A sheet supplying apparatus, which is capable of winding a sheet tightly, includes a driving unit configured to cause a roll including a wound consecutive sheet to rotate in a first direction for feeding the sheet or a second direction opposite to the first direction, a sensor that detects a leading end portion of the sheet separated from an outer circumferential surface of the roll, and a contact body that presses the outer circumferential surface. Before the sheet is fed, in a state in which the contact body presses the outer circumferential surface, the driving unit causes the roll to continuously rotate in the second direction until a detection cycle of the leading end portion by the sensor is less than a predetermined value.

A sheet supplying apparatus, which is capable of winding a sheet tightly, includes a driving unit configured to cause a roll including a wound consecutive sheet to rotate in a first direction for feeding the sheet or a second direction opposite to the first direction, a sensor that detects a leading end portion of the sheet separated from an outer circumferential surface of the roll, and a contact body that presses the outer circumferential surface. Before the sheet is fed, in a state in which the contact body presses the outer circumferential surface, the driving unit causes the roll to continuously rotate in the second direction until a detection cycle of the leading end portion by the sensor is less than a predetermined value.

A process for the continuous production of thin-walled, radially closed hollow profiles which are composed of nonferrous metals and have a small cross section comprises supply of a flat strip of the nonferrous metal to a forming apparatus (212) at a first supply speed, where the thickness of the strip corresponds to the wall thickness of the hollow profile. The forming apparatus (212) is configured for continuous forming of the flat strip supplied into a shape corresponding to the hollow profile. After forming, two opposite edges of the flat strip rest flush against one another in a contact region. A welding apparatus (216) continuously welds the edges which rest flush against one another by means of a laser which emits light having a wavelength of less than 600 nm. The laser heats a point in a welding region which has a diameter which is less than 20% of the cross-sectional dimension of the hollow profile. The welded hollow profile is taken off from the welding region, provided in a corrugator (225) with parallel or helical corrugation in sections and taken up in an uptake device (226).

A process for the continuous production of thin-walled, radially closed hollow profiles which are composed of nonferrous metals and have a small cross section comprises supply of a flat strip of the nonferrous metal to a forming apparatus (212) at a first supply speed, where the thickness of the strip corresponds to the wall thickness of the hollow profile. The forming apparatus (212) is configured for continuous forming of the flat strip supplied into a shape corresponding to the hollow profile. After forming, two opposite edges of the flat strip rest flush against one another in a contact region. A welding apparatus (216) continuously welds the edges which rest flush against one another by means of a laser which emits light having a wavelength of less than 600 nm. The laser heats a point in a welding region which has a diameter which is less than 20% of the cross-sectional dimension of the hollow profile. The welded hollow profile is taken off from the welding region, provided in a corrugator (225) with parallel or helical corrugation in sections and taken up in an uptake device (226).

The present invention relates to a machine for producing multi-layer cardboard or paper, or a machine for either printing or converting, starting from a reel of paper, cardboard or other material. In general, the invention can be applied to machines wherein a reel of different materials is unwound and which requires a contrast system to regulate the tensioning of the ribbon. In particular, the invention relates to a system for braking said reel.

In particular, the invention relates to a braking system (2) for a support member (1) of a reel (B), for example, a reel of paper in a machine for producing cardboard or corrugated cardboard, wherein said braking system (2) comprises a motor-generator device (8) and a mechanical brake device (9) arranged coaxially.

A tube holder supports a spool of flexible line wrapped onto the outer surface of a tube. The tube holder comprises a body portion configured to support the tube thereon, such that the interior surface of the tube rests of the top surface of the body portion; and an end protector detachably secured to the distal end of the body portion via a quick-release, contact fastener. The end protector is configured to be detachably secured to the body portion, while remaining spaced away from the tube such that the tube does not interfere with connecting the end protector with the body portion.

A tube holder supports a spool of flexible line wrapped onto the outer surface of a tube. The tube holder comprises a body portion configured to support the tube thereon, such that the interior surface of the tube rests of the top surface of the body portion; and an end protector detachably secured to the distal end of the body portion via a quick-release, contact fastener. The end protector is configured to be detachably secured to the body portion, while remaining spaced away from the tube such that the tube does not interfere with connecting the end protector with the body portion.

A printing device includes a supply roller on which a roll of substrate is wound, and a tension motor to apply a tension to the roll of substrate. The printing device includes a drive roller to advance the substrate from the roll through a print zone, a drive roller motor to rotate the drive roller, and a drive roller motor controller to apply a drive roller motor signal to the drive roller motor. The printing device includes a closed loop tension controller to adjust the tension applied by the tension motor to the roll of substrate based on the drive roller motor signal applied to the drive roller motor.

A printing device includes a supply roller on which a roll of substrate is wound, and a tension motor to apply a tension to the roll of substrate. The printing device includes a drive roller to advance the substrate from the roll through a print zone, a drive roller motor to rotate the drive roller, and a drive roller motor controller to apply a drive roller motor signal to the drive roller motor. The printing device includes a closed loop tension controller to adjust the tension applied by the tension motor to the roll of substrate based on the drive roller motor signal applied to the drive roller motor.

A strapping material dispenser may include a housing having a hinged door. A roll of strapping material may be received within the housing and fed into contact with an advancing wheel. A portion of the advancing wheel may extend outside the housing to be contacted by a user. Rotation of the advancing wheel dispenses strapping material from the dispenser. A cutting mechanism may be arranged within the housing to cut the strapping material once the desired length has been dispensed from the dispenser. A motor and digital control circuit may be provided to electronically control the advancing wheel and therefore the dispensing of material from the dispenser.