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.

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.

Disclosed are product (e.g., panels), slurry, and methods relating to a pregelatinized starch having a mid-range viscosity (i.e., from about 20 centipoise to about 700 centipoise), and an extruded pregelatinized starch.

Disclosed are product (e.g., panels), slurry, and methods relating to a pregelatinized starch having a mid-range viscosity (i.e., from about 20 centipoise to about 700 centipoise), and an extruded pregelatinized starch.

A toilet assembly includes a flush engine having a bowl, a sump at a lower portion of the bowl, and a trapway extending from the sump. The toilet assembly further includes a first polymeric layer at least partially surrounding the flush engine, the first polymeric layer comprising a foam. The toilet assembly further includes a second polymeric layer provided on the first polymeric layer, the second polymeric layer comprising resin.

A toilet assembly includes a flush engine having a bowl, a sump at a lower portion of the bowl, and a trapway extending from the sump. The toilet assembly further includes a first polymeric layer at least partially surrounding the flush engine, the first polymeric layer comprising a foam. The toilet assembly further includes a second polymeric layer provided on the first polymeric layer, the second polymeric layer comprising resin.

A multi-layered structure with improved stability and insulation is disclosed. Methods for making the multi-layered structure are also disclosed. The structure comprises layers of foam and layers of solid material which are sprayed onto each other via an industrial robot having spray nozzles. The layers of foam are sprayed onto a supporting structure of a building, and the process of spraying is such that each consecutively sprayed layer is initiated after only a short lag in time from the initiation of the previous layer. The structure comprises at least two layers (preferably at least three layers), each layer having different mechanical properties. The layers may further be reinforced with reinforcing fibers and/or fiber fragments. An additional layer of fibrous material may comprise outer and/or inner layers of the structure. The disclosed structure is built faster and has significantly higher load-bearing and insulative capacities than the state of the art.

A composite pallet is made of concrete fill material that is enclosed in a frame structure. The frame structure includes a first frame member and a second frame member. The first frame member has a first frame member cavity that contains the concrete fill material. The first frame member has a tenon, and the second frame member has a mortice in which the tenon of the first frame member is received. The tenon of the first frame member defines a fill gap through which the fill material is able to flow during manufacturing. The frame structure is made of sheet metal that has seams located inside the frame structure.

A composite pallet is made of concrete fill material that is enclosed in a frame structure. The frame structure includes a first frame member and a second frame member. The first frame member has a first frame member cavity that contains the concrete fill material. The first frame member has a tenon, and the second frame member has a mortice in which the tenon of the first frame member is received. The tenon of the first frame member defines a fill gap through which the fill material is able to flow during manufacturing. The frame structure is made of sheet metal that has seams located inside the frame structure.

A seismic steel tubular column with internal local restraint and filled with high-strength compound concrete containing normal-strength demolished concrete lumps, and a construction process. The seismic column includes a steel tube (1), high-strength fresh concrete (2), normal-strength demolished concrete lumps (3), horizontal stirrups (4), and longitudinal erection bars (5). The horizontal stirrups (4) are arranged at upper and lower ends inside the steel tube (1). The high-strength fresh concrete (2) is poured and the normal-strength demolished concrete lumps (3) are put alternately inside the steel tube (1). A compressive strength of the high-strength fresh concrete (2) is 3090 MPa greater than that of the normal-strength demolished concrete lumps (3).