A product leveling device mounted to the front of a feeder box of a tile machine. The device includes a scraper mechanism with a plate having an edge to manufacture tile products of predetermined dimensions from material contained in a lower mold. A production board cooperates with the lower mold to receive the material. The thickness of the tile product can be selectively reduced without affecting the structure of the tile machine. Optionally, fingers can be added to the edge to form longitudinally channels in the material. Shoes are mounted to the end of the tamper head that coact with the material, including any channels, to produce a uniform pressure to the material.

An apparatus including a computer processor; a first tool device; a first device configured to hold the first tool device; and a second device configured to move the first tool device in x, y, and z directions, when the first tool device is being held by the first device, in response to commands from the computer processor; and a conveyor device having a belt. The first tool device may include a wheel. The first device may be configured with respect to the conveyor device, so that the wheel of the first tool device is configured to be lowered in the z direction into a material located on the belt of the conveyor device, and the first tool device is configured to be moved in the x and y direction, with the wheel simultaneously rotating and rolling through the material on the belt, in response to commands from the computer processor.

This document describes systems and processes for forming stone slabs, which may be suitable for use in living or working spaces (e.g., along a countertop, table, floor, shower surrounds, tiles, or the like). In some embodiments, the stone slabs may be processed by partially filling a mold with a particulate mineral mix, and preparing a top surface of the particulate mineral mix to received one or more additional materials.

Disclosed are various embodiments of a mobile 3D printer layer smoothing apparatus. The apparatus utilizes a plurality of heads, the surfaces of which are coupled at their adjacent edges. The surfaces are collectively utilized to apply cosmetic features to extruded material(s), such as concrete, by manipulating the heads and applying pressure to the extruded material(s). The surfaces of each head are coupled to a joint movably coupled to a linear actuator. The operation of the linear actuators causes the heads to change position and/or orientation along flexible couplings between adjacent edges of adjacent surfaces. The apparatus may be integrated into a stand-alone, single-purpose device or integrated into a multi-purpose 3D printing machine, such as a mobile 3D printer device.

The present invention relates to a method of manufacturing an artificial stone slab with veins comprises preparing a moldable hardenable fluid mixture of a first material (11); pouring said mixture into a mold (20) an upper face being exposed; engraving the exposed upper face with a predefined precise pattern of grooves (30) coinciding with a pattern of thin veins to be obtained; impregnating at least the inner faces (31) of said grooves (30) with a moldable hardenable fluid mixture of a second material (12), the color of both materials being different; causing the collapse and closure of the grooves, a visible pattern of thin veins of a second material with a natural look being left behind; curing the artificial stone slab by subjecting it to vibration, compression and vacuum until the fluid mixtures of the first material and of the second material are hardened.

The invention relates to an additive production method involving the production of a layer of geometrically compact particles, having the following steps: a) providing a particle layer depositing arrangement, comprising a first and a second semi-chamber, wherein a partition separates the first semi-chamber from the second semi-chamber, and the partition is permeable for a dispersion medium and impermeable for particles dispersed in the dispersion medium; b) providing a particle dispersion comprising the dispersion medium and particles dispersed therein in the first semi-chamber, the particle dispersion being distributed substantially homogenously in the first semi-chamber; c) generating a pressure gradient between the first and the second semi-chamber such that the pressure gradient in the first semi-chamber causes a particle dispersion flow directed towards the partition; and d) depositing a particle aggregate material comprising geometrically compact particles on the partition by transporting a dispersion agent into the second semi-chamber.

This document describes systems and processes for forming stone slabs, which may be suitable for use in living or working spaces (e.g., along a countertop, table, floor, shower surrounds, tiles, or the like). In some embodiments, the stone slabs may be processed by partially filling a mold with a particulate mineral mix, and preparing a top surface of the particulate mineral mix to received one or more additional materials.

A method for producing engineered stone slabs which includes: compressing composite material to form compressed composite material; fragmenting the compressed composite material into a plurality of fragments of composite material; depositing colorant in a predefined region onto at least part of side walls of some of the plurality of fragments of composite material; and using a device to press, flatten and stretch the plurality of fragments of composite material into a slab. The method may further include moving one or more of the plurality of fragments without substantially breaking or deforming them to form a channel in the plurality of fragments prior to depositing colorant in the predefined region. The device may include a first press roller and a second press roller; wherein the plurality of fragments pass between the first and second press rollers to press, flatten and stretch the plurality of fragments of composite material into the slab.

A method comprising: a) determining the bow (28) in the extension direction of one or more linear paths on an outer surface or outer surfaces (11,13,14,16) of an extruded ceramic part (10) so that maximum extrusion direction bow (28) of the one of more linear paths or outer surfaces (11,13,14,16) may be determined of the extruded ceramic greenware part (10); b) identifying the linear path on the outer surface or the outer surfaces (11,13,14,16) having maximum convex bow; c) placing the greenware part (10) on a carrier with the linear path on the outer surface or the outer surface location having the maximum convex shape in contact with the carrier; and d) processing the greenware part (10) while disposed on the carrier with the linear path on the outer surface or the surface having the convex shape on the carrier, such that the bow (28) is reduced as a result of the process.

A construction block or suchlike comprises at least one part made of conglomerate material, to which an insert made of filling material is constrained, to define a connection face for connection to another structural element. The connection face has visible a first surface of the insert and at least a connected second surface of the part made of conglomerate material. On the connection face other structural element(s) are combined, along a support plane (R, R1, R2) provided in correspondence with the connection face, to be stably connected by a layer of binder material. The second surface has a seating made longitudinally and lowered with respect to the support plane (R, R1, R2), on which seating the layer of binder material is located. The seating has a determinate depth (D), with respect to the support plane (R, R1, R2) correlated to the predefined thickness of the binder material to be laid.