A medium carrying device includes a carrying part that carries a continuous print medium, a detection part that includes a light emitting part and a light receiving part arranged sandwiching a carrying path, and that detects the print medium carried on the carrying path according to a light amount that is received by the light receiving part, and a control part that controls operations of the carrying part and the detection part, wherein the control part sets a first emitted light amount of the emitted light of the light emitting part used in image formation to the print medium by performing a light amount measurement using the light emitting part and the light receiving part in a state where the print medium is carried to a first position, and sets a threshold light amount that is used in detecting a boundary position between the first region and the second region by the detection part through performing another light amount measurement by obtaining a receiving light amount of the light receiving part with the first emitted light amount and by determining the threshold light amount based on the receiving light amount in a state where the print medium is carried from the first position to another second position.

A printer has a light source that directs light toward a print medium path. An RGB sensor is positioned to receive light from the light source that is reflected by the print medium. An infrared light filter is situated between the RGB sensor and the paper to filter out infrared light. A programmed processor is coupled to an output of the RGB sensor in order to detect form elements in the output from the RGB light sensor, retrieve a stored electronic representation of a form, match the form elements to the stored electronic representation of the form to identify locations on the form, and control printing to the form.

A printer includes: a first roller feeding a liner; a print unit printing information on a print medium temporarily adhering to the liner fed by the first roller; a second roller located at a first position when performing a print operation in a first print mode, and a second position when performing the print operation in a second print mode, at which second position the second roller rotates by the rotation of the first roller to separate the print medium from the liner; a reflective optical sensor including a light emitting part and a light receiving part arranged in an upward and downward direction defined when the printer is placed on a horizontal surface, and that is used to determine a position of the second roller; and a sensor housing containing the light receiving part. The sensor housing has a surface opposite to the light receiving part. The surface has an opening on a side of the light emitting part, and a light blocking part on a side opposite to the side of the light emitting part.

A printer according to an embodiment includes a conveying unit, a holding unit, a supporting unit, a second detecting unit, and a control unit. The conveying unit conveys paper. The holding unit includes a light emitting unit configured to radiate light and a first detecting unit configured to detect the light reflected on the paper. The supporting unit supports the holding unit to be movable in an orthogonal direction orthogonal to a conveying direction of the paper. The second detecting unit is disposed on an opposite side of the light emitting unit across a paper conveying path, on which the conveying unit conveys the paper, and detects the light radiated by the light emitting unit. The control unit determines, based on a detection result of the second detecting unit, whether the light emitting unit is present in a position opposed to the second detecting unit.

A printing apparatus includes: a printing head configured to discharge ink onto a recording medium to form an image; a platen including a support surface that supports the recording medium; and a recording medium holding portion being configured to hold a plurality of star wheels configured to hold the recording medium toward the support surface in a direction perpendicular to the support surface. In a case in which a maximum value of a height of the recording medium from the support surface in the direction perpendicular to the support surface is less than 2.2 mm when the recording medium passes between the support surface and the recording medium pressing portion, a load of one of the star wheels for holding the recording medium with presence of the recording medium holding portion is equal to or less than 4.5 gf.

Systems and methods create labels and include a mobile device including communication circuitry, an imaging device, an object recognition application, and a label creation application. A label printer includes printer memory and printer communication circuitry. The object recognition application is configured to analyze an image of a device taken by the imaging device and generate device data for the device in the image. The label creation application the uses the device data to automatically populate at least a portion of a label data entry screen. Once the label data entry screen is populated, the label creation application creates a print job and, via the mobile device communication circuitry, communicate the print job to the label printer to print at least one label sized specifically for the device.

A manufacturing method of decorative laminates includes the steps of: a) printing an ink acceptance layer by jetting droplets having a volume of 1 to 200 nL onto a paper substrate; b) forming a decorative layer by jetting ink droplets having a volume of up to 30 pL of one or more aqueous pigmented inkjet inks onto the dried ink acceptance layer; and c) heat pressing the decorative layer into a decorative laminate; wherein the ink acceptance layer contains an inorganic pigment P and a polymeric binder B in a weight ratio P/B larger than 1.5.

A shipping label is operable to be applied to a package and includes a single label ply. The single label ply presents longitudinally spaced ends, opposite top and bottom faces extending between the ends, and a generally transverse fold line of weakness spaced between the ends. The label ply is foldable about the fold line to define upper and lower label sections, with the upper label section overlying the lower label section when the label ply is folded, and the top face of the upper label section being operable to receive package address indicia thereon. The upper label section includes a separation line of weakness defining a border portion and a separable central portion. The upper label section includes adhesive applied to the bottom face along at least part of the border portion. The lower label section includes a dividing line of weakness defining a connecting portion and an end portion, with the connecting portion extending between the fold line and dividing line. The end portion is at least in part positioned underneath the central portion of the upper label section when the label ply is folded, with separation of the central portion from the border portion providing access to the end portion thereunder.

The disclosure discloses a tape cartridge including a first tape roll, a first support member, a storage medium, and a terminal part. The first tape roll has a first core that includes an outer circumferential side around which a tape is wound capable of being fed out. The first support member rotatably supports the first core of the first tape roll. The storage medium is disposed on the first support member and is capable of reading or writing of information. The terminal part is disposed on the first support member while being exposed outside and is conductive with the storage medium.

The disclosure discloses a printer comprising a first control portion configured to control a feeder and a conducting device to perform printing on a recording medium. The first control portion executing a first processing, a second processing, and a third processing. In the first processing, printing on the recording medium is performed while feeding the recording medium to a forward direction, based on first print data. In the second processing, printing on a first predetermined section is performed while continuously feeding the recording medium to the forward direction, based on second print data, triggered by receipt of a print stop instruction in the middle of the first processing. In the third processing, feeding the recording medium to a reverse direction is performed and, with current conduction to the heating elements stopped, making the heating elements face the first predetermined section for a first predetermined amount of time.