Abstract: The invention relates to an article having a single-layered or multilayered main body having elastic properties, in particular an air spring bellows, a metal-rubber element or a vibration damper. To improve the flame-retardant properties the main body of the article consists of or contains at least one layer D which is constructed from a rubber mixture which is free from halogen-containing flame retardants and contains at least one carbon black having a BET surface area according to DIN-ISO 9277 between 35 and 140 m2/g and an oil absorption number (OAN) according to ISO 4656 between 70 and 140 ml/100 g.

Abstract: A printing sleeve includes a first and radially inward layer having an inner side for directly contacting the outer side of a printing cylinder, and an outer side which is radially opposite the inner side. The first and radially inward layer has a glass fiber reinforced compressible compound such that the glass fibers may absorb the forces that arise in the circumferential direction and/or in the longitudinal direction, and the compressible compound elements may absorb the pressures that arise in the radial direction. In this way, the materials which to date act separately in the base sleeve and the compressible layer are combined in one common layer in which said materials each may perform their function.

Abstract: The invention relates to a multilayer sheet material 10 in the form of a printing blanket or of a printing plate, in particular for the printing of conical or cylindrical vessels made of, for example, plastic, styropore, paperboard, metal, etc., with a multiple-ply printing layer 1,2 made of at least one polymeric material and at least one other layer 3, 4, where the individual layers form, with one another, an adhesive bond that is not amenable to non-destructive separation. The upper ply 1 of the printing layer, which during the printing procedure faces toward the object to be printed, comprises from 40 to 80 phr of butadiene rubber (BR) and from 20 to 60 phr of butyl rubber (IIR), and the lower ply 2, which during the printing procedure faces away from the object to be printed, comprises from 80 to 100 phr of butyl rubber (IIR).

Abstract: The invention relates to a printing sleeve (1) comprising a first, radially inner layer (11) that has an inner side (11a) for making direct contact with the outer side of a printing cylinder (10), and an outer side (11b) which lies radially opposite said inner side (11a); as well as a second, radially outer layer (12) that has an outer side (12b) for forming a printing surface, and an inner side (12a) which lies radially opposite said outer side (12b). Said printing sleeve (1) is characterised in that the outer side (11b) of the first, radially inner layer (11) and the inner side (12a) of the second, radially outer layer (12) lie directly one against the other, and in that said first, radially inner layer (11) is designed to be able to absorb both forces occurring in the circumferential direction (U) and/or longitudinal direction (L), and pressures that arise in the radial direction (R).

Abstract: A process for the coating a substrate with a microporous layer includes at least incorporation by mixing of at least one physical and/or chemical blowing agent into an elastomer mixture, shaping of the elastomer mixture including the physical and/or chemical blowing agent by means of a calender or of a roller-head system, and application of the calendered elastomer mixture including the physical and/or chemical blowing agent to a substrate to be coated. Further, heating and blowing of the coating including the physical and/or chemical blowing agent is then provided by means of at least one heat source. In some cases, the blowing agent is composed of microspheres, which in some embodiments, may be present in non-expanded form. In some aspects, the heating and blowing of the coating directly follows the application procedure. The heat source may be an infrared source, such as a ceramic source.

Abstract: The invention is directed to a method for grinding a printing form in the area of flexographic or relief printing wherein the material to be ground is an elastomer material or an elastomer-containing material. A feed or first speed (v) is imparted to the material to be ground. The material is grindingly abraded with a grinding belt or grinding paper moving at a second speed (V) at least five times greater than the first speed (v).

Abstract: The invention relates to a flexible insulating material based on a high temperature resistant rubber mixture. The insulation material for use at temperatures of more than 130° C., which is easy to apply to complex components to be insulated and also fills in undercuts, is an insulation material in which at least a portion of the rubber mixture is not crosslinked and can be plastically deformed, wherein the Mooney viscosity ML(1+4) of the mixture, determined at 23° C. according to DIN 53523 Part 3, is 5 to 20 MU.

Abstract: A printing form is for use in relief printing, in particular flexographic printing. The printing form is configured as a single or multilayered cylindrical layer structure having at least a first layer having a vulcanizate based on at least one elastomer. The first layer is extruded.

Abstract: A multilayered structure is for use as one of a printing blanket and a printing plate for relief printing including flexographic printing. The multilayered structure has a first layer including a vulcanizate based on at least one elastomer and at least one further layer adhesively connected to the first layer in such a manner that the first layer is peelable or strippable from the further layer.

Abstract: The invention relates to a flexible insulating material based on a high temperature resistant rubber mixture. The insulation material for use at temperatures of more than 130° C., which is easy to apply to complex components to be insulated and also fills in undercuts, is an insulation material in which at least a portion of the rubber mixture is not crosslinked and can be plastically deformed, wherein the Mooney viscosity ML(1+4) of the mixture, determined at 23° C. according to DIN 53523 Part 3, is 5 to 20 MU.

Abstract: A metal-backed printing blanket includes the following layers: a printing layer, a metal foil and a cover layer bonded to the surface of the metal foil that faces away from the printing layer. The cover layer is irreversibly bonded to the metal foil by a chemically-curing adhesive.

Abstract: A metal-back printing blanket (2) includes a printing layer (4), a metal foil (10), a cover layer (14) which is bonded via an adhesive layer (12) to that surface of the metal foil (10) which faces away from the printing layer (4). The cover layer (14) is made of a nonwoven fabric.

Abstract: A printing blanket unit for a printing blanket cylinder of a rotary printing press includes a printing blanket defining a transverse direction and having two mutually parallel side edges extending in the transverse direction. One of the side edges defines a leading side edge and the other one of the side edges defines a trailing side edge referred to the rotation of the printing blanket cylinder. The printing blanket has a top side and defines a longitudinal direction running perpendicular to the transverse direction. The top side of the printing blanket has a groove therein running in the longitudinal direction of the printing blanket.

Abstract: A flexible insulation material in the form of sheets or strips, based on a rubber mixture of high thermal stability and a method for insulation of components with the insulation material. An insulation material proposed for use at temperatures of more than 130° C., which can be applied in a simple manner to complex components to be insulated and retains its desired shape and position, is one in which the rubber mixture is at least partially uncrosslinked and is plastically deformable. In the method, the insulation material comprising the at least partially uncrosslinked and plastically deformable rubber mixture is applied to the component to be insulated and, after the application, crosslinked or crosslinked further by thermal and/or radiative action.

Abstract: The invention relates to a printing blanket assembly for a blanket cylinder of a rotary printing press. The printing blanket assembly comprises a dimensionally stable support plate (02, 18) with two ends, one of which is the forward end and the other one is the trailing end with respect to the rotation of the blanket cylinder, these ends being fastened to the blanket cylinder with folded, printing-blanket free limbs (21, 22). The assembly further comprises a printing blanket (03, 19), fastened to the outside of the support plate (02, 18) and having a forward end (12, 31) and a trailing end (11, 32). Said printing blanket assembly allows for perfect printing also in the area of a gap between the limbs (21, 22) and can be produced in a simple manner.

Abstract: Rubber blanket sleeve for a channel-free rubber blanket cylinder of an offset printing machine and process of producing rubber blanket sleeve. The rubber blanket sleeve includes an inner, dimensionally stable support sleeve arranged as a supporting layer, and a microporous compressible elastomer layer having a compressibility within a range between about 7% and 15% with a load of 100 N/cm2. The elastomer layer includes a rubber matrix having a tensile stress of greater than about 2.2 N/mm2 and less than about 15 N/mm2 with 100% elongation. An outer covering rubber layer is arranged as a printing layer. All of the layers are composed of seamless, cylindrical bodies and are coupled to one another. The process includes arranging an inner, dimensionally stable support sleeve as a supporting layer, and positioning a microporous compressible elastomer layer having a compressibility within a range between about 7% and 15% with a load of 100 N/cm2 over the support sleeve.

Abstract: Printing web for utilization on printing cylinders and process of producing printing web. Printing web includes an internal carrying layer arranged to face the printing cylinder during use of the printing web. The internal carrying layer includes a flexible metal sheet which is adaptable to a curvature of the printing cylinder and which is coupled to an adjacent layer via a bonding agent. The printing web also includes a microporous compressible intermediate layer, and an exterior printing layer.