A method for manufacturing a curable light-conducting body (21) in a casting method, in particular for the manufacture of light-conducting bodies (21) of a curable concrete material (36, 56), wherein a light-conducting mat (1) is embedded in a curable casting material (36, 56), and a casting mold (27) with a recessed mold cavity (18) open at the top is filled with the not-yet-cured casting material (36, 56), wherein, in a first method step, a plurality of molding punches (32) moveably arranged in the mold cavity (18) of the casting mold (27) are moved to at least the plane of the upper edge (43) of the mold cavity (18), 1. in a second method step, the space between the molding punches (32) in the mold cavity (18) is filled with a curable casting material (36), 2. in a fifth method step, the light-conducting mat (1) to be embedded in the casting material (36, 56) is placed on the end sides (61) of the molding punches (32) raised in the mold cavity (18), 3. and that, in a sixth method step, the light-conducting mat (1) is pressed into the casting material (36, 56) wherein, with the pressing movement of the light-conducting mat (1) into the casting material (36, 56), the molding punches (32) are approximately synchronously moved downwards out of the bottom surface of the mold cavity (18).

The present invention pertains to integrated machine for manufacturing anchor embedded cladding elements. Essentially, this machine comprises a cladding block manufacturing machine and anchor feeding and embedding machine, where the concrete block manufacturing machine and anchor feeding and embedding machine are configured for coordinated operation for producing anchors embedded cladding elements comprising concrete blocks and anchors embedded within said blocks. The flexibility and versatility of the machine is in determining the end location of the anchors in the final cladding elements before even manufacturing the cladding blocks. This provides greater degree of freedom, which in turn allows increasing the strength in fixing the cladding elements to a support wall on the one hand, and decreasing onsite or prefabrication workload and difficulties in the cladding process.

A method for manufacturing a curable light-conducting body (21) in a casting method, in particular for the manufacture of light-conducting bodies (21) of a curable concrete material (36, 56), wherein a light-conducting mat (1) is embedded in a curable casting material (36, 56), and a casting mold (27) with a recessed mold cavity (18) open at the top is filled with the not-yet-cured casting material (36, 56), wherein, in a first method step, a plurality of molding punches (32) moveably arranged in the mold cavity (18) of the casting mold (27) are moved to at least the plane of the upper edge (43) of the mold cavity (18), 1. in a second method step, the space between the molding punches (32) in the mold cavity (18) is filled with a curable casting material (36), 2. in a fifth method step, the light-conducting mat (1) to be embedded in the casting material (36, 56) is placed on the end sides (61) of the molding punches (32) raised in the mold cavity (18), 3. and that, in a sixth method step, the light-conducting mat (1) is pressed into the casting material (36, 56) wherein, with the pressing movement of the light-conducting mat (1) into the casting material (36, 56), the molding punches (32) are approximately synchronously moved downwards out of the bottom surface of the mold cavity (18).

A device for forming high-strength and high-toughness concrete product and a method thereof are provided. The device includes a vehicle body; a rotating disk rotatably connected to the vehicle body, a platform located above the rotating disk, and a vibration assembly. Three placement grooves are evenly spaced on a top surface of the rotating disk, and the placement grooves are used to place forming molds. The platform is fixedly connected to a storage tank, and a bottom of the storage tank is in communication with one of the forming molds in the placement grooves via a pipeline component. The platform is further provided with a thermal pressure forming component, and the platform is further provided with an ejection component. The vibration assembly includes a concrete vibrator and a lifting mechanism.

A device for forming high-strength and high-toughness concrete product and a method thereof are provided. The device includes a vehicle body; a rotating disk rotatably connected to the vehicle body, a platform located above the rotating disk, and a vibration assembly. Three placement grooves are evenly spaced on a top surface of the rotating disk, and the placement grooves are used to place forming molds. The platform is fixedly connected to a storage tank, and a bottom of the storage tank is in communication with one of the forming molds in the placement grooves via a pipeline component. The platform is further provided with a thermal pressure forming component, and the platform is further provided with an ejection component. The vibration assembly includes a concrete vibrator and a lifting mechanism.