초록 ▼

A system for removing particulates and/or contaminants, including impure compounds and elements from fluid to be treated is provided. The systems can include a receptacle having chamber in which a volume of fluid may be accommodated, a cover for placement across an opening into the chamber, so as to

A system for removing particulates and/or contaminants, including impure compounds and elements from fluid to be treated is provided. The systems can include a receptacle having chamber in which a volume of fluid may be accommodated, a cover for placement across an opening into the chamber, so as to prevent fluid from within the chamber from spilling, and a porous matrix, positioned within the chamber and having a nanostructured adsorption material for trapping and retaining, within its pores, particles and contaminants in the fluid. A method for removing particulates and contaminants is also provided.

대표청구항 ▼

What is claimed is: 1. A system for purification of fluid, the system comprising: a receptacle; a chamber situated within the receptacle and into which a volume of fluid to be treated may be placed; and a porous matrix, positioned within the chamber, having a plurality of nanoscaled pores dispersed

What is claimed is: 1. A system for purification of fluid, the system comprising: a receptacle; a chamber situated within the receptacle and into which a volume of fluid to be treated may be placed; and a porous matrix, positioned within the chamber, having a plurality of nanoscaled pores dispersed therein, such that fluid having particulates and/or contaminants flowing across one surface of the matrix flows back out along the same surface of the matrix substantially without the particulates and contaminants; wherein the nanoscaled pores of the porous matrix are dispersed between a fluid contact surface across which fluid may flow and a substantially fluid impermeable surface, such that fluid flowing across the contact surface into the pores of the matrix flows back out along the contact surface. 2. A system as set forth in claim 1, wherein the matrix is embedded within walls of the chamber with the surface across which fluid flows exposed to the fluid within the chamber. 3. A system as set forth in claim 1, wherein the porous matrix is adhered to the chambers with the surface across which fluid flows exposed to the fluid within the chamber. 4. A system as set forth in claim 1, wherein the porous matrix comprises a loose mass macro particles within the chamber, the macro particles having a fluid impermeable core. 5. A system as set forth in claim 1, wherein the porous matrix comprises a substantially cylindrical tube having a fluid impermeable interior surface. 6. A system as set forth in claim 1, wherein the porous matrix is adhered to the chamber walls at a bottom end of the chamber so that the surface across which fluid flows is exposed to the fluid within the chamber. 7. A system as set forth in claim 1, further including a sensor for detecting the amount of particulates removed from the fluid. 8. A system as set forth in claim 1, further including a sensor for warning the user when the porous matrix approaches its capacity to trap and retain particulates therein. 9. A system as set forth in claim 8, wherein the sensor can display the amount of particulates removed from the fluid. 10. A porous matrix for purification of a fluid, the matrix comprising: a nanostructured adsorption body having a contact surface across which fluid may flow; a fluid impermeable layer positioned on a surface opposite the contact surface; and a plurality of nanoscaled pores interspersed between the contact surface and the fluid impermeable layer; wherein fluid having particulates and/or contaminants flowing across the contact surface into the pores subsequently flows back out along the contact surface substantially without the particulates and contaminants. 11. A porous matrix as set forth in claim 10, wherein the nanoscaled pores are arranged in distinct layers according to size range. 12. A porous matrix as set forth in claim 11, wherein the nanoscaled pores in each layer get successively smaller in size, moving from the layer immediately adjacent the contact surface to the layer immediately adjacent the fluid impermeable layer. 13. A porous matrix as set forth in claim 10 further including a content of silver or silver compound distributed within the pores to minimize microbial growth within the matrix. 14. A method for purification of a fluid, the method comprising: providing a receptacle having a chamber for accommodating fluid to be treated; placing, within the chamber, a porous matrix having a plurality of nanoscaled pores dispersed between a fluid contact surface and a fluid impermeable surface, such that fluid having particulates and/or contaminants flowing across the fluid contact surface of the matrix flows back out along the same fluid contact surface of the matrix substantially without the particulates and/or contaminants; introducing fluid to be purified into the chamber; facilitate fluid flow within the chamber so that the fluid flows across the fluid contact surface of the porous matrix and into the pores; and allowing the particles and/or contaminants in the fluid to be trapped within the pores. 15. A method as set forth in claim 14, further including determining the amount of particulates and/or contaminants removed from the fluid. 16. A method as set forth in claim 14, further including notifying the user when the porous matrix approaches its capacity for trapping and retaining particulates and/or contaminants therein. 17. A method as set forth in claim 14, further including replacing the porous matrix when the matrix approaches its capacity for trapping and retaining particulates and/or contaminants therein. 18. A method as set forth in claim 14, further disposing the receptacle along with the porous matrix when the matrix approaches its capacity for trapping and retaining particulates and/or contaminants therein. 19. A kit for use in removing particulates from a fluid, the kit comprising: a receptacle having a chamber for accommodating therein fluid to be treated; and a porous matrix for placement within the chamber of the receptacle, the matrix having a plurality of nanoscaled pores dispersed between a fluid contact surface and a fluid impermeable surface, such that fluid having particulates and/or contaminants flowing across the fluid contact surface of the matrix flows back out along the same fluid contact surface of the matrix substantially without the particulates and/or contaminants.