A conveying system for shock-sensitive items, in particular eggs, comprises a plurality of conveying devices in which the items are transferred from one conveying device to another. More particularly, the items are transferred from a conveying device oriented in a substantially horizontal direction to an adjacent conveying device oriented in a substantially vertical direction, without the risk of being damaged. The advancing movement of the conveying device having a substantially horizontal orientation is not movement at constant speed but, on the contrary, it is a movement at variable speed, sometimes accelerated and sometimes decelerated, and the transfer of the conveyed item from the conveying device to the conveying device having a substantially vertical orientation takes place when the advancement speed of the conveying device having a substantially horizontal orientation is at its minimum value.

This sample rack conveying apparatus is provided with a pusher unit, a linear motion guide, and a conveyance drive mechanism. The pusher unit has a base portion, a moving member, and a base-side guide. The base portion is supported by the linear motion guide so as to be movable in a first guide direction. The moving member is provided with a pusher that pushes a sample rack. The base-side guide supports the moving member such that the moving member is movable in a second guide direction that crosses the first guide direction.

A self-adaptive luggage transfer device and system. The self-adaptive luggage transfer device includes a base, a conveyor mechanism, a lifting mechanism and a self-adaptive extendable transfer mechanism. The lifting mechanism is arranged between the conveyor mechanism and the base and is configured to drive the conveyor mechanism to lift. The self-adaptive extendable transfer mechanism is obliquely arranged between the conveyor mechanism and the base and is in transmission connection with the lifting mechanism. Two ends of the self-adaptive extendable transfer mechanism are movably connected to an output end of the conveyor mechanism and the base, respectively. The conveyor mechanism is configured to drive an end of the self-adaptive extendable transfer mechanism connected to the conveyor mechanism to lift in a first direction, and the lifting mechanism is configured to drive at least one end of the self-adaptive extendable transfer mechanism to move in a second direction.

A self-adaptive luggage transfer device and system. The self-adaptive luggage transfer device includes a base, a conveyor mechanism, a lifting mechanism and a self-adaptive extendable transfer mechanism. The lifting mechanism is arranged between the conveyor mechanism and the base and is configured to drive the conveyor mechanism to lift. The self-adaptive extendable transfer mechanism is obliquely arranged between the conveyor mechanism and the base and is in transmission connection with the lifting mechanism. Two ends of the self-adaptive extendable transfer mechanism are movably connected to an output end of the conveyor mechanism and the base, respectively. The conveyor mechanism is configured to drive an end of the self-adaptive extendable transfer mechanism connected to the conveyor mechanism to lift in a first direction, and the lifting mechanism is configured to drive at least one end of the self-adaptive extendable transfer mechanism to move in a second direction.

A conveyor includes a first conveyor belt with a first surface along which an article is conveyed in a conveyance direction from an upstream end to a downstream end, The first surface has an upstream end and a downstream end along the conveyance direction. A second conveyor belt is directly downstream of the first conveyor belt in the conveyance direction and has a second surface along which the article is conveyed in the conveyance direction from an upstream end to a downstream end. The downstream end of the first surface is at a height greater than the upstream end of the second surface. A first reading unit is positioned to read a symbol on the article through a gap left between the first and second conveyor belts.

A conveyor includes a first conveyor belt with a first surface along which an article is conveyed in a conveyance direction from an upstream end to a downstream end, The first surface has an upstream end and a downstream end along the conveyance direction. A second conveyor belt is directly downstream of the first conveyor belt in the conveyance direction and has a second surface along which the article is conveyed in the conveyance direction from an upstream end to a downstream end. The downstream end of the first surface is at a height greater than the upstream end of the second surface. A first reading unit is positioned to read a symbol on the article through a gap left between the first and second conveyor belts.

A conveying system for shock-sensitive items, in particular eggs, is provided and comprises a plurality of conveying devices in which items are transferred from one conveying device to another. In particular, the conveying system comprises a motion transmission assembly which ensures synchronism between the advancement of a first conveying device and the advancement of a second conveying device, so as to optimize the transfer of items carried by the first to the second conveying device and allow the items to be transferred in the smoothest possible way.

A conveying system for shock-sensitive items, in particular eggs, is provided and comprises a plurality of conveying devices in which items are transferred from one conveying device to another. In particular, the conveying system comprises a motion transmission assembly which ensures synchronism between the advancement of a first conveying device and the advancement of a second conveying device, so as to optimize the transfer of items carried by the first to the second conveying device and allow the items to be transferred in the smoothest possible way.

A conveying system for shock-sensitive items, in particular eggs, comprises a plurality of conveying devices in which the items are transferred from one conveying device to another. More particularly, the items are transferred from a conveying device oriented in a substantially horizontal direction to an adjacent conveying device oriented in a substantially vertical direction, without the risk of being damaged. The advancing movement of the conveying device having a substantially horizontal orientation is not movement at constant speed but, on the contrary, it is a movement at variable speed, sometimes accelerated and sometimes decelerated, and the transfer of the conveyed item from the conveying device to the conveying device having a substantially vertical orientation takes place when the advancement speed of the conveying device having a substantially horizontal orientation is at its minimum value.

A conveying system for shock-sensitive items, in particular eggs, comprises a plurality of conveying devices in which the items are transferred from one conveying device to another. More particularly, the items are transferred from a conveying device oriented in a substantially horizontal direction to an adjacent conveying device oriented in a substantially vertical direction, without the risk of being damaged. The advancing movement of the conveying device having a substantially horizontal orientation is not movement at constant speed but, on the contrary, it is a movement at variable speed, sometimes accelerated and sometimes decelerated, and the transfer of the conveyed item from the conveying device to the conveying device having a substantially vertical orientation takes place when the advancement speed of the conveying device having a substantially horizontal orientation is at its minimum value.