Disclosed herein is a dispensing head that includes a motor, an air pump operably connected to and powered by the motor, and a first spindle connected to the air pump. The air pump is configured to create airflow in the first spindle. Further disclosed is a method of creating airflow in a dispensing head, and an assembly machine system having a dispensing head.

A component mounting device includes a mounting head that mounts a component at a mounting position on a substrate, an imaging unit capable of imaging the mounting position from a plurality of fields of view, imaging directions of which are different from each other, and a controller that selects a success or failure determination field of view used for success or failure determination of whether or not the component has been mounted at the mounting position from the plurality of fields of view according to a state of a shield around the mounting position.

An assembly machine includes a plurality of track modules, each track module including a section of track, the plurality of track modules connectable to form a continuous circuitous track, the continuous circuitous track configured to receive a dispensing head, the dispensing head configured to rotate about the continuous circuitous track and at least partially assemble an unfinished product. The machine includes a first feeder module attached to a first length of the continuous circuitous track configured to feed a component to the dispensing head, and a first placement module attached to a second length of the continuous circuitous track configured to receive the unfinished product. The dispensing head is configured to place the component on the unfinished product. The assembly machine is reconfigurable by attaching or removing one or more of the plurality of track modules, the first feeder module and the first placement module.

A component mounting machine includes a feeder device that has a tape feeding mechanism that feeds out a carrier tape that stores components in respective component storage sections, and a tape peeling mechanism that has a tape peeling blade that carries out peeling, and a component transfer device that has a mounting head that holds a suction nozzle, and a head driving mechanism, the component mounting machine further provided with a peeling start determination section of determining whether or not the peeling starts before the suction nozzle starts a suction operation, and a recovery function section of carrying out a recovery operation in which the recovery function section returns the leading end of the carrier tape temporarily to the front of the tape peeling blade and feeds out the carrier tape again in a case where it is determined that peeling is not started.

A feeder device including a tape feeding mechanism which feeds out a carrier tape which stores components in corresponding multiple component storage sections and a cover tape which is adhered to the bottom tape and covers the component storage sections, and a tape peeling mechanism which includes a tape peeling blade which proceeds between the bottom tape and the cover tape as the carrier tape is fed out to perform peeling, the feeder device supplying the components from the component storage sections at a component supply position, and the feeder device further including a feed speed determination section which determines the feed speed at a peeling start time at which a leading end of the carrier tape comes into contact with the tape peeling blade according to at least one of properties of multiple types of carrier tape and characteristics of the components which are stored.

A component mounter includes a side; imaging camera that is provided to be integral with the placing head having a plurality of suction nozzles, that moves relatively with respect to the plurality of suction nozzles, and thereby that images, from a side, peripheral regions of front ends of the plurality of suction nozzles, respectively, in order. Incidentally, a component presence/absence determiner (determiner) determines the presence or absence of a component, sucked on the front end of the suction nozzle, based on primary image data obtained by the side imaging camera and the calculator calculates a thickness of the component sucked on the front end of the suction nozzle, based on secondary image data obtained by the side imaging camera.

A method for manufacturing a liquid ejection head includes joining a support member to a print element substrate using another member to which the print element substrate is attached. The other member has a suction region to be held at the time of being attached to the support member.

A component mounting device includes a heater unit which heats a range which is narrower than a movement range of a head which is a partial range of a board using a heater, 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.

A working apparatus includes a component holder that holds a component and mounts the component at a predetermined position of a work. In the working apparatus, the component holder that holds a component is configured to include a pair of grip members that pinch and grip the component, a grip member opening/closing portion that opens and closes the pair of grip members with an opening/closing motor as a drive source, a pair of contact portions that are disposed on the pair of grip members and freely rotate around a rotary shaft provided in an opening/closing direction of the grip member, and a contact portion driving portion that causes a roller, which is provided to be in contact with a side of a nozzle shaft, to convert a lifting and lowering motion of a nozzle shaft into a rotational motion of a spline shaft, and that causes the rotational motion to be transmitted to the contact portion via a plurality of rollers such that the contact portion rotates around the rotary shaft.

An apparatus for installing and removing glass panels and methods of using the apparatus are disclosed. The apparatus includes a base portion, a back support structure secured to the base portion, and a glass adjustment system moveably coupled to the back support structure. Methods for using the apparatus to install and remove glass panels from, for example, ice rink boards, are also disclosed.