An ambulance cot and cot loading and unloading system for an emergency vehicle comprises a cot having a head end, a base for mounting to a deck of an emergency vehicle, a track mounted for linear movement along said base, and an arm mounted for linear movement along said track from a retracted position to an extended position. The arm is and configured to engage the cot, and wherein when the track is extended along the base and the arm is extended along the track the arm is extended from the base in an extended position and is configured for lifting the cot and providing cantilevered support to the cot while in the extended position.

A stone dumping vessel having symmetrical stone compartments includes a hull, a stone conveying unit, and an oblique fallpipe unit. The hull has a control cabin. A cannula compensating device of the oblique fallpipe unit is disposed on a side of the hull and connected with a fallpipe. Two sides of the control cabin are symmetrically provided with the stone compartments and dynamic positioning (DP) system cabins, respectively. The stone compartments are operated independently for automatically unloading stones to the stone conveying unit disposed at a lower center thereof. The stones are conveyed by independent conveyor systems disposed at the left and right of the control cabin to the fallpipe. The dynamic positioning (DP) system cabins and the cannula compensating device are adapted to position the hull and the fallpipe respectively so that the stone dumping vessel having symmetrical stone compartments can achieve high accuracy of stone dumping.

Disclosed is a friction conveying system, comprising a friction driving unit, a clamping unit and a friction driving component, wherein the friction driving unit comprises a rotation driving component, a first connecting rod, a second connecting rod, at least one first rollers arranged on the first connecting rod, and at least one second rollers arranged on the second connecting rod, the clamping unit comprises a clamping driving component by which the first connecting rod and the second connecting rod are moved towards each other to cause the first rollers and the second rollers to clamp the friction driving component, the first rollers and/or the second rollers are drivable by the rotation driving component to rotate, causing the friction driving component clamped between the first rollers and the second rollers to move by means of frictional force. According to the invention, the rollers are used to drive the friction driving component to move at a high speed by means of frictional force, providing high-speed conveyance at lower cost. The present invention has the advantages of lower cost, reliable performance, and convenient mounting, satisfying the conveying requirements of industrial automatic production line.

An apparatus including a first conveyor device including a first conveyor belt; a second conveyor device including a second conveyor belt; a movement device; and a mold device including a mold; wherein the first conveyor device is connected to the second conveyor device so that when the movement device moves the first conveyor device, the second conveyor device also moves with respect to the mold device; wherein the first conveyor belt moves independent of the second conveyor belt; and wherein the first conveyor belt and the second conveyor belt move independent from the movement device. The apparatus may further include a first and second dispensing devices configured to dispense first and second materials, first and second gate devices to control height, and a computer processor to control the various components and the resulting ratio of first material to second material in a processed slab.

An apparatus including a first conveyor device including a first conveyor belt; a second conveyor device including a second conveyor belt; a movement device; and a mold device including a mold; wherein the first conveyor device is connected to the second conveyor device so that when the movement device moves the first conveyor device, the second conveyor device also moves with respect to the mold device; wherein the first conveyor belt moves independent of the second conveyor belt; and wherein the first conveyor belt and the second conveyor belt move independent from the movement device. The apparatus may further include a first and second dispensing devices configured to dispense first and second materials, first and second gate devices to control height, and a computer processor to control the various components and the resulting ratio of first material to second material in a processed slab.

A stone dumping vessel having symmetrical stone compartments includes a hull, a stone conveying unit, and an oblique fallpipe unit. The hull has a control cabin. A cannula compensating device of the oblique fallpipe unit is disposed on a side of the hull and connected with a fallpipe. Two sides of the control cabin are symmetrically provided with the stone compartments and dynamic positioning (DP) system cabins, respectively. The stone compartments are operated independently for automatically unloading stones to the stone conveying unit disposed at a lower center thereof. The stones are conveyed by independent conveyor systems disposed at the left and right of the control cabin to the fallpipe. The dynamic positioning (DP) system cabins and the cannula compensating device are adapted to position the hull and the fallpipe respectively so that the stone dumping vessel having symmetrical stone compartments can achieve high accuracy of stone dumping.

In a walking floor conveyor, an arrangement of panels lined longitudinally in a side-by-side fashion are organized into at least two correlating groups of panels. At least two panels within each group. Each panel grouping is propelled and retracted in a reciprocating manner, each by a hydraulic cylinder. The panels comprising wheel receptacles underneath the panels and at least one wheel fitted within a wheel receptacle to allow for forward and backward movement along a wheel support beam. These reciprocating panels supported by a series of wheel support beams, interior support beams and side support beams. These side support beams are at their tallest in the back and shortest in the front to provide a slant allowing for a flow of cargo and liquid runoff captured within a plurality of panel drains located between the panels towards a frontally placed auger designed for the assistance of cargo discharge.

Disclosed is a friction conveying system, comprising a friction driving unit, a clamping unit and a friction driving component, wherein the friction driving unit comprises a rotation driving component, a first connecting rod, a second connecting rod, at least one first rollers arranged on the first connecting rod, and at least one second rollers arranged on the second connecting rod, the clamping unit comprises a clamping driving component by which the first connecting rod and the second connecting rod are moved towards each other to cause the first rollers and the second rollers to clamp the friction driving component, the first rollers and/or the second rollers are drivable by the rotation driving component to rotate, causing the friction driving component clamped between the first rollers and the second rollers to move by means of frictional force. According to the invention, the rollers are used to drive the friction driving component to move at a high speed by means of frictional force, providing high-speed conveyance at lower cost. The present invention has the advantages of lower cost, reliable performance, and convenient mounting, satisfying the conveying requirements of industrial automatic production line

A conveyer system mountable to an installation floor defined by a conveyance path has a plurality of stationary subdecks mounted to the installation floor and extending along the conveyance path. A plurality of elongate floor slats extend along the conveyance path, with each elongate floor slats being in interlocked sliding engagement with a respective one of the stationary subdecks. A plurality of floating inner slat side seals extend along the conveyance path, and are disposed between, and in interlocked sliding engagement with adjacent ones of the elongate floor slats. Outer slat side seals extend along the conveyance path and abutting against outermost ones of the plurality of elongate floor slats, with the outer slat slide seal being mounted to a sidewall of the installation floor.

A feeding apparatus for supplying electronic devices for pick-up comprises a guide track for guiding and feeding a plurality of electronic devices and a separator operative to receive electronic devices from the guide track for the electronic devices to be picked up from the separator. A protrusion is located on either of the guide track or the separator, and a cavity is located on the other of the guide track or the separator for receiving the protrusion. The protrusion and the cavity cooperate to form a substantially continuous surface for transferring the electronic devices to the separator.