A positioning jig assembly includes a positioning main body with holes into which electronic component bodies are respectively press-fit, a first and a second guide bodies disposed to be superimposed on the positioning main body in a planar view. First through-holes are formed in the first guide body. Second through-holes formed in the second guide body guide the electronic component main bodies to the first through-holes. The first through-holes provisionally position the electronic component main bodies. When height in the first direction of the electronic component main bodies is represented as H, lengths of the first through-hole and the second through-hole are respectively represented as L1 and L2, and depth of the hole is represented as D, L1<H<D+L1+L2 and D<H hold.

A positioning jig assembly includes a positioning main body with holes into which electronic component bodies are respectively press-fit, a first and a second guide bodies disposed to be superimposed on the positioning main body in a planar view. First through-holes are formed in the first guide body. Second through-holes formed in the second guide body guide the electronic component main bodies to the first through-holes. The first through-holes provisionally position the electronic component main bodies. When height in the first direction of the electronic component main bodies is represented as H, lengths of the first through-hole and the second through-hole are respectively represented as L1 and L2, and depth of the hole is represented as D, L1<H<D+L1+L2 and D<H hold.

A pre-press process includes a first step for bonding a first end portion of each of a plurality of electronic component bodies to a bonding surface of a flat plate material disposed in a jig, a second step for moving the jig relative to a surface plate, a third step for bringing a second end portions of each of the plurality of electronic component bodies into contact with the surface plate while the flat plate material is in a softened state so that the flat plate material is deformed to align respective positions of end surfaces of the second end portions, a fourth step for curing the flat plate material, and then a fifth step for moving the jig relative to the surface plate to separate from the surface plate the plurality of electronic component bodies in which the respective positions of the end surfaces are aligned.

A pre-press process includes a first step for bonding a first end portion of each of a plurality of electronic component bodies to a bonding surface of a flat plate material disposed in a jig, a second step for moving the jig relative to a surface plate, a third step for bringing a second end portions of each of the plurality of electronic component bodies into contact with the surface plate while the flat plate material is in a softened state so that the flat plate material is deformed to align respective positions of end surfaces of the second end portions, a fourth step for curing the flat plate material, and then a fifth step for moving the jig relative to the surface plate to separate from the surface plate the plurality of electronic component bodies in which the respective positions of the end surfaces are aligned.

A drum coater device (10) for coating tablets, comprising a mixing drum (18) which can be rotated about an axis of rotation (20) and which has an interior (24) for arranging a tablet batch to be coated, further comprising a spraying device for introducing a coating material into the interior, wherein the mixing drum has a hollow-cylindrical, perforated wall which delimits at least part of the interior of the mixing drum, wherein mixing elements for mixing the tablets of a tablet batch are arranged on the inner side, which faces the interior, of the wall, wherein pairs (36) of mixing elements (34a, 34b) form legs which are oriented with respect to one another in a V shape, wherein the distance between the legs of a pair widens from a central annular region, as seen along the axis of rotation, of the wall in the direction of lateral annular regions adjacent to the central annular region.

A drum coater device (10) for coating tablets, comprising a mixing drum (18) which can be rotated about an axis of rotation (20) and which has an interior (24) for arranging a tablet batch to be coated, further comprising a spraying device for introducing a coating material into the interior, wherein the mixing drum has a hollow-cylindrical, perforated wall which delimits at least part of the interior of the mixing drum, wherein mixing elements for mixing the tablets of a tablet batch are arranged on the inner side, which faces the interior, of the wall, wherein pairs (36) of mixing elements (34a, 34b) form legs which are oriented with respect to one another in a V shape, wherein the distance between the legs of a pair widens from a central annular region, as seen along the axis of rotation, of the wall in the direction of lateral annular regions adjacent to the central annular region.

The present invention relates to a method for coating a component of a turbomachine in a bath, in which method, the component is partially immersed in the bath containing a coating material; the component is rotated at least intermittently around an axis of rotation, which lies outside of the bath, during the at least partial immersion; the component is at most immersed partially over and beyond the rotation.

A coating frame, a coating system, and methods of coating a component using one or more coating frames are disclosed. The coating frame includes a frame member and at least one bracket coupled to the frame member. The bracket includes at least one hanger attachment point extending into a hollow interior of the at least one bracket. The at least one bracket isolates the at least one hanger attachment point from a coating material when the coating frame is used in a coating process. The method includes suspending a component from the coating frame, conveying the coating frame and the component to a coating applicator, and applying a coating material to the coating frame and the component while isolating the at least one hanger attachment point from the coating material via an air pocket formed within the at least one bracket.

A breading and sifting apparatus is disclosed. The breading and sifting apparatus may include a frame, a plate, and a breading lug adapter. The breading and sifting apparatus may be configured to accommodate work surface in a lowered position and in an elevated position, as well as in a left-handed configuration and a right-handed configuration.

Lens holding device holding an optical lens at its edge during a dip coating in a dip coating bath. First elastic lens holder having first lens edge holder holds the optical lens at a right edge of the optical lens, second elastic lens holder with second lens edge holder holds the optical lens at a left edge of the optical lens, and a circumferential frame with a third lens edge holder holds the optical lens at a lower edge of the optical lens. The circumferential frame has first and second lateral frame portions such that when the lens holder is raised out of the dip coating bath, waves caused at a surface of the dip coating bath are damped by the right or left lens edge holder, respectively.