A greeting card assembly that contains a first flap and a second flap that are joined at a central fold seam. The first flap and the second flap can move between an open configuration and a closed configuration. A flat center support is provided that extends vertically over the central fold seam. The flat center support has a flat face surface and a flat back surface. A plush body is set in the center of the greeting card assembly. The plush body is attached to both the first flap and the second flap. The flat center support extends into an interior of said plush body through an open bottom. When the first flap and the second flap are moved into their closed configuration, the plush body is pressed against both the flat face surface and the flat back surface of the flat center support.

A system for personalizing printed cards or scrapbooks with web-based links comprises a point of sale display of greeting cards or scrapbooks and a plurality of affixable media. Each of the affixable media comprise a scannable code and a description of the online content that will be displayed when the code is scanned by a recipient. A purchaser is able to create a personalized card or scrapbook by selecting a card or scrapbook from the point of sale display, selecting a scannable code based on its associated description, and then affixing the selected scannable code to the selected card or scrapbook, thereby creating a personalized card or scrapbook that directs the recipient to online content chosen by the purchaser from the set of options provided by the various affixable media.

The present disclosure and related inventions describe a greeting card with audio capabilities and party blower. The greeting card can include a squeeze trigger which initiates audio playback and the unfurling of the party blower. Release of the squeeze trigger causes the retraction of the party blower.

Interactive greeting card and gift card holders with a hinged mechanism which provide fun user interaction and triggers audio playback. Each greeting card and gift card holder includes portion thereof which hinges or pivots about an axis. When the greeting card or gift card holder is hinged, or pivoted about the hinge, one or more special effects are triggered. Special effects may include audio, emergence or ejection of a gift card holder (w/gift card) or gift card, the appearance of a thought or word bubble, or any other special effect.

A device is provided including a first sleeve for receiving a graphic medium, the first sleeve having a first window allowing the graphic medium to be viewed, and a second sleeve allowing an electronic appliance with a built-in electronic display to be received, the second sleeve including a second window allowing all of part of the electronic display to be viewed, the first and second sleeves being connected to each other. The first window allows the graphic medium to be viewed, which allows the personalization of the device.

A system for a greeting card. The greeting card has a planar greeting card portion and a greeting card cover moveably coupled to the planar greeting card portion. The greeting card cover can move from an open position whereby the planar greeting card portion is readable to a closed position adjacent to said planar greeting card portion whereby the planar greeting card portion is not readable. The greeting card portion is coupled to a gift storage compartment which has a volume and a depth for storing an item. The greeting card cover can open and close without moving the gift storage compartment.

An apparatus for dispensing small objects is disclosed. The apparatus includes a frame forming an upper chamber and a lower chamber. The frame supports a rotatable barrel that is disposed between the chambers. The barrel is constructed from a folded rectangular sheet that forms a chamber with an opening. The rotatable barrel is oriented with the opening facing upward to receive objects from the upper chamber into the barrel's chamber, such that when the handle is rotated about a horizontal axis the barrel turns to orient the opening downward and deposit objects in the barrel's chamber into the lower chamber.

A printed article is described. The printed article includes first and second sheets and a circuit board interposed between the first and second sheets. The circuit board supports a coin cell holder adjacent to the second sheet. The second sheet has a slit arranged to form a flap over the coin cell holder which is configured to allow a coin cell to be re-insertably removed from the coin cell holder.

A printed material includes: a recording medium having a pressure-bonding surface on which an image portion and a pressure phase transition layer are formed, the recording medium being folded upon the recording medium and pressure-bonded; or a recording medium having a pressure-bonding surface on which an image portion and a pressure phase transition layer are formed and an additional recording medium, the recording medium and the additional recording medium being stacked and pressure-bonded together. The average thickness of the pressure phase transition layer formed on the image portion on the pressure-bonding surface of the recording medium is larger than the average thickness of the pressure phase transition layer formed on a non-image portion on the pressure-bonding surface of the recording medium.

A method for producing pressure-responsive particles includes: adding an aggregating agent to a dispersion containing composite resin particles containing a styrene-based resin including a styrene compound and a vinyl monomer other than the styrene compound as polymer components and a (meth)acrylic acid ester-based resin including a (meth)acrylic acid ester compound as a polymer component to aggregate the composite resin particles so as to form aggregated particles A; forming a shell by adding an aggregating agent and styrene-based resin particles containing a styrene compound and a vinyl monomer other than the styrene compound as polymer components to a dispersion containing the aggregated particles A to aggregate the styrene-based resin particles so as to form aggregated particles B; and heating and fusing the aggregated particles B to form pressure-responsive particles. The amount of the styrene-based resin particles added in the formation of the shell is 5 mass % or more and 40 mass % or less relative to the total mass of the composite resin particles. The amount of the aggregating agent added in the formation of the shell is 0.1 mass % or more and 1.0 mass % or less relative to the total mass of the composite resin particles. The mass ratio of the styrene-based resin to the (meth)acrylic acid ester-based resin in the pressure-responsive particles is from 80:20 to 20:80. A difference between the lowest glass transition temperature and the highest glass transition temperature of resins contained in the pressure-responsive particles is 30° C. or more.