Abstract: A carrier (1) for the simultaneous measurement of sealing temperature, sealing time and sealing force in a primary packaging line for ophthalmic lenses comprises a temperature sensing plate (2), a force sensing plate (3), and a supporting plate (4). Temperature sensing plate (2) is arranged atop force sensing plate (3), which is arranged atop supporting plate (4).

Abstract: An apparatus for dispensing a liquid into one or more cavities of one packaging shells for ophthalmic lenses, comprises a dispenser block, a dispenser head separate from the dispenser block. The apparatus further comprises one or more tubes connecting the dispenser block and the dispenser head. Additionally, the dispenser block comprises a reservoir for the liquid to be dispensed, and one or more dosing pumps for conveying the liquid from the reservoir to the dispenser head. The dispenser head comprises one or more dispensing tips detachably arranged on the dispenser head, each of the dispensing tips being in fluid communication with the dispenser block by a separate one of the one or more tubes.

Abstract: An apparatus for thermally bonding together a cover film of an ophthalmic lens package and a base part of the package, including a carrier for supporting the base part with film arranged thereon; a bonding unit above the carrier having a mounting plate with a bonding stamp extending therefrom, the bonding stamp having a mounting portion fixedly attached to the mounting plate, a bonding head arranged beneath the mounting portion with a heatable bonding contour on a side of the bonding head facing the carrier, and an articulated connector arranged between and connecting the mounting portion and the bonding head; and an actuator for performing movement of the carrier and the bonding stamp towards and away from each other for thermally bonding the film with the base part by pressing the heated bonding contour against the film and subsequent separation of the bonding head from the cover film bonded to the base part, the articulated connector being a cardanic joint with two rotational axes.

Abstract: A treatment container (1) for accommodating an ophthalmic lens (2) comprises a bottom (3), a side wall (4) surrounding the bottom (3) and together with the bottom (3) forming a cavity (5) for accommodating the ophthalmic lens, a container opening (6) arranged opposite to the bottom (3), and a fluid opening (7) arranged in the bottom (3) or in the side wall (4) of the treatment container (1). The fluid opening (7) is in fluid communication with the cavity (5). The treatment container (1) further comprises a fluid conveyance channel (8) and a supply connector (9). The fluid conveyance channel (8) is connected to the fluid opening (7) so as to be in fluid communication with the fluid opening (7).

Abstract: An apparatus for thermally bonding together a cover film of an ophthalmic lens package and a base part of the package, including a carrier for supporting the base part with film arranged thereon; a bonding unit above the carrier having a mounting plate with a bonding stamp extending therefrom, the bonding stamp having a mounting portion fixedly attached to the mounting plate, a bonding head arranged beneath the mounting portion with a heatable bonding contour on a side of the bonding head facing the carrier, and an articulated connector arranged between and connecting the mounting portion and the bonding head; and an actuator for performing movement of the carrier and the bonding stamp towards and away from each other for thermally bonding the film with the base part by pressing the heated bonding contour against the film and subsequent separation of the bonding head from the cover film bonded to the base part, the articulated connector being a cardanic joint with two rotational axes.

Abstract: A method for thermally bonding together a cover film (3) of an ophthalmic lens package (1) and a base part (2) of the ophthalmic lens package (1), such as a contact lens package, in particular a soft contact lens package, including the steps of providing a package holder (9) supporting a base part (2) and a cover film (3) arranged thereon, the base part (2) comprising a depression (4) containing an ophthalmic lens (5) immersed in a liquid (6); mechanically pressing the cover film (3) and the base part (2) together along a bonding area (7) having a shape completely enclosing the depression (4) while applying heat to the bonding area (7), thereby thermally bonding together the cover film (3) and the base part (2) along the bonding area (7); wherein the step of providing the package holder (9) includes arranging a flexible support element (18) on an upper surface (10) of the package holder (9) to form a support area (19) corresponding in shape to and being arranged in alignment with the bonding area (7), wit

Abstract: Disclosed here are methods of determining the mass design of the resonating bar and the reaction chamber in a sonar reactor of use in upgrading Heavy Oil Feedstocks (HOFs).

Abstract: A system and process for frac water sonic treatment are disclosed. The process involve novel treatment in which frac water is cleaned to potable water standards using a proprietary sonic reactor. Treatment enable neutralization of toxins and may remove bacteria, oil, and/or heavy metals when contained in frac water. The novel treatment system includes portable and scalable equipment of design that may allow optimal economic operation to a plurality of industrial process using clean water.

Abstract: The present disclosure refers to a method for hydrocarbon recovery from a variety of oil spills, using a proprietary sonic treatment process for removal of solids from hydrocarbon substances, to convert contaminated hydrocarbons into de-asphalted oil and heavy oil fuel output. This method may generally require a solvent for removal of material in suspension, which may dissolve contaminated hydrocarbons by using a plurality of alkane containing non polar solvents, which may be filtered through simple separation. The sonic treatment method may reduce the production time of de-asphalted oil and heavy oil fuel, from a range from about six hours up to more than ten hours to about two minutes up to 30 seconds depending on the solvent-feedstock mixture being processed.

Abstract: Disclosed here are methods of determining magnet position and distance from a resonating component in a sonic reactor of use in upgrading Heavy Oil Feedstock's (HOFs).

Abstract: A sonic reactor and resonating components for sonic reactors are disclosed; where these resonating components may have optimized mass and shape. The mass of the resonating component may be redistributed to increase the energy transmission of towards the resonance chambers and optimize the system for specific application requirements. The proper selection of the material may allow improved elasticity and lower internal damping, which may increase the amplitude at a given power and the tuning of the natural frequency; these factors may also translate on higher energy transmission towards the resonance chambers.

Abstract: An emulsification method for converting deasphalted oil and/or asphaltenes into more suitable products for market demands and utilization in self sufficient energy production treatments plants is disclosed. Asphaltenes and residues from sonication of heavy oil feedstocks, as well as de-asphalted oil, may be used in combination with water and other chemical additives for conversion into a suitable fuel which may be stored, handled, and transported.

Abstract: A system and process for solvent recovery after sonic treatment of heavy oil feedstocks is disclosed. The system avoids supercritical variations. The separation process involves solvent selection and use of a proprietary sonic reactor. The solvent recovery process may include pressure variations to solvent materials in order to obtain separation from of solvents from separated asphaltenes or deasphalted oil at high temperatures. The applied pressure variations allow the separation to occur avoiding supecritical states in the solvent materials.

Abstract: A system and process for solvent and asphaltene separation after sonic treatment of heavy oil feedstocks are disclosed. The separation process involves solvent selection and use of a proprietary sonic reactor which are paramount for the efficient operation of the whole process. The solvent and asphaltene separation system include portable and scalable equipment of design that may allow optimal recover of recyclable solvent, deasphalted oil that may be practically free of solvent and asphaltenes, and high extraction of asphaltenes in the heavy oil feedstocks processed. The system and process may enable economic operation to small to medium oil producers.

Abstract: A method for solvent selection to be used in asphaltene and de-asphalted oils (DAO) separation process is disclosed. Such process uses solvents and sonication in heavy oil, which is the main feedstock for asphaltenes and DAO's. The method may involve consideration of variety of factors that drive solvent selection. The method disclosed herein may be used as part of an algorithm or as part of a planning sequence for selecting the optimal solvent. Furthermore, the method may include considerations for using of a plurality of solvents to meet requested volume and characteristics of asphaltenes and DAO's.

Abstract: The present disclosure refers to a method for clay removal using sonication treatment process for hydrocarbon recovery from a variety of mine pits or tailing ponds, to convert contaminated hydrocarbons substances into de-asphalted oil, heavy oil fuel or asphalt output. This method may generally require a solvent for removal of material in suspension, which may dissolve contaminated hydrocarbons by using a plurality of alkane containing non polar solvents, which may be filtered through simple separation. The sonication treatment process may reduce the production time of de-asphalted oil and heavy oil fuel, from a range from about six hours up to more than ten hours to about 5 seconds to 2 minutes depending on the solvent-feedstock mixture being processed.

Abstract: A process for the automatic manufacturing of different toric optical lenses having a front surface and a rear surface having a predetermined rotational orientation relative to one another, and with at least one of the front and rear surfaces having a toric portion, comprises forming a first toric lens by: introducing a starting material into a lens mold (3) comprising a male mold half (30) and a female mold half (31) defining a mold cavity between the shaping surfaces of the male and female mold halves, the shaping surfaces being arranged at a first rotational position relative to one another and at least one of them being toric, and curing the starting material in the mold cavity to form the first toric lens.

Abstract: A process for the automatic manufacturing of different toric optical lenses having a front surface and a rear surface having a predetermined rotational orientation relative to one another, and with at least one of the front and rear surfaces having a toric portion, comprises forming a first toric lens by: introducing a starting material into a lens mold (3) comprising a male mold half (30) and a female mold half (31) defining a mold cavity between the shaping surfaces of the male and female mold halves, the shaping surfaces being arranged at a first rotational position relative to one another and at least one of them being toric, and curing the starting material in the mold cavity to form the first toric lens.

Abstract: A printing station for producing a layer of coloring for a contact lens, comprising a transport system to carry and transport a molding tool which comprises at least one contact lens forming mold, a pad unit comprising at least one pad, and a blade unit suitable to carry and ink a cliché with an ink. When in use the pad transfers an inked image from the cliché to the contact lens forming mold. The printing station further at least partially cures the inked image after it has been transferred to the mold and cleans the pad.

Abstract: A method comprises the steps of (a) providing a water based ink in at least one cliché with a contact lens pattern; (b) transferring the water based ink from the cliché to at least a surface of at least a contact lens forming mold by means of at least a transfer pad; (c) at least partially curing the ink transferred on the mold to form a colored film; (d) dispensing a hydrogel lens-forming material into a lens-forming cavity of the mold; and (e) curing the lens-forming material within the lens-forming cavity to form the contact lens, whereby the colored film detaches from the molding surface and becomes integral with the body of the contact lens; characterized in that the relative air humidity in the immediate vicinities of the transfer pad/s is kept higher than 50% at standard temperature and pressure conditions during ink transfer.