Abstract: The present invention is a device for sterilizing microorganisms on a liquid or solid substrate. The device includes a light source for producing a continuous light and an optical device positioned proximate the light source. The optical device is configured to focus the light generated by the light source to provide a continuous high intensity light output. The optical device also includes a dichroic reflector. The dichroic reflector is configured to pass thermal energy generated by the light source and reflect the light produced by the light source. The device also includes a power supply, where the power supply is coupled to the light source and the optical device. The device thereby killing microbial organisms presented within the range of the continuous high intensity light output.

Abstract: A method of producing attenuated cells for a mammalian vaccine comprising killing or attenuating the cells with a high energy, low heat UV light.

Abstract: The device is a tumbler which provides a high energy UV light with low or no heat suitable for disinfecting objects, especially heat sensitive objects.

Abstract: A method of producing attenuated cells for a mammalian vaccine comprising killing or attenuating the cells with a high energy, low heat UV light.

Abstract: Present device is a cabinet which produces a low/no heat high energy UV beam for disinfecting heat sensitive or non-heat sensitive items.

Abstract: A method of killing cancer cells quickly without damaging cell structures and doing little or no damage to surrounding tissue. A high energy UV light with little to no heat is utilized.

Abstract: A method of producing attenuated cells for a mammalian vaccine comprising killing or attenuating the cells with a high energy, low heat UV light.

Abstract: A method of producing attenuated cells for a mammalian vaccine comprising killing or attenuating the cells with a high energy, low heat UV light.

Abstract: The present invention is a device for sterilizing microorganisms on a liquid or solid substrate. The device includes a light source for producing a light and an optical device positioned proximate the light source. The optical device is configured to focus the light generated by the light source to provide a high intensity light output. The optical device also includes a dichroic reflector. The dichroic reflector is configured to pass thermal energy generated by the light source and reflect the light produced by the light source. The device also includes a power supply, where the power supply is coupled to the light source and the optical device. The device thereby killing microbial organisms presented within the range of the high intensity light output.

Abstract: The present invention is a device for sterilizing microorganisms on a liquid or solid substrate. The device includes a light source for producing a light and an optical device positioned proximate the light source. The optical device is configured to focus the light generated by the light source to provide a high intensity light output. The optical device also includes a dichroic reflector. The dichroic reflector is configured to pass thermal energy generated by the light source and reflect the light produced by the light source. The device also includes a power supply, where the power supply is coupled to the light source and the optical device. The device thereby killing microbial organisms presented within the range of the high intensity light output.

Abstract: The present invention is a device for sterilizing microorganisms on a liquid or solid substrate. The device includes a light source for producing a light and an optical device positioned proximate the light source. The optical device is configured to focus the light generated by the light source to provide a high intensity light output. The optical device also includes a dichroic reflector. The dichroic reflector is configured to pass thermal energy generated by the light source and reflect the light produced by the light source. The device also includes a power supply, where the power supply is coupled to the light source and the optical device. The device thereby killing microbial organisms presented within the range of the high intensity light output.

Abstract: The present invention is a device for sterilizing microorganisms on a liquid or solid substrate. The device includes a light source for producing a light and an optical device positioned proximate the light source. The optical device is configured to focus the light generated by the light source to provide a high intensity light output. The optical device also includes a dichroic reflector. The dichroic reflector is configured to pass thermal energy generated by the light source and reflect the light produced by the light source. The device also includes a power supply, where the power supply is coupled to the light source and the optical device. The device thereby killing microbial organisms presented within the range of the high intensity light output.

Abstract: The present invention is a device for sterilizing microorganisms on a liquid or solid substrate. The device includes a light source for producing a light and an optical device positioned proximate the light source. The optical device is configured to focus the light generated by the light source to provide a high intensity light output. The optical device also includes a dichroic reflector. The dichroic reflector is configured to pass thermal energy generated by the light source and reflect the light produced by the light source. The device also includes a power supply, where the power supply is coupled to the light source and the optical device. The device thereby killing microbial organisms presented within the range of the high intensity light output.

Abstract: In a method and apparatus for securing engagement between fastening components of a pre-fastened garment upon initial assembly thereof, the fastening components are arranged by the apparatus in at least partially opposed relationship with each other and then engaged with each other to define an engagement seam. The garment is then mechanically handled by the apparatus to subject the engagement seam to a shear stress to promote increased engagement between the fastening components during initial assembly of the garment.

Abstract: A method for formulating a cleaning composition, wherein the cleaning composition comprises a water-soluble organic solvent, an ionic surfactant, a nonionic surfactant, a chelating agent, and distilled water.

Abstract: A method for formulating a cleaning composition for use in cleaning surfaces, wherein the cleaning composition comprises a water-soluble organic solvent, an ionic surfactant, a nonionic surfactant, a chelating agent, and distilled water.

Abstract: A method for positioning side panels during manufacture of a pant includes positioning the side panels within fluid flow devices. The side panels can move parallel or perpendicular to a pant transport plane as the pant is transported in the machine direction and the side panels reside within the fluid flow devices. The side panels can include refastenable fastening components. The method and apparatus can move the fastening components closer together in the cross-machine direction while the side panels reside within the fluid flow devices.

Abstract: A process for making prefastened and refastenable garments includes providing a plurality of discrete articles with mating fastening components disposed in the waist regions. First fastening components are separated from one another by an initial transverse distance. The waist region containing the first fastening components is modified to transversely displace these fastening components to a post displacement distance that is not equal to the initial distance. The process allows for convenient alignment of the fastening components to form refastenable seams.

Abstract: In a method and apparatus for securing engagement between fastening components of a pre-fastened garment upon initial assembly thereof, the fastening components are arranged by the apparatus in at least partially opposed relationship with each other and then engaged with each other to define an engagement seam. The garment is then mechanically handled by the apparatus to subject the engagement seam to a shear stress to promote increased engagement between the fastening components during initial assembly of the garment.

Abstract: A method for positioning side panels during manufacture of a pant includes positioning the side panels within fluid flow devices. The side panels can move parallel or perpendicular to a pant transport plane as the pant is transported in the machine direction and the side panels reside within the fluid flow devices. The side panels can include refastenable fastening components. The method and apparatus can move the fastening components closer together in the cross-machine direction while the side panels reside within the fluid flow devices.