A method is provided for the creation of an addendum for use in the design and production of sheet metal formed components, which method uses a sectionless approach. In a preferred approach, elevation curve (EC) lines are established relating to the component (ECc) and binder (ECb), and it is these lines which are used to design the addendum. Additional EC lines (EC1, EC2, EC3, etc.) can be added to modify or optimize the addendum design. The spaces between the EC lines are filled using various parameterized filling techniques so as to provide the addendum design. Optimization of the addendum can be achieved by modification of the various EC lines, so as to modify or control the various design parameters, in accordance with various quality or design criteria. A more rapid, and less complicated approach to addendum design is provided.

Certain exemplary embodiments can provide a method comprising, via computer aided design, designing parts of an object that comprises an outer shell and an inner body, at least one of the outer shell and the inner body defining a specific volume negative space relief. In certain exemplary embodiments, the specific volume negative space relief defines a channel constructed to pass at least one of a fluid and a gas.

Methods and systems for creating a mold for a cast memorialization product are described herein. In a process for creating a mold, a three-dimensional (3D) model of a product design is generated. The product design includes customized features for a memorialization product. A mold design is generated based upon the 3D model of the product design. Printing instructions for creating the mold are generated and accessed by a processing device. The mold is created according to the printing instructions. A product, such as a bronze memorialization product, can be cast using the mold.

Methods and systems for creating a mold for a cast memorialization product are described herein. In a process for creating a mold, a three-dimensional (3D) model of a product design is generated. The product design includes customized features for a memorialization product. A mold design is generated based upon the 3D model of the product design. Printing instructions for creating the mold are generated and accessed by a processing device. The mold is created according to the printing instructions. A product, such as a bronze memorialization product, can be cast using the mold.

An apparatus for washing a set of objects. The apparatus includes a washing chamber and a ROX generator fluidically connected to the washing chamber via a fluid conduit having a distal end that terminates at the washing chamber. The ROX generator is configured to provide reactive oxidizers to a carrier liquid to form a cleaning liquid with ROX cleaning bubbles, wherein the cleaning liquid is transported through the fluid conduit and into the washing chamber.

A method for regulating a facility for processing a series of containers includes an operating phase during which a first machine for processing containers that is equipped with a number of first stations is driven in rotation, and a second machine for processing containers that is equipped with a number of second stations is driven in rotation. The facility has a transfer point from the first to the second processing machine. The operating phase includes a synchronized and paired operating step in which the synchronized rotation of the first and second machines is accompanied by a repetitive series of pairing partners at the transfer point, each pairing partner including a first station arriving at the transfer point coincidentally with a second station, enabling transfer of a container from the first station of the pairing partner to the second station of the pairing partner.

An apparatus for washing a set of objects. The apparatus includes a washing chamber and a ROX generator fluidically connected to the washing chamber via a fluid conduit having a distal end that terminates at the washing chamber. The ROX generator is configured to provide reactive oxidizers to a carrier liquid to form a cleaning liquid with ROX cleaning bubbles, wherein the cleaning liquid is transported through the fluid conduit and into the washing chamber.

An imprint apparatus includes a mold holding unit configured to hold a mold, a correction mechanism configured to correct a shape of a pattern formed in the mold to a desired shape by applying a force to the mold held in the mold holding unit, and a controller configured to assume a plurality of mold pattern shapes for a specific mold, calculate a parameter for associating the plurality of assumed mold pattern shapes and a deformation amount of the specific mold by causing the correction mechanism to apply the force to the specific mold to obtain the deformation amount of the specific mold so that the plurality of assumed mold pattern shapes are formed, and calibrate the correction mechanism using the parameter.

A method is provided for the creation of an addendum for use in the design and production of sheet metal formed components, which method uses a sectionless approach. In a preferred approach, elevation curve (EC) lines are established relating to the component (ECc) and binder (ECb), and it is these lines which are used to design the addendum. Additional EC lines (EC1, EC2, EC3, etc.) can be added to modify or optimize the addendum design. The spaces between the EC lines are filled using various parameterized filling techniques so as to provide the addendum design. Optimization of the addendum can be achieved by modification of the various EC lines, so as to modify or control the various design parameters, in accordance with various quality or design criteria. A more rapid, and less complicated approach to addendum design is provided.

Provided is an endmill (5). The maximum spindle speed, per one minute, of a main spindle to which the endmill is attached is Smax. The number of teeth of the endmill (5) is N. The outer shape of the endmill (5) is Da. The natural frequency at which vibrations at the end of the endmill (5) reach a maximum level is 1. 1 and/or N are set so that when the diameter-direction infeed amount of the endmill (5) is set to Rd: i) 160/N6<Smax, if Rd is at least 4% of Da; and ii) 160/N3<Smax, if Rd is less than 4% of Da.