Satisfied Performance Brakes

1. Do I need to follow a break-in procedure when I install new brake pads?

Yes.... a proper break-in of rotors and pads is crucial to ensure proper braking performance and wear characteristics of your new pads. Pads and rotors that are not properly broken in may end up creating other symptoms such as vibration or noise or the pads may end up "glazing" which could dramatically affect stopping performance. Always follow the break-in procedure described in the Break in Instructions document (Adobe PDF format).

2. Do I need to resurface existing rotors when I am installing a new set of pads?

In order to ensure a uniform mating surface between the new brake pad and existing rotor, it is optimal to resurface the rotor prior to installing and bedding-in new brake pads. Resurfacing the rotor will also help ensure maximum pad life and braking torque (i.e. stopping power). Further, when changing from one brake compound to another, especially when switching from semi-metallic brake pad to a ceramic-based brake compound, it is necessary to turn your rotors to remove any existing friction material deposits on the rotor. These friction material deposits (called "film transfer") can often interfere with the proper "bedding" of new brake pads and, additionally, can cause a notable shudder during the initial stages of new pad use.

Keep in mind, however, that when resurfacing the rotor, make sure you are within 20% of the factory specified rotor thickness after resurfacing, or else your rotor will be more prone to warping and cracking, or otherwise present a condition where catastrophic failure may occur (e.g. a rotor may crack severely and then shatter under hard braking).

3. I am experiencing a brake shudder - what is causing this?

There are three main causes of "brake shudder", which is generally felt as a brake pedal or steering wheel pulsation or vibration. Having verified that your rotors are not warped (i.e. warped rotors are another, more obvious, cause of the brake shudder phenomenon), the following are possible, commonly overlooked, explanations for an experienced brake shudder:

a. An improperly seated or mounted rotor (i.e. the rotor does not turn perfectly parallel to the brake pad surfaces). This can be due to:

debris trapped between the backside mating surface of the rotor and the wheel hub
improperly tightened lug nuts/bolts
pads that are not properly re-aligning themselves after releasing the brake pedal, due to a very rough or dry (i.e. non-lubricated) brake pad to mounting clip interface.

b. Heavy friction material film transfers on the rotors. Very heavy use of the brake pads, especially use that exceeds the manufacturer's recommended heat range, can result in uneven friction material deposits on the rotors. This results in a "grab-release" effect when the brakes are applied. While this will generally even itself out over time, in extreme cases, the rotors may need to be resurfaced/turned/cut.

c. Worn suspension parts (i.e. springs, shocks/dampers, bushings, etc.). "Old timers" call this type of suspension shift under torque load "tramp". In this situation, the car's alignment is slightly changing due to brake torque upon brake pedal application. Severe cases of this result in a very notable pull in the steering, and can become evident as a shudder. If this is the cause of your brake shudder, the suspect suspension components should be replaced.

4. What is brake fade and why does it occur?

Pad fade occurs for several reasons. All friction materials have a coefficient of friction curve over temperature. Friction materials have an optimal working temperature where the coefficient of friction is the highest. Sometimes you can use the brakes so hard that you get the temperature over the point of maximum friction to where the coefficient of friction curve starts to decline.

The mechanics of this decline in the coefficient of friction are varied. At a certain temperature, certain elements of the pad can melt or smear causing a lubrication effect, this is the classic glazed pad. Usually the organic binder resin starts to go first, then even the metallic elements of the friction material can start to melt. At really high temperatures the friction material starts to vaporize and the pad can sort of hydroplane on a boundary layer of vaporized metal and friction material which acts like a lubricant. Pad fade is felt as a car that still has a decent, non mushy feeling brake pedal that won't stop even if you are pushing as hard as you can. Usually it builds somewhat slowly giving you time to compensate for it, but some friction materials have a sudden drop off of friction when the heat is put on them resulting in sudden dangerous fade.

Green Fade Green fade is a type of fade that manifests itself on brand new brake pads. Brake pads are usually made of different types of heat resistant materials bound together with a phenolic resin binder. These are thermosetting plastic resins with a high heat resistance. On a new brake pad, these resins will out-gas or cure when used hard on their first few heat cycles. The new pad can hydroplane on this layer of excreted gas. Green fade is dangerous because many people assume that new brakes are perfect and can be used hard right off the bat. Green fade typically will occur much earlier than normal fade so it can catch a driver that is used to a certain car's characteristics unaware. Typically the onset of green fade is rather sudden, further increasing the danger factor. Green fade can occur if you change the pads and drive on the street for a few hundred or even thousand miles, never braking hard, then suddenly start using the brakes hard.

5. What do edge codes mean?

An edge code is a means of identification that may be used to describe the initial frictional characteristic of any brake lining.

Typically, a two-character code (e.g. EE, FF, GG, HH, etc) is used on specific friction formulation. These characters represent the coefficient of friction when a 1" square piece of friction material is subjected to varying conditions of load, temperature, pressure and rubbing speed on a test apparatus known as the Chase machine.

The coefficient of friction measured by the Chase test describes the relationship between the two forces acting on the friction material. A clamping force is exerted on the friction material, resulting in a frictional or resistance force. A low coefficient of friction means that very little of the clamping force is transferred into resistance force. On the other hand, a high coefficient of friction means that given the same level of clamping force, a higher resistance force is generated by the brake pad.

For example, a pad that carries an HH code has a normal coefficient of friction of 0.55 or higher, and a hot coefficient of friction of 0.55 or higher.

The first letter of the code represents the normal friction coefficient. This is defined as the average of four test data points measured at 200, 250, 300 and 400 degrees Farenheit.

The second letter of the code represents the hot friction coefficient based on a fade and recovery test. We all should know what brake fade is. If you've ever had to use the front brake extensively and found that its effectiveness quickly diminished, that's fade. Recovery is basically the period where the brakes are gradually cooling off.

The hot friction coefficient is defined as the average of 10 data points located at 400 and 300F. On the first recovery cycle of the pad; 450, 500, 550, 600 and 650F. On the second fade cycle; and 500, 400, and 300F on the second recovery cycle.

The range of friction coefficients assigned to each code letter are as follows: C = less than 0.15. D= 0.15 to 0.25. E= 0.25 to 0.35. F= 0.35 to 0.45. G= 0.45 to 0.55, and H= over 0.55.

6. What types of brake fluids are available for my vehicle?

There are three main components or considerations that must be addressed when selecting the proper brake fluid for your braking system. The first is the DOT-specified compliance of your brake system: DOT 3, DOT 4, DOT 5, or DOT 5.1. You can find this information in your owner's manual. In general, DOT 3 and DOT 4 fluids and systems are compatible with each other, and are differentiated by their dry and wet boiling points (more on this later). Some synthetic DOT 5.1 fluids are also compatible with DOT 3 and DOT 4 fluids/systems. DOT 5 fluids are silicone based, and must NEVER be mixed with a DOT 3 or DOT 4 fluid/system, and vice-versa.

The second consideration is the boiling point of the brake fluid. For brake fluids, there are two key temperature points that you should be aware of: the dry boiling point and the wet boiling point. The dry boiling point is the temperature at which the brake fluid will boil when freshly installed. The wet boiling point is the temperature at which the brake fluid will boil after it has absorbed moisture from the environment; i.e. after being used in the brake system for a while. The most important of the two is arguably the wet boiling point, especially for those who do not change their brake fluid often.

The third point to consider is the hydroscopic nature of the fluid, often termed "hydroscopicity". Quite simply, a brake fluid's hydroscopicity is its propensity to absorb moisture: a brake fluid that is very hydroscopic will absorb moisture at a faster rate than a brake fluid with a low(er) hydroscopicity. In general, high-performance brake fluids which are designed for use on the street (where the vehicle owner is assumed to change the brake fluid on an annual basis, on average) have a low hydroscopicity (along with lower dry and wet boiling points), while brake fluids designed for use In a performance environment will have a higher hydroscopicity (along with a higher dry and wet boiling points). There are exceptions to this general rule-of-thumb, of course, but "in general" these statements are correct.

7. What is the proper method for bleeding brakes?

When bleeding brakes it is best to manually bleed them as pressure bleeders can cause cavitation and bubbles inside the system. Empty the brake reservoir with a turkey baster then fill the reservoir with a high quality brake fluid. Start bleeding at the furthest wheel away from the Master Cylinder and progress to the closest. So that would go right-rear, left-rear, right-front and left-front. Attach a length of clear Tigon tubing (available form any auto parts store) to the bleeder nipple, put the other end of the line into some sort of container so the other end will be submerged in brake fluid and open the nipple. Have someone in the car to pump the brakes. Slowly pump all of the old fluid out of the line until new clear fluid comes out and then have the person in the car hold the pedal down while you close the bleeder. Have the person lift the pedal up slowly and then push down slowly while you open the nipple. You have to communicate with the pumper because the bleeder should only be open on the down stroke of the brake pedal. It is important to pump slowly to avoid bubble-forming cavitation. Continue to pump until you cannot observe any bubbles in the clear Tigon tube.

Get a rubber mallet and tap the caliper to dislodge any bubbles that may be stuck inside the caliper and bleed some more until no more bubbles come out. Do this at all the wheels and you are done. Be careful not to let the reservoir run dry or you will have to start all over. On ABS equipped cars you want to be extra careful about this because it takes forever and a lot of fluid to bleed a completely dry ABS system. Some ABS cars require bleeding from nipples on the ABS modulator so check your manual.

Title - d3ea the true measure of performance

It’s time to separate the hype from the reality. For years the aftermarket friction industry has been claiming to deliver OE performance – promises that are easy to make but harder to prove.

At Satisfied we’ve adopted the D3EA® Certification standard as definitive proof of the advanced performance and reliability of our brake products. D3EA® has empowered us to come “full circle” in our quest for the ideal balance of performance and cost – allowing us to outperform the national brands while maintaining a value proposition that ensures your profitability.

The Motor Vehicle Safety Act requires new vehicle braking systems to conform to Federal Motor Vehicle Safety Standards (FMVSS 105 and FMVSS 135) with a clearly implied obligation on suppliers and installers of braking components to not adversely affect the braking performance of the vehicle. In other words, if your braking components don’t match the same minimum performance levels as the OE, you may be held responsible.

In 1989, a landmark NHTSA Study comparing O.E. to Aftermarket friction revealed average braking distance increases of 10%. With instances of stopping distance increased by up to 50%, the study concluded that under-performing aftermarket friction was causing fatalities and significant societal costs.

Satisfied believes that measuring up to O.E. performance is important to responsibly ensure the safety of your customers, and to provide you with the peace of mind that comes only with the purchase and sale of D3EA® Certified Satisfied friction.

D3EA® was developed by Dr. Thomas Flaim and Greening Testing Laboratories, Inc. Their goal was to define vehicle-relevant and objective performance standards, and testing procedures that could accurately recreate real-world vehicle-specific braking conditions covering a wide range of platforms.

Today two major automobile manufacturers and a significant number of leading aftermarket friction manufacturers use D3EA®, since no Federal certification is established by the Federal government.

In fact, with the absence of Federally conducted testing, D3EA® is widely acknowledged and adopted by responsible industry leaders as the only reliable and truly vehicle-specific laboratory based performance standard.

By adopting D3EA® as part of our comprehensive SMART Braking System, Satisfied enhances the value of your friction program, providing a more responsible and affordable alternative to the national brands.

Emergency stops require full use of the adhesion available at the four corners of the vehicle to achieve maximum controlled vehicle deceleration rates [shortest stopping distances]. Braking systems use different strategies to counteract the potentially destabilizing “pitch and roll” movements generated during hard braking events including fixed or dynamic proportioning. Fixed proportioning delivers a predetermined [fixed] fraction of front brake pressure to the rear wheels while dynamic of electronic proportioning modulates rear pressures based on differences in wheel speeds at the front and rear axles.

Other vehicles use ABS and electronic stability systems [such as Stabilitrak®] to compensate for the inherent changes in brake force distribution required to avoid skidding and potential loss of control during hard braking.

The D3EA® Certification process comprehends these vehicle characteristics and uses acceptance criteria that permit maximum vehicle deceleration without encountering loss of steering response or vehicle stability in hard braking events.

Friction material is at the heart of every braking system – working with all other brake system components – and must be designed and tested under those conditions.

Satisfied’s balanced friction formulations build on the D3EA® test data, which recreates simultaneous front and rear braking with vehicle-specific conditions including vehicle loading and brake cooling, and comprehends all existing brake system components including rear brake proportioning, electronic brake distribution, ABS systems and hydraulic displacement limits. By confirming dynamic front and rear braking performance in real time, D3EA® provides the only laboratory based way to properly predict, evaluate and confirm friction balance and true braking performance.

In this realistic and truly demanding testing environment, Satisfied determines when the friction compositions deliver the exact front-to-rear balance required to achieve straight and safe braking without skidding or loss of steering control. Other laboratory testing methods do not provide a truly dynamic and proven way to create brakes that live up to the requirements of the law, and the responsibility of equipping your customers with the right brakes.

Satisfied’s engineers, armed with D3EA® test data, create friction that responds to the requirements of the entire OE ABS or stability system. When the system sensors encounter friction characteristics that are OE compliant, the entire system can function correctly and safely. If the friction is outside the range of performance expected by the system, the entire system may react incorrectly and the performance can be greatly compromised – even if the friction is not defective, but simply mismatched to the vehicle’s braking system.

With D3EA®, Satisfied can measure exactly what is happening. If the friction is “too hot” the rotor may deform, causing premature wear and potential failure. If the calipers have to work over their capacity to make up for friction that is too light, dangerous results may occur.

With D3EA® and Satisfied’s advanced engineering capabilities, the complex realities of platform-specific braking dynamics can be quantified and used to create better, safer, and ultimately more satisfying friction products.

	Satisfied's advanced friction is layered to further dampen noise and vibration while solidifying the friction bond. Vehicle-specific formulations, including Ceramic, Semi-Metallics, and NAO´s ensure compliance with OE noise reduction specifications.
	Our multi-layer constrained shims and precision friction profiling (slots and chamfers), work in tandem to relieve pressure and eliminate binding that can cause noise when braking.
	Innovations like GridLok®, combined with Satisfied's precision manufacturing, create brake parts that effectively resist vibration and other noise generating effects.