DELIGNIFICATION OF HEMP AWN WITH PEROXO COMPOUNDS AND CHARACTERISTIC OF THE CELLULOSE
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Abstract (English):
The hemp awn (Cannabis sativa) was delignified with the reaction mixture "acetic acid - hydrogen peroxide - sulfuric acid catalyst - water" at a sulfuric acid concentration of 0.45%, a liquid module of 6, and a temperature of 85°C. The influence of the concentration of hydrogen peroxide and the duration of the process on the yield, strength properties and whiteness of technical cellulose was studied. With a yield of about 45%, it is comparable to the properties of bleached sulphate cellulose from hardwood (OB-0 grade in accordance with GOST 14940-96) and without additional expensive bleaching can be used in the production of many high-quality mass types of paper.

Keywords:
hemp, awn, cellulose, delignification, hydrogen peroxide, peracetic acid, cellulose whiteness, cellulose strength
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In the XIX and early XX centuries in Russia, hemp (Cannabis sativa L - ordinary hemp) was one of the main crops. The area of its cultivation in 1928 reached 996 thousand hectares. But in 1961 the USSR joined the UN convention, which prohibited varieties with a narcotic content of more than 0.2%, and hemp sowing dropped sharply [1]. As a result of breeding work, varieties of industrial hemp were bred, in which the content of tetrahydrocannabinol (THC) and other psychoactive substances does not exceed 0.01%, and in 2011 industrial cultivation of this crop was allowed in Russia. For 2013, 23 varieties and hybrids of cannabis are included in the Russian state register of breeding achievements approved for use. The area under agricultural hemp in Russia is growing. It is expected that by 2025 the sown area will reach 20 thousand hectares, and the hemp yield will be 8.5 centners per hectare [2].

 

            About 65% of the mass of hemp trusts is fibrous awn. One of the most promising areas of industrial use of technical hemp is the production of pulp and paper products. Currently, about 40% of all deforestation meets the needs of the paper industry. One hectare of hemp can produce the same amount of cellulose as 4-7 hectares of forest. A field planted with hemp bears fruit every year, while trees need at least 20 years to reach the condition necessary for production. Also noteworthy is the high strength inherent in hemp cellulose paper.

Oxidative delignification of plant raw materials with peroxo compounds is considered as a "green" and resource-saving alternative to the existing industrial methods of cellulose production. To date, the results of a large number of studies in this area have been published, including reviews [3-6]. The essence of the method consists in processing plant materials with a solution of hydrogen peroxide and acetic acid. In this reaction system, acetic acid undergoes a catalyzed oxidation to peracetic acid, which, in its middle, oxidizes lignin, converting it into a soluble state. Sulfuric acid is used as catalysts, as well as its combinations with tungstic acid, tungstate and sodium molybdate, titanium dioxide.

            We have studied the effect of the conditions of one-stage delignification ("cooking") of hemp awn by the oxidative method on the yield and properties of technical cellulose.

The raw material for the research was awn from hemp brand "Surskaya". The chemical composition is determined by conventional methods [7]: mass fraction of cellulose (Kurschner-Hoffer method) 41.2%; lignin (sulfuric acid method modified by Komarov) 23.4%; extractives (extraction in a Soxhlet apparatus with an azeotropic ethanol-toluene mixture) 4.64%; ash 1.10%.

The prepared awn was delignified with the reaction mixture "acetic acid - hydrogen peroxide - sulfuric acid catalyst - water". Delignification conditions: initial concentration of acetic acid in the cooking solution 6 g-mol/dm3 (36%); sulfuric acid concentration 0.046 g-mol/dm3 (0.45%); liquid module 6.0; isothermal cooking temperature 85°C. Variable brewing factors:

X1  initial concentration of hydrogen peroxide in the cooking solution (variation range 3 ... 5 g-mol/dm3);

X2  – cooking duration (variation interval 180 ... 270 minutes).

These factors varied according to a three-level design of the second-order experiment on cube elements [8] (table 1).

The pulp washed after cooking was ground in a CRA apparatus (Yokro mill) for 2 minutes to a grinding degree of 34 ... 36 oShR. Paper casts of 75 g/m2 were made on a Rapid-Keten sheet-molding machine. The experimental results were characterized by the following output parameters:

            Y1 – concentration of residual hydrogen peroxide in the liquor, %;

Y2 – concentration of residual peracetic acid in the liquor, %;

Y3 – cellulose yield, %;

Y4 – breaking length, m;

Y5 – elongation to break, %;

Y6 –bursting resistance, kPa;

Y7 – tear resistance, mN;

Y8 – whiteness of castings, %.

            The results of the experiments are shown in table 1.

.

Table 1. Conditions and results of the experiment

Mode number

Variable factors

 

Output parameters

 

X1

X2

Y1

Y2

Y3

Y4

Y5

Y6

Y7

Y8

1

2

3

4

5

6

7

8

9

10

11

4

3

4

5

3

4

5

3

4

5

4

225

180

180

180

225

225

225

270

270

270

225

4.59

3.99

5.78

6.20

3.65

4.59

5.52

2.80

3.82

3.57

4.59

1.43

0.85

1.52

1.71

0.76

1.23

1.52

0.95

1.42

0.95

1.45

47.3

53.9

48.8

45.6

52.1

48.1

45.4

50.8

47.4

44.3

47.9

10032

8500

10236

11333

12000

11850

10777

10910

9906

10108

10090

2.41

2.25

2.42

2.51

2.40

2.42

2.47

2.46

2.42

2.40

2.45

249

198

272

273

238

253

253

281

245

250

249

196

236

210

166

166

172

166

196

220

176

190

74

57

67

79

60

74

84

63

81

88

72

                         

           

            Mathematical processing of the results was performed using the Statgraphics Centurion software package. The dependence of each of the output parameters Y on variable factors was approximated by polynomial second-order regression equations [8]:

Ý – b0 + b1X1 + b2X2 + b11X12 + b22X22 + b12X1X2.

                    The terms with an estimate of the confidence probability of the regression coefficients of less than 95% were excluded from the equation with the recalculation of the remaining coefficients. Statistically significant coefficients (threshold significance level 0.05) are shown in table 2.

 

 

Table 2. Coefficients and statistical characteristics of the regression equations

bij  coefficients and statistical characteristics

Output parameters

Y1

Y2

Y3

Y4

Y5

Y6

Y7

Y8

b0

b1

b2

b11

b22

b12

Determination coefficient

Forecast standard error Ý

-1.153

2.608

0.019

-0.008

 

0.928

 

0.332

-3.493

1.345

0.016

-0.005

 

0.694

 

0.213

79.9

-10.0

-0.021

0.803

 

0.980

 

0.491

10523

 

 

524

0.556

0.445

0.007

-0.002

 

0.919

 

0.022

-346.2

142.3

2.48

-0.588

 

0.731

 

13.7

267.0

-15.0

-0.074

 

0.247

 

23.2

-7.42

22.6

-0.002

0.0167

 

0.983

 

1.86

 

Regression equations were used to graphically represent the results in the form of three-dimensional response surfaces [9].

The dependences of the concentration of residual values of hydrogen peroxide Y1 and peracetic acid Y2 in the liquor on variable factors (fig. 1) are almost identical and predictable, they are due to the nature of the above-mentioned successive oxidative reactions.

 

Figure 1. Dependence of the concentration of residual hydrogen peroxide in the liquor on the variables of cooking

           

The yield of technical cellulose decreases linearly with an increase in the initial concentration of hydrogen peroxide and the duration of cooking within the used range of their variation (Y3, Figure 2).

            The tensile strength of paper castings (breaking length Y4) remained unchanged under the experimental conditions (did not go beyond the "noise background"; all regression coefficients are statistically insignificant, tab. 1). Since the breaking strength is highly dependent on the strength of the individual fibers, it can be argued that awn hemp fibers are resistant to the action of the cooking liquor components. The magnitude of the elongation of the paper samples under tension Y5, on the contrary, is largely due to the strength of the interfiber bonds, the dependence of this parameter on the cooking conditions is ambiguous (Y5, figure 2). These results are consistent with other strength properties - resistance to bursting and tearing, this is clearly seen when comparing figures 2 and 3.

 

Figure 2. Dependence of pulp yield Y3 and elongation at break Y5 on variable cooking factors

 

    Figure 3. Dependence of the resistance of castings to punching shear Y6 and tearing Y7 on the variable factors of cooking

 

The whiteness of cellulose Y8 grows from 58 to 89% in proportion to a decrease in the yield of Y3 from 54 to 44% (the linear correlation coefficient is -0.966); therefore, we do not present the graph of the response surface of this parameter here. Note that according to GOST 14940-96, bleached sulfate cellulose from hardwood (aspen) of all grades, including OB-0, must have a whiteness of at least 86%. Consequently, the discussed awn hemp pulp without additional expensive bleaching can be used instead of bleached hardwood sulphate pulp in the production of many high-quality mass grades of paper.

 

The work was carried out within the framework of the state assignment of the Ministry of Education and Science of Russia for the implementation of the project "Technology and equipment for the chemical processing of plant raw materials biomass" by the team of the scientific laboratory "Deep processing of vegetable raw materials" (topic number FEFE-2020-0016).

           

References

1. Lunin A. Why are forbidden and forgotten agricultural crops reviving in Russia? // Newspaper "Arguments and Facts", 2020, № 41, P. 9.

2. Belopukhova Yu. B. Russian cannabis growing 2019. Results of the three-year plan // Third All-Russian meeting of cannabis growers, Moscow, December 16, 2019.

3. Pen R.Z., Karetnikova N.V. Catalyzed delignification of wood with hydrogen peroxide and peroxyacids (review) // Chemistry of vegetable raw materials. 2005, № 3, P. 61-73.

4. Pen R.Z., Karetnikova N.V., Shapiro I.L.Catalyzed delignification of plant raw materials with hydrogen peroxide and peroxyacids (review) // Chemistry of vegetable raw materials. 2020, № 4, P. 329-347. (DOIhttps://doi.org/10.14258/jcprm.2020048119)

5. Pen R., Karetnikova N., Shapiro I. Peroxide cellulose. Delignification of plant raw materials with peroxo compounds. Saarbrücken (Germany), LAMBERT Academic Publishing, 2013. 245 P.

6. Kuznetsov B.N., Kuznetsova S.A., Yatsenkova O.V., Danilov V.G. Production of cellulose by catalytic delignification with hydrogen peroxide. Krasnoyarsk, Siberian Federal University, 2014. 146 P.

7. Obolenskaya A.V., Elnitskaya Z.P., Leonovich A.A. Laboratory workshop on the chemistry of wood and cellulose. Moscow, 1991. 320 P.

8. Penh R.Z. Planning an Experiment in Statgraphics Centurion. Krasnoyarsk, Siberian State Technological University, 2014. 293 P.

9. Pen R.Z., Pen V.R. Statistical methods of mathematical modeling, analysis and optimization of technological processes. Saint Petersburg, Doe, 2020. 308 P.

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