Sealed Mixture Research Articles

Performance Evaluation of Colored Slurry Seal Mixture with Steel Slag as a Substituent of Natural Aggregates

Performance Evaluation of Colored Slurry Seal Mixture with Steel Slag as a Substituent of Natural Aggregates

The study of the feasibility and manufacture of slurry seal surface treatment with steel slag industry wastes: use of basic oxygen furnace (BOF) slag filler as raw material replacement

Slurry seal is a preventive maintenance method to preserve pavement. This research is focused on the effect of steel slag filler (SSF) as a natural filler (NF) substitute on the behaviour of slurry seal mixtures. Five different combinations containing 100% NF, 25% SSF + 75% NF, 50% SSF + 50% NF, 75% SSF + 25% NF, and 100% SSF based on the total filler weight were used. The samples were evaluated by the wet cohesion, wet track abrasion, loaded wheel-displacement, and loaded wheel-sand adhesion tests. For investigating the SSF impact on the performance characteristics of mixtures, an analysis of variance (ANOVA) was performed. The results indicated that mixtures with 75% SSF increase the bitumen cohesion by 45%, decrease the displacement by 50.8%, improve the abrasion resistance by 48.3%, and reduce the bleeding by 29.3%. ANOVA results showed that SSF has the greatest effect on increasing the adhesion and reducing the displacement in slurry seal.

Evaluation of chip seal mixture design methods using modified Hamburg wheel tracking test and sweep test

The objective of this study was to identify the most effective chip seal design method and chip sizes by conducting a modified Hamburg wheel tracking test and sweep test. Three chip seal design methods, including Austroads, McLeod, and Vietnam methods, were evaluated to design several chip seal mixtures with varying aggregate sizes (e.g., 12.5, 9.5, 4.75, and 2.36 mm) and binder types. To assess the performance of the chip seal mixtures, aggregate loss and bleeding susceptibility were measured. The sweep test was utilized to determine the amount of aggregate loss caused by the sweeping effect, while the modified Hamburg wheel tracking (HWT) test was developed to estimate the aggregate loss caused by the braking effect using a fixed pneumatic rubber tire. Additionally, a modified Hamburg wheel tracking test with a rolling pneumatic rubber tire was used to assess bleeding susceptibility, and the bleeding area was quantified using an image analysis process. The results indicated that the Austroads design method exhibited the lowest aggregate loss compared to the McLeod and Vietnam methods. Moreover, the consistent findings from both the sweep test and modified HWT test demonstrated the feasibility of using the modified HWT test to simulate aggregate loss caused by the braking effect. The bleeding percentage was found to be affected not only by the binder application rate but also by the aggregate size and the number of layers applied. The Austroads and McLeod chip seal mixtures exhibited an approximately 20 % lower bleeding percentage than that of the Vietnam mixtures. Finally, for a single chip seal, a 9.5 mm chip aggregate was determined to be the optimal size, while for a double chip seal, 4.75 mm and 2.36 mm chips were recommended.

Investigation of Shelf Life for Door Seal Mixture in Automotive Industry

The door seals for vehicles in automotive industry, which are one of the most important components, provide insulation and damping. Quality of the product highly depends on the shelf life of the seal compound under required temperature. The most important parameters of the compound are its viscosity and scorch values. The aim of this study is to determine the most suitable shelf life in manufacturing and storage processes for seal compound. For stating the important factors affecting shelf life of frequently used main two types of seal compound, interviews are made with the producing firm. Then for both types of compound, series of controlled experiments are performed, and linear estimation models are developed with the help of the results of these experiments. In this study, the results of generated multi variable regression models are presented. It is seen that the generated estimation models can be employed by the producers, and the results of the experiments are overlapping with the results of studies performed in the literature.

Recycled materials in railroad substructure: an energy perspective

Given that the current ballasted tracks in Australia may not be able to support faster and significantly heavier freight trains as planned for the future, the imminent need for innovative and sustainable ballasted tracks for transport infrastructure is crucial. Over the past two decades, a number of studies have been conducted by the researchers of Transport Research Centre (TRC) at the University of Technology Sydney (UTS) to investigate the ability of recycled rubber mats, as well as waste tyre cells and granulated rubber to improve the stability of track substructure including ballast and subballast layers. This paper reviews four applications of these novel methods, including using recycled rubber products such as CWRC mixtures (i.e., mixtures of coal wash (CW) and rubber crumbs (RC)) and SEAL mixtures (i.e., mixtures of steel furnace slag, CW and RC) to replace subballast/capping materials, tyre cells reinforcements for subballast/capping layer and under ballast mats; and investigates the energy dissipation capacity for each application based on small-scale cyclic triaxial tests and large-scale track model tests. It has been found that the inclusion of these rubber products increases the energy dissipation effect of the track, hence reducing the ballast degradation efficiently and increasing the track stability. Moreover, a rheological model is also proposed to investigate the effect of different rubber inclusions on their efficiency to reduce the transient motion of rail track under dynamic loading. The outcomes elucidated in this paper will lead to a better understanding of the performance of ballast tracks upgraded with resilient rubber products, while promoting environmentally sustainable and more affordable ballasted tracks for greater passenger comfort and increased safety.

Laboratory Investigation of the Composite of Slurry Seal Asphalt Reinforced by Hybrid Nanomaterials and Fiber

Abstract Slurry seals are a hard wearing surface for pavement preservation. The main purpose of this study is to investigate the effects of nanomaterials and styrene butadiene rubber (SBR) latex on fatigue and rutting performance, wet cohesion properties, abrasive performance, and raveling resistance of the fiber-reinforced slurry seal. Firstly, the optimal slurry seal composition was determined under the effect of SBR polymer and synergistic nanomaterials. Results showed that simultaneous addition of nanolime and nanoclay significantly improves the fatigue life and rutting resistance of slurry seal mixtures. In addition, the simultaneous addition of nanomaterials reduces the amount of abrasion by about 63 % and significantly enhances the resistance of a slurry seal mixture. Moreover, the combination of nanomaterials, in particular, nanoclay, with 4 % modified asphalt binder, increases the raveling resistance and ultimately improves the friction resistance of the slurry seal. Finally, after comparing the performance of different mixtures, the slurry seal modified with polyester fiber with 8 % asphalt binder emulsion containing 6 % latex, 3 % nanoclay, and 3 % nanolime was determined as the optimum mixture. The analysis of variance showed that the nanomaterials have a significant effect on the fatigue and rutting properties, adhesion and cohesion resistance and abrasion performance of slurry seal at the confidence level of 95 %.

Mix design and performance evaluation of coloured slurry seal mixture containing natural iron oxide red pigments

The use of durable coloured surface treatment can be one of the best cost reduction strategies for road maintenance. The purpose of this study was to investigate the feasibility of applying natural iron oxide red pigments in a slurry seal mix design in order to change the colour of this type of asphalt and evaluate its performance. In this regard, first, the physical and chemical properties of the rock and pigment materials were evaluated. Then, 4 different mixtures containing 0, 3, 6, and 9% pigment as filler replacement by dry weight of total aggregate with three different levels of bitumen emulsion were used. The design results indicated that the mixture containing 9% of the pigment had the best performance among the mixtures. According to the results, red iron oxide pigment would improve adhesion of bitumen emulsion to rock aggregate, abrasion resistance, and also vertical deformation.

Composition Optimization and Field Application of Colored Emulsified Asphalt Seal Mixture

A uniform test design method was used to investigate the storage stability, wear resistance performance, anti-slide performance, and color durability of a colored emulsified asphalt seal mixture (CEASM). The optimal mix proportions of the seal mixture were determined, and the engineering test application and effect evaluation analysis were performed. The results show that the clay, silica fume, pigment, mineral aggregate, and emulsified asphalt contents in the prepared mixture ranged from 15–17%, 12–16%, 10–14%, 28–32%, and 25–32%, respectively. In practical engineering applications, CEASM with a molding thickness of 2–3 mm stored in liquid form has a good storage stability and wear resistance, which is suitable for manual scraping pavement or mechanical spraying construction. In addition, it has been shown that colored pavement has the advantages of low cost, safety, environmental protection, convenient construction, good durability, and rapid molding. The CEASM also has great application prospects in color repaving for non-color roads, the early maintenance of colored pavement, and road disease maintenance. The results guide colored pavement designs to improve the storage stability of CEASM and enhance the color durability and crack resistance of colored pavements.

Microstructure characterisation and performance investigation of a rapid hardening emulsified asphalt seal mixture

In terms of longer hardening time of emulsified asphalt seal mixture, a rapid hardening seal mixture was prepared by adding cement and carbon fibre to the Styrene–Butadiene-Rubber (SBR)-modified emulsified asphalt. The mix proportion of mixture was determined by testing the mixable time, consistency, wet track abrasion value, adhered sand content, cohesion force and the cracking rate. The microscopic mechanisms of rapid hardening and cracking control were studied using the Scanning Electron Microscopy (SEM) and the Fourier Transform Infrared Spectroscopy (FTIR). It is found that the optimum contents of SBR-modified emulsified asphalt, added water, cement and carbon fibre in the prepared mixture are 12%, 13%, 4% and 4%, respectively. At 20°C, with a relative humidity of 90% and a wind speed of 10 km/h, the opening time to traffic of mixture adding 4% ordinary Portland cement can be 2 h earlier than that without cement.

Performance Evaluation of Slurry Seals Containing Reclaimed Asphalt Pavement

Preventive pavement maintenance methods such as slurry seals are cost-effective treatments that increase the longevity of pavements. The incorporation of recycled materials such as reclaimed asphalt pavement (RAP) into asphalt pavement helps to further reduce costs and energy consumption. The present research studied the feasibility of incorporating RAP into slurry seal mixtures or RAP slurry seals. Two slurry seal mixtures containing cement and hydrated lime as fillers were tested. The first mixture comprised slurry seal made with virgin aggregate and the second used RAP as the aggregate. The wet track abrasion test (WTAT) and loaded wheel test (LWT) were conducted to evaluate the performance of the mixtures. Wet cohesion and friction tests (sand patch and British pendulum) were performed on the selected slurry seal mixtures with the best performance under WTAT and LWT. The results show that it is possible to prepare slurry seal containing RAP. Although the curing time relative to the virgin aggregates increased by 1 h for RAP aggregate, the wear value in the WTAT decreased by half. Lateral displacement and the British pendulum test results improved considerably for slurry seals made with RAP aggregates. The results of the sand patch test on WTAT samples showed that slurry seals made with RAP should be lightly rolled after lay-down to improve their friction life. Cost analysis indicates that the use of RAP as an aggregate in slurry seal decreased costs by up to 14%. RAP slurry seal showed better overall performance with lower cost than the virgin slurry seal.

Assessing The Durability of Polymer Modified Asphalt Emulsions Slurry Seal

Slurry Seal is an application of road preservation in the form of impermeable nonstructural thin layer with maximum thickness of 10 mm, which consisting of a cold laid mixture of asphalt emulsion with continuous graded fine aggregate, mineral filler, water and other added ingredients. Road preservation use slurry seal only functioning as a surface layer on the existing pavement structure. This preliminary research was conducted to determine the value of consistency, setting time, and indirect tensile strength of polymer modified slurry seal. The laboratory tests were conducted to determine the optimum residual asphalt content. The results show that the value of the optimum water content by pre-wetting 5% is getting smaller with increasing levels of residual asphalt emulsion. The addition of water 0 – 2.5% with 5% water for pre-wetting, the mixture provides a sufficient consistency in accordance with the specifications. The increasing levels of residual asphalt emulsion obtained the longer setting time at all slurry seal mixtures, but all of the mixtures still meet the specifications. The use of polymer modified asphalt emulsion on slurry seal was improved durability significantly, based on the value of indirect tensile strength.

Addressing Raveling Resistance in Chip Seal Specifications

Chip seals are applied to existing roadways to slow deterioration and improve pavement surface conditions without increasing the pavement’s structural capacity. The raveling of chip seals can cause damage to vehicles and thus is a safety concern. Raveling resistance is related to both material application rates and material properties. The current chip seal specifications fail to adequately address the material-related aspects of raveling resistance. This study seeks to develop recommendations to address raveling resistance in future chip seal specifications. Strain sweep binder tests, binder bond strength (BBS) tests, and Vialit chip seal mixture tests were conducted to assess early raveling, late raveling, and wet raveling at two intermediate temperatures. The results demonstrate that the bond that develops between the residual binder and the aggregate is highly dependent on the interaction between the emulsion and the aggregate during curing. The importance of emulsion–aggregate compatibility in raveling resistance indicates that raveling resistance cannot be addressed in binder specifications alone. Rather, it is recommended that intermediate temperature raveling resistance should be addressed during chip seal mixture design. Vialit and BBS tests, in which emulsion is cured on rock, can both be used to effectively quantify the aggregate loss potential of a chip seal. These two tests are able to capture the benefits of polymer modification and produce results that correlate. However, the Vialit tests are easier to implement than the BBS tests and require no expensive equipment. Therefore, Vialit tests are recommended to address early, late, and wet raveling resistance in future chip seal specifications.

Utilizing High Density Polyethylene (HDPE) Synthetic Aggregate as a Chip Sealing Material in Improving Skid Resistance

There are four main factors causing traffic accident : human factor, vehicle factor, road factor and environment factor. Accident data from Poltabes Yogyakarata in 2007 showed that road factor causes accident is 2.45%. In effort to achieve traffic safety, the infrastructure must be considered in the first list. This research is dealing with “Utilizing High Density Polyethylene (HDPE) Synthetic Aggregate as a Chip Sealing Material in Improving Skid Resistance”. The purpose of this research is to understand the effect of chip sealing using HDPE synthetic aggregate on the skid resistance, so that the surface pavement can provide good service for traffic and road users and the quantity of accident can be reduced. In this research the skid resistance was measured using British Pendulum Tester such that the its skid resistance is also called British Pendulum Number (BPN). BPN is a measured based on 3 variations of aggregate weight being spreaded, that are 240 grams, 271 grams and 304 grams. The result of BPN will be correlated with the wet accident ratio, friction coefficient and stopping distance. The BPN values being obtained are 55.96, 55.6 and 53.4, respectively. The BPN was found to increase with the increase of aggregate weight in chip seal mixture. It was revealed that BPN with chip sealing using HDPE could be increased by approximately 10 % in comparison with that without chip sealing. In addition, chip sealing using HDPE can reduce the accident ratio by 47.32 %, improve the traffic safety by 47.32 %, and shorten the stopping distance. The greater friction coefficient the lower stopping distance, and the lower stopping distance the better traffic safety.

Solid State Electrochemical Sensors in Metal Processing

Measurement and control of impurity elements in the processing and refining of metals is critical in order to achieve optimum properties of the metals concerned. Solid electrolyte sensors for monitoring oxygen are well established and have made a major impact in the metal industry. This paper presents a review of developments in measuring elements other than oxygen with reference to real industrial trials and applications. Recently, a new sensor for the determination of dissolved hydrogen in molten aluminium has been developed and successfully validated in industry. This sensor relies on a proton conducting perovskite as the solid electrolyte and a sealed solid mixture of either titanium and hydrogen or zirconium and hydrogen as the reference electrode. Furthermore, a new sulphur sensor for molten iron has been advanced and tested. This sensor utilises strontium β-alumina as the solid electrolyte, which has been optimised for thermal shock resistance and toughness by the incorporation of partially stabilised zirconia. An auxiliary layer of strontium sulphide forming in situ during sensor operation serves as the sensing electrode, and a sealed mixture of molybdenum and molybdenum sulphide is used as the reference electrode. The aim of these developments is to optimise and automate process control in order to minimise the amount of out-of-specification products.

Improving slurry seal performance in Eastern Saudi Arabia using steel slag

Harsh climate, heavy traffic and, most importantly, use of low-quality aggregates have resulted in unsatisfactory slurry seal performance in the eastern region of Saudi Arabia. On the other hand, blast furnace steel slag, a superior aggregate type with excellent strength and surface properties, is being wasted as a by-product during the steel manufacturing process. This research was carried out to assess and improve the performance of slurry seal mixtures in the laboratory using the Aggregate Blend Improvement Technique by incorporating steel slag aggregate. Aggregate blends consisting of slag and limestone were evaluated to form an improved slurry seal mixture that will generate simultaneously greater wear-resistance and improved bonding characteristics with bitumen. Results indicate that significant improvements in mixtures are guaranteed through improved aggregate blending of slag with limestone.

Diverting Agents-History and Application

When porous zones or perforations in porous zones are opened for production, the stimulation fluids must be diverted if proper production, the stimulation fluids must be diverted if proper treating is to be assured. It seems that from the time the need for diverting agents was first recognized in the early 1930's, everything has been tried from soup to nuts. Introduction In 1932 the oil industry started using hydrochloric acid to stimulate oil wells. Immediately the problem arose of diverting the acid treatments into a desired zone, and over the years the diverting methods used have been dictated by the reservoirs being developed. In the period from 1932 to about 1945, the Permian Grayburg-San Andres carbonate reservoirs were primary drilling objectives in the Permian Basin. primary drilling objectives in the Permian Basin. These reservoirs were from 3,000 to 5,000 ft deep and were generally prolific. Stimulation treatments were usually small in volume (less than 2,000 gal) and the major concern was to avoid acidizing into bottom water. During the period from about 1946 to 1960, Permian reservoirs such as the Clearfork, Tubb, and Spraberry were exploited. These 4,000- to 8,000-ft-deep reservoirs were stimulated with large volumes of acid or fracturing fluids, or both. During the 1960's, deep gas fields (15,000 to 22,000 ft), principally Ellenburger, required new diverting principally Ellenburger, required new diverting materials to achieve effective stimulation at high reservoir temperatures and pressures. 1936 to 1946 The earliest documentation of a diverting agent was in 1936 when a patent was issued to Halliburton Oil Well Cementing Co. for the use of a soap solution that reacted with calcium chloride to form a precipitate. This was a water-insoluble, oil-soluble calcium soap that acted as a diverting material for the acid. One year later Halliburton was issued a patent for a diverting material that utilized locust bean gum to gel calcium chloride and sodium chloride for blanking off a zone and thus diverting acid into untreated intervals. Sulfuric acid was used as a diverting agent in connection with a conventional hydrochloric acid treatment. After the sulfuric acid was pumped into the wellbore, the pumps were shut down for a short time and then pumping of the hydrochloric acid was resumed. When in contact with the calcium carbonate, the sulfuric acid formed insoluble calcium sulfate, which was the diverting agent. This system was not widely accepted, owing, it is assumed, to the recognition that it could cause potentially permanent productivity damage. productivity damage. A major concern in the development of the Grayburg-San Andres carbonate reservoirs was that treatment could extend into the bottom water, particularly since the wells were open-hole completions. particularly since the wells were open-hole completions. Beginning in the late 1930's, various materials were designed to avoid this problem. Dowell developed "Blanket," which was a heavy calcium chloride solution that depended on its viscosity to divert the acid up the hole. Dowell later introduced "Jelly Seal" as the second-generation blocking material. This was a natural gum (locust bean gum) that when mixed with water formed a viscous, gelatinous fluid. When difficulty was encountered in obtaining a plug because of high porosity and permeability, "Jelflake," or cellophane, was mixed with the Jelly Seal to accomplish the shut-off. An internal breaker had to be used to lower the viscosity of Jelly Seal after treatment. For this purpose, a bacteria mixture was prepared by exposing a Jelly Seal mixture to air circulating in a warm room. JPT P. 593