A component supply device includes multiple magazines each provided with multiple slots accommodating the respective pallets by allotting one or more of the slots depending on the height of the accommodating section, the multiple magazines including a first magazine accommodating the pallets to be dispensed to a supply area of the components, and a second magazine accommodating the pallets to be transferred to and from the first magazine; and a control device, in a case of moving the pallet from the first magazine to the second magazine among the multiple magazines, setting a moving destination from among available slots based on the accommodation information about the second magazine taking into consideration a number of slots occupied by the pallet to be moved, and controlling the loading/unloading device so as to move the pallet to the moving destination.

Provided is an electronic component supply system determining the types of electronic components installed on component pallets at a time when the electronic components are installed on the component pallets for installation, which determines the types of the electronic components installed on the component pallets based on planned multiple jobs continuously performed by multiple electronic component mounting machines to which the component pallets are attached and an execution order for the jobs such that the number of the component pallets exchanged during job switching is minimized.

The present disclosure provides a feeder and a backlight production apparatus. The feeder includes: a storing assembly configured to store a material tray on which a plurality of elements to be fed are placed; a fetching assembly configured to obtain the material tray from the storing assembly by sucking and transport the material tray; a distributing assembly configured to obtain at least one element to be fed by sucking from the material tray transported by the fetching assembly, and distribute the at least one element to be fed; and a turn-over assembly configured to turn over the at least one element to be fed distributed by the distributing assembly, and transport the at least one element to be fed to a next process unit.

A component supply device including a component support which supports multiple components in a scattered state; a first component holding tool which holds a component of the multiple components which is supported by the component support; a first moving device which includes a motor an which moves the first component holding tool; and a placement section on which the components are placed in a lined up state by the first component holding tool moved by the first moving device. The placement section includes a first recessed section corresponding to a shape of the components, and a second recessed section which having a same shape as the first recessed section rotated by a predetermined angle and which overlaps a portion of the first recessed section. The first component holding tool places the components in both the first recessed section and the second recessed section.

A component depositing device in which components P stored inside storage container 140 in a bulk state are consecutively conveyed above depositing path 154 by rotating multiple magnets 142 in a first direction, the conveyed components are stopped by stopping wall 156 provided above the depositing path so as to fall onto the depositing path, thereby depositing a specified amount of the components into a case, wherein, when the specified amount of components has been deposited, the multiple magnets are stopped at a position such that the magnets currently pulling a component are not positioned above the depositing path. For example, the multiple magnets are stopped after being reverse rotated by a set angle. Because a magnet currently conveying a component is not above the depositing path when component depositing is completed, components are prevented from falling into the depositing path after component depositing is complete, thus preventing component blockages at the depositing path.

A component confirmation device images components arranged in a pallet before the components are picked up to confirm the components based on a captured image of the components. A pick-and-place cycle is defined as a cycle from when a mounting head configured to pick up and mount a component on a board starts picking up a target component that is at least one of the components that the mounting head picks up at one time until when the mounting head mounts the target component on the board. At this time, the component confirmation device includes a moving section configured to move target equipment that is a first one of a lighting device configured to illuminate the target component and the pallet, relative to a second one of the lighting device and the pallet as required every pick-and-place cycle, in imaging of the target component.

A temperature control system and method for devices under test and an image sensor-testing apparatus having the system are provided. The temperature control method for devices under test mainly comprises the steps of regulating the temperatures of a plurality of devices under test (DUTs) to a specific temperature in a temperature control zone; transferring the plurality of devices under test to a test plate and placing them into a plurality of test slots respectively; and measuring the temperatures of the device under test by the temperature-sensing elements in the test slots, wherein when at least one temperature-sensing element of the temperature-sensing elements detects that the device under test in the test slot corresponding to said at least one temperature-sensing element fails to meet the specific temperature, a temperature control element corresponding to the test slot regulates the temperature of the device under test.

An electronic component supply device, comprising: a tape feeder configured to feed out a taped electronic component and supply an electronic component; and a holding mechanism arranged to handle the tape feeder and configured to hold a container for accommodating the taped electronic component supplied to the tape feeder, in which the holding mechanism is configured to hold the container having a width larger than the width of the tape feeder.

An article supplying device is provided. The article supplying device has a conveyance portion for conveying conveyed objects, and a movable block. The movable block includes a housing portion capable of housing one conveyed object at a receiving position in which the housing portion communicates with a downstream end of the conveyance portion. The movable block is capable of a reciprocal movement in a direction intersecting a receiving direction of the conveyed objects. Moreover, the movable block includes a biting preventing portion for pushing back a subsequent conveyed object entered into the housing portion after the conveyed object having been housed in the housing portion toward the conveyance portion.

A method in an automated Surface Mount Device (SMD) warehouse configured to store bins at predetermined positions within said automated Surface Mount Device (SMD) warehouse, the method comprising receiving a bin at a port of said automated Surface Mount Device (SMD) warehouse and scanning an identity tag attached to said bin to obtain a bin ID.