The present invention provides a telescopic conveyor (1) having at least two conveyor belts (10). Said belts are arranged one above the other and can be moved relative to one another in the longitudinal direction. Each conveyor belt (10) here has a frame (11), a circulatory belt (12) and a first deflecting roller (13) at a first end (A), and a second deflecting roller (14) at a second end (B), of the conveyor belt (10), wherein the second end (B) is a transfer end of the conveyor belt (10), and wherein a bridging device (2, 2) is provided between in each case two adjacent conveyor belts (10) located one above the other, and said device bridges, at least to some extent, the difference in height (H) between the two conveyor belts (10) arranged one above the other, it being necessary for said difference in height to be overcome at the transfer end. The bridging device (2) comprises a ramp (3, 3) with a slope (S) and also a first deflecting roller (4), which is arranged at the higher end of the ramp (3, 3), as well as a first holding-down device (5), which is arranged beneath the first deflecting roller (4), and also a second holding-down device (7) at the foot of the ramp (3, 3). The circulatory belt (12) of the respectively lower conveyor belt (10) is guided, from a conveying plane (E1) beneath the second holding-down device (7), over the ramp (3, 3) with the slope (S) and, from there, is deflected over the first deflecting roller (4) and guided back to the conveying plane (E1) beneath the first holding-down device (5). The slope (S) of the ramp (3, 3) continues in stepless fashion tangentially along the circulatory belt (12) of the conveyor belt (10) located above, said circulatory belt being guided over its second end-side deflecting roller (14).

The present disclosure is related to a device for aligning a number of packages including at least one bottom belt. In some embodiments, the at least one bottom belt may include a first end portion for receiving packages and a second end portion for exiting packages. In some embodiments, said at least one bottom belt may include a laterally declined portion facing a support surface arranged along a side of the at least one bottom belt, whereby in use, packages conveyed by the at least one bottom belt move laterally towards the support surface for alignment thereto due to the laterally declined portion and by means of gravity.

A recording apparatus can convey a recording sheet such as a long sheet with high precision without decreasing productivity even if a back tension occurs during conveyance of the recording sheet. The recording apparatus sets a first acceleration period in which the conveying speed is increased up to a first predetermined speed before a leading end of the roll paper reaches a detecting position of the leading end detecting sensor with the roll paper being nipped by the upstream side nip roller and the conveying belt. Further, the recording apparatus sets a first constant speed period in which the conveying speed is kept constant at the first predetermined speed before the leading end of the roll paper reaches the detecting position until the leading end of the roll paper is nipped by the downstream side nip roller and the conveying belt. Furthermore, the recording apparatus sets a second acceleration period in which the conveying speed is increased up to a second predetermined speed before the recording by the recording head is started after the leading end of the roll paper is nipped by the downstream side nip roller and the conveying belt.

A recording apparatus can convey a recording sheet such as a long sheet with high precision without decreasing productivity even if a back tension occurs during conveyance of the recording sheet. The recording apparatus sets a first acceleration period in which the conveying speed is increased up to a first predetermined speed before a leading end of the roll paper reaches a detecting position of the leading end detecting sensor with the roll paper being nipped by the upstream side nip roller and the conveying belt. Further, the recording apparatus sets a first constant speed period in which the conveying speed is kept constant at the first predetermined speed before the leading end of the roll paper reaches the detecting position until the leading end of the roll paper is nipped by the downstream side nip roller and the conveying belt. Furthermore, the recording apparatus sets a second acceleration period in which the conveying speed is increased up to a second predetermined speed before the recording by the recording head is started after the leading end of the roll paper is nipped by the downstream side nip roller and the conveying belt.

The present invention provides a telescopic conveyor (1) having at least two conveyor belts (10). Said belts are arranged one above the other and can be moved relative to one another in the longitudinal direction. Each conveyor belt (10) here has a frame (11), a circulatory belt (12) and a first deflecting roller (13) at a first end (A), and a second deflecting roller (14) at a second end (B), of the conveyor belt (10), wherein the second end (B) is a transfer end of the conveyor belt (10), and wherein a bridging device (2, 2) is provided between in each case two adjacent conveyor belts (10) located one above the other, and said device bridges, at least to some extent, the difference in height (H) between the two conveyor belts (10) arranged one above the other, it being necessary for said difference in height to be overcome at the transfer end. The bridging device (2) comprises a ramp (3, 3) with a slope (S) and also a first deflecting roller (4), which is arranged at the higher end of the ramp (3, 3), as well as a first holding-down device (5), which is arranged beneath the first deflecting roller (4), and also a second holding-down device (7) at the foot of the ramp (3, 3). The circulatory belt (12) of the respectively lower conveyor belt (10) is guided, from a conveying plane (E1) beneath the second holding-down device (7), over the ramp (3, 3) with the slope (S) and, from there, is deflected over the first deflecting roller (4) and guided back to the conveying plane (E1) beneath the first holding-down device (5). The slope (S) of the ramp (3, 3) continues in stepless fashion tangentially along the circulatory belt (12) of the conveyor belt (10) located above, said circulatory belt being guided over its second end-side deflecting roller (14).

The present invention provides a telescopic conveyor (1) having at least two conveyor belts (10). Said belts are arranged one above the other and can be moved relative to one another in the longitudinal direction. Each conveyor belt (10) here has a frame (11), a circulatory belt (12) and a first deflecting roller (13) at a first end (A), and a second deflecting roller (14) at a second end (B), of the conveyor belt (10), wherein the second end (B) is a transfer end of the conveyor belt (10), and wherein a bridging device (2, 2) is provided between in each case two adjacent conveyor belts (10) located one above the other, and said device bridges, at least to some extent, the difference in height (H) between the two conveyor belts (10) arranged one above the other, it being necessary for said difference in height to be overcome at the transfer end. The bridging device (2) comprises a ramp (3, 3) with a slope (S) and also a first deflecting roller (4), which is arranged at the higher end of the ramp (3, 3), as well as a first holding-down device (5), which is arranged beneath the first deflecting roller (4), and also a second holding-down device (7) at the foot of the ramp (3, 3). The circulatory belt (12) of the respectively lower conveyor belt (10) is guided, from a conveying plane (E1) beneath the second holding-down device (7), over the ramp (3, 3) with the slope (S) and, from there, is deflected over the first deflecting roller (4) and guided back to the conveying plane (E1) beneath the first holding-down device (5). The slope (S) of the ramp (3, 3) continues in stepless fashion tangentially along the circulatory belt (12) of the conveyor belt (10) located above, said circulatory belt being guided over its second end-side deflecting roller (14).

Conveyor idler monitoring apparatus, systems and methods are provided. In some embodiments, one or more sensors (e.g., temperature sensors, load sensors, etc.) are supported by the shaft of a conveyor idler. In some embodiments, one or more sensors are in data communication with a wireless transmitter. In some embodiments, a power generator driven by rotation of the idler is in electrical communication with one or more sensors and/or a wireless transmitter. In some embodiments, a plurality of idlers monitoring systems are in data communication with a conveyor monitoring system and/or operational monitoring system.

Conveyor idler monitoring apparatus, systems and methods are provided. In some embodiments, one or more sensors (e.g., temperature sensors, load sensors, etc.) are supported by the shaft of a conveyor idler. In some embodiments, one or more sensors are in data communication with a wireless transmitter. In some embodiments, a power generator driven by rotation of the idler is in electrical communication with one or more sensors and/or a wireless transmitter. In some embodiments, a plurality of idlers monitoring systems are in data communication with a conveyor monitoring system and/or operational monitoring system.

A conveyor tunnel oven incorporating a baking case opened by longitudinal and oppositely longitudinal food passage ports; a first conveyor extending through the at least baking case, the first conveyor being adapted for carrying the food item therethrough, a second conveyor supported at the oppositely longitudinal end of the baking case, the second conveyor being adapted for carrying the food item longitudinally toward or away from the food passage port; a third conveyor carried by the second conveyor, the third conveyor being adapted for carrying the food item laterally toward or away from the food passage port; a fourth conveyor carried by the third conveyor, the fourth conveyor being adapted for orbiting the food item; and a fifth conveyor carried by the fourth conveyor, the fifth conveyor having food item engaging arms and being adapted for moving the food item upwardly or downwardly.

A conveyor tunnel oven incorporating a baking case opened by longitudinal and oppositely longitudinal food passage ports; a first conveyor extending through the at least baking case, the first conveyor being adapted for carrying the food item therethrough, a second conveyor supported at the oppositely longitudinal end of the baking case, the second conveyor being adapted for carrying the food item longitudinally toward or away from the food passage port; a third conveyor carried by the second conveyor, the third conveyor being adapted for carrying the food item laterally toward or away from the food passage port; a fourth conveyor carried by the third conveyor, the fourth conveyor being adapted for orbiting the food item; and a fifth conveyor carried by the fourth conveyor, the fifth conveyor having food item engaging arms and being adapted for moving the food item upwardly or downwardly.