VISPLEX cold flow improvers (FIs) LW-TEMPERATURE SLUTINS FR FUEL HALLENGES
BST EFFIIENY WITH VISPLEX BIDIESEL LD FLW IMPRVERS (FIs) Biodiesel is a fuel composed of monoalkyl esters of long chain fatty acids derived from vegetable oil or animal fats, designated as B100. An example of the mechanism of biodiesel formation is shown in Figure 1. It is also commonly referred to as fatty acid methyl esters (FAMEs). It can be derived from different sources, such as rapeseed, soy, palm, tallow and used cooking oil. Each source also consists of a mixture of long-chain fatty acid esters, each differing in carbon chain length and degree of saturation. Thus, the biodiesel mixture can have components with a wide range of temperature properties. These properties, such as pour point (PP), cold filter plugging point (FPP), etc., are quite varied, as indicated in Figure 2. The primary negative influence on biodiesel cold flow properties comes from the crystallization of long-chain saturated fatty acid methyl esters. Failure to address this issue results in the inability to fully utilize these alternative fuels. onsequently, there is a vital need to improve these properties to meet the performance standards of current fuel specifications. FIGURE 1: hemistry of biodiesel synthesis R H H R + 3 H 3 H H H + 3 R H 3 R H 80 YEARS F HIGH-PERFRMANE FUEL AND LUBRIANT ADDITIVE SLUTINS (triglycerides) (methanol) (glycerol) (FAMEs - fatty acid methyl esters) FIGURE 2: Pour point and FPP of untreated FAMEs R= Alkyl group Pour point FPP 16 12 The il Additives specialists at Evonik are global leaders in the development of highperformance fuel and lubricant additives for use in automotive, hydraulic and industrial applications. State-of-the-art regional technology centers and manufacturing facilities linked through a global supply chain enable Evonik to reliably provide high-quality customized products and solutions to customers worldwide. Evonik s team of fuel and lubricant specialists is poised to help EMs, formulators and oil marketers get an edge and boost efficiency in a range of applications. Temperature 8 4 0-4 -8 ME RAPESEED/ ANLA ME NUT ME SY ME USED KING IL ME LARD ME PALM ME TALLW -12-16 2 3
Evonik has developed VISPLEX cold flow improvers (FIs) for biodiesel fuels. Evonik s VISPLEX FIs boost efficiency by: Reducing the old Filter Plugging Point (FPP) of biodiesel B100 from different sources such as: rapeseed methyl ester (RME), soy methyl ester (SME), palm methyl ester (PME), tallow methyl ester (TME) and used cooking oil methyl ester (UME). Enabling blends of fatty acid methyl ester (FAME) feedstocks of various costs and levels of low-temperature performance to achieve an ideal performance/cost ratio. ptimizing the FPP of blends of biodiesel with fossil diesel, meeting or exceeding required fuel specifications. FIGURE 3: VISPLEX FI effect on the FPP of PME+SME blends Temperature Temperature F 15 59 10 50 5 41-0 32-5 23-10 14 0 10 20 30 40 50 60 70 80 90 100 PME/SME blend neat % PME in blend PME/SME blend treated with 1% VISPLEX 10-330 In order to combat these issues, a customized VISPLEX cold flow improver (FI) must act at the molecular level to alter the crystallization process and crystal morphology. Therefore, the effectiveness of the FI depends on the distribution of its wax-interacting side chains along the polymer backbone. When a biodiesel blend containing an appropriate VISPLEX FI polymer is cooled, the waxy side chains of the FI co-crystallize with the waxy components in the biodiesel (see illustrations in Figure 4 below). The polymer backbone interferes with the continued growth of the crystals, rendering them smaller in size. VISPLEX FIs can effectively alter the development of the crystal matrix and extend the temperature range of biodiesel fluidity. FIGURE 4: How VISPLEX FIs modify wax crystals as temperature drops Without VISPLEX FI IMPRVE BIDIESEL PERFRMANE WITH VISPLEX LD FLW IMPRVERS FAMEs are a clear, solids-free liquid at room temperature and, upon cooling to cloud point (ASTM D2500), defined as the onset temperature of wax crystallization, the waxier components with higher melting points begin to crystallize. Upon further cooling, the waxy crystals will continue to grow, eventually becoming large and numerous enough to stop or slow down the flow of the FAME through a filter. The highest temperature for 20 ml of fuel fails to pass through a standardized filter within 60 seconds as described by the ASTM D6371 old Filter Plugging Point (FPP) test. As FAME temperature continues to decrease, crystals continue to grow in size, forming a network extending throughout the fluid that prevents it from flowing. The temperature at which the fluid ceases to flow is the Pour Point (PP), measured with the ASTM D97 method. Both FPP and PP are important for FAME producers and users to prevent plugging from cold biodiesel, which could result in engine shutdown and loss of time and money. rystallization of wax molecules below cloud point temperature With VISPLEX FI o-crystallization occurs between wax molecules and VISPLEX FI crystalline units Mainly lateral growth, forming needles or plates VISPLEX FI modifies wax crystal growth Wax crystal structure continues to grow Interlocking of wax crystals is prevented, leading to smaller and more random structure. Large, structured crystal network, diesel fuel ceases to flow No aggregation of gel-like wax network. Diesel fuel continues to flow through the filter. rystalline unit formed by wax molecules rystalline unit formed by VISPLEX FI VISPLEX Polymer backbone 4 5
Interaction of VISPLEX FIs with wax crystals resulting in low-temperature performance improvement The mechanism is illustrated in the photomicrograph of rapeseed methyl ester crystals (RME) shown in Figure 4. Temperature Nucleation rystal growth Agglomeration/gelation Non-treated crystals rystallites treated with 0.5% VISPLEX 10-305 Without FI Significant low-temperature performance improvement Improved cold flow rystalline unit formed by wax molecules rystalline unit formed by VISPLEX FI rystal size With VISPLEX FI VISPLEX Polymer backbone LW-TEMPERATURE FILTRATIN PERFRMANE, FPP In the photomicrograph above on the left, crystals in the untreated RME sample have grown to ca. 50 microns or more and are large enough to plug diesel fuel filters and fail stringent FPP requirements. The photomicrograph above and on the right represents the same sample treated with VISPLEX FI. The crystals are ca. 10 times smaller, enabling this treated biodiesel to more easily pass the FPP test and to perform satisfactorily in actual service. FIGURE 5: Significant FPP reduction with VISPLEX FI Temperature Temperature F -5-10 -15-20 -25-30 -35-35 -40-40 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 In addition to reducing wax crystal size, VISPLEX FIs can also improve low-temperature performance, demonstrated by the example in Figure 5 on the right. The figure shows a % FI -1 FPP PP significant improvement of FPP and PP of RME with only 0.3% of FI-1. At 0.5% treat rate, a substantial decrease is achieved in FPP and PP to -25 and -36, respectively. -25-30 6 7
FIGURE 7: VISPLEX Series 10 FI portfolio and selection reference High Tallow/Palm 10-340 10-530 EFFET N THE LW- TEMPERATURE STRAGE STABILITY F BIDIESEL The flow performance of biodiesel can deteriorate when stored at low temperature. Wax molecules in storage are given more time to rearrange and form stronger structures. Figure 6 shows the performance of VISPLEX FIs. Samples of treated and untreated SME were kept for three days at -5. Solidification of the untreated samples would likely pose severe problems when attempting to move the material out of a tank. Blends of Soybean methyl ester with Palm or Tallow methyl ester Soybean or Blend with UME Rapeseed/anola 10-330 10-502 10-330 10-610 10-781 10-505 10-605 10-608 10-780 + Low FPP of FAMEs Figure 6: VISPLEX FIs enhance biodiesel low-temperature storage stability 24h 72h No FI 1% FI-1 1% FI-2 8 9
anada France Germany United States hina Japan Singapore Headquarters Regional offices Technology centers Manufacturing facilities Sales offices & representatives VISPLEX FI HANDLING & APPLIATIN VISPLEX FIs should be added to fuel at temperatures well above the fuel s cloud point. The dosing can be done in-line when fuel is pumped through pipes from one tank into another, or to the loading station, or directly into a tank that can provide adequate mixing. Before dosing, please make sure the temperature of the fuel is at least 10 above its cloud point. The recommended VISPLEX FIs temperature is 40. THE IL ADDITIVES SPEIALISTS AT EVNIK - A GLBAL PRESENE Evonik s il Additives Team draws upon a robust and secure supply chain, strategically positioned worldwide. The global scale of Evonik s oil additives operations ensures uninterrupted supply, rapid and localized production and on-time delivery. Partner with the il Additives specialists at Evonik for custom formulation solutions that boost efficiency and future-proof business with a sharp competitive edge. 10 11
This information and all further technical advice is based on our present knowledge and experience. However, it implies no liability or other legal responsibility on our part, including with regard to existing third party intellectual property rights, especially patent rights. In particular, no warranty, whether express or implied, or guarantee of product properties in the legal sense is intended or implied. We reserve the right to make any changes according to technological progress or further developments. The customer is not released from the obligation to conduct careful inspection and testing of incoming goods. Performance of the product described herein should be verified by testing, which should be carried out only by qualified experts and is the sole responsibility of the customer. Reference to trade names used by other companies is neither a recommendation, nor does it imply that similar products could not be used. VISPLEX is a registered trademark of Evonik Resource Efficiency GmbH. 12/2016 EVNIK INDUSTRIES AG v10 EURPE, AFRIA, MIDEAST Evonik Resource Efficiency GmbH Kirschenallee 64293 Darmstadt Germany PHNE +49 6151 1809 FAX +49 6151 18-4100 oil-additives@evonik.com www.evonik.com AMERIAS Evonik il Additives USA, Inc. 723 Electronic Drive Horsham, PA 19044-4050 USA PHNE +1 215 706-5800 FAX +1 215 706-5801 Toll-free +1 888 876-4629 ASIA PAIFI Evonik il Additives Asia Pacific Pte. Ltd. 3 International Business Park 07-18 Nordic European entre Singapore 609927 PHNE +65 6809-6571 FAX +65 6809-6707