A tamping assembly for capsule filling machine is provided. The tamping assembly comprises a fixed base/platform for accommodating a dosing disc assembly; a movable platform disposed above the fixed platform, the movable platform having plurality of sets of top tamping plungers; a pair of movable rods extending from the movable platform; and a lifting assembly mounted below the fixed base, and operably connected with the pair of movable rods for lifting/lowering the movable rods and/or the movable platform, the lifting assembly comprising a pair of first link members, each first link member extends along an incline from a first end to a second end, at the first end each first link members is pivotally mounted below the fixed base; a pair of second link members, each second link member extends from a proximal to a distal end, the proximal end of each second link member pivotally coupled with the second end of the each link member via a first pivot rod, and the distal end of each second link member pivotally coupled with each movable rod via a second pivot rod; and a drive mechanism connected with the second end of each first link member for moving the first link members, movement of the first link member causes the second member to lift or lower the movable platform, and thereby the tamping assembly.

A tamping assembly for capsule filling machine is provided. The tamping assembly comprises a fixed base/platform for accommodating a dosing disc assembly; a movable platform disposed above the fixed platform, the movable platform having plurality of sets of top tamping plungers; a pair of movable rods extending from the movable platform; and a lifting assembly mounted below the fixed base, and operably connected with the pair of movable rods for lifting/lowering the movable rods and/or the movable platform, the lifting assembly comprising a pair of first link members, each first link member extends along an incline from a first end to a second end, at the first end each first link members is pivotally mounted below the fixed base; a pair of second link members, each second link member extends from a proximal to a distal end, the proximal end of each second link member pivotally coupled with the second end of the each link member via a first pivot rod, and the distal end of each second link member pivotally coupled with each movable rod via a second pivot rod; and a drive mechanism connected with the second end of each first link member for moving the first link members, movement of the first link member causes the second member to lift or lower the movable platform, and thereby the tamping assembly.

An apparatus for the treatment of residual thermoplastic powder from an additive manufacturing process includes a feed apparatus for feeding powder, which includes the residual thermoplastic powder, to a pressing area, and two rotatable roller elements which are drivable in opposite directions. Lateral surfaces of the two rotatable roller elements are adjacent to one another in a pressing area and each laterally have a plurality of molding elements that are assigned to one another in pairs in order to compress powder into granules in the pressing area. Also, a cam mechanism is included and configured to deflect the molding elements of one of the two rotatable roller elements radially depending on the angle of rotation.

A rotary molding system for molding food products, mold cavities formed when a mold shell rotates mold shapes disposed along the mold shell into a fill position between a fill plate and a wear plate. Molded food products are removed from mold cavities using knock-out cups, the use of air pressure, or the use of a vacuum source disposed below the mold cavity, without the need to slow the rotation of the mold shell. Knock-out cups may be used with a heating system to reduce accumulation of unwanted materials on the knock-out cups. The rotary molding system can also be used to form products with contoured surfaces. A smart tagging system can be used to ensure that compatible sets of mold shells and knock out cups are being used. A vacuum region may be disposed upstream of the fill position to remove air within the mold cavity prior to filling.

A rotary molding system for molding food products, mold cavities formed when a mold shell rotates mold shapes disposed along the mold shell into a fill position between a fill plate and a wear plate. Molded food products are removed from mold cavities using knock-out cups, the use of air pressure, or the use of a vacuum source disposed below the mold cavity, without the need to slow the rotation of the mold shell. Knock-out cups may be used with a heating system to reduce accumulation of unwanted materials on the knock-out cups. The rotary molding system can also be used to form products with contoured surfaces. A smart tagging system can be used to ensure that compatible sets of mold shells and knock out cups are being used. A vacuum region may be disposed upstream of the fill position to remove air within the mold cavity prior to filling.

An apparatus for the treatment of residual thermoplastic powder from an additive manufacturing process includes a feed apparatus for feeding powder, which includes the residual thermoplastic powder, to a pressing area, and two rotatable roller elements which are drivable in opposite directions. Lateral surfaces of the two rotatable roller elements are adjacent to one another in a pressing area and each laterally have a plurality of molding elements that are assigned to one another in pairs in order to compress powder into granules in the pressing area. Also, a cam mechanism is included and configured to deflect the molding elements of one of the two rotatable roller elements radially depending on the angle of rotation.

The present invention relates to a mold drum for molding products from a mass of food starting material. The mold drum comprises one or more cavities with a mold cavity wall having at least partially a porous structure, whereas each cavity is connected to a passage. The present invention further relates to a cleaning apparatus for the inventive mold drum with supporting means for supporting the axis of the drum. Additionally, the present invention relates to a process for cleaning the inventive drum.

The present invention relates to a mold drum for molding products from a mass of food starting material. The mold drum comprises one or more cavities with a mold cavity wall having at least partially a porous structure, whereas each cavity is connected to a passage. The present invention further relates to a cleaning apparatus for the inventive mold drum with supporting means for supporting the axis of the drum. Additionally, the present invention relates to a process for cleaning the inventive drum.

A rotary molding system for molding food products, mold cavities formed when a mold shell rotates mold shapes disposed along the mold shell into a fill position between a fill plate and a wear plate. Molded food products are removed from mold cavities using knock-out cups, the use of air pressure, or the use of a vacuum source disposed below the mold cavity, without the need to slow the rotation of the mold shell. Knock-out cups may be used with a heating system to reduce accumulation of unwanted materials on the knock-out cups. The rotary molding system can also be used to form products with contoured surfaces. A smart tagging system can be used to ensure that compatible sets of mold shells and knock out cups are being used. A vacuum region may be disposed upstream of the fill position to remove air within the mold cavity prior to filling.

A rotary molding system for molding food products, mold cavities formed when a mold shell rotates mold shapes disposed along the mold shell into a fill position between a fill plate and a wear plate. Molded food products are removed from mold cavities using knock-out cups, the use of air pressure, or the use of a vacuum source disposed below the mold cavity, without the need to slow the rotation of the mold shell. Knock-out cups may be used with a heating system to reduce accumulation of unwanted materials on the knock-out cups. The rotary molding system can also be used to form products with contoured surfaces. A smart tagging system can be used to ensure that compatible sets of mold shells and knock out cups are being used. A vacuum region may be disposed upstream of the fill position to remove air within the mold cavity prior to filling.