A processing apparatus includes a delivery unit for delivering a workpiece between a cassette placed on a cassette rest and a chuck table and a measuring unit for measuring a thickness of the workpiece. The delivery unit includes a base having a non-contact-type suction holder for ejecting air to develop a negative pressure to attract and hold the workpiece under suction out of contact therewith, and a moving unit for moving the base. The height of the non-contact-type suction holder is adjusted according to the thickness of the workpiece measured by the measuring unit to place the non-contact-type suction holder in a position that is spaced from a face side of the workpiece by a distance in a predetermined range while the workpiece is being delivered by the delivery unit.

There is provided a manufacturing method of a protective-component-provided workpiece. The manufacturing method of a protective-component-provided workpiece includes a step of dissolving a thermoplastic resin whose solubility parameter is equal to or higher than 8.5, in a liquid ultraviolet-curable resin, to prepare a liquid mixed resin, a step of supplying the mixed resin to a support surface of a support table to form a resin layer with a predetermined thickness, a step of irradiating the resin layer with ultraviolet rays and curing the resin layer to form a protective component with a sheet shape, and a step of heating the sheet-shaped protective component before or after one surface of the sheet-shaped protective component and one surface of the workpiece are brought into close contact with each other, and causing the sheet-shaped protective component to come into close contact with the workpiece and integrate with the workpiece.

A motor vehicle tire includes a sidewall having an inner layer of a first color and an outer layer adjacent the inner layer. The outer layer is of a second color different from the first color. The outer layer has a plurality of throughholes that visually expose the inner layer. The throughholes are in a pattern that encodes information about a history of the motor vehicle tire and/or a unique identifier

A motor vehicle tire includes a sidewall having an inner layer of a first color and an outer layer adjacent the inner layer. The outer layer is of a second color different from the first color. The outer layer has a plurality of throughholes that visually expose the inner layer. The throughholes are in a pattern that encodes information about a history of the motor vehicle tire and/or a unique identifier

A method includes forming a plurality of perforations in a ceramic mastercard by a first laser process, wherein forming the plurality of perforations includes reducing a first thickness of the ceramic mastercard to a second thickness along first predefined lines, and cutting through an entire thickness of the ceramic mastercard along a plurality of second predefined lines by a second laser process, wherein the first predefined lines and the second predefined lines overlap only partly.

A method includes forming a plurality of perforations in a ceramic mastercard by a first laser process, wherein forming the plurality of perforations includes reducing a first thickness of the ceramic mastercard to a second thickness along first predefined lines, and cutting through an entire thickness of the ceramic mastercard along a plurality of second predefined lines by a second laser process, wherein the first predefined lines and the second predefined lines overlap only partly.

A laser processing device includes an irradiation unit configured to irradiate an object with laser light, an image capturing part configured to capture an image of the object with light having transparency to the object, a display unit configured to display information, and a control unit configured to control at least the irradiation unit, the image capturing part, and the display unit. The control unit performs a first process of irradiating the object with the laser light by control of the irradiation unit to form a modified spot and a fracture extending from the modified spot in the object so as not to reach an outer surface of the object, a second process of, after the first process, capturing an image of the object by control of the image capturing part and acquiring information indicating a formation state of the modified spot and/or the fracture.

A manufacturing method for a printed circuit board includes: passing a first laser beam output from a laser output device through a first aperture so as to define an outer diameter of the first laser beam, positioning the first laser beam by an optical axis positioning device including a galvano device and an fθ lens, and irradiating the printed circuit board with the first laser beam such that a through-hole is formed in a copper layer; and passing a second laser beam output from the laser output device through a second aperture so as to define an outer diameter of the second laser beam whereby a diameter of the second aperture is smaller than a diameter of the first aperture, positioning the second laser beam by the optical axis positioning device, and irradiating the printed circuit board with the second laser beam such that an insulating layer is processed.

Presented is a cooking robot system. The system includes a housing, a pair of cooking pots, and a motion mechanism to allow each of the cooking pots to perform a movement in 3 Degrees of Freedom (DoF) along horizontal, vertical, and rotational axes. The motion mechanism includes a horizontal motion arrangement, a vertical motion arrangement, and a rotational motion arrangement. The cooking robot system further includes a pair of heating elements rotatably coupled to the rotational motion arrangement. The heating arrangements detachably engage the cooking pots for heating the cooking ingredient contained in the cooking pots. The cooking robot system further includes a stirring mechanism for stirring the contents of the cooking pots, an ingredient-holding container containing cooking ingredients, and a dispenser assembly for selectively dispensing the cooking ingredients contained within the ingredient holding container.

Presented is a cooking robot system. The system includes a housing, a pair of cooking pots, and a motion mechanism to allow each of the cooking pots to perform a movement in 3 Degrees of Freedom (DoF) along horizontal, vertical, and rotational axes. The motion mechanism includes a horizontal motion arrangement, a vertical motion arrangement, and a rotational motion arrangement. The cooking robot system further includes a pair of heating elements rotatably coupled to the rotational motion arrangement. The heating arrangements detachably engage the cooking pots for heating the cooking ingredient contained in the cooking pots. The cooking robot system further includes a stirring mechanism for stirring the contents of the cooking pots, an ingredient-holding container containing cooking ingredients, and a dispenser assembly for selectively dispensing the cooking ingredients contained within the ingredient holding container.