A working machine causes a working mechanism to install, on a workpiece, a storing-target body stored in a tape. The working machine includes: a storing-target-body supply device that supplies the storing-target body stored in the tape to the working mechanism; and a drive device that gives a drive force to the storing-target-body supply device. The storing-target-body supply device includes a supply-reel storage that stores a supply reel around which the tape storing the storing-target body is wound, a tape feed mechanism that unwinds the tape from the supply reel so as to feed the storing-target body to a predetermined supply position, and a drive transmitting mechanism that transmits, to the tape feed mechanism, the drive force given from the drive device.

A coil component includes a core including a winding core portion and a first flange portion, a first wire and a second wire that are wound around the winding core portion in the same direction, and a first terminal electrode that is disposed on the first flange portion and that is connected to a first end portion of the first wire. The shape of an outer edge of the first terminal electrode includes a convex curve.

A component mounting device includes a heater unit which heats along a range which is narrower than a movement range of a head and which is a partial length of a board, in which the head is controlled to mount components onto the board using a heating range of the heater as a mounting range, the board is conveyed to shift the mounting range every time mounting of components in the mounting range is completed such that an unmounted range in which components are not mounted on the board becomes the mounting range, and components are mounted in a new mounting range.

An integrated circuit package comprising a first substrate having a cavity; a second substrate; and one or more semiconductor device(s) and/or passive component (s) are coupled to the second substrate. The cavity is formed using two opposite side walls of the first substrate where two opposite sides of the cavity are kept open, the one or more semiconductor device(s) and/or passive component(s) is/are electrically coupled using redistribution layers, and the second substrate is located inside the cavity of the first substrate.

The mounting device comprises: a mounting head, having a pickup member picking up a component, which moves and places the component at a placement position by picking up the component with the pickup member from a supply section having a holding member holding the component; an imaging section configured to image the component held by the mounting head; and a control section configured to execute: a first placement process in which the component is picked up by the mounting head, positional deviation is corrected based on imaging results of the component captured by the imaging section, and the component is placed at the placement position, and a second placement process in which the component is placed at the placement position by omitting the imaging process by the imaging section at the mounting head when the positional deviation is within a predetermined allowable range.

Methods and systems for stacking multiple chips with high speed serializer/deserializer blocks are presented. These methods make use of Through Via (TV) to connect the dice to each other, and to the external pads. The methods enable efficient multilayer stacking that simplifies design and manufacturing, and at the same time, ensure high speed operation of serializer/deserializer blocks, using the TVs.

A component mounting machine includes a tool station and a determination section. The tool station detachably accommodates a holding member including a main body section which can hold a component to be mounted on a board and multiple identification sections which can identify multiple accommodation angles. The determination section determines an angle difference in which the accommodation angle of the holding member differs from a predetermined accommodation angle. At least one identification section of the multiple identification sections is defined as a first identification section, the at least one identification section being exposed when the accommodation angle of the holding member is the predetermined accommodation angle in a close state in which the multiple identification sections are partially covered by a shielding member. When the determination section cannot recognize the first identification section in the close state, the determination section attempts to recognize a second identification section.

A system for applying materials to components generally includes a tool operable for transferring a portion of a material from a supply of the material to a component. The tool may include a resilient material configured for tamping the portion of the material onto the component and imprinting the portion of the material for release and transfer from the supply.

A flip-chip bonding device and method are disclosed. The bonding device includes: a supply unit (10) for separating a flip-chip (200) from a carrier (100) and providing the flip-chip (200), the supply unit (10) including flipping device (11); a transfer unit (20) for receiving the flip-chip (200) from the flipping device (11); a position adjustment unit (30) for adjusting the positions of flip-chips (200) on the transfer unit (20); a bonding unit (40) for bonding the flip-chips (200) on the transfer unit (20) onto a substrate (400); a transportation unit (50) for transporting the transfer unit (20); and a control unit (60) for controlling the movement of the preceding units. The transfer unit (20) is capable of receiving multiple flip-chips (200) and allows the flip-chips (200) to be bonded simultaneously. This can result in savings in bonding time and an improvement in throughput. Moreover, during the transportation of the transfer unit (20), the positions of the flip-chips (200) thereon can be adjusted by the position adjustment unit (30), thereby ensuring high positional accuracy of the flip-chips (200) in the subsequent bonding step. As a result, a high-accuracy bonding can be achieved.

A method for replacing an element of a display device includes: forming a structure with a first liquid layer between a first micro device and a conductive pad of a substrate in which the first micro device is gripped by a capillary force produced by the first liquid layer; evaporating the first liquid layer such that the first micro device is bound to the substrate; determining if the first micro device is malfunctioned or misplaced; removing the first micro device when the first micro device is malfunctioned or misplaced; forming an another structure with a second liquid layer between a second micro device and the conductive pad of the substrate in which the second micro device is gripped by a capillary force produced by the second liquid layer; and evaporating the second liquid layer such that the second micro device is bound to the substrate.