Screening members, screening assemblies, methods for fabricating screening members and assemblies and methods for screening materials are provided for vibratory screening machines that incorporate the use of injection molded materials. Use of injection molded screen elements provide, inter alia, for: varying screening surface configurations; fast and relatively simple screen assembly fabrication; and a combination of outstanding screen assembly mechanical and electrical properties, including toughness, wear and chemical resistance. Embodiments of the present invention use a thermoplastic injection molded material.

A flip-flop screening machine includes two screening machine side walls and transverse supports which carry screen panels. The transverse supports are provided as a powered transverse support and as a non-powered transverse support. The transverse supports are arranged between the two screening machine side walls in a transverse direction of a direction in which a screened material is conveyed. At least every second of the transverse supports is provided as the powered transverse support. Each powered transverse support performs oscillations and/or vibrations with movements in a transverse direction of a longitudinal axis of the powered transverse support to alternately compress and stretch the screen panels. Each powered transverse support has over a substantial part of a length or over an entire length thereof a separate oscillatory or vibratory drive which is arranged between the two screening machine side walls.

An apparatus, system and method have a rod attached to and extending across a screen to engage with a receptacle. A box is positioned beneath the filtration screen. An air bag is activated to inflate the filtration screen to compress against a plate. A junction extends from the plate, and the air bag rises to move the junction toward the receptacle to compress the rod against the receptacle to hold the rod. The filtration screen may be constructed from mesh material sized to permit materials to flow through the filtration screen. A vibratory element in the box vibrates to assist filtration.

An apparatus, system and method have a rod attached to and extending across a screen to engage with a receptacle. A box is positioned beneath the filtration screen. An air bag is activated to inflate the filtration screen to compress against a plate. A junction extends from the plate, and the air bag rises to move the junction toward the receptacle to compress the rod against the receptacle to hold the rod. The filtration screen may be constructed from mesh material sized to permit materials to flow through the filtration screen. A vibratory element in the box vibrates to assist filtration.

An apparatus, system and method provides for the installation of a filtration screen assembly in a vibratory separator. The apparatus has a screen rail extending across a vibratory separator. A ball box is inserted in the screen rail and encloses vibratory elements. A screen assembly is placed on the ball box parallel to the screen rail and extends across the vibratory separator. An inflatable seal is inserted into the screen rail and receives fluid to inflate and compress the screen assembly against the screen rail. A clamping element is attached to the screen assembly. The inflatable seal compresses the clamping element against the screen rail.

An apparatus, system and method provides for the installation of a filtration screen assembly in a vibratory separator. The apparatus has a screen rail extending across a vibratory separator. A ball box is inserted in the screen rail and encloses vibratory elements. A screen assembly is placed on the ball box parallel to the screen rail and extends across the vibratory separator. An inflatable seal is inserted into the screen rail and receives fluid to inflate and compress the screen assembly against the screen rail. A clamping element is attached to the screen assembly. The inflatable seal compresses the clamping element against the screen rail.

Screen assemblies for vibratory screening machines are provided herein. A screen assembly comprising: a plate comprising: a center portion with a plurality of apertures, a first end having a first series of finger-receiving apertures, a second end having a second series of finger-receiving apertures, wherein the first and second ends of the plate extend to cover the first and second series of finger-receiving apertures; and a screen covering the plurality of apertures.

Screen assemblies for vibratory screening machines are provided herein. A screen assembly comprising: a plate comprising: a center portion with a plurality of apertures, a first end having a first series of finger-receiving apertures, a second end having a second series of finger-receiving apertures, wherein the first and second ends of the plate extend to cover the first and second series of finger-receiving apertures; and a screen covering the plurality of apertures.

A flip-flow screener machine includes a carrier frame with primary, drive-induced vibration, to which a vibrating frame is coupled in a freely oscillating manner by means of elastic transmission elements and is excited and set to vibrate secondarily by the carrier frame via said transmission elements, transverse carriers being arranged on the carrier frame and on the vibrating frame, a transverse carrier on the vibrating frame lying downstream of a transverse carrier on said carrier frame, with a flexible screen bottom being arranged between two transverse carriers and detachably secured to said transverse carriers, each of the screen bottoms including at least one undercut portion by means of which they can engage behind an undercut on the transverse carrier, and two adjacent screen bottoms abutting one another directly at their front ends.

[Object] To provide a building material manufacturing apparatus and a building material manufacturing method each of which is suitable to vary, in a receiver width direction, a building raw material deposit amount on a building material forming receiver that receives a building raw material under a sieve portion that screens the building raw material.

[Solution] A building material manufacturing apparatus includes a sieve portion 10 and a receiver 30 that receives a building raw material M that has passed through the meshes of the sieve portion 10. The sieve portion 10 includes a series of sheets that are each capable of performing a wave motion when the apparatus is operating, that have an inclination, and that are arranged in a direction of the inclination. The series of sheets include a sieve sheet 12 and a sieve sheet 13 positioned below the sieve sheet 12. In the sieve sheet 12, meshes having an identical size are arranged at a regular pitch in a sheet width direction W. In the sieve sheet 13, meshes having two or more different sizes are arranged or a mesh region R1 and a non-mesh region R2 are arranged, in the sheet width direction W. The receiver 30 is movable below the series of sheets. The building material manufacturing method includes, by using the apparatus, forming a mat on the receiver 30, the mat including a first layer formed from a part of the building raw material M that has passed through the meshes of the sieve sheet 12 and a second layer formed from a part of the building raw material M that has passed through the meshes of the sieve sheet 13.