A decorative door wreath having an annular ring and at least a first decorative ornament detachably attached to the annular ring is disclosed. The annular ring includes a front annular planar body and a back annular support base. The front annular planar body includes a front surface disposed between a continuous inner edge opposite a continuous outer edge. The back annular support base has a smaller width than a width of the front annular planar body. The first retention member includes a first base plate and a first pair of resiliently flexible spring arms removably connected to the front surface of the front annular planar body. The first pair of resiliently flexible spring arms flex laterally to provide for passage of at least a first portion of the front annular planar body therebetween. The at least first decorative ornament is detachably coupled to and retained by the annular ring.

A decorative door wreath having an annular ring and at least a first decorative ornament detachably attached to the annular ring is disclosed. The annular ring includes a front annular planar body and a back annular support base. The front annular planar body includes a front surface disposed between a continuous inner edge opposite a continuous outer edge. The back annular support base has a smaller width than a width of the front annular planar body. The first retention member includes a first base plate and a first pair of resiliently flexible spring arms removably connected to the front surface of the front annular planar body. The first pair of resiliently flexible spring arms flex laterally to provide for passage of at least a first portion of the front annular planar body therebetween. The at least first decorative ornament is detachably coupled to and retained by the annular ring.

Disclosed is a process for the production of synchronous-pore layered materials. Also disclosed is a device for the conduct of the process. In further aspects, the invention relates to layered materials which can be produced by the process, and also to wood-composite boards equipped with the layered materials produced by the process of the invention.

Disclosed is a process for the production of synchronous-pore layered materials. Also disclosed is a device for the conduct of the process. In further aspects, the invention relates to layered materials which can be produced by the process, and also to wood-composite boards equipped with the layered materials produced by the process of the invention.

A game bird fan can be created using a fixation template having a plurality of radial lines extending from a center region that define a plurality of spaced grid portions circumferentially arranged in a semicircular pattern. The base of the tail is initially aligned with the center region of the template and each of the tail feathers are individually aligned with the spaced grid regions. The tail feathers are temporarily secured to the template after each individual aligning step. An adhesive or epoxy is applied to the quills of the tail in order to retain the tail fan after which the formed tail can be removed from the template. Optionally, a riser can be disposed on the fixation template and beneath the base of the tail prior to aligning, enabling the created fan to have a curved or bowed configuration.

This document describes systems and processes for forming synthetic molded slabs, which may be suitable for use in living or working spaces (e.g., along a countertop, table, floor, or the like).

This document describes systems and processes for forming synthetic molded slabs, which may be suitable for use in living or working spaces (e.g., along a countertop, table, floor, or the like).

A floral arrangement insert comprising: a foam insert; a plurality of tubes arranged and removably secured in the foam insert in a pre-designed configuration; and a plurality of artificial foliage inserted into the foam insert and around the plurality of tubes in a pre-designed configuration. A method of manufacturing a floral arrangement insert comprising: obtaining or preparing a mold; filling the mold with an expandable, curable foam to form a foam insert; inserting a plurality of tubes into the foam in a pre-designed configuration; causing or allowing the foam to cure after insertion of the plurality of tubes; and removing the foam insert from the mold after the foam has cured. The plurality of tubes can be filled with water and an artificial or fresh flower and/or foliage can be inserted into the plurality of tubes to create a beautiful floral piece.

A floral arrangement insert comprising: a foam insert; a plurality of tubes arranged and removably secured in the foam insert in a pre-designed configuration; and a plurality of artificial foliage inserted into the foam insert and around the plurality of tubes in a pre-designed configuration. A method of manufacturing a floral arrangement insert comprising: obtaining or preparing a mold; filling the mold with an expandable, curable foam to form a foam insert; inserting a plurality of tubes into the foam in a pre-designed configuration; causing or allowing the foam to cure after insertion of the plurality of tubes; and removing the foam insert from the mold after the foam has cured. The plurality of tubes can be filled with water and an artificial or fresh flower and/or foliage can be inserted into the plurality of tubes to create a beautiful floral piece.

The disclosure relates to a method for producing a printed panel, comprising the following steps: a) providing a flat carrier; b) optionally applying a resin layer to the flat carrier; c) optionally applying a paper layer or nonwoven layer to the flat carrier; d) optionally calendering the produced layer structure, in particular at a temperature between 40 C. and 250 C., and e) optionally applying a printing substrate to the flat carrier; characterized in that the method has the following further steps: f) printing an application amount of radiation-curing printing ink onto the carrier, and g) curing the previously applied printing ink by treating the printing ink with radiation, wherein h) at least one parameter of radiation used in step g) is adapted to an application amount of radiation-curing printing ink, wherein step h) is based on an application amount of the radiation-curing printing ink determined by a sensor during the printing process, wherein at least one parameter of radiation used in step g) is adapted during the printing on the carrier according to step f).