Contribution to Development of Copper Free Automotive Brake Pad

Lee, Lin

01 August 2013

When passenger vehicle drivers hit the brakes of their cars, the friction releases airborne wear particles from the contact between rotor and brake pad onto the road which are eventually washed down storm drains and into rivers. The wear particles includes copper, which functions as solid lubricant for increasing thermal heat fade as well as increasing friction coefficient for the brake pad. Nevertheless, copper not only endangers aquatic life, but it also directly affects the economy by lowering the supply of salmon. Copper is toxic to most aquatic life and is especially harmful to the sensory systems of salmon. Copper impairs salmon's sense of smell, thus reducing their ability to escape from predators. Up to half of the copper found in waterways from urban areas are from copper brake pads and is a key factor in the reduction of salmon population. In 2010, Washington and California each passed laws to ban production of brake pads containing more than 0.5% copper which will be effective in 2025. Since then, several other states including New York, Rhode Island, and Oregon have all introduced similar bills to ban copper brake pads. The raw materials that were added to the newly developed copper free sample brake pads are geopolymers; they are synthetic mineral products that combine properties of polymers, ceramics and cements. Geopolymers have the characteristic of behaving as adhesive rubber in order to replace phenolic resin matrix in the brake materials also it can be harden at room temperature which can increase friction coefficient of the brake pad. Sample brake pads manufactured on site with known constituents were tested with friction assessment and screening test machine, which measured and recorded the friction coefficient and wear of the brake pad. According to the experience in the past, the sample brake pads will be analyzed with density test and Shore Durometer test. The results presented in this report shows that geopolymers brake pad shows promising results for copper replacement for low-metallic friction material. Developed copper free friction sample shows promising result of coefficient of friction of 0.44 with thickness loss of 0.62 mm from friction assessment and screening test machine compare to commercial brake pad.

Automotive

Brake Pad

Copper

OPTIMIZATION OF BRAKE PAD GEOMETRY TO PROMOTE GREATER CONVECTIVE COOLING TO INCREASE HEAT DISSIPATION RATE

Premkumar, Daryl

01 May 2018

Despite many research pieces on brake systems, there is still research to be done on brake pad geometry and the dissipation of heat during brake engagements using the finite element analysis method. Brake application is a process in which the kinetic energy of the vehicle is mostly converted into thermal energy and then dissipated in the form of heat. Based on dynamometer test results it was seen that brake pad temperatures could reach up to 600° C [23]. Preliminary research using computer modeling software has shown that heat dissipation in brake pads with wavy geometries and air channels from the top to bottom is much better compared to pads that do not have those specific features. Brake pads that dissipate heat faster are prone to brake fade and other braking issues that may arise due to overheating [15]. For this research, two readily available brake pads and two designs of brake pads with new geometry were modeled using CAE software. Finite element analysis was then performed to test how well each brake pad dissipated heat after reaching brake fade temperatures. The readily available brake pads were from Power Stop and Wagner [26]. ANSYS Space Claim [25] was used to design and model the brake pads, ANSYS 18.2 [24] was used to perform the finite element analysis on the pads. After performing the analysis, results indicate that a brake pad with a design that had zones for turbulent air at ambient conditions and convection slots from the top to the bottom decreased in temperature by about 90° C more in the same time compared to the conventional design. By studying the changing values of the convection heat transfer coefficient with velocity, the placing of the turbulence zones can be more precise in order attain greater airflow to remove heat from the brake pad quicker.

Brake Pad FEA

Finite Element Analysis

Estudo da influência do cobre no desempenho tribológico de pastilhas de freio automotivo

Barros, Liu Yesukai de

January 2018

Estudos recentes mostram que o cobre oriundo do desgaste de materiais de fricção de freio automotivo é a principal fonte do depósito deste metal em rios e lagos, afetando negativamente o meio ambiente. Consequentemente, novas legislações de agências governamentais internacionais têm imposto uma redução drástica da utilização do cobre em materiais de fricção nos próximos anos, sendo esta uma tendência a ser seguida por governos de todo o mundo. Embora o cobre seja largamente utilizado em materiais de fricção, a compreensão dos mecanismos de ação deste metal para esta aplicação ainda é bastante limitada. Este trabalho tem como intuito contribuir para uma melhor compreensão do papel do cobre em pastilhas de freio automotivo no que diz respeito ao coeficiente de atrito e ao desgaste. Ensaios de frenagens foram realizados no tribômetro do Laboratório de Tribologia da UFRGS, onde três tipos de pastilhas de freio (contendo 0%, 10% e 30% de cobre cada) foram testadas em diferentes temperaturas (100 ºC, 200 ºC e 300 ºC). Foram aplicados métodos para avaliar o coeficiente de atrito, desgaste de pastilha, desgaste de disco, parâmetros morfológicos de platôs de contato e depósito de filme no disco O material sem cobre em sua composição apresentou valores de coeficiente de atrito maiores do que os materiais com cobre para os três patamares de temperatura. O material com 10% de cobre apresentou maior sensibilidade do atrito em função da velocidade de deslizamento do que os outros dois materiais. Correlação inversa forte foi observada entre desgaste de pastilha e desgaste de disco. A quantidade de platôs de contato foi o parâmetro morfológico que mais se correlacionou com o coeficiente de atrito em diferentes temperaturas. Em alguns ensaios foi observada uma variação abrupta do coeficiente de atrito em determinadas frenagens dos materiais sem cobre e com 10% de cobre. Juntamente com esta variação, foi constatada uma perturbação do filme depositado sobre o disco, onde este é removido quando ocorre o aumento repentino do atrito. Entretanto, este fenômeno ocorreu apenas para a temperatura de 100 ºC, indicando que esta variação de atrito e perturbação do filme ocorre apenas em baixas temperaturas, e independente do percentual de cobre. / Previous studies have shown that the copper originated from the wear of automotive brake friction materials is the main source of the deposit of this metal in rivers and lakes, leading to environmental impacts. As a result, recent legislations from international governmental agencies have forced a drastic reduction of the copper used in friction materials in next years, which is likely to be followed by other governments in the world. Although the copper is widely used in friction materials, the understanding of the action mechanisms of this metal in friction materials is quite limited. This work aims to contribute to a better understanding of the role of copper in automotive brake pads in terms of friction and wear. Tests were carried out in the tribometer of the Laboratory of Tribology of UFRGS, where three kinds of brake pads (with 0%, 10% and 30% of copper each) were subjected to different temperatures (100 ºC, 200 ºC e 300 ºC). Methodologies to evaluate friction, wear of brake pads, wear of discs, morphological parameters of contact plateaus and deposit of film on disc surface were used. The sample without copper presented higher friction than the samples with copper for the three temperature levels. The material with 10% of copper presented higher friction sensibility due the sliding speed than other samples. Strong inverse correlation between wear of brake pads and wear of discs was observed. Quantity of contact plateaus was the parameter that presented the higher correlation with the friction in different temperatures. An abrupted variation of friction was observed in some experiments for samples without copper and with 10% of copper. At the same time, it was observed a disturbance of the film deposited on the disc surface, where the film was removed when the sudden increase of the friction occurs. However, this phenomenon occurred only at 100 °C, indicating that the variation of friction and the disturbance of film occurs only at low temperatures, and seems to be regardless of percentage of copper.

Freios

Cobre

Tribologia

Atrito

Automotive brake pad

Copper

Legislation

Friction

Wear

Towards elimination of airborne particles from rail traffic

Abbasi, Saeed

January 2013

Since the investigation of wear particles from rail transport started in the late 1910s, the high mass concentrations of these particles have prompted concern among researchers interested in air quality. However, effective action has yet to be taken because relevant knowledge is still missing. This thesis provides knowledge of airborne wear particles originating from rail transport. Some aspects of their characteristic parameters, such as size, mass concentration, number concentration, and morphology, were investigated in the field and in laboratory tests. We also discuss means to mitigate non-exhaust emissions, as well as the advantages and disadvantages of various test set-ups in the seven appended journal papers:Paper A reviews recent studies of exhaust and non-exhaust emissions from rail vehicles. The results, measurements, adverse health effects, and proposed or applied solutions presented in this literature are summarized in this paper.Paper B summarizes the results of field tests we conducted. The effects of curve negotiation and braking under different real conditions were investigated in a field test in which on-board measurements were made. The elemental composition and morphology of the particles emitted and their potential sources were also investigated.Paper C describes how a pin-on-disc machine can be used to reproduce real operating conditions during mechanical train braking in a controlled laboratory setting. The results were validated by comparing the field test results with the results of laboratory studies.Paper D presents comprehensive results of laboratory studies of airborne particles from different braking materials. A new index is introduced in this paper, which can be used as a quantitative metric for assessing airborne wear particle emission rates.Paper E describes the effects of using various friction modifiers and lubricants on the characteristics of airborne particles from wheel–rail contact under lubricated and unlubricated conditions.Paper F reports work to simulate thermoelastic instability in the cast-iron braking material. We simulated the fluctuation of the flash temperature by considering the temperature dependency of the material properties and the transformation of the contact state due to thermomechanical phenomena and wear.Paper G reviews new full- and sub-scale measurements of non-exhaust emissions from ground transport. The advantages and disadvantages of on-board measurements, pin-on-disc tests, dynamometer tests, and test rig studies are discussed in this paper. / <p>QC 20131025</p>

Airborne

brake block

brake pad

railway

subway

TEI

wheel–rail

wear

CHARACTERIZATION AND TRIBOLOGICAL PERFORMANCE OF AUTOMOTIVE BRAKE PADS WITH DIFFERENT RAW MATERIALS

Mohamed Iqbal, Amir Asyraf

01 May 2017

Over the years, numerous studies have been conducted for the development of alternative materials for better performance of brake pads. With a huge selection of materials, automobile manufacturers must prioritize the performance standards, safety, cost and environmental factors of the brake pads. To improve the friction performance of brake pads, maintain customers comfort level and environment safety, design engineers test and verify the best materials to satisfy the federal performance standards. Raw materials of brake pads compose of different categories such as organic, semi metallic and low-metallic. Besides the difference in composition, these materials affect the brake pads in terms of friction properties, wear rates and noise levels. It is crucial for engineers and manufacturers to improve friction stability while minimizing vibration by manipulating the composition of different raw materials and additive materials. Automotive brake pads normally consist of numerous metallic and composite materials that are formed by hot compression which can result in various mechanical properties [14]. This research proposes to investigate different composition of metallic raw materials and how their frictional performance is affected under different environmental testing standards. This research investigates the frictional performance of six types of raw materials with different mechanical properties and morphology using a universal mechanical tester (Bruker UMT). This paper examines the overall friction performance, coefficient of friction and creep groan behavior of six different raw materials under different humidity levels. By scrutinizing the static and kinetic coefficient of friction(COF) at different humidity levels, humidity-induced friction instability at low speed is studied and presented in this paper. After performing friction tests for each material, it was concluded that the friction performance and kinetic coefficient of friction of the brake pad samples were drastically affected by longer exposure to humid air.

Brake Pad Materials

Coefficient of Friction

Creep Groan

Friction Performance

Humidity

Tribology

Estudo da influência do cobre no desempenho tribológico de pastilhas de freio automotivo

Barros, Liu Yesukai de

January 2018

Estudos recentes mostram que o cobre oriundo do desgaste de materiais de fricção de freio automotivo é a principal fonte do depósito deste metal em rios e lagos, afetando negativamente o meio ambiente. Consequentemente, novas legislações de agências governamentais internacionais têm imposto uma redução drástica da utilização do cobre em materiais de fricção nos próximos anos, sendo esta uma tendência a ser seguida por governos de todo o mundo. Embora o cobre seja largamente utilizado em materiais de fricção, a compreensão dos mecanismos de ação deste metal para esta aplicação ainda é bastante limitada. Este trabalho tem como intuito contribuir para uma melhor compreensão do papel do cobre em pastilhas de freio automotivo no que diz respeito ao coeficiente de atrito e ao desgaste. Ensaios de frenagens foram realizados no tribômetro do Laboratório de Tribologia da UFRGS, onde três tipos de pastilhas de freio (contendo 0%, 10% e 30% de cobre cada) foram testadas em diferentes temperaturas (100 ºC, 200 ºC e 300 ºC). Foram aplicados métodos para avaliar o coeficiente de atrito, desgaste de pastilha, desgaste de disco, parâmetros morfológicos de platôs de contato e depósito de filme no disco O material sem cobre em sua composição apresentou valores de coeficiente de atrito maiores do que os materiais com cobre para os três patamares de temperatura. O material com 10% de cobre apresentou maior sensibilidade do atrito em função da velocidade de deslizamento do que os outros dois materiais. Correlação inversa forte foi observada entre desgaste de pastilha e desgaste de disco. A quantidade de platôs de contato foi o parâmetro morfológico que mais se correlacionou com o coeficiente de atrito em diferentes temperaturas. Em alguns ensaios foi observada uma variação abrupta do coeficiente de atrito em determinadas frenagens dos materiais sem cobre e com 10% de cobre. Juntamente com esta variação, foi constatada uma perturbação do filme depositado sobre o disco, onde este é removido quando ocorre o aumento repentino do atrito. Entretanto, este fenômeno ocorreu apenas para a temperatura de 100 ºC, indicando que esta variação de atrito e perturbação do filme ocorre apenas em baixas temperaturas, e independente do percentual de cobre. / Previous studies have shown that the copper originated from the wear of automotive brake friction materials is the main source of the deposit of this metal in rivers and lakes, leading to environmental impacts. As a result, recent legislations from international governmental agencies have forced a drastic reduction of the copper used in friction materials in next years, which is likely to be followed by other governments in the world. Although the copper is widely used in friction materials, the understanding of the action mechanisms of this metal in friction materials is quite limited. This work aims to contribute to a better understanding of the role of copper in automotive brake pads in terms of friction and wear. Tests were carried out in the tribometer of the Laboratory of Tribology of UFRGS, where three kinds of brake pads (with 0%, 10% and 30% of copper each) were subjected to different temperatures (100 ºC, 200 ºC e 300 ºC). Methodologies to evaluate friction, wear of brake pads, wear of discs, morphological parameters of contact plateaus and deposit of film on disc surface were used. The sample without copper presented higher friction than the samples with copper for the three temperature levels. The material with 10% of copper presented higher friction sensibility due the sliding speed than other samples. Strong inverse correlation between wear of brake pads and wear of discs was observed. Quantity of contact plateaus was the parameter that presented the higher correlation with the friction in different temperatures. An abrupted variation of friction was observed in some experiments for samples without copper and with 10% of copper. At the same time, it was observed a disturbance of the film deposited on the disc surface, where the film was removed when the sudden increase of the friction occurs. However, this phenomenon occurred only at 100 °C, indicating that the variation of friction and the disturbance of film occurs only at low temperatures, and seems to be regardless of percentage of copper.

Freios

Cobre

Tribologia

Atrito

Automotive brake pad

Copper

Legislation

Friction

Wear

Estudo da influência do cobre no desempenho tribológico de pastilhas de freio automotivo

Barros, Liu Yesukai de

January 2018

Estudos recentes mostram que o cobre oriundo do desgaste de materiais de fricção de freio automotivo é a principal fonte do depósito deste metal em rios e lagos, afetando negativamente o meio ambiente. Consequentemente, novas legislações de agências governamentais internacionais têm imposto uma redução drástica da utilização do cobre em materiais de fricção nos próximos anos, sendo esta uma tendência a ser seguida por governos de todo o mundo. Embora o cobre seja largamente utilizado em materiais de fricção, a compreensão dos mecanismos de ação deste metal para esta aplicação ainda é bastante limitada. Este trabalho tem como intuito contribuir para uma melhor compreensão do papel do cobre em pastilhas de freio automotivo no que diz respeito ao coeficiente de atrito e ao desgaste. Ensaios de frenagens foram realizados no tribômetro do Laboratório de Tribologia da UFRGS, onde três tipos de pastilhas de freio (contendo 0%, 10% e 30% de cobre cada) foram testadas em diferentes temperaturas (100 ºC, 200 ºC e 300 ºC). Foram aplicados métodos para avaliar o coeficiente de atrito, desgaste de pastilha, desgaste de disco, parâmetros morfológicos de platôs de contato e depósito de filme no disco O material sem cobre em sua composição apresentou valores de coeficiente de atrito maiores do que os materiais com cobre para os três patamares de temperatura. O material com 10% de cobre apresentou maior sensibilidade do atrito em função da velocidade de deslizamento do que os outros dois materiais. Correlação inversa forte foi observada entre desgaste de pastilha e desgaste de disco. A quantidade de platôs de contato foi o parâmetro morfológico que mais se correlacionou com o coeficiente de atrito em diferentes temperaturas. Em alguns ensaios foi observada uma variação abrupta do coeficiente de atrito em determinadas frenagens dos materiais sem cobre e com 10% de cobre. Juntamente com esta variação, foi constatada uma perturbação do filme depositado sobre o disco, onde este é removido quando ocorre o aumento repentino do atrito. Entretanto, este fenômeno ocorreu apenas para a temperatura de 100 ºC, indicando que esta variação de atrito e perturbação do filme ocorre apenas em baixas temperaturas, e independente do percentual de cobre. / Previous studies have shown that the copper originated from the wear of automotive brake friction materials is the main source of the deposit of this metal in rivers and lakes, leading to environmental impacts. As a result, recent legislations from international governmental agencies have forced a drastic reduction of the copper used in friction materials in next years, which is likely to be followed by other governments in the world. Although the copper is widely used in friction materials, the understanding of the action mechanisms of this metal in friction materials is quite limited. This work aims to contribute to a better understanding of the role of copper in automotive brake pads in terms of friction and wear. Tests were carried out in the tribometer of the Laboratory of Tribology of UFRGS, where three kinds of brake pads (with 0%, 10% and 30% of copper each) were subjected to different temperatures (100 ºC, 200 ºC e 300 ºC). Methodologies to evaluate friction, wear of brake pads, wear of discs, morphological parameters of contact plateaus and deposit of film on disc surface were used. The sample without copper presented higher friction than the samples with copper for the three temperature levels. The material with 10% of copper presented higher friction sensibility due the sliding speed than other samples. Strong inverse correlation between wear of brake pads and wear of discs was observed. Quantity of contact plateaus was the parameter that presented the higher correlation with the friction in different temperatures. An abrupted variation of friction was observed in some experiments for samples without copper and with 10% of copper. At the same time, it was observed a disturbance of the film deposited on the disc surface, where the film was removed when the sudden increase of the friction occurs. However, this phenomenon occurred only at 100 °C, indicating that the variation of friction and the disturbance of film occurs only at low temperatures, and seems to be regardless of percentage of copper.

Freios

Cobre

Tribologia

Atrito

Automotive brake pad

Copper

Legislation

Friction

Wear

Environmentally acceptable friction composites

Newby, William Robert

January 2014

Currently, the production of most non-asbestos organic (NAO) friction materials depends on a long and energy intensive manufacturing process and an unsustainable supply of synthetic resins and fibres; it is both expensive and bad for the environment. In this research, a new, more energy efficient, manufacturing process was developed which makes use of a naturally derived resin and natural plant fibres. The new process is known as 'cold moulding' and is fundamentally different from the conventional method. It was used to develop a new brake pad for use in low temperature (<400 °C) applications, such as rapid urban rail transit (RURT) trains. A commercially available resin based upon cashew nut shell liquid (CNSL) was analysed and found to have properties suitable for cold moulding. In addition, hemp fibre was identified as a suitable composite reinforcement. This was processed to improve its morphology and blended with aramid to improve its thermal stability. Each stage of cold mould manufacture was thoroughly investigated and the critical process parameters were identified. The entire procedure was successfully scaled up to produce an industrially sized 250 kg batch of material and the resultant composites were found to have appropriate thermal and mechanical properties for use in a rail brake pad. The tribological performance of these composites was iteratively developed through a rigorous testing and evaluation procedure. This was performed on both sub- and full-scale dynamometers. By adding various abrasives, lubricants, and fillers to the formulation it was possible to produce a brake pad with similar friction characteristics to the current market material, but with a 60% lower wear rate. In addition, this brake pad caused 15% less wear to the brake disc. A detailed examination of both halves of the friction couple found that cold moulded composites exhibit a different wear mechanism from the current market material, which was suggested to be the reason for their superior properties. Cold moulding is 3.5x faster and uses 400% less energy than the conventional method.

621.8