ANTICORROSION MATERIAL PRODUCED FROM DATE PALM TREE WASTE

Abstract

Anti-corrosion material is produced from date palm tree waste by extracting lignin and modifying by sulfonation. The anti-corrosion material produced from date palm tree waste is non-toxic and effective at preventing or reducing corrosion of, for example, metals subject to corrosive environments, and particularly marine environments.

Claims

1. An anti-corrosion material produced from date palm tree waste, comprising a lignosulfonate formulated as a paste from lignin extracted from date palm tree waste by Klason extraction.

2. The anti-corrosion material according to claim 1, wherein said date palm tree waste comprises waste from Phoenix dactylifera L. trees grown in the United Arab Emirates.

3. The anti-corrosion material according to claim 1, wherein said lignosulfonate comprises sodium lignosulfonate.

4. A method of making a corrosion inhibitor, comprising the steps of: extracting lignin from date palm tree waste; immersing the lignin in alkaline media; adding formaldehyde to the lignin immersed in alkaline media to methylolate the lignin; adding sodium sulfite to the methylolated lignin to sulfonate the lignin, the methylolated and sulfonated lignin immersed in the alkaline media forming a reaction mixture; heating the reaction mixture at 100 C. to complete sulfonating the lignin; adding 25M sulfuric acid to the reaction mixture to precipitate sodium lignosulfonate; and recovering the sodium lignosulfonate in paste form.

5. The method of making a corrosion inhibitor according to claim 4, wherein said step of heating the reaction mixture at 100 C. further comprises stirring the reaction mixture for three hours.

6. The method of making a corrosion inhibitor according to claim 4, wherein said step of heating the reaction mixture at 100 C. further comprises heating the reaction mixture under reflux.

7. The method of making a corrosion inhibitor according to claim 4, further comprising the steps of centrifuging, washing, and drying the precipitated sodium lignosulfonate before said recovering step.

8. The method of making a corrosion inhibitor according to claim 4, further comprising the step of extracting proteins, waxes, resins, and other extractives from the date palm tree waste in an ethanol-benzene extraction solvent mixture prior to said step of extracting lignin from date palm tree waste.

9. The method of making a corrosion inhibitor according to claim 8, further comprising the step of oven-drying solid residue obtained from the ethanol-benzene extraction solvent mixture to recover an extractive-free biomass from the date palm tree waste.

10. The method of making a corrosion inhibitor according to claim 9, wherein said step of extracting lignin from date palm tree waste further comprises the steps of: treating the extractive-free biomass with 72% sulfuric acid for two hours to form biomass in acid solution; diluting the acid solution to 3% sulfuric acid; heating the biomass in diluted acid solution under reflux for four hours; and separating acid-insoluble lignin from the refluxed acid solution.

11. The method of making a corrosion inhibitor according to claim 10, wherein said separating step comprises filtering the refluxed acid solution on a Buchner funnel to recover the acid-insoluble lignin.

12. The method of making a corrosion inhibitor according to claim 10, wherein said separating step comprises the steps of allowing residue to settle in the diluted acid solution after reflux and decanting liquid separated above the residue to recover the acid-insoluble lignin.

13. The method of making a corrosion inhibitor according to claim 10, wherein said step of treating the extractive-free biomass with 72% sulfuric acid comprises stirring the extractive-free biomass in 72% sulfuric acid at 37 C. for two hours.

14. The method of making a corrosion inhibitor according to claim 4, wherein said date palm tree waste comprises waste from Phoenix dactylifera L. trees grown in the United Arab Emirates.

15. A corrosion inhibitor made according to the method of claim 4.

16. A method of inhibiting corrosion, comprising the step of coating exposed surfaces of a substrate with a paste including a lignosulfonate made from lignin extracted from date palm tree waste.

17. The method of inhibiting corrosion according to claim 16, wherein the substrate comprises mild steel.

18. The method of inhibiting corrosion according to claim 16, wherein said date palm tree waste comprises waste from Phoenix dactylifera L. trees grown in the United Arab Emirates.

19. The method of inhibiting corrosion according to claim 16, wherein said lignosulfonate comprises sodium lignosulfonate.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0009] The sole drawing FIGURE is a plot of TGA (thermogravimetric analysis) and DTG (differential gravimetric) curves of extracted lignin at heating rates of 10, 15, 20 and 25 C./min.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0010] The anti-corrosion material or corrosion inhibitor produced from date palm tree waste is made from lignin that is extracted from the waste and then converted to sodium lignosulfonate, which can be used to coat a substrate, e.g., mild steel, to protect the substrate from corrosion. Lignin is extracted from date palm waste by removing extractives, extracting the remaining biomass by Klason extraction in 72% sulfuric acid, diluting the extraction mixture to 3% sulfuric acid and refluxing for four hours. The lignin is placed in water, pH is raised to 10, the lignin is methylolated by addition of formaldehyde, sulfonated by addition of sodium sulfite, and heated to 100 C. with stirring for 3 hours. The sodium lignosulfonate product was solidified by addition of 25M sulfuric acid, washed, and dried. Mild steel immersed in the lignosulfonate resisted corrosion by acid in weight loss testing.

[0011] The process for extracting lignin from date palm tree waste includes the following steps. (1) Biomass (i.e., date palm tree waste) was treated to make it extractive-free (free of protein, waxes and resins), and in a particular example, a 5 g biomass sample was transferred to a weighed thimble tube and extracted with 150 ml of ethanol-benzene solvent 1/2 v/v for 5 hours. (2) The residue from the above extraction process was oven-dried at 103 C. for 1 hour, cooled in a desiccator and weighed to determine the extractive-free biomass to be used for the following improved-Klason lignin extraction. (3) 1 g of the extractive free biomass produced as above was treated with 72% H.sub.2SO.sub.4 for 2 hours under stirring at 37 C. (4) The treated extractive-free biomass was then diluted to a 3% H.sub.2SO.sub.4 solution. (5) The solution was refluxed at 80 C. for 4 hours, resulting in a hydrolyzed residue. (6) The hydrolyzed residue is filtered on a Buchner funnel and washed free of acid by means of hot water. (7) After filtration, the isolated insolubles, i.e., extracted lignin, was oven-dried at 105 C. for 1 hour and cooled in a desiccator until a constant weight was obtained, the difference in weight before and after oven-drying giving the amount of extracted lignin.

[0012] It is noted that, in step 3, a temperature of 37 C. was used to break the linkages between lignin, cellulose and hemicellulose and to remove the cellulose and hemicellulose, the lignin being insoluble in sulfuric acid, in order to extract pure lignin from the date palm waste. When a temperature of 20 C. was used, as in the traditional Klason method, cellulose and hemicellulose were still present in the product. Lignin content and structure differs from one species to another, and even from one tissue to another in the same plant (the present exemplary extraction being performed on Phoenix dactylifera L., obtained from the United Arab Emirates); hence, the properties of the extracted lignin may vary according to the source of the date palm tree waste. Also, the extracted lignin may require unexpectedly different experimental conditions from what is otherwise known. The purity of extracted lignin was confirmed by TGA as shown in the sole drawing FIGURE.

[0013] The extracted lignin was converted to sodium lignosulfonate by the following procedure. The main method of sulfomethylolation of extracted lignin involves a three-step process. In particular, phenol components of the extracted lignin are ionized at an alkaline pH, the lignin is methylolated (also referred to as hydroxymethylation, i.e., a hydroxymethyl [CH2OH] functional group is added to the lignin) by addition of formaldehyde in alkaline media, and the lignin is sulfonated by addition of sodium sulfite. Specifically, (1) 5 g of extracted lignin and 100 mL of deionized water were added into a 250 mL three-neck flask equipped with a stirrer, a thermometer, and a reflux condenser. (2) The pH was adjusted to 10 by addition of 0.5 M NaOH solution. (3) 1.0 mL of 0.123 M formaldehyde was added to the solution. (4) 4 g of 0.317 M sodium sulfite was added to the solution to form a reaction mixture. (5) The reaction mixture was heated to 100 C. (6) The reaction mixture was stirred for 3 h at 150 rpm. (7) 25 M sulfuric acid was added in order to solidify (precipitate) sodium lignosulfonate from the reaction mixture. (8) Finally, the precipitated lignosulfonate was centrifuged, washed and dried. The resulting lignosulfonate produced was in the form of a paste capable of being spread or painted on a surface.

[0014] The composition was tested as follows. Weight loss measurements were performed using mild steel (MS) specimens of size 4.7 cm1.5 cm0.2 cm. The specifications of the mild steel used for weight loss analysis are shown in Table 1, as follows.

TABLE-US-00001 TABLE 1 Specifications of Mild Steel Samples Mild Steel (MS) MS Density (g/cm.sup.3) 7.75 Exposure Time (h) 120 Dimensions (cm) 4.7*1.5*0.2 Surface Area (cm.sup.2) 7.05 Original Weight (g) 15.258
For the corrosion test, the paste form of lignosulfonate prepared as described above was used (about 2 ml) to cover/coat the MS specimens with one layer on both sides. Uncoated MS specimens were used as controls. The following steps were then performed. (1) MS specimens were weighed to get an initial weight. (2) MS specimens were immersed in 1M of sulfuric acid H.sub.2SO.sub.4 solution for a period of 5 days. (3) Weight loss studies were performed at controlled temperatures of 25 C. (4) After immersion, the surface of each specimen was cleaned by distilled water and dried. (5) The dried MS specimens were weighed to get a corroded weight. (6) MS specimen corrosion was determined by weight loss and visual inspection.

[0015] The metal weight loss after performing the weight loss test can be converted to a corrosion rate, a percentage metal loss, or an inhibition efficiency (%), which are calculated according to equations (1), (2), and (3), respectively.

[00001]$\begin{array}{cc}\mathrm{Corrosion}.Math..Math.\mathrm{Rate}\left(\frac{\mathrm{mm}}{\mathrm{yr}}\right)=\frac{\mathrm{Weight}.Math..Math.\mathrm{loss}.Math..Math.\left(g\right)*K}{\begin{array}{c}\mathrm{Alloy}.Math..Math.\mathrm{density}.Math..Math.\left(\frac{g}{{\mathrm{cm}}^3}\right)*\\ \mathrm{Exposed}.Math..Math.\mathrm{Area}.Math..Math.\mathrm{of}.Math..Math.\mathrm{Specimen}.Math..Math.\left({\mathrm{cm}}^2\right)*\mathrm{Exposure}.Math..Math.\mathrm{Time}.Math..Math.\left(\mathrm{hr}\right)\end{array}},& \left(1\right)\end{array}$

where K=8.75*10.sup.4 and the corrosion rate is expressed in millimeters (thickness) per year.

[00002]$\begin{array}{cc}\mathrm{Metal}.Math..Math.\mathrm{Loss}\left(\mathrm{mm}\right)=\frac{\mathrm{Weight}.Math..Math.\mathrm{loss}.Math..Math.\left(g\right)*k}{\mathrm{Alloy}.Math..Math.\mathrm{density}.Math..Math.\left(\frac{g}{{\mathrm{cm}}^3}\right)*\mathrm{Exposed}.Math..Math.\mathrm{Area}.Math..Math.\mathrm{of}.Math..Math.\mathrm{Specimen}.Math..Math.\left({\mathrm{cm}}^2\right)},& \left(2\right)\end{array}$

where k=10 and the metal loss is expressed in millimeters (thickness).

[00003]$\begin{array}{cc}\mathrm{Inhibition}.Math..Math.\mathrm{efficiency}.Math..Math.\left(\%\right)=\frac{\begin{array}{c}\mathrm{Weight}.Math..Math.\mathrm{loss}.Math..Math.\mathrm{without}.Math..Math.\mathrm{inhibitor}.Math..Math.\left(g\right)-\\ \mathrm{Weight}.Math..Math.\mathrm{loss}.Math..Math.\mathrm{with}.Math..Math.\mathrm{inhibitor}.Math..Math.\left(g\right)\end{array}}{\mathrm{Weight}.Math..Math.\mathrm{loss}.Math..Math.\mathrm{without}.Math..Math.\mathrm{inhibitor}.Math..Math.\left(g\right)}*100,& \left(3\right)\end{array}$

where:

Weight loss=Original specimen weight (g)Specimen weight after corrosion test (g).(4)

The results are shown in Table 2, below.

TABLE-US-00002 TABLE 2 Weight loss analysis Specimen coated with Control lignosulfonate MS Weight after test (g) 13.586 15.198 Weight loss (g) 1.672 0.059 Corrosion rate (mm/yr) 22.313 0.799 Metal loss (mm) 0.306 0.011 Inhibition efficiency (%) 96.417

[0016] The corrosion rate of the tested samples significantly decreased from 22.313 to 0.799 (mm/yr) with the addition of sodium lignosulfonate. These results indicate that the sodium lignosulfonate produced from the lignin extracted from date palm tree waste acts as a good corrosion inhibitor and can be used to protect mild steel from corrosion with an efficiency of 96.417%.

[0017] It is to be understood that the production of anti-corrosion material from date palm tree waste is not limited to the specific embodiments described above, but encompasses any and all embodiments within the scope of the generic language of the following claims enabled by the embodiments described herein, or otherwise shown in the drawings or described above in terms sufficient to enable one of ordinary skill in the art to make and use the claimed subject matter.