Nativa, Sinop, v. 11, n. 2, p. 283-291, 2023.

Pesquisas Agrárias e Ambientais

DOI: https://doi.org/10.31413/nativa.v11i2.15566

ISSN: 2318-7670

Rheological investigation of asphalt binder modified with soybean oil sludge

Osires de Medeiros MELO NETO1* , Lara Pereira Tavares MENDES1,

Milena Cristina Rocha de SOUZA1, Albaniza Maria da Silva LOPES1,

Mateus Valdevino de SIQUEIRA1, Evando Lucio Candido da COSTA2, José Lucas da Silva CASTRO2,

Ben Hur Andrade de Medeiros NÓBREGA2

1Federal University of Campina Grande, Campina Grande, PB, Brazil.

2State University of Paraíba, Araruna, PB, Brazil.

*E-mail: osiresdemedeiros@gmail.com

Submitted on 05/18/2023; Accepted on 08/18/2023; Published on 08/22/2023.

ABSTRACT: The utilization of alternative materials to asphalt binder in pavement aims to diminish the

consumption of natural resources and energy, and in some cases, enhance pavement performance. This study

thus examined the effects on physical and rheological properties of asphalt binder with 50/70 penetration,

modified by soybean oil sludge at percentages of 1%, 3%, 5%, 7%, and 9% by binder weight. This modification

was aimed at reducing viscosity for application in recycled asphalt mixtures. The asphalt binder was assessed

through rotational viscosity tests, Performance Grade (PG), and Multiple Stress Creep Recovery in natura

sludge and post-drying process. Results indicated that adding sludge led to increased viscosity in the asphalt

binder. The modifier also couldn't lower the PG temperature of the pure binder. The modified binders

exhibited greater susceptibility to permanent deformation, except for adding in natura sludge at 9% content.

Consequently, soybean oil sludge didn't act as a viscosity-reducing material and thus didn't exhibit a rejuvenating

effect for use in recycled asphalt mixtures.

Keywords: recycled mixtures; rejuvenating agent; viscosity; waste.

Investigação reológica do ligante asfáltico modificado com a borra do óleo de soja

RESUMO: A utilização de materiais alternativos ao ligante asfáltico na pavimentação tem por finalidade reduzir

o consumo de recursos naturais, de energia e, em alguns casos, melhorar o desempenho do pavimento. Assim,

este trabalho investigou os efeitos nas propriedades físicas e reológicas do ligante asfáltico com penetração

50/70 modificado pela borra do óleo de soja nos teores de 1%, 3%, 5%, 7% e 9% por peso do ligante,

empregada como o objetivo de reduzir a viscosidade para o uso em misturas asfálticas recicladas. O ligante

asfáltico foi avaliado por meio de testes de viscosidade rotacional, performance grade (PG) e Multiple Stress Creep

Recovery, modificado com a borra in natura e após processo de secagem. Os resultados apontaram que a adição

da borra gerou um ganho de viscosidade ao ligante asfáltico. O modificador também não foi capaz de reduzir a

temperatura de PG do ligante puro. Os ligantes modificados se apresentaram mais suscetíveis à deformação

permanente, com exceção da adição da borra in natura no teor de 9%. Assim, a borra de óleo de soja não se

configurou como um material redutor de viscosidade, e com isso, não demonstrou um efeito rejuvenescedor

para uso em misturas asfálticas recicladas.

Palavras-chave: agente rejuvenescedor; misturas recicladas; viscosidade; resíduos.

1. INTRODUCTION

In Brazil, approximately 95% of paved roads rely on

asphalt coating. According to Zhang et al. (2018), the asphalt

mixture is the predominant material for road surface layers

globally. The key ingredient in producing this mixture is

asphalt binder, a viscoelastic binder derived from petroleum.

As Benachio et al. (2020) highlighted, road pavements

consume around 30% of natural resources and contribute to

25% of construction industry-generated solid waste. This

waste typically ends up in landfills.

Flexible pavements require maintenance, preservation,

and reconstruction over their lifespan. During

reconstruction, material from the asphalt surface layer is

termed Reclaimed Asphalt Pavement (RAP). RAP has

significant recycling potential, offering reduced

environmental impact and costs when used as aggregate,

leading to substantial reductions in Greenhouse Gas (GHG)

emissions and energy consumption related to the pavement

sector (AURANGZEB et al., 2014). Consequently, reusing

RAP is crucial for formulating new asphalt mixtures (SILVA

et al., 2012).

When incorporating RAP into asphalt mixtures at high

levels exceeding 30%, the use of Rejuvenating Agents (RA)

becomes necessary. These agents soften the rigid binder,

offsetting RAP's inherent stiffness. The utilization of

rejuvenating agents, termed bio-oils, sourced from organic

plant materials and plant oil residues, has garnered attention

among modern researchers. These modifiers have

demonstrated notable outcomes, particularly restoring

asphalt binder properties, including enhanced crack

resistance and reduced binder viscosity (SANTOS;

FAXINA, 2019).

Rheological investigation of asphalt binder modified with soybean oil sludge

Nativa, Sinop, v. 11, n. 2, p. 283-291, 2023.

284

These endeavors aim to introduce alternative materials to

asphalt binders, reducing natural resource consumption,

lowering energy usage, and, in some cases, improving

pavement performance (PORTUGAL, 2016). In this

context, Zargar et al. (2012) explored using residual cooking

oil to rejuvenate aged asphalt binder. The authors observed a

progressive decrease in complex shear modulus for the

analyzed samples (virgin, aged, and rejuvenated binder with

1%, 2%, 3%, 4%, and 5% modifiers) as temperature

increased from 30°C to 80°C. Additionally, the aged binder

displayed a lower phase angle than virgin asphalt binder,

increasing with the addition of residual cooking oil. The

rheological and chemical analysis led the authors to conclude

that residual cooking oil acts as a rejuvenator for aged

binders, offering an environmentally and economically viable

solution for waste reuse.

The literature features studies employing post-consumer

residual cooking oil as a rejuvenating agent (SUN et al., 2017;

LI et al., 2021; YAN et al., 2021). Melo Neto et al. (2022a)

explored the use of fatty acid from soybean oil sludge, the

residue after acidulation with hydrochloric acid. The authors

indicated a rejuvenating effect on aged asphalt binders,

although the production process requires appropriate

treatment for the generated acidic water.

This research, therefore, investigated the application of in

natura soybean oil sludge, without acidulation, as a viscosity-

reducing agent for asphalt binder. Addressing the gaps in

knowledge regarding the use of industrial soybean oil refining

process residues as rejuvenating agents, this study examined

the impact of adding in natura soybean oil sludge, both

before and after oven-drying, on the rheological behavior of

50/70 penetration-grade asphalt binder at 1%, 3%, 5%, 7%,

and 9% content levels by binder weight.

Recycling this residue, a byproduct of the neutralization

process in soybean oil production, as a modifying agent for

asphalt binder, benefits from its rich content of saponified

fatty acids, cost-effectiveness, and wide availability in

soybean oil and biodiesel industries, presenting itself as a

sustainable raw material choice for reducing asphalt binder

viscosity (SEIDEL; HADDOCK, 2014).

2. EXPERIMENTAL PROGRAM

The procedures implemented in this study adhered to the

guidelines outlined by the American Society for Testing and

Materials (ASTM) and the American Oil Chemists Society

(AOCS). Each test was conducted in triplicate, and the

average of the results for each test was provided.

2.1. Materials

The asphalt binder used in this study was supplied by

Cordilheira Company, located in Campina Grande - PB. This

binder was classified as a penetration grade of 50/70 with a

maximum performance grade (PG) temperature of 64°C,

representing the predominant binder type used in the

Northeast region of Brazil. All tests conducted for the

unmodified binder (AB) were also carried out on asphalt

binder samples modified with soybean oil sludge.

Various characterization tests were conducted, including

penetration, softening point, rotational viscosity, and

performance grade (PG) assessments. These tests were

performed on both virgin and aged binder samples through

the Rolling Thin-Film Oven (RTFO) short-term aging

process. Viscosity evaluations were executed using a

Brookfield viscometer, while rheological analyses were

carried out using a Dynamic Shear Rheometer (DSR) from

the Discovery Hybrid Rheometer (DHR-1) series. The

asphalt binder characterization outcomes are summarized in

Table 1.

Table 1. Binder characterization.

Tabela 1. Caracterização do ligante.

Tests

Conducted Results (AB)

Standards

Utilized

Penetration 0.1

mm (100g, 5s at

25ºC)

58.00

ASTM D5/D5M

(2020)

Softening Point

(ºC) 52.00

ASTM D36/D36M

– 14 (2020)

Rotational

Viscosity (cP)

135ºC

–

401.00

150ºC – 198.00

177ºC – 72.75

ASTM

D4402/D4402M

(2015)

Maximum PG

Temperature (°C) 64.00

ASTM D6373

(2021)

RTFO (Rolling Thin-Film Oven)

ASTM D2872

(2019)

Rotational

Viscosity (cP)

135ºC

–

557.50

150ºC – 269.00

177ºC – 94.00

ASTM

D4402/D4402M

(2015)

Maximum PG

Temperature (°C) 64.00

ASTM D6373

(2021)

Multiple Stress

Creep Recovery

(MSCR)

Jnr at 0.1 kPa

–

3.40

Jnr at 3.2 kPa – 5.30

% Recovery at 0.1

kPa – 5.03

% Recovery at 3.2

kPa – 0.37

ASTM D7405

(2020)

For the rejuvenating agent, soybean oil sludge from

IMCOPA company located in Paraná was employed. The

characteristic properties of this material were determined

using tests specified by the American Oil Chemists Society

(AOCS) and methodologies outlined by Da Fré (2009) and

Araújo (2016), as detailed in Table 2.

Table 2. Characterization of soybean oil sludge.

Tabela 2. Caracterização da borra de óleo de soja.

Tests

Conducted Results

Standards

Utilized

Free fatty acids in oleic

acid (%) 0.68 AOCS Ca 5a-40 (2017)

Total fatty acids

content (%) 41.59 AOCS G 3-53 (2017)

Oxidized fatty acids

content (%) 1.22 AOCS G 3-53 (2017)

Unsaponifiable matter

content (%) 0.87 AOCS Ca 6a-40 (2017)

Neutral oil content (%)

12.44

AOCS G5

40 (2017)

pH at 25°C

9.96

AOCS G

56 (2017)

Moisture and volatile

content (%) 41.85 AOCS Ca 2c-25 (2017)

Based on the data presented in Table 2, the total content

of fatty acids was determined to be 41.59%, which falls within

the range of 35% to 50%, as stipulated by Swern (1982).

Notably, the moisture content of the material exceeded 40%,

a feature that could impact the outcomes of binder

modification. The pH test conducted at 25°C indicated that

the material exhibits a basic or alkaline nature, as evidenced

by its pH value exceeding 7.

Melo Neto et al.

Nativa, Sinop, v. 11, n. 2, p. 283-291, 2023.

285

2.2. Methods

2.2.1. Drying of soybean oil sludge

As indicated in Table 2, the soybean oil sludge displayed

a notable moisture content of 41.85%, constituting nearly

half the total sludge added to the binder. This prompted the

consideration that the inclusion of 1% sludge into the binder

would effectively mean adding 0.58% actual sludge content,

with the remaining 0.42% accounting for the moisture

present in the sludge. In response, a drying protocol was

implemented, as outlined in Figure 1, facilitating the

examination of the behavior of the binder modified with

both in natura and dried sludge.

This protocol was executed at the Pavement Engineering

Laboratory (LEP) of the Federal University of Campina

Grande (UFCG) over a span of 72 hours (3 days). Initially,

two samples were weighed, positioned on aluminum foil, and

subjected to drying in an oven set at a temperature of 65°C.

After 17 hours, the samples underwent another weighing

process. This weighing procedure was repeated at 40, 43, 65,

68, and 72 hours. The protocol concluded after 72 hours of

drying, during which approximately 35% of the moisture

content was extracted from the soybean oil sludge samples.

Considering the boiling point of water at 100°C, exceeding

the temperature employed in the protocol, a more extended

duration would be necessary to eliminate moisture from the

soybean oil sludge entirely. As such, the practical

implementation of this material as a modifying agent for

asphalt binder within large-scale asphalt mixture production

is logistically unviable. The samples displayed the subsequent

masses during the various weighings (Table 3).

Figure 1. Soybean oil sludge drying process.

Figura 1. Processo de secagem da borra de óleo de soja.

2.2.2. Modification of asphalt binder

For the study, percentages of 1%, 3%, 5%, 7%, and 9%

of soybean oil sludge based on asphalt binder weight were

examined, falling within the modifier range established by He

et al. (2017). The FISATOM model 722D mechanical shaker

was employed for the mixing process (modifier + binder).

Initially, the binder was heated to 135°C for 90 minutes to

achieve fluidity. Following preheating, the material was

transferred to a Becker flask and positioned on the

mechanical shaker at a rotation speed of 600 rpm to ensure

thorough mixture homogeneity. As the temperature reached

140°C, the additives were added separately based on the pure

binder weight, and the rotation speed was increased to 1000

rpm for 30 minutes for the 1%, 3%, 5%, 7%, and 9%

contents. This technique was adopted based on studies by

Faxina (2006), Souza (2012), and Melo Neto (2022). Table 4

presents the descriptions of the samples and their respective

nomenclatures.

Table 3. Nomenclature of samples used in the research.

Tabela 3. Nomenclatura das amostras utilizadas na pesquisa.

Drying period Sample 1 (g) Sample 2 (g)

Without drying 288.76 288.18

17 hours

245.35

245.70

40 hours 214.11 216.19

43 hours 210.91 212.94

65 hours 194.33 196.79

68 hours

192.54

194.96

72 hours 190.59 193.03

Table 4. Nomenclature of samples used in the research.

Tabela 4. Nomenclatura das amostras utilizadas na pesquisa.

Samples

Nomenclatures

Penetration

grade 50/70 asphalt binder

AB + 1% in natura soybean oil

sludge

1% SS

AB + 3% in natura soybean oil sludge

3% SS

AB + 5% in natura soybean oil sludge

5% SS

AB + 7% in natura soybean oil sludge

7% SS

AB + 9% in natura soybean oil sludge

9% SS

AB + 1% dried soybean oil sludge

1% DSS

AB + 3% dried

soybean oil sludge

3% DSS

AB + 5% dried soybean oil sludge

5% DSS

AB + 7% dried soybean oil sludge

7% DSS

AB + 9% dried soybean oil sludge

9% DSS

2.2.3. Test procedures

The modified asphalt binders were characterized at the

Pavement Engineering Laboratory (LEP) of the Federal

University of Campina Grande (UFCG). The samples

underwent testing before and after the Rolling Thin Film

Oven (RTFO) aging procedure (ASTM D2872, 2019)

without any treatment and after the drying process.

Rotational viscosity analyses (ASTM D4402, 2015)

involved placing the samples within a controlled-temperature

container with a rotating rod set at a specified speed. The

force needed to overcome the resistance posed by the

binder's viscosity was determined based on the recorded

rotation during the test.

For the Performance Grade (PG) test (ASTM D6373,

2021), the parameter G*/senδ was examined. The initial

temperature was set at 46°C, with subsequent increments to

temperatures of 52°C, 58°C, and 64°C. The maximum test

temperature corresponded to the point of binder failure.

The Multiple Stress Creep Recovery (MSCR) test (ASTM

D7405, 2020) was conducted at the PG temperatures of the

asphalt binder. The goal was to compare pure binder samples

with modified binder samples. This test assesses that lower

Jnr values at 3.2 kPa indicate more viscous binders, while

higher values suggest more fluid materials.

Rheological investigation of asphalt binder modified with soybean oil sludge

Nativa, Sinop, v. 11, n. 2, p. 283-291, 2023.

286

3. RESULTS

This section presents the outcomes obtained from the

physical and rheological characterization of the asphalt

binders modified in natura soybean oil sludge and after the

drying procedure to eliminate moisture.

3.1. Rotational Viscosity

Table 5 displays the findings of the rotational viscosity

assessment for the pure binders (AB) and binders altered

with in natura soybean oil sludge (SS). The procedure

adhered to the ASTM D4402 (2015) standard and aimed to

ascertain the binder's viscosity and consistency.

Table 6 illustrates the viscosity outcomes for the pure

binders and binders that underwent modification with dried

soybean oil sludge (DSS).

Table 5. Results of the rotational viscosity test within natura sludge.

Tabela 5. Resultados do teste de viscosidade rotacional com borra

in natura.

Tests

Before

RTFO

Rotational Viscosity (cP)

ºC 135.00 150.00 177.00

AB 401.00 198.00 72.75

1%SS 397.50 194.00 71.25

3%SS 356.25 181.50 69.50

5%SS 354.30 182.50 680.00

7%SS 428.75 211.00 104.75

9%SS 446.25 182.50 72.25

Limits ≥274.00 ≥112.00

57.00 at

285.00

Tests

After

RTFO

Rotational Viscosity (cP)

ºC 135.00 150.00 177.00

AB 548.00 269.00 94.00

1%SS 553.75 264.50 91.75

3%SS 496.25 240.50 85.25

5%SS 563.75 268.50 98.25

7%SS 558.75 272.00 103.25

9%SS 593.75 286.50 99.50

Limits ≥55.00 NA NA

NA = Not Applicable. NA = Não Aplicável.

Table 6. Results of the rotational viscosity test with dried sludge.

Tabela 6. Resultados do teste de viscosidade rotacional com borra

seca.

Tests

Before

RTFO

Rotational Viscosity (cP)

ºC 135.00 150.00 177.00

AB 404.43 200.34 72.24

1%DSS 398.53 193.65 71.06

3%DSS 457.50 201.27 74.17

5%DSS 674.57 248.47 119.61

7%DSS 879.34 251.52 115.16

9%DSS 401.00 198.00 73.00

Limites ≥274.00 ≥112.00

57.00 at

285.00

Tests

After

RTFO

Rotational Viscosity (cP)

ºC 135.00 150.00 177.00

AB 535.00 257.00 89.50

1%DSS 518.48 249.24 88.82

3%DSS 584.55 278.74 98.32

5%DSS 705.53 326.60 114.25

7%DSS 974.50 418.78 155.42

9%DSS 548.00 269.00 94.00

Limites ≥55.00 NA NA

NA = Not Applicable. NA = Não Aplicável.

For both pre and post RTFO conditions, only the binder

containing 1% sludge exhibited viscosity values lower than

those of the pure asphalt binder. As the additive content

increased, viscosity also increased. These findings differ from

those obtained with the asphalt binder modified with

soybean oil sludge fatty acid. Melo Neto (2022) reported a

linear decrease in asphalt binder viscosity with increasing

fatty acid content.

3.2. Performance Grade (PG)

In the performance grade tests, the values corresponding

to the minimum PG temperatures were excluded due to the

negligible likelihood of negative temperatures in tropical

countries like Brazil. Figures 2 and 3 illustrate the variations

in the G*/Sinδ parameter values across temperatures ranging

from 46°C to 64°C. These figures pertain to the asphalt

binders modified with in natura and dried soybean oil sludge,

respectively, before and after the short-term aging process.

Figure 2. G*/Sinδ parameter versus temperature before and after

short-term aging RTFO for binders modified with in natura sludge.

Figura 2. Parâmetro G*/Senδ versus temperatura antes e após o

envelhecimento a curto prazo RTFO para os ligantes modificados

com a borra in natura.

Figure 3. G*/Sinδ parameter versus temperature before and after

short-term aging RTFO for binders modified with dried sludge.

Figura 3. Parâmetro G*/Senδ versus temperatura antes e após o

envelhecimento a curto prazo RTFO para os ligantes modificados

com a borra seca.

0.00

5.00

10.00

15.00

20.00

25.00

30.00

35.00

40.00

G*/Sinδ

46 ºC 52ºC 58ºC 64ºC

0.00

5.00

10.00

15.00

20.00

25.00

30.00

35.00

40.00

G*/Sinδ

46 ºC 52 ºC 58 ºC 64 ºC

Melo Neto et al.

Nativa, Sinop, v. 11, n. 2, p. 283-291, 2023.

287

From the information depicted in Figures 2 and 3, it is

evident that the G*/Sinδ parameter of the pure binders, both

pre and post RTFO, exceeded those attained with the

addition of soybean oil sludge under both considered

conditions and lower temperatures (46°C and 52°C). At the

temperature of 64°C, before the short-term aging process,

the asphalt binder modified with in natura sludge at contents

of 7% and 9% exhibited values surpassing those of the pure

binder. The latter recorded a value of 1.53, while the former

marked 1.87 and 1.88, respectively.

Regarding the binder amended with dried sludge, at the

temperature of 64°C, binders containing percentages

exceeding 3% displayed G*/Sinδ values surpassing the pure

binder before RTFO. Figures 4 and 5 provide a graphical

representation of the PG and continuous PG values for the

pure asphalt binders and those modified with in natura

soybean oil sludge, encompassing conditions before and after

the short-term aging RTFO procedure.

Figure 4. Performance Grade of pure asphalt binders and binders

modified with in natura soybean oil sludge before and after short-

term aging RTFO.

Figura 4. Grau de desempenho dos ligantes asfálticos puro e

modificados com a borra do óleo de soja in natura antes e após o

envelhecimento a curto prazo RTFO.

Figure 5. Continuous Performance Grade of pure asphalt binders

and binders modified with in natura soybean oil sludge before and

after short-term aging RTFO.

Figura 5. PG contínuo dos ligantes asfálticos puro e modificados

com a borra do óleo de soja in natura antes e após o envelhecimento

a curto prazo RTFO.

A discernible pattern emerges after thoroughly examining

the outcomes depicted in Figure 4. The asphalt binder,

subject to modification with 3% SS and 5% SS, exhibits a

notable reduction in PG temperature post-aging, resulting in

a shift from 64°C to 58°C. This shift signifies an increased

susceptibility to oxidative effects, which, in turn, contributes

to reduced deformability and enhanced rigidity at elevated

temperatures. The specimen treated with 7% SS showcases a

similar PG temperature shift following RTFO, marking a

decrease of one interval, corresponding to a 6°C range, and

descending from 70°C to 64°C. Conversely, the 9% SS

sample demonstrates a more pronounced reduction,

spanning two intervals and descending from 70°C to 58°C.

Figures 6 and 7 graphically depict the PG and continuous

PG values of the unmodified pure asphalt binders and those

that underwent modification by incorporating dried soybean

oil sludge. These graphical representations encompass

conditions before and after the short-term aging RTFO

procedure, providing a comprehensive visual overview of the

evolving performance of the binder.

Figure 6. Performance Grade of pure asphalt binders and binders

modified with dried soybean oil sludge before and after short-term

aging RTFO.

Figura 6. Grau de desempenho dos ligantes asfálticos puro e

modificados com a borra do óleo de soja seca antes e após o

envelhecimento a curto prazo RTFO.

Figure 7. Continuous Performance Grade of pure asphalt binders

and binders modified with dried soybean oil sludge before and after

short-term aging RTFO.

Figura 7. PG contínuo dos ligantes asfálticos puro e modificados

com a borra do óleo de soja seca antes e após o envelhecimento a

curto prazo RTFO.

Continuing the analysis concerning Figure 6, it becomes

evident that including dried soybean oil sludge leads to

consistent PG values when employing 1% DSS (64°C).

Nonetheless, upon the incorporation of 3% sludge, there is a

discernible reduction in PG temperature after the short-term

aging RTFO assessment. Notably, the sample treated with

5% DSS displays an intriguing pattern, indicating an elevation

in PG value pre-RTFO from 64°C to 70°C, encompassing a

AB 1%SS 3%SS 5%SS 7%SS 9%SS

Before RTFO 64.00 64.00 64.00 64.00 70.00 70.00

After RTFO 64.00 64.00 58.00 58.00 64.00 58.00

0.0

10.0

20.0

30.0

40.0

50.0

60.0

70.0

80.0

90.0

PG (ºC)

AB 1%SS 3%SS 5%SS 7%SS 9%SS

Before RTFO 67.00 66.00 64.00 64.00 70.00 71.70

After RTFO 65.00 65.00 63.00 63.00 64.40 63.70

0.00

10.00

20.00

30.00

40.00

50.00

60.00

70.00

80.00

90.00

Continuous PG (°C)

AB 1%DSS 3%DSS 5%DSS 7%DSS 9%DSS

Before RTFO 64.00 64.00 64.00 70.00 70.00 76.00

After RTFO 64.00 64.00 58.00 58.00 64.00 64.00

0.0

10.0

20.0

30.0

40.0

50.0

60.0

70.0

80.0

90.0

PG (°C)

AB 1%DSS 3%DSS 5%DSS 7%DSS 9%DSS

Before RTFO 67.00 66.60 69.10 70.80 74.00 77.00

After RTFO 65.00 65.00 61.40 63.70 67.70 66.20

0.00

10.00

20.00

30.00

40.00

50.00

60.00

70.00

80.00

90.00

Continuous PG (°C)

Rheological investigation of asphalt binder modified with soybean oil sludge

Nativa, Sinop, v. 11, n. 2, p. 283-291, 2023.

288

6°C range. In cases involving the application of natural

soybean oil sludge, an intriguing discrepancy at the 5%

threshold emerges: the pre-RTFO value is 64°C for the 5%SS

sample, whereas it registers at 70°C for the 5%DSS sample.

This discrepancy suggests a more notable increase in asphalt

binder stiffness with sludge utilization post the drying

procedure. These findings bolster the observations from the

rotational viscosity tests, reiterating that the drying process

insignificantly interferes with soybean oil sludge's efficacy as

a viscosity-reducing agent in asphalt binder.

Turning attention to the 7%DSS and 9%DSS samples,

there surfaces an elevated PG before RTFO. Following the

aging examination, both the 7%DSS and 9%DSS samples

manifest a reduction in continuous PG temperature,

recording reductions of 6.3°C and 10.8°C, respectively. This

comprehensive analysis intimates that introducing soybean

oil sludge yields negligible effects on the PG value when

juxtaposed against the unadulterated binder sample.

Table 7 shows the temperature deviations prior to and

post RTFO between PG and continuous PG values for the

specimens under scrutiny. Notably, the transition from PG

to continuous PG spans a spectrum of 0 to 5°C, findings that

parallel the investigation by Melo Neto et al. (2022b)

involving the analysis of the physical-rheological dynamics of

asphalt binders modified with refined cotton oil. Their study

echoes similar temperature variations, with the authors

emphasizing that the amplitude of 6°C in PG variation also

translates to the determination of lower performance grades

than the authentic ones.

Table 7. Variation of PG and Continuous PG temperatures in

asphalt binder samples.

Tabela 7. Variação das temperaturas de PG e PG contínuo nas

amostras dos ligantes asfálticos.

Samples Before RTFO After RTFO

AB (°C) 3.00 1.00

(%) 4.69 1.56

1%SS (°C) 2.00 1.00

(%) 3.13 1.56

3%SS (°C) 0.00 5.00

(%) 0.00 8.62

5%SS (°C) 0.00 5.00

(%) 0.00 8.62

7%SS (°C) 0.00 0.40

(%) 0.00 0.63

9%SS (°C) 1.70 5.70

(%) 2.43 9.83

Samples Before RTFO After RTFO

AB (°C) 3.00 1.00

(%) 4.69 1.56

1%DSS (°C) 2.60 1.00

(%) 4.06 1.56

3%DSS (°C) 5.10 3.40

(%) 7.97 5.86

5%DSS (°C) 0.80 5.70

(%) 1.14 9.83

7%DSS (°C) 4.00 3.70

(%) 5.71 5.78

9%DSS (°C) 1.00 2.20

(%) 1.32 3.44

As depicted in Table 7, a notable observation emerges,

underscoring the 7%SS sample for exhibiting the most

minimal variance in both PG and continuous PG values. This

finding designates it as the most indicative and faithful

representation within the analyzed set. Remarkably, the PG

classification value for this specific sample closely aligns with

its actual failure point, signifying its heightened accuracy and

reliability.

3.3. Multiple Stress Creep Recovery (MSCR)

The multiple stress creep and recovery test serves as a

valuable tool for assessing critical parameters such as

recovery percentage (%R), non-recoverable compliance (Jnr),

and the percentage difference between non-recoverable

compliances (Jnr, diff). These metrics provide insights into

elasticity, susceptibility to permanent deformation

accumulation, and sensitivity to increased stress levels. The

test facilitates the determination of suitable traffic levels for

the binder and its recovery behavior under the applied

stresses corresponding to the chosen levels. Notably, higher

Jnr values indicate a heightened susceptibility to permanent

deformations.

Figures 8 and 9 impeccably portray the test outcomes

conducted at the asphalt binder's maximum PG temperature

(64°C) and its elastic recovery concerning binders modified

with in-nature soybean oil sludge, respectively.

Figure 8. Non-recoverable compliances of pure and soybean oil

sludge-modified binders.

Figura 8. Compliâncias não recuperáveis dos ligantes puro e

modificados com a borra de óleo de soja in natura.

Figure 9. Elastic recovery at 0.1 kPa and 3.2 kPa for pure and

soybean oil sludge-modified binders.

Figura 9. Recuperação elástica a 0.1 kPa e 3.2 kPa para os ligantes

puro e modificados com a borra de óleo de soja in natura.

According to AASHTO M320 (2021), a relationship can

be established between the values obtained for Jnr at 3.2 kPa

and the traffic grade to which the binder belongs. This

classification is shown in Table 8. Based on the values

obtained for Jnr at 3.2 kPa, binders with 1%, 3%, and 5% can

AB 1%SS 3%SS 5%SS 7%SS 9%SS

0.1 kPa 3.40 3.90 1.89 2.15 3.82 3.66

3.2 kPa 3.83 4.21 2.27 2.30 5.28 5.49

Jnr, diff (%) 12.68 8.01 20.91 6.63 38.17 50.13

0.00

100.00

200.00

300.00

400.00

500.00

600.00

700.00

800.00

0.0

1.0

2.0

3.0

4.0

5.0

6.0

7.0

Non-recoverable

Compliance - Jnr ((kPa-1)

0.1 kPa 3.2 kPa Jnr, diff (%)

AB 1%SS 3%SS 5%SS 7%SS 9%SS

0.1 kPa 5.03 1.93 9.34 3.03 6.74 15.18

3.2 kPa 0.37 0.27 1.50 0.90 1.09 1.10

0.0

10.0

20.0

30.0

40.0

50.0

60.0

70.0

Recovery Percentage (%)

0.1 kPa 3.2 kPa

Melo Neto et al.

Nativa, Sinop, v. 11, n. 2, p. 283-291, 2023.

289

be classified for standard traffic use. However, the additions

of 7%SS and 9%SS had Jnr values above the specified limit,

making them unsuitable for highway use.

Table 8. Classification of traffic level based on Jnr values.

Tabela 8. Classificação do nível de tráfego com base nos valores de

Jnr.

Property Jnr (kPa)

Traffic Type Traffic level

Jnr up to 3.2

kPa at

maximum PG

temperature

2.0

4.0

Standard

< 10

million

1.0

2.0

Heavy

> 10

million

0.5

1.0

Very Heavy

> 30

million

0.0 - 0.5

Extremely

Heavy > 100 million

When analyzing the recovery percentage, as shown in

Figure 9, it can be observed that the highest (%R) values are

for the additions of 3%SS, 7%SS, and 9%SS, with values

above those of the pure binder, both for Jnr at 0.1 kPa and

Jnr at 3.2 kPa. Figures 10 and 11 present the Jnr test data

conducted at the maximum PG temperature of the asphalt

binder (64°C) and the elastic recovery for binders modified

with dried soybean oil sludge.

Figure 10. Non-recoverable compliances of pure binders and

binders modified with dried soybean oil sludge.

Figura 10. Compliâncias não recuperáveis dos ligantes puro e

modificados com a borra de óleo de soja seca.

Figure 11. Elastic recovery at 0.1 kPa and 3.2 kPa for pure binders

and binders modified with dried soybean oil sludge.

Figura 11. Recuperação elástica a 0.1 kPa e 3.2 kPa para os ligantes

puro e modificados com a borra de óleo de soja seca.

According to Figure 10, it can be observed that with the

incorporation of dried soybean oil sludge at 1%, 3%, and 5%,

the values of Jnr at 3.2 kPa tend to increase.

Regarding the percentages of 7%DSS and 9%DSS, a

decrease in the value of Jnr at 3.2 kPa is noticeable compared

to the previous percentages. This behavior was unexpected

due to the stiffness gain observed in the rotational viscosity

and PG tests for these additions.

4. DISCUSSION

4.1. Rotational Viscosity

Based on the results presented in Table 5, a reduction in

asphalt binder viscosity was observed for additions of up to

5% soybean oil sludge (SS), particularly at the lower test

temperatures, consistent with the findings reported by Melo

Neto et al. (2022a). However, 7% and 9% increased viscosity

compared to the pure asphalt binder before the short-term

aging procedure (RTFO). Following the RTFO test, only the

3% addition exhibited lower viscosity than the pure binder at

all three temperatures. Overall, all percentages yielded results

within the limits stipulated by the standard.

In the case of binders modified with dry soybean oil

sludge, the viscosity increased with higher additive

percentages. The study aimed to establish soybean oil sludge

as a potential viscosity reducer, and the test results indicate

that adding up to 5% raw sludge ensures this reduction.

However, samples with dry sludge suggest that values lower

than 1% can achieve this viscosity reduction. Given that raw

sludge contains a notable moisture content, the effective

added amount of soybean oil sludge is lower than the actual

quantity employed.

According to Silva et al. (2022), as viscosity decreases

relative to the pure binder, the action of the modifying agent

will consequently influence compaction and mixing

temperatures, which are linked to the workability of the

binder.

4.2. Performance Grade (PG)

The results presented in Figures 2 and 3 allowed us to

ascertain that following the addition of crude soybean oil

sludge (in natura) and dried sludge, as well as when subjected

to higher temperatures, there is increased development of

stiffness in the asphalt binder. For lower temperatures, these

findings indicate that incorporating the modifier contributes

to reducing the stiffness of the binders. Furthermore, it's

noteworthy that for both crude and dried sludge, there was

an increase in the G*/Senδ parameter with short-term aging,

albeit consistently maintaining values lower than those of the

pure sample. This phenomenon arises from the samples

becoming stiffer after RTFO, with parameters around twice

as high as those obtained before the procedure, a behavior

also observed in the studies by Portugal (2016) and Melo

Neto et al. (2022b).

It's worth noting that in the case of adding dried sludge,

the fact that this parameter is lower than that of the pure

binder diverges from the values obtained in the viscosity

tests. This suggests that there may have been incomplete

homogeneity in the mixture, leading to non-representative

results, or that this modifying agent may behave as a viscosity

reducer under low temperatures.

An increase was observed regarding the PG values for the

binders modified with both crude and dried sludge, as

presented in Figures 4 and 6. This increase could be

attributed to the high moisture content present in the

material (approximately 40%). As the amount of sludge

added to the asphalt binder increases, the water content also

AB 1%

DSS

0.1 kPa 3.40 3.82 4.22 4.02 1.93 0.53

3.2 kPa 3.83 4.10 4.59 4.99 4.37 4.37

Jnr, diff (%) 12.68 7.21 8.87 24.21 125.94 721.54

0.00

100.00

200.00

300.00

400.00

500.00

600.00

700.00

800.00

0.0

1.0

2.0

3.0

4.0

5.0

6.0

7.0

Non-recoverable

Compliance - Jnr ((kPa-1)

0.1 kPa 3.2 kPa Jnr, diff (%)

AB 1%DSS 3%DSS 5%DSS 7%DSS 9%DSS

0.1 kPa 5.03 1.62 0.96 6.18 33.53 73.95

3.2 kPa 0.37 0.28 0.30 0.58 3.13 3.40

0.00

10.00

20.00

30.00

40.00

50.00

60.00

70.00

Recovery Percentage (%)

0.1 kPa 3.2 kPa

Rheological investigation of asphalt binder modified with soybean oil sludge

Nativa, Sinop, v. 11, n. 2, p. 283-291, 2023.

290

increases, which could have oxidized the asphalt binder and

increased its stiffness.

4.3. Multiple Stress Creep Recovery (MSCR)

Regarding the samples of modified binder derived from

crude sludge, based on the Jnr values presented in Figure 8,

it can be observed that when applying stress levels of 0.1 kPa

and 3.2 kPa, the binders modified with 3%SS and 5%SS

exhibited the lowest values of non-recoverable compliance

compared to the other modified binders. These values were

also lower than those obtained for the binder without

additives. The reduction of this parameter indicates a less

fluid binder and, thus, a lower susceptibility to permanent

deformation, which contradicts the rotational viscosity test

results indicating a reduction in material stiffness. The

samples 7%SS and 9%SS had Jnr values at 3.2 kPa above the

specified norm, rendering them unsuitable for use, according

to AASHTO M320 (2021). High Jnr values at 3.2 kPa indicate

a more fluid asphalt binder and, consequently, a binder more

susceptible to permanent deformation.

As for the differential Jnr values (Jnr diff), it can be

observed that for all tested samples, the Jnr diff values were

below the limit of 75%, indicating that the samples are

suitable for use at this temperature range.

Regarding the percentage of recovery shown in Figure 9, as

mentioned by Mendonça et al. (2022), the Multiple Stress

Creep Recovery (MSCR) percentage can identify and quantify

the effect of the additive in the binder. Based on this, it is

noted that the additions of 3%SS, 7%SS, and 9%SS

significantly influence the elastic characteristics of the binder

under high traffic levels.

As for the binders modified with dry sludge, according to

Figure 10, it was observed that for additions of 1%, 3%, and

5%, the Jnr values at 3.2 kPa tend to increase. This indicates

that adding material at these percentages to the pure binder

increases its stiffness and reduces its susceptibility to

permanent deformation.

However, it is important to note that these results are for

a temperature of 64°C above the RTFO-aged PG

temperature obtained for these samples (58°C). This might

have led to oxidation and increased consistency. These

inconsistent values could result from a lack of chemical

interaction between the asphalt binder and the dry soybean

oil sludge. This absence of interaction prevents a

homogeneous mixture from forming, rendering the samples

unrepresentative and invalidating the data or the material's

use in pavement applications.

In terms of the percentages of 7%DSS and 9%DSS, a

decrease in the value of Jnr at 3.2 kPa was observed, a

behavior unexpected due to the stiffness gain observed in

rotational viscosity and PG tests for these additions.

Concerning their recovery percentages, these samples are

classified as inadequate due to having values significantly

above 75%, as shown in Figure 11.

5. FINAL CONSIDERATIONS

Based on the obtained results, it can be concluded that

using soybean oil sludge as a viscosity-reducing agent is not

viable. The modified samples exhibited higher stiffness than

the pure binder. The PG temperatures before the aging

process were higher than the reference values, but after aging,

the found values were equal to or lower than the reference

values. Thus, the modifier was not effective in reducing the

PG temperature.

In the case of raw soybean oil sludge, adding this modifier

reduced susceptibility to permanent deformation at the 9%

level. Concerning this material, it was noted that the high

moisture content present in the soybean oil sludge could have

contributed to the oxidation process of the asphalt binder

during modification and short-term aging, resulting in

increased stiffness.

Such uncertainties led to analyzing the binder modified

with dried soybean oil sludge. The results showed that

additions of up to 5% provided viscosity values equivalent to

those of the pure binder. In comparison, percentages above

7% increased the stiffness of the asphalt binder. Like the raw

sludge, the dried sludge did not reduce the PG temperature,

rendering it unsuitable as a rejuvenating agent for recycled

asphalt mixtures.

Furthermore, removing moisture from the soybean oil

sludge samples increased the materials' sensitivity to elevated

stress levels, making the modified binder more susceptible to

deformation under increased load, as demonstrated in the

MSCR test. Thus, the hypothesis that removing moisture

from the sludge would improve its performance in the

asphalt binder was disregarded.

6. REFERENCES

AMERICAN SOCIETY FOR TESTING AND

MATERIALS. ASTM D2872: Standard Test Method for

Effect of Heat and Air on a Moving Film of Asphalt

(Rolling Thin-Film Oven Test). Estados Unidos, 2019.

AMERICAN SOCIETY FOR TESTING AND

MATERIALS. ASTM D4402: Standard Test Method for

Viscosity Determination of Asphalt at Elevated

Temperatures Using a Rotational Viscometer. Estados

Unidos, 2015.

AMERICAN SOCIETY FOR TESTING AND

MATERIALS. ASTM D6373: Standard Specification for

Performance-Graded Asphalt Binder. Estados Unidos,

2021.

AMERICAN SOCIETY FOR TESTING AND

MATERIALS. ASTM D7405: Standard Test Method for

Multiple Stress Creep and Recovery (MSCR) of Asphalt

Binder Using a Dynamic Shear Rheometer. Estados

Unidos, 2020.

AMERICAN ASSOCIATION OF STATE HIGHWAY

AND TRANSPORTATION. AASHTO M320:

Standard specification for performance-graded asphalt

binder, Washington, D.C., AASHTO, 2021.

ARAÚJO, A. M. Borra de óleo de soja: caracterização

físico-química e avaliação da potencialidade

econômica. 79f. Monografia [Engenharia de Petróleo] -

Universidade Federal do Ceará, Fortaleza, 2016.

AURANGZEB, Q.; AL-QADI, I. L.; OZER, H.; YANG, R.

Hybrid life cycle assessment for asphalt mixtures with

high RAP content. Resources, Conservation and

Recycling, v. 83, p. 77-86, 2014.

http://dx.doi.org/10.1016/j.resconrec.2013.12.004.

BENACHIO, G. L. F., FREITAS, M. d. C. D., TAVARES,

S. F. Circular economy in the construction industry: A

systematic literature review. Journal of Cleaner

Production, v. 260, e121046, 2020.

https://doi.org/10.1016/j.jclepro.2020.121046

Melo Neto et al.

Nativa, Sinop, v. 11, n. 2, p. 283-291, 2023.

291

FAXINA, A. L. Estudo da viabilidade técnica do uso do

resíduo de óleo de xisto como óleo extensor em

ligantes asfalto-borracha. 308f. Tese [Doutorado em

Engenharia de Transportes] - Universidade de São Paulo,

São Paulo, 2006.

HE, M., TU, C., CAO, D.W., CHEN, Y.J. Comparative

analysis of bio-binder properties derived from different

sources. International Journal of Pavement

Engineering, v. 20, p. 792-800, 2017.

https://doi.org/10.1080/10298436.2017.1347434

LI, H.; ZHANG, F.; FENG, Z.; LI, W.; ZOU, X. Study on

waste engine oil and waste cooking oil on performance

improvement of aged asphalt and application in

reclaimed asphalt mixture. Construction and Building

Materials, v. 276, e122138, 2021.

https://doi.org/10.1016/j.conbuildmat.2020.122138

MELO NETO, O. M. Viabilidade de misturas asfálticas

recicladas com ácido graxo da borra do óleo de soja.

120f. Dissertação [Mestrado em Engenharia Civil e

Ambiental] - Universidade Federal de Campina Grande,

Campina Grande, 2022.

MELO NETO, O. M.; SILVA, I. M.; LUCENA, L. C. D. F.

L.; LUCENA, L. D. F. L.; MENDONÇA, A. M. G. D.;

DE LIMA, R. K. B. Physical and rheological study of

asphalt binders with soybean oil sludge and soybean oil

sludge fatty acid. Waste and Biomass Valorization, v.

14, p. 1945-1967, 2022a.

https://doi.org/10.1007/s12649-022-01951-2

MELO NETO, O. M.; MENDONÇA, A. M. G. D.;

RODRIGUES, J. K. G.; LIMA, R. K. B.; SILVANI, C.;

SILVA, I. M. Rheological study of asphalt binder

modified by cotton and copaiba oils. Revista Cubana de

Ingeniería, v. 13, n. 1, e315, 2022(b).

MENDONÇA, A. M. G. D.; NETO, O. D. M. M.;

RODRIGUES, J. K. G.; DE SOUSA DANTAS, I.;

SILVA, I. M.; COSTA, D. B.; DE LIMA, R. K. B. Análise

física-reológica de ligantes asfálticos modificados com

óleo de algodão refinado para uso em misturas asfálticas

mornas. Revista Cubana de Ingeniería, v. 13, n. 2, p.

1-12, 2022.

PORTUGAL, A. C. X. Avaliação reológica de cimentos

asfálticos de petróleo modificados com óleo de soja

e de milho. 126f. Dissertação [Mestrado em Engenharia

Civil e Ambiental)] - Universidade Federal de Campina

Grande, Campina Grande, 2016.

SANTOS, F.; FAXINA, A. Estudo da incorporação de

bio-óleos à base de soja como agentes

rejuvenescedores de ligantes asfálticos. In:

CONGRESSO DE PESQUISA E ENSINO EM

TRANSPORTE DA ANPET, 33. Anais... Balneário

Camboriú: ANPET, 2019. 4p. Disponível em:

http://www.anpet.org.br/anais/documentos/2019/Infr

aestrutura/Materiais%20e%20Tecnologias%20Ambient

ais%20III/1_604_RT.pdf

SEIDEL, J. C.; HADDOCK, J. E. Rheological

characterization of asphalt binders modified with

soybean fatty acids. Construction and Building

Materials, v. 53, p. 324-332, 2014.

https://doi.org/10.1016/j.conbuildmat.2013.11.087

SILVA, C. C. V. P. D.; MELO NETO, O. D. M.;

RODRIGUES, J. K. G.; MENDONÇA, A. M. G. D.;

ARRUDA, S. M.; LIMA, R. K. B. D. Evaluation of the

rheological effect of asphalt binder modification using

Linum usitatissimum oil. Matéria, v. 27, n. 3, p. 1-12,

2022. https://doi.org/10.1590/1517-7076-RMAT-2022-

0138.

SILVA, H. M.; OLIVEIRA, J. R.; JESUS, C. M. Are totally

recycled hot mix asphalts a sustainable alternative for

road paving? Resources, Conservation and Recycling,

v. 60, p. 38-48, 2012.

https://doi.org/10.1016/j.resconrec.2011.11.013.

SOUZA, J. L. S. Estudo das propriedades mecânicas de

misturas asfálticas com cimento asfáltico de petróleo

modificado com óleo de mamona. 101f. Dissertação

[Mestrado em Engenharia Civil] - Universidade Federal

de Campina Grande, Campina Grande, 2012.

SUN, D.; SUN, G.; DU, Y.; ZHU, X.; LU, T.; PANG, Q.;

SHI, S.; DAI, Z. Evaluation of optimized bio-asphalt

containing high content waste cooking oil residues. Fuel,

n. 202, p. 529-540, 2017.

https://doi.org/10.1016/j.fuel.2017.04.069.

SWERN, D. Refining and Bleaching. In: SWERN, D.

Bailey’s Industrial Oil and Fat Products. 4 ed. New

York: J. Wiley and Sons, v. 2, 1982. p. 253-314.

ZARGAR, M.; AHMADINIA, E.; ASLI, H.; KARIM, M. R.

Investigation of the possibility of using waste cooking oil

as a rejuvenating agent for aged bitumen. Journal of

Hazardous Materials, v. 233, p. 254-258, 2012.

https://doi.org/10.1016/j.jhazmat.2012.06.021

ZHANG, J.; LIU, S.; YAO, Z.; WU, S.; JIANG, H.; LIANG,

M.; QIAO, Y. Environmental aspects and pavement

properties of red mud waste as the replacement of

mineral filler in asphalt mixture. Construction and

Building Materials, v. 180, p. 605-613, 2018.

https://doi.org/10.1016/j.conbuildmat.2018.05.268

YAN, K.; LAN, H.; DUAN, Z.; LIU, W.; YOU, L.; WU, S.;

MILIJKOVIC, M. Mechanical performance of asphalt

rejuvenated with various vegetable oils. Construction

and Building Materials, v. 293, n. 1, e123485, 2021.

https://doi.org/10.1016/j.conbuildmat.2021.123485

Author Contributions: O.M.M.N. - conceptualization,

methodology, investigation, data curation, writing - original draft,

writing - review and editing; L.P.T.M.; M.C.R.S.; A.M.S.L.; M.V.S.;

E.L.C.C.; J.L.S.C.; B.H.A.M.N. - methodology, investigation, data

curation, writing - original draft.

Funding: Not applicable.

Institutional Review Board Statement: Not applicable.

Informed Consent Statement (Ethics Committee of the area):

Not applicable.

Data Availability Statement (how the data can be made

available): Study data can be obtained by request to the

corresponding author or the first author, via e-mail. It is not

available on the website as the research project is still under

development.

Conflicts of Interest: The author affirms that she has no financial

or personal affiliations that could unduly affect or skew the paper's

content.