A kit for dispensing disposable stethoscope covers is provided. The kit may include a cartridge and a dispenser for automatic touch-free dispensing of disposable stethoscope covers. The kit further includes a first spool having a roll of backing member with disposable stethoscope covers disposed thereon and a second spool for receiving the spent backing member after a disposable stethoscope cover has been removed, self-contained within the cartridge. The cartridge is inserted within the dispenser so that a user may insert a stethoscope head through a window of the dispenser to attach to a disposable stethoscope cover. The kit may further include a proximity sensor for detecting a user. Upon detection of the user, the first and second spools rotate to align a disposable stethoscope cover with the window of the dispenser in a ready-to dispense position.

To provide a medicine inspection system capable of appropriately outputting an inspection result while minimizing damage and the like to a packaging bag and a medicine. A medicine inspection system 10 includes an inspection device 20 which inspects a numerical quantity and/or a type of a medicine contained in a packaging bag p based on an image photographed of the packaging bag p to be inspected, and a marking device 50 which records an inspection result from the inspection device on the packaging bag p. After the packaging bag p, which has a seal section S formed by pressure bonding an overlapping portion of a packaging paper, is inspected at the inspection device 20, a stamp which indicates the inspection result thereof is output by a marking device 50 onto the seal section S.

A tape ejection guide structure (8) is a structure which guides ejection of a component storing tape (100) ejected from a tape ejection port (23) of a component supply unit (1A), and includes a guide body (81), and a pair of restraining portions (83). The guide body (81) guides an upper surface portion (100A) of the component storing tape (100) which is ejected from the tape ejection port (23) in a tape ejection direction (H2). A pair of restraining portions (83) is connected to both end portions of the guide body (81) in a tape width direction (H3) respectively, and restrains the displacement in the tape width direction (H3) of the component storing tape (100) which is ejected in a state where the upper surface (100A) is guided by the guide body (81).

A carrier for reversibly immobilizing one or more objects is disclosed. The carrier comprises a frame having a major axis, a top surface, a bottom surface, and one or more openings through the frame along the major axis. The carrier also comprises a film comprising a thermoplastic elastomer material and having a top surface and a bottom surface. The film is attached to the frame based on thermal bonding of the top surface of the film to the bottom surface of the frame, is under tension along the major axis, and is free to flex at the openings. The top surface of the film comprises one or more exposed top surface portions that are accessible through the openings. The exposed top surface portions exhibit a holding force on stainless steel as per ASTM D1000 that is greater than that of the bottom surface of the film.

A self-piercing rivet tape path can extend through a clamshell receiver assembly between the upper and lower receiver bodies and can open between the upper and lower bodies along a longitudinal length of the self-piercing rivet tape path that extends through the clamshell receiver assembly. The upper and lower bodies can separate at a lead rivet cavity and above a proximal end of a discharge cavity of the lower body. A tool-free interlock coupling can rigidly couple the upper and lower receiver bodies together in a closed position. This tool-free coupling can unlock the upper and lower receiver bodies so they are hingedly movable into the open position. The clamshell receiver assembly can be rigidly coupled to an end of a self-piercing rivet spindle to receive self-piercing rivets carried by the tape along the tape path and support a lead self-piercing rivet in alignment with a punch of the spindle.

An automatic splicing device (20) provided with a communication device (40) configured to communicate with a component mounter (M) or a host computer (HC) that is connected to the component mounter (M) such that communication is possible, a connection control device (100 [103]) configured to control connecting of the a first tape (Tc) and a second tape (Tc), and a display device (90) configured to display information related to connecting of the first tape (Tc) and the second tape (Tc).

The present invention relates to a band-like joint tape for covering a butting portion formed by butting an end portion of a one packing film to an end portion of another packing film and connecting the respective end portions of these packing films to each other. The joint tape is comprised of a laminate film formed by adhering a joint layer to a support layer at a peelable state, and covered so as to face the joint portion. to the butting portion and heat-sealed so that the joint layer is fused to the butting portion and the fused portion of the joint layer is peeled off from the support layer.

A tape feeder includes a tape guideway that has an insertion port, a first tape transporter that transports a leading tape to a component extraction position in the tape guideway, a second tape transporter that transports the following tape from the insertion port to the first tape transporter, a following tape holder that has a first supporter that supports one side of an uninserted portion of the following tape in a width direction from a lower side, and a second supporter that supports the other side of the uninserted portion in a width direction from the lower side, and holds the uninserted portion of the following tape, and a displacer that displaces the uninserted portion of the following tape from the following tape holder. A width of one end portion of the second supporter decreases toward the insertion port.

A component supplying device includes a body portion including a component pick-up position, a tape path, first and second transfer portions, a control portion, and an input portion. The control portion includes a discharge processing portion which executes a discharge process in response to an instruction at the input, and a transfer processing portion which executes a transfer process after the discharge process. In the discharge process, a first component supply tape is transferred by the first transfer portion away from the first transfer position so that at least a part of the first component supply tape is discharged outside the body portion while holding the components. In the transfer process, a second component supply tape that is at the second transfer position is transferred by the second transfer portion toward the first transfer position, and transferred by the first transfer portion toward the component pick-up position.

A splicing device includes a drive device configured to cause a pressing surface of a first pressing member and a pressing surface of a second pressing member to reciprocate relatively towards and away from each other through a series of actions and a control device configured to stop temporarily the series of actions of the drive device in a pressing state where the first pressing member and the second pressing member press a first splicing tape and a second splicing tape against a first carrier tape and a second carrier tape through the series of actions of the drive device.