon fiber preform, 3D needle-punched directly with continuous carbon fibers, which ensure the strength of the discs. Second, the carbon carbon material, it is a carbon carbon ring with density 1.45 g/cm3. We use CVD (chemical vapor deposition) technology to make the carbon fiber preform become carbon carbon. Third, carbon ceramic disc. After machining the carbon carbon ring to the required application, we use RMI (reactive melting infiltration ) to make the carbon carbon to carbon ceramic.
For nearly 40 years now, since the 1970s, classic traditional carbon ceramic discs havebeen made from discontinuous (chopped) carbon fibers with a mold, exactly as in the Youtube
But is making the next-generation carbon ceramic disc from continuous carbon fibers with 3D needle-punched technology. With high grade (Japanese T700 Torayca) continuous carbon fibers and 3D needle-punched technology, our discs have a lot of benefits compared with traditional carbon ceramic discs.
1). Stronger. Unlikely to crack with a 3D continuous carbon fibers structure in the discs, disintegration occurring as temperatures approach 1800C, a temperature unlikely to be encountered outside the most extreme motorsports applications.
2) Longer life span. The whole body of the disc are C/CSi material. Theoretically, it can be used as its whole life.
3). Higher heat conductivity. Faster heat releasing to ensure excellent brake performance.
4). Can be used both on track and street.
The matrix of carbon carbon material is carbon only. Carbon carbon brakes are always used in Formula 1 or DTM. The brake performance goes higher when the temperature goes higher. It is not so good for everyday driving. And it is even lighter weight than carbon ceramic. That’s another reason why it is chosen for Formula 1. But it is softer, and easy to be worn out. Thus he team will have to replace the discs after every race. Carbon carbon discs always work with carbon carbon pads only, like the aircraft carbon brake pairs.
The main ingredient of carbon ceramic discs are C (carbon) and CSi (ceramic). The friction of carbon ceramic discs are relatively stable, will not change much as the temperature changes. The stiffness of carbon ceramic is very high, that’s why we need to use diamond knifes to cut it when we do the balancing. And the life-span of the carbon ceramic disc is very long, almost equal to a vehicle’s life. Low-metal or semi-metal pads are proven to be the best option pads for carbon ceramic discs. But these pads are special formulated to carbon ceramic brake discs, not every pads are working effectively. There is a saying that F1 will use carbon ceramic brakes in the future. But carbon ceramic brake discs have been installed on aircraft for many years.
Brake bedding is also called brake-in or conditioning. During the process of the bedded-in, the brake pads compound will be transferred on the friction surface of the carbon ceramic brake discs. The process mainly contains heating procedure and cooling procedure. After the process finished properly, the discs friction surface will be covered with brake pad compound homogeneously. If not, it may cause NVH issues(Noise, Vibration, Harshness). has developed a procedure of bedding carbon ceramic brake discs.
Following the pad and rotor bedding procedure should ensure that an adequate transfer of pad.
1). Initial bed-in
Speed: gentle stops from 80km/h to 30km/h
Pedal strength: ≤50%
Repetition: 20 times
Effect : rotors and pads fit
2). Heavy bed-in
Speed: heavy stops from 150km/h to 120km/h
Pedal strength: 30%→50%→80%
Repetition: 10 times
Effect: friction layer formed between rotors and pads.
3). Cool bed-in
Speed: stop from 80km/h to 30km/h
Pedal strength: ≤50%
Repetition: 20 times
When you finish all above steps, surface of rotors will be shining. Please repeat above steps if the rotors have no good effect due to the car model and road situation difference.
We have developed carbon ceramic brake discs and special pads for mainly performance cars in the market. The following brands are already covered by us: BMW (M Performance or M), Mercedes AMG series, Audi RS series and S series, Porsche, Ferrari, Lamborghini etc. Please ask us for the application list. And we are keeping developing applications for more vehicles. Customization or OEM are available. Please let us know your project, we are able to provide you a suitable solution.
We can tell after we evaluated your project. We offer play and plug in solutions for many performance cars. Customers just need to replace the original steel brake discs and original brake pads. We can supply the OE size carbon ceramic brake discs and OE shape special brake pads for you.
Most 3D Carbon Ceramic rotors will exceed the life of the vehicle, and still be good when the ownership transfers. Potential new clients may worry if they are about to receive worn-out rotors. Our rotors are guaranteed to be delivered with a 2mm surface tolerance, and a default pre-bedded process that should ensure a headache free mating of the new pads with the brand-new rotor discs. Methods to determine that a 3d Carbon rotor is nearing end of life is to check the thickness of the rotors. When the rotors were worn to the suggested thickness, we suggest to replace the rotors.
Although the rotors should last hundreds of thousands of Kms, this is not the case with the pads. The pads are the softer of these two materials, with the right composition that ensure maximal braking characteristics, and wear against a ceramic surface that does not change. It is recommended to service and inspect the pads especially after repeat track sessions, annually or bi-annually in order to ensure that the pad surface is optimal. In the extremely rare case of a minor debris lodging on the pad, a prompt inspection is recommended to avoid that debris wearing cutting the rotor surface. As the pad nears its end of life, the owner has the option of ordering one of many CCB compatible pads. Alternatively, can procure a replacement according to the pad’s industrial design code and dimensions.
Bedded in Carbon rotors are unlikely to develop any NVH or Disk Thickness Variation (DTV). However, extreme circumstances, such as intensive heat applications exceeding 1000⁰C without a cooldown, or with sudden stop, may produce some NVH. For classic CCBs, premium car service centres have been known to claim that brand new recently tracked chopped CCBs have developed DTV, and requested 10,000$ fee needed to replace them.
That is not the case with continuous CCBs, which need to reach over 1500C to commence loosing structural integrity. But things could happen, wrong pads, poor DOT fluid state. If indeed DTV was to occur, a re-bedding procedure could or should remove the extra pad material and restore the smooth contact surface. If that proves unsuccessful, can facilitate a return to our technical centre, and reconditioning the surface, which can be done multiple times. Surface reconditioning is an unparalleled advantage that the new 3D Continuous CCBs offer versus the 40 year older chopped technology.
All crossed-drilled rotors have a characteristic “whoooot” that some clients love, and others may dislike. On a MacLaren, a Lamborghini or a Ferrari this sound is present but often exceeded by their V8-V12 engine decibel levels. Noisier V6 or inline 6 engines (BMW M) reduce the cross-drilled sound, but it is perceptible. However, the newer generation of client vehicles, with insulated cabin acoustics and quieter engines, may indeed permit more of the cross-drilled sound entering the cabin. A BMW M Performance inline 6 cannot supress the CCB cross-drilled sound in the same way the V12 Lambo does at idle. Clients that are sure not wanting any additional sounds should opt for the non-drilled rotor versions.
Forums and videos document that classical CCBs have given their owners squeal related headaches for many years, even though most times their cars are driven in optimal weather. Some owners driving classical CCBs have been told that it is normal, “Live with it”, or lost countless service days trying replacements. In their case, squeal is caused by improperly bedded in brakes resonating, or just material vibration between their particular pads and OEM chopped fibre CCBs.
However, our 3D Continuous clients have reported no squeal during summertime torrential rain conditions, no squeal during cold morning startup, no squeal in 0C icy rain condition, no squeal as low as -30⁰C. This could be due to the material properties of 3D Continuous CCB its CoF and surface characteristics.