Abstracts

Acid and Enzymatic Hydrolysis to Recover Reducing Sugars from Cassava Bagasse: an Economic Study

Adenise Lorenci Woiciechowski¹; Saul Nitsche¹; Ashok Pandey² and Carlos Ricardo Soccol1^* * Author for correspondence

¹Laboratório de Processos Biotecnológicos; Departamento de Engenharia Química; Centro Politécnico; C. P.19011; 81531-970; Curitiba - PR - Brazil. ²Biotechnology Division; Regional Research Laboratory; CSIR; Trivandrum - 695-019; India

ABSTRACT

The objective of this work was to study the acid and enzymatic hydrolysis of cassava bagasse for the recovery of reducing sugars and to establish the operational costs. A statistical program "Statistica", based on the surface response was used to optimize the recovery of reducing sugars in both the processes. The process economics was determined considering the values of reducing sugars obtained at laboratory scale, and the operations costs of a cylindrical reactor of 1500 L, with flat walls at the top and bottom. The reactor was operated with 150 kg of cassava bagasse and 1350 kg of water. The yield of the acid hydrolysis was 62.4 g of reducing sugars from 100 g of cassava bagasse containing 66% starch. It represented 94.5% of reducing sugar recovery. The yield of the enzymatic hydrolysis was 77.1 g of reducing sugars from 120 g of cassava bagasse, which represented 97.3% of reducing sugars recovery. Concerning to the time, a batch of acid hydrolysis required 10 minutes, plus the time to heat and cool the reactor, and a batch of the enzymatic hydrolysis needed 25 hours and 20 minutes, plus the time to heat and to cool the reactor. Thus, the acid hydrolysis of 150 kg of cassava bagasse required US$ 34.27, and the enzymatic hydrolysis of the same amount of cassava bagasse required US$ 2470.99.

Key words: Cassava bagasse, hydrolysis, acid, enzyme, reducing sugars, economics

INTRODUCTION

Cassava (Manioca esculenta Crantz) is a plant cultivated in tropical countries. Brazil is one of the largest producers of cassava in the world. One part of cassava production in Brazil is used to obtain the cassava flour, or used directly as meal and the other part is processed to obtain starch. Industries that produce starch from the cassava roots generate daily thousands of tons of cassava bagasse as solid waste of the process. It is composed basically of fibers and residual starch that was not extracted from the cassava tubers. Cassava bagasse is generally disposed in the surrounding environment of the processing units. However, due to its high organic material content and it’s high biodegradability, it could cause serious environmental pollution (Pandey et al., 2000, 2001).

Starch is a polymer of glucose and contains amylose and amylopectin as building blocks. The hydrolysis of the starch present in cassava bagasse produces a broth with available reducing sugars, chiefly glucose, which could be directly fermented by microrganisms (Bobbio and Bobbio, 1995).

Due to richness in organic matter, basically starch, cassava bagasse could be in ideal substrate for biotechnological processes where the objective could be to produce metabolites with commercial value. Cassava bagasse can be used directly in solid-state fermentation, or in submerged fermentation after hydrolysis. Table 1 shows the range of variation of its physico-chemical contents.

Various biotechnological processes, which involved the use of cassava bagasse as substrates include production of edible mushrooms (Beux 1995; Tonial, 1997), enzymes and, organic acids such as citric acid (Kolicheski 1995), fumáric acid (Carta, 1998; Soccol, 1994), lactic acid (Soccol et al., 1994a, 1994b), etc. Another approach to utilize cassava bagasse involves its hydrolyze to convert starch present in it into reducing sugars (mainly glucose), and then uses it in submerged fermentation to produce metabolites.

To obtain reducing sugars from cassava bagasse, it must have a thermal hydrolytic treatment with acid or enzyme. The acid or enzymatic hydrolysis of cassava bagasse produces two fractions: one liquid composed of soluble sugars from the starch hydrolysis (basically glucose), and one solid fraction composed of insoluble cellulose and fibers.

The objective of this work was to compare the recovery of reducing sugars from cassava bagasse using two different hydrolysis methods, and also to compare the cost economics of both the methods of hydrolysis.

MATERIALS AND METHODS

The physical conditions for acid and enzymatic hydrolysis were optimized using an experimental factorial design, where the response variable was the reducing sugars concentration. The response data were analyzed using the statistical program "Statistica" based on the response surface.

Acid Hydrolysis: Acid hydrolysis was performed using hydrochloric acid at 0.5, 1.0 and 1.5% concentrations. Cassava bagasse in acid solutions was submitted to a thermal treatment at different temperatures (100, 120 and 130° C) for 5, 10 and 15 minutes. The tests were made in 250 mL flasks, using 5 g of cassava bagasse and 50 mL of the acid solution.

Enzymatic Hydrolysis: To perform the enzymatic hydrolysis, the starch present in the cassava bagasse was pre-gelatinized by heating at 100° C for 15 min. The enzymatic hydrolysis was performed in two steps. The first, using a -amylase (Termamyl 120L-Novo Nordisk), and the second using amyloglucosidase (AMG 200L-Novo Nordisk). The optimal pH, reaction time, temperature and the enzyme concentration of both the steps were determined using the experimental factorial design. After the hydrolysis, the enzymes were inactivated with heat for 10 minutes at 100° C. The tests were made in 250 mL flasks, using 6 g of cassava bagasse, and 50 mL of water with the appropriate enzyme (Carta, 1999).

Reducing Sugar Analysis: The reducing sugars recovered from the cassava bagasse was analyzed by Somogyi-Nelson method (Nelson, 1944; Somogyi, 1945; Somogyi, 1952).

Energy Costs: The energy costs of both the processes, viz. acid and enzymatic hydrolysis were done considering the reducing sugars recovered during the optimization studies, and a scale-up in a reactor of 1500 L. The hydrolysis costs were calculated considering the energy and the chemicals necessary for both the processes.

Reactor: A cylindrical stainless steel reactor (1500 L) with thermal insulation and jacket heated was used. Its diameter was 1.0 m, height (L) 2.15 m, (working height 1.9 m) and insulation thickness: D x = 0.05 m of glass wool.

Heat Needed for the Processes: In order to compare the heat necessary by both the methods of hydrolysis, the heat necessary to increase the temperature and the heat necessary to maintain it during each step of the both processes was calculated as described by Holman (1992).

Heat to increase the temperature of the aqueous medium with cassava bagasse:

Q = m.c_p.DT

Where

m = 1500 Kg (10% of cassava bagasse = 150 kg + 90% of water = 1350 kg).

c_p = 3.9 kJ/kg° C ® 0.1x1.25 kJ/kg (cassava bagasse) + 0.9x4.18 kJ/kg (water ).

DT = temperature variation depending on the process step.

Heat to maintain the temperature = heat lost during the processes: Here the heat lost by free convection though the cylindrical wall and through the plan wall at the top and at the bottom of the reactor was considered.

a. Through the cylindrical wall (Holman 1992):

Q = U. A_outDT

The global coefficient of thermal exchange for the cylindrical wall was calculated using the following expression:

U= 1/[A_out/A_inh_in + A_outln (r_out/r_in)/2p KL + 1/h_ar]

1.The first term was related to the convection inside the reactor. To determine the medium parameters, water was considered.

h_in = Nu . K_in / D

K_in = 0.685 W/m K.

For reactor heat with coil:

Nu = 0.87 Re^0,62 Pr^0,33.

Re = N.D^2r/m (Doran 1998)

N = 3.33 rpm

r = 1000 kg/m³

m = 2.3.10^-4 kg/ms

Pr = 1.45 (water-120° C)

2. The second term was related to the insulation of reactor wall.

A_out = 7.43 m²

r_out/r_in = 0.55m/0.5m

K_{glass wool} = 0.038 W/m.K

3. The third term was related to the convection outside the reactor

h_out = Nu . K_air / D_out

D_out = 1.005 m

K_air = 0.0328 W/m K.

For cylindrical wall:

Nu = C (Gr . Pr)^m

Where:

C, m = constants for the system

Gr = g.b (T_surface - T_¥ ) L³ / u².

g = 9.8 m/s²

b = 1/T_surface = 3 10^-3 K^-1

T_surface = considered 60° C = 333 K

T_¥ = 25° C = 298 K

u = 2.59.10 ^–7 m²/s

Pr = 0.7 (for the air)

Gr.Pr = 7.9.10⁹® Table: C = 0.10; m = 1/3 (Holmann, 1992)

b. Through the top and bottom flat walls (Holman1992):

Q = U. A_outDT

The global coefficient of thermal exchange for top and bottom flat walls was calculated using the following expression:

U = 1[Dx/k_isolant + 1/h_out]

1. The first term was related to the conduction through the insulation walls:

K_isolant = 0.038 W/m K

2. The second term was related to the convection out side the reactor:

h_out = Nu . k_out / M

Nu = C (Gr Pr)^m

M = characteristic measure = 0.9 D = 0.9

Gr = as above

Pr = as above

Gr.Pr = 7.14 .10^{8 ®} Table: C = 0.1; m = 1/3 (Holmann1992).

3. As h_in >>>> h_out the term related to the convection inside the reactor was not considered for plain wall.

Total heat to maintain the temperature during the processes: The total heat necessary for the processes was calculated considering the time of each step of the process:

Q_t = Q . t

RESULTS AND DISCUSSION

Table 2 shows the physico-chemical characteristics of the cassava bagasse used in this work, which has in general matching with those reported by Pandey et al. (2000).

Acid Hydrolysis: Figures 1 and 2 show the data obtained with cassava bagasse hydrolysis using acid. Evidently best acid hydrolysis conditions were: hydrochloric acid concentration of 1%, reaction time of 10 minutes, and temperature of 120° C, which resulted 62.4 g of reducing sugars from 100 g of cassava bagasse This value represented 94.5% of recovery of reducing sugars from the starch available in cassava bagasse.

Enzymatic Hydrolysis: According to Carta (1999), in enzymatic hydrolysis of cassava bagasse, firstly starch must be gelatinized at 100° C for 10 minutes. Best reaction conditions for the hydrolysis were by using 100 mL of the a -amylase (Termamyl 120L/g starch) at pH 6.5 for 1 hour at 90° C. In the second step, 471 mL of the amyloglucosidase (AMG 200L)/g of starch at pH 4.5 was used for 24 hours at 60° C. The last step consisted of inactivating the enzymes by increasing the reaction temperature to 100° C for 10 minutes. Highest reducing sugars value obtained was 77.1 g from 120 g of cassava. This value represented 97.3% recovery of reducing sugars.

Energy Costs for the Acid Hydrolysis:

Energy to heat the material from 25° C (environment temperature considered) to 120° C = 556 MJ . (1)

Heat lost to the environment = 550 J/s

Hydrolysis time = 10 minutes = 600 s

Total lost heat= 330 kJ .. (2)

Total heat required = 556.4 MJ . (1) + (2)

The total energy necessary to the cassava bagasse acid hydrolysis was 154.1 kWh.

Energy Costs for the Enzymatic Hydrolysis: Gelatinization

Energy to heat the material from 25 to 100° C = 439 MJ (1)

Heat lost to the environment = 435 J/s

Hydrolysis time: 15 minutes = 900 s

Total heat lost = 391.5 k (2)

Total heat required = 439.4 MJ (1) + (2)

Hydrolysis with Termamyl 120 L (90° C)

Heat lost to the environment = 377 J/s .. (1)

Hydrolysis time = 60 minutes = 3600 s

Total heat lost = 1400 kJ . (2)

Total heat required = 1400 kJ . (1) + (2)

Hydrolysis with AMG 200 L (60° )

Heat lost to the environment = 203 J/s . (1)

Hydrolysis time = 24 h = 86 400 s

Total heat lost = 18 MJ . (2)

Total heat required = 18 MJ . (1) + (2)

Enzyme inactivation

Energy to heat the material from 60 to 100° C = 234 MJ. . (1)

Heat lost to the environment = 435 J/s

Inactivation time = 10 min = 600 s

Total heat lost = 261 kJ . (2)

Total heat required = 234.3 MJ . (1) + (2)

Total energy necessary to the cassava bagasse enzymatic hydrolysis was 692.8 MJ = 192.5 kWh.

Considering the costs in energy, the most advantageous process to use for the hydrolysis of the residual starch present at the cassava bagasse was the acid one. The energy consumption for the enzymatic hydrolysis was 24.92 % more expensive then the acid hydrolysis, although the reactor was well insulated.

While doing these comparisons, the equipment cost was not considered, as it was the same for both the processes.

Costs of the chemical components for the Acid and Enzyme Hydrolysis of cassava bagasse (150 kg):

Tables 3 and 4 show the costs of the chemical components of acid and enzyme hydrolysis for a batch (considering the specific weight of hydrochloric acid = 1.159 g/L and enzyme specific weight = 1.2 g/L), respectively.

Considering the chemicals necessary for a batch, acid hydrolysis was much less expensive than the enzymatic one. Cost of chemicals was considered as an important factor because the price difference was very high, which would largely affect any cost analysis. The only limitation with acid hydrolysis could be the issue of toxicity, because the acid process increases the medium salinity, and it could be a limiting factor

CONCLUSION

Analysing the process yields of the recovered reducing sugars from the starch present in cassava bagasse, both processes were quite efficient and similar with 94.5% for the acid hydrolysis against 97.3% for the enzymatic hydrolysis. Looking at the time required for each process, acid hydrolysis was more advantageous than the enzymatic process. For a batch, the acid hydrolysis was completed in only 10 minutes plus the time to heat and cool the material. The enzymatic hydrolysis, on the contrast took 25 hours and 20 minutes, plus the time to heat and cool the material for the whole process in a batch.

This study showed that the both methods were almost equally efficient concerning to the yield based on the reducing sugar recovered from the cassava bagasse, but economically, the acid hydrolysis was more advantageous.

RESUMO

O objetivo deste trabalho foi estudar a hidrólise acida e enzimática do bagaço de mandioca relacionando a eficiência de recuperação de açúcar redutor com os custos de operação. As condições de operação de ambos os processos foram otimizados usando o programa de análise de dados "Statistica", baseado em superfície de resposta. O estudo econômico foi feito tomando-se por base os valores de açúcar redutor obtidos nas hidrólises em escala de laboratório, e os custos de operação foram calculados para um reator de escala industrial com volume útil de 1500 L, de paredes laterais cilíndricas, e planas no topo e no fundo. O reator pode operar com 136 kg de bagaço e 1360 kg de água. Para o cálculo do gasto de energia foram considerados os calores necessários para aquecer o material e o calor necessário para manter a temperatura do reator em cada etapa do processo.Os custos com produtos químicos foram considerados, e também o tempo de reação, que mostrou ser um ponto muito importante na definição da viabilidade do processo.

O rendimento da hidrólise ácida foi 62.35 g de açúcar redutor a partir de 100 g of bagaço de mandioca com 66% de amido residual. Isto representa 94.5% de açúcar redutor recuperado. O rendimento da hidrólise enzimática foi de 77.1 g de açúcar redutor a partir de 120 g de bagaço de mandioca com 66% de amido residual, representando 97.3% recuperação de açúcar redutor.Em relação ao tempo, uma batelada da hidrólise ácida gasta 10 minutos, mais o tempo para aquecer e resfriar o reator, e uma batelada da hidrólise enzimática precisa de 25 horas e 20 minutos, mais o tempo para aquecer e resfriar o reator Quanto aos custos operacionais com produtos químicos e energia, a hidrólise ácida de 150 kg de bagaço de mandioca, custa US$ 34.27, e a hidrólise enzimática da mesma quantidade de bagaço de mandioca custa US$ 2470.99.

LIST OF SIMBOLS

A - Area of thermal exchange,

A_out/in - area outside/inside the reactor

A_out - outside reactor area

C, m - Constants for the system

D - inside diameter

D_out- Reactor outside diameter

g - acceleration of gravity

Gr - Grashof number

h - convective coefficient of thermal exchange

h_in- convective coefficient inside the reactor

h_out- convective coefficient outside the reactor

K - thermal conductivity

K_in - inside thermal conductivity

K_{glass wool} - glass wool thermal conductivity

K_air - air thermal conductivity

L - wall height

N - agitation

Nu - Nusselt number

Pr - Prandtl number

Q - Heat

r_out/r_in - reactor outside/inside ratio conductivity

Re - Reynolds number

t - time

T_surface - wall temperature

T_¥- environment temperature

U - Global coefficient of thermal exchange

D T - temperature degree.

Dx - isolant wall thickness

b - thermal coefficient of expansion = 1/T vc

m - medium viscosity

u - kinematic viscosity.

r - medium density

Received: October 19, 2001;

Revised: March 26, 2002;

Accepted: May 09, 2002.

Publication Dates

History