New Product
DurA Cycle A50
Driving innovation and performance while
reducing cost of goods.
DurA Cycle A50
Driving innovation and performance while
reducing cost of goods.
Como líder global em tecnologia de resina, desenvolvemos e fabricamos pequenos grânulos que são usados nas indústrias mais regulamentadas do mundo para separar, remover ou recuperar elementos e compostos muito específicos.
Saber maisCom 40 anos de experiência em fabricação e 30 anos de experiência regulatória, fornecemos tecnologias líderes de separação, purificação e extração para apoiar aplicações de cromatografia e biocatálise em saúde e ciências da vida.
(Atualmente apenas em inglês)
Somos líderes mundiais em tecnologia de separação, purificação e extração baseada em resina, que fornece soluções sustentáveis para nosso meio ambiente, negócios e saúde.
Learn MoreIon Exchange Resins in Corn Sweetener Refining
Nosso suporte técnico sempre pronto e equipes de serviço vão além para ser seu recurso mais confiável. Estamos aqui para ajudá-lo.
Starch hydrolyzate plants around the world are utilizing high surface area synthetic adsorbents to replace granular and powdered activated carbon for removal of color, taste, odor, HMF (hydroxymethylfurfural) and other impurities from sweetener solutions. The Macronet™ line of chemically regenerated styrenic adsorbents offers economic, aesthetic, purity and ease of process advantages for replacing carbon in the production of bottler’s quality syrup.
Purolite adsorbents for corn sweetener refining and improving corn sweetener quality include:
Organic impurities are attracted and held to adsorbents by surface energies such as Van der Waals forces. Since adsorption is a surface phenomenon, the Macronet adsorbents are manufactured with large surface area in the range of 800-1100 square meters/gram. But molecules are three dimensional and not flat, so it is important for the surface area to conform to the molecular size of the impurities being adsorbed for the collective surface energy to be large enough to retain them. Thus, the surface area must be employed in micropores which are small enough to form an “adsorption cavity.”
Most of the surface area of Macronet adsorbents are contained in adsorption cavities of less than 20 Angstroms diameter. Macronet also contains a significant population of large transport pores which facilitate rapid diffusion from the bulk fluid into the microporous region where adsorption occurs.
The hydrophobic styrene/divinylbenzene matrix of the Macronet will readily adsorb nonpolar hydrophobic impurities. Since many of the impurities are polar or even ionizable molecules, the presence of hydrophilic ion exchange functional groups on the matrix improves the range of impurities which can be removed by attracting more hydrophilic compounds. The hydrophilic functional groups also improve the ease of regeneration of the adsorbent.
Macronet Operating Options
A. Color Adsorber for Non-demineralized Syrups
Macronet MN152 replaces conventional carbon powdered treatment of glucose syrups. Expensive and dirty powdered carbon and carbon filters are replaced with a simple chemically regenerated unit operation which produces no solid discharge to handle.
B. Taste and Odor Polishing
The primary and secondary ion exchange pairs remove the vast majority of impurities, leaving the MN500 available to remove the difficult taste and odor impurities and polish the color even further.
C. Color, Taste and Odor Polishing
A layered bed of MN152 over MN502 offers improved color and heat color removal in addition to taste and odor polishing.
D. Color, Taste and Odor Polishing with Enhanced pH and Conductivity Stability
The layered bed of MN152 over MN502 is air mixed prior to service to offer mixed bed quality pH and conductivity.
E. Color, Taste and Odor Polishing with Enhanced pH Stability
A layered bed of MN152 over a weak acid cation resin is air mixed prior to service to offer better pH stability.
Service and Regeneration Sequence for Macronet™ MN102, MN152 or MN502 | ||||||
---|---|---|---|---|---|---|
Step | Solution | Temp (°C) | Flow (BV/hr) | Volume (BV) | Time (min) | Comments |
Service | Syrup | 40-60 | 2-5 | 30-200 | Variable | Downflow |
Sweeten Off | Demineralized water or condensate | 40-60 | 2-5 | 2 | Variable | Downflow |
Backwash1 | Demineralized water or condensate | 30-60 | 2.5-3.7 gpm/ft2 of vessel area | 1.5-2.0 | 30 | Upflow 50% expansion |
NaOH In2 | 1N NaOH | 40-60 | 1 | 1.5 | 90 | Downflow |
Slow Rinse | Demineralized water or condensate | 40-60 | 2 | 2 | 60 | Downflow |
HCl In3,4 | 0.1N HCl | 40-60 | 2 | 3 | 90 | Upflow |
Slow Rinse | Demineralized water or condensate | 40-60 | 2 | 2 | 60 | Upflow |
Fast Rinse5 | Demineralized water or condensate | 40-60 | 4 | 4 | 60 | Downflow |
Sweeten On | Syrup | 40-60 | 2-5 | 1 | Variable | Downflow |
1For MN502, the backwash flow rate should be increased to 6.0 gpm/ft2
2For HMF removal, the temperature should be increased to 110 °C and the first 1 BV is allowed to soak for 2 hours.
3For MN502 regeneration, the HCl concentration should be increased to 0.3 N.
4For a 1/3 MN102 or MN152 and 2/3 MN502 layered bed, the HCl concentration should be increased to 0.2 N.
5For mixed bed operation, an air mix follows the fast rinse.
Remoção de Cor, Sabor e Odor - Soluções Adoçantes
Purolite.com uses cookies to give you the best possible experience. By using Purolite.com, you consent to our use of cookies. If you do not wish to receive our cookies, adjust your browser settings. Read our Cookies Policy to learn more.