A particulate sizer includes an infeed for receiving a plurality of particulates, a first roller, and a second roller. The first and second rollers break down the plurality of particulates as the plurality of particulates passes through a gap between the first and second rollers. The width of the gap varies along a length of the first and second rollers. Accordingly, the first and second rollers compress some particulates to a first size and compress other particulates to a second smaller size. In addition, each of the first and second rollers has a textured outer surface for carrying the plurality of particulates through the gap.

A roller for a roller press has a core formed with axially opposite outer ends, an axially central passage, and axially spaced and radially extending inlet and outlet passages extending radially at the outer ends from the central passage and opening radially outward at an outer surface of the core. A coolable jacket surrounds the core, and respective manifold rings are mounted on outer ends of the core, cover inlet and outlet passages at the end faces of the jacket. Respective L-shaped connecting passages each have an axially extending segment opening into a respective one of the cooling passages of the jacket and a radially extending segment opening into the respective groove.

A roller press comprising including a roller face defining a plurality of individual reliefs shaped and sized to compress feed material into a plurality of discrete briquettes, each of the individual reliefs defining a quadrilateral shaped depression having rounded corners to reduce stress concentrations in the resulting briquettes, wherein a pair of leading edge rounded corners are defined by a first radius and a pair of trailing edge rounded corners are defined by a second radius, the first radius being smaller than the second radius.

A calendering roll of a calendering roll press for manufacturing a dry electrode disposed as a pair to press and elongate an electrode sheet in both directions includes: a cylindrical roll main body installed to extend in a width direction of the electrode sheet; a roll driving shaft installed to pass through a center portion of the roll main body in a longitudinal direction; and a plurality of oil paths formed outside the roll driving shaft to form a flow path through which oil flows, and formed to pass through the roll main body in the longitudinal direction. An interval between the oil path and the roll driving shaft is formed to be largest at both sides of the roll main body in the longitudinal direction, and is formed to be smallest at the center portion of the roll main body.

A novel briquetting roll having excellent performance such as providing both abrasion resistance and spalling resistance, which can also be manufactured at low cost and in a short period of time, and a method for manufacturing the same, are provided wherein the briquetting roll 1 integrally has an inner layer material 4 and an outer layer material 5, which comprise mutually different materials and are in contact with each other at the respective exterior and interior thereof, and has pockets 6 formed at the outer circumference of the outer layer material 5. A chromium-molybdenum forged steel material is used for the inner layer material 4 and a high-carbon high-speed steel material is used for the outer layer material 5. The outer layer material 5 may be formed on the outside of the inner layer material 4 by a continuous pouring process.

An electrode manufacturing device that applies pressure to an electrode containing a coating part and a non-coating part is provided. The electrode manufacturing device includes: a first pressure roll that applies pressure to the non-coating part; a second pressure roll that applies pressure to the coating part; and a connection part that penetrates through the center of the first pressure roll and the center of the second pressure roll, respectively, wherein a difference between a radius of the first pressure roll and a radius of the second pressure roll is equal to or smaller than a step difference between the coating part and the non-coating part.

Provided is a die roll for manufacturing softgels, a softgel, and methods for producing a softgel. The die roll includes a die roll surface and a pocket defined therein. The pocket includes a floor, an interior sidewall surface, a chamfer, and an exterior sidewall surface. The floor is recessed relative to the die roll surface and the interior sidewall surface is connected to the floor and extends above the die roll surface to the chamfer. The pocket also includes a landing surface that is elevated from the die role surface and connects the chamfer to the exterior sidewall surface of the pocket. The landing surface includes a taper (such that the landing surface tapers inwardly towards the pocket floor) and a radius (such that the landing surface is not flat). Also provided is a softgel having a trailing edge thickness that is at least about 40% the thickness of the softgel wall thickness.

Provided is a die roll for manufacturing softgels, a softgel, and methods for producing a softgel. The die roll includes a die roll surface and a pocket defined therein. The pocket includes a floor, an interior sidewall surface, a chamfer, and an exterior sidewall surface. The floor is recessed relative to the die roll surface and the interior sidewall surface is connected to the floor and extends above the die roll surface to the chamfer. The pocket also includes a landing surface that is elevated from the die role surface and connects the chamfer to the exterior sidewall surface of the pocket. The landing surface includes a taper (such that the landing surface tapers inwardly towards the pocket floor) and a radius (such that the landing surface is not flat). Also provided is a softgel having a trailing edge thickness that is at least about 40% the thickness of the softgel wall thickness.

Provided is a die roll for manufacturing softgels, a softgel, and methods for producing a softgel. The die roll includes a die roll surface and a pocket defined therein. The pocket includes a floor, an interior sidewall surface, a chamfer, and an exterior sidewall surface. The floor is recessed relative to the die roll surface and the interior sidewall surface is connected to the floor and extends above the die roll surface to the chamfer. The pocket also includes a landing surface that is elevated from the die role surface and connects the chamfer to the exterior sidewall surface of the pocket. The landing surface includes a taper (such that the landing surface tapers inwardly towards the pocket floor) and a radius (such that the landing surface is not flat). Also provided is a softgel having a trailing edge thickness that is at least about 40% the thickness of the softgel wall thickness.

The invention relates to a method for removing a roller tire (3) shrink fitted to a roller core (2) of a roller-press roller (1) where the roller tire is expanded by heating and pulled off the roller core. This method is characterized in that the roller tire is inductively heated with an induction coil (4).