Purification of Polyether Polyols Made by Double Metal Cyanide Catalysis

Wei Hua Ma; Liu Yang; Qin Zhong

doi:10.4028/www.scientific.net/AMR.455-456.660

Paper Titles

Study on the Precipitation Polymerization of Acrylamide and Methacrylic Acid in Ethanol by Conductimetry: Phase- Separation Prior to Polymerization
p.639

Effects of ZrO₂ Fiber on the Mechanical Properties of Nano-ZrO₂/Al₂O₃ Ceramic Composite
p.645

Preparation of ZrO₂ Composite Ceramics with High Thermal Shock Resistance
p.650

Efficient Synthesis of Thieno [2,3-d] Pyrimidin-4(4H)-ones by the Aza-Wittig Methodology
p.655

Purification of Polyether Polyols Made by Double Metal Cyanide Catalysis
p.660

A Study of Predominated Pathway of Initial Processes in Chemical Vapor Deposition of Silicon-Carbide from Methyltrichlorosilane and Hydrogen System
p.665

Synthesis and Luminescence Properties of Three Europium Complexes with Phenanthroline Derivatives and β-Diketonates
p.671

Adsorption Properties of Dye onto Mg/Al-CO₃ Layered Double Hydroxide
p.677

Influence of Photoinitiator Sensitometric Characteristic on Light-Thermal Sensitive Microcapsule Materials
p.683

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 455-456Purification of Polyether Polyols Made by Double...

Purification of Polyether Polyols Made by Double Metal Cyanide Catalysis

Abstract:

Purification of polyether polyols made by double metal cyanide catalysis was studied. The removal effect of residual double metal cyanide in the polyols by the methods of adsorption and precipitation-filtration is characterized by the residual concentration of the zinc and cobalt ions which is measured by Inductively Coupled Plasma Atomic Emission Spectrometry. Compared with precipitation-filtration, the method of adsorption was more practical and efficient for the purification of the polyols. And the optimum kind and amount of the adsorbent were obtained. The results showed that the combination of chelating fiber and attapulgus clay was the most favorable for the removal of zinc and cobalt ions and the appropriate weight ratio of chelating fiber and attapulgus clay was 1:1. The total concentration of zinc and cobalt ions can be reduced to lower than 1×10^-6. And the amount of the adsorbent added was 3.33% by the weight of the polyether polyols. Also through Scanning Electron Spectroscopy the morphology of the chelating fiber was characterized before and after adsorption. The functional groups on the surface of the fiber could be coordinated with the catalyst attached to the polyol polymer chains to form the separable insoluble particles.

You might also be interested in these eBooks

Future Material Research and Industry Application

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 455-456)

Pages:

660-664

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.455-456.660

Citation:

Cite this paper

Online since:

January 2012

Authors:

Wei Hua Ma, Liu Yang, Qin Zhong

Keywords:

Adsorption, Chelating Fiber, Polyether Polyols, Purification

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] S. Chen, N. P. Xu, J. Shi. Structure and properties of polyether polyols catalyzed by Fe/Zn double metal cyanide complex catalyst. Progress in Organic Coatings. 49(2004): 125-129.

DOI: 10.1016/j.porgcoat.2003.08.021

Google Scholar

[2] B. Le-Khac. Highly active double metal cyanide catalysts. US 6018017. January 25, (2000).

Google Scholar

[3] T. Ostrowski, K. Harre, G. H. Grosch, W. Ju. Preparation of polyether polyols in the presence of a multimetal cyanide complex catalyst. US 7022884. April 4, (2006).

Google Scholar

[4] I. Kim, J. T. Ahn，C. S. Ha, C. S. Yang, I. Park. Polymerization of propylene oxide by using double metal cyanide catalysts and the application to polyurethane elastomer. Polymer, 2003, 44：3417~3428.

DOI: 10.1016/s0032-3861(03)00226-x

Google Scholar

[5] I. Miltiadis, F. B. Gert. Process for the production of inorganic-organic compositions. US 4355188. October 19, (1982).

Google Scholar

[6] W. Takashi, T. Hiromitsu, D. Takao, K. Nobuaki. Method for purifying a polyoxyalkylene alcohol. US4987271. February 14, (1990).

Google Scholar

[7] T. R. Jude. Method for purifying polyether polyols made with double metal cyanide catalysts. US 5416241. May 16, (1995).

Google Scholar

[8] D. H. Stephen. Purification of polyols prepared using double metal cyanide complex catalysts. US4877906. October 31, (1989).

Google Scholar

[9] H. Werner, M. D. Eward. Process for removing and regenerating a double metal cyanide (DMC) catalyst from a polymer polyol. US6806348. October 19, (2004).

Google Scholar

[10] E. K. Lawrence, W. R. John. Process for removing double metal cyanide catalyst residues from a polyol. US 5099075. March 24, (1992).

Google Scholar

[11] L. S. Jonathan. Recovery of double metal cyanide complex catalyst from a polymer. US 5010047. April 23, (1991).

Google Scholar

[12] D. H. Stephen, H. H. Stephen. Purification of polyols prepared using double metal cyanide complex catalysts. US 4721818. January 26, (1988).

Google Scholar

[13] M. M. Malaga, B. B. Montalvo. Process to purify polyether polyols. EP 03380158. 0. Dec 30, (2004).

Google Scholar

[14] S. Li, Q. Y. Shu, Y. C. Cui. Process for purifying polyether polyols by ultrafiltration. CN1884340A. Dec 27, (2006).

Google Scholar

[15] B. Le-khac. Foam-supported double metal cyanide catalysts for polyol synthesis. US5255565. June 11, (1996).

Google Scholar

[16] H. G. Heinrich, L. Harald, L. Reinhard, J. Dieter, K. Ulrich. Supported double metal cyanide catalysts, method for producing them, and their use for producing polyether alcohols. US 6362126. Mar 26, (2002).

Google Scholar