A component mounting device including a component mounting head that mounts a component on a board by using a first raising and lowering device and a second raising and lowering device. The second raising and lowering device causes an engaging member to engage with an engaged member of a suction nozzle, and by further advancing the engaging member causes the suction nozzle to advance against a biasing force of biasing member. Further, a control device is configured to cause the engaging member to move in the advancing direction by using the actuator of the second raising and lowering device and detect an engaging position in a vertical direction at which engaging member engages with engaged member.

A component placement device is provided. The component placement device includes a machine frame, a subframe supported by the machine frame, and a component pickup unit. The component pickup unit is movable relative to the subframe. The component pickup unit is movable by a first drive at least in a direction of movement. The component placement device includes a movable counter-mass being movable relative to the subframe by a second drive in a direction opposite to the direction of movement of the component pickup unit to at least partially counteract a reactive force exerted on the subframe by the component pickup unit during movement of the component pickup unit in the direction of movement relative to the subframe.

This application relates to a substrate pick-and-place equipment and method. The equipment includes: a bearer platform, configured to bear a substrate; a retractable apparatus, including: a foldable bracket, disposed above the bearer platform and foldable along a horizontal direction; a plurality of suction structures, disposed on a bottom of the foldable bracket, where the suction structures are evenly distributed in a coverage area of the foldable bracket, and are configured to suck the substrate; a first drive unit, configured to drive the foldable bracket to extend and retract along the horizontal direction; and a second drive unit, configured to drive the retractable apparatus to rise and descend along a vertical direction; and a conveying apparatus, operating between the bearer platform and the foldable bracket. In the substrate pick-and-place method, a substrate is picked and placed from an upward side by using a suction structure.

The disclosure shows a mounting apparatus including a primary pedestal with a mounting stage installed thereon, a gantry frame supported on the primary pedestal, mounting heads supported on the gantry frame in a manner movable in the Y direction, a secondary pedestal arranged apart from the primary pedestal, and a Y-direction load receiver installed on the secondary pedestal in a manner movable in the X direction and immovable in the Y direction, in which an X-direction stator is attached to the secondary pedestal, and in which one end of a Y-direction stator attached to the gantry frame and the Y-direction load receiver are connected using a connection member, thereby suppressing vibration of the primary pedestal caused when the plurality of mounting heads are moved in the X and Y directions.

A method and a placement machine for equipping a carrier with components. The procedure includes: (a) positioning of the carrier in a first spatial location within the placement machine, such that components in a first section of the carrier are placeable by a placement head of the placement machine; (b) placement, by means of the placement head, of a multitude of marker components on the carrier in an overlap area of the carrier; (c) transferring of the carrier along a transport direction into a second spatial location within the placement machine, the second spatial location being selected such that components in a second section of the carrier are placeable by the placement head and that the marker components placed in the overlap area are optically detectable by a camera; (d) second optical detection by means of the camera of the marker components placed in the overlap area; and (e) placement of a multitude of components on the carrier in predefined placement positions within the second section, the spatial locations of the placement positions on the carrier depending at least on the result of the second optical detection of the placed marker components.

A component mounting device capable of selectively performing a tolerance check mode that recognizes a position of a lead after determining whether the size of a lead region is within a tolerance range, and a non-tolerance check mode that recognizes a position of the lead without performing determination of whether the size of the lead region is within the tolerance range. Therefore, even in cases in which it is difficult to set a tolerance range due to the tip of the lead being covered with a viscous fluid such as solder or plating, the position of the lead is appropriately recognized.

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.

A slip track includes a continuous circuitous track. The continuous circuitous track includes a layered printed circuit board. The layered printed circuit board includes a top track layer configured to supply electric power to a device having a contact element sliding across the top track layer, the layered printed circuit board further having a lower layer connected to the top track layer, the lower layer configured to supply electric power to the top track layer. The layered printed circuit board is flexible and is bent around curves in the continuous circuitous track. A method of assembly using the slip track is further disclosed.

A component supply device includes a transport path that guides a component connected body from a component insertion port on an upstream side in a component feeding direction to a component supply position on a downstream side, the component connected body including a plurality of axial components arranged and connected at a predetermined pitch, the plurality of axial components each having a lead, and a feed mechanism that pitch-feeds the component connected body along the transport path to the downstream side. The feed mechanism includes a feed member which has a plurality of feed hooks disposed at the predetermined pitch along the component feeding direction, a rotating shaft which is connected to one end side of the feed member, and a moving mechanism which is connected to the feed member through the rotating shaft and reciprocates the rotating shaft along the component feeding direction. A length of one feed hook among the plurality of feed hooks is longer than a length of an other feed hook among the plurality of feed hooks, the other feed hook being adjacent to the one feed hook on the rotating shaft side.

An assembly system comprises a fixing device configured to fix a housing and a pressing mechanism adapted to assemble a contact into the housing. The pressing mechanism includes a fixing block having a contact guiding slot adapted to receive the contact therein and a movable block movably mounted on the fixing block and adapted to press the contact downward. The movable block is moved downward to press the contact received in the contact guiding slot into a contact installation slot of the housing in a condition in which the contact guiding slot of the fixing block is aligned with the contact installation slot of the housing.