A stamp head unit including: a stamp component including at least a silicone-based rubber film on a quartz glass substrate; a stamp-component-holding component including a surface having a hole for vacuum suction of a surface of the quartz glass substrate of the stamp component; and a tubular component having an evacuation suction hole connected to communicate with the hole for vacuum suction so as to maintain a vacuum, and being coupled and fixed with the stamp-component-holding component. This provides: a stamp component that can be fixed stably by a simple and convenient vacuum chuck system; a stamp head unit with which the stamp component can be replaced in a short time; and a microstructure-transfer apparatus provided with the stamp component and the stamp head unit.

A mounting apparatus for mounting a semiconductor chip on a mounting body includes a stage on which the mounting body is placed, a mounting head provided to be movable up and down above the stage and pressing the semiconductor chip against the mounting body, and a film disposition mechanism which interposes a belt-like cover film between the mounting head and the stage, and the film disposition mechanism includes a film feeding part having a feeding reel around which at least the cover film has been wound, a film recovery part having a recovery reel also winding up at least the fed cover film, and one or more relay shafts provided in the course of a path of the cover film from the feeding reel to the recovery reel and by which the cover film is folded back in order to bend a moving direction of the cover film.

A mounting shaft device comprises a spline shaft including a supply passage for air pressure that extends through a shaft hole in a support, a conduit in communication with a valve and allowing the air pressure from the valve to be introduced to the supply passage, a component retainer disposed at an axial end of the spline shaft and configured to hold an electronic component by using the air pressure applied through the supply passage, a spline nut connected to the spline shaft through a spline mechanism, and a bearing supporting the spline shaft in the shaft hole in the support both in a linearly movable manner in an axial direction and in a rotatable manner about an axis thereof. The bearing, the conduit, and the spline nut are arranged on an axis of the spline shaft in this order from the component retainer.

A component placing device to place a component on a board, including: a shaft having a lower portion and an upper portion; a component holder that is attached to the lower portion of the shaft in a state of being vertically displaceable and has a suction hole for holding the component by a negative pressure; an elastic body that biases the component holder downward with respect to the shaft; a servo motor that raises and lowers the shaft; and a controller that sets a thrust limit value for limiting a thrust of the servo motor and limits the thrust of the servo motor to be equal to or lower than the thrust limit value when the component holder is lowered toward the board. The thrust limit value is set within a range in which a load is smaller than a force by which the elastic body biases the component holder.

A component mounting machine including a head unit that has a head main body configured to hold multiple pickup members each capable of picking up a component at a predetermined interval along a predetermined circumference and to be capable of rotating forward and reverse directions; a moving device configured to move the head unit; a lifting and lowering device configured to lift and lower a pickup member; a component supply device configured to be capable of supplying the component to the pickup member; and a control device configured to control those described above. The control device performs a control such that the pickup members pick up the components supplied by the component supply device, and each component is mounted on a board after a completion of the pickup, while performing an operation of rotating the head main body and an operation of moving the head unit together.

A filter removal method for removing a filter held in a filter holding space provided in a tip part of a nozzle shaft in a component suction head, in which a suction nozzle is detachably attached to the tip part of the nozzle shaft, from the component suction head. The method comprises a deforming step of compressing and deforming the filter in the filter holding space, and a discharging step of discharging the compressed and deformed filter from the filter holding space.

The present invention comprises an arrangement and process for the fluxless manufacture of an integrated circuit component, comprising the steps of loading a solder ball and chip arrangement, solder ball side up or down, onto a first or a second donor chuck respectively; monitoring the solder ball and chip arrangement by a computer-controlled camera; removing the solder ball and chip arrangement from the donor chuck by a computer-controlled gripper mechanism; moving the solder ball and chip arrangement via the gripper mechanism onto a computer-controlled gang carrier, the monitored by a second computer controlled camera; flipping the gang carrier about a horizontal axis so as to arrange the solder ball and chip arrangement into an inverted, solder ball side down orientation over a receiver chuck substrate, monitored and positionally controlled by a third computer-controlled camera; and compressing the solder ball side down solder ball and chip arrangement onto the receiver chuck substrate by a computer-controlled compression rod so as to bond the solder ball side down solder ball and chip arrangement onto the receiver chuck substrate so as to form an integrated circuit assembly.

A semiconductor mounting device for mounting chip components on a substrate, wherein the device is reduced in size. A semiconductor mounting device 10 comprises: a temporary placement stage 12 on which are loaded a plurality of chip components 30a, 30b, 30c; a conveyance head 14 that conveys the chip components 30a, 30b, 30c to the temporary placement stage 12, and also loads each of the chip components 30a, 30b, 30c on the temporary placement stage 12 so that the relative positions of the plurality of chip components 30a, 30b, 30c reach predetermined positions; a mounting stage 16 that secures a substrate 36 by suction; and a mounting head 18 that suctions the plurality of chip components 30a, 30b, 30c loaded on the temporary placement stage 12, and pressurizes while keeping the relative positions at prescribed positions on the substrate 36 that is secured by suction to the mounting stage 16.

A receiving device for components. The receiving device is designed to be adjusted in a controlled manner relative to a deposit point at least partly along a first, second, and/or third axis by at least one linear drive and/or move a support guided by the receiving device along one of the first and/or second axes by a drive. The receiving device has a position sensor which is paired with a component deposit point in order to detect a component which has only been partly deposited in a pocket of the support at the component deposit point, where the position sensor is connected to the receiving device laterally of the support such that the position sensor is moved directly together with the receiving device.

An adjustment jig for performing position alignment of nozzle holders, including: multiple positioning pins including a primary insertion section configured such that multiple nozzle holders of a primary side device are insertable into the primary insertion section and a secondary insertion section configured such that multiple nozzle holders of a secondary side device are insertable into the secondary insertion section; and a board member configured such that the multiple positioning pins protruding to an opposite side to the primary insertion section and the secondary insertion section can be attached at a specified fixing position via a fixing section, a position of which is adjustable.