A vehicle inspection system is described. The vehicle inspection system comprises: an inspection device, for performing an inspection on a vehicle to be inspected; a carrier platform, for carrying the vehicle to be inspected; and an unmanned controlled travelling device for moving the carrier platform to pass through a scanning area of the inspection device, so as to perform the inspection on the vehicle to be inspected. In the present disclosure, the vehicle to be inspected is carried by the carrier platform, and the unmanned controlled travelling device is used to move the carrier platform to pass through the scanning area of the inspection device, so that the vehicle to be inspected can be subject to inspection smoothly. There is no driver required to drive through the scanning area in this process, thus avoiding exposure of a driver to a threat of radiation.

A system for providing automatic feedback and adjusting transmittal pulling force for transporting glass fragment, where the system comprises a delivery machine, a glass broken machine and a recycle box. The glass fragment is transmitted by the delivery machine and triturated by the glass broken machine, and the triturated glass fragment is then transported to the recycle box, the delivery machine comprises a driving motor, a conveyer belt and two driving rollers, where the conveyer belt surrounds the two driving rollers, the driving rollers are driven by the driving motor to rotate the conveyer belt, and the glass fragment on the conveyer belt is transported into the glass broken machine for triturating and recycling.

The present disclosure provides a carbide blade cutter head filling device and method, and relates to the field of alloy blade processing. The carbide blade cutter head filling device includes a feeding unit, a storage unit, a loading unit and a discharging unit which are arranged successively. The output end of the feeding unit is matched with the input end of the storage unit through the guide mechanism. The output end of the storage unit faces a conveying tray of the loading unit. The conveying tray is provided with a plurality of group of transition holes for accommodating blades. A receiving mechanism for accommodating a cutter head is arranged below the falling pull plate of the discharging unit. The falling pull plate adjusts the communication and isolation between the transition hole and the cutter head in the receiving mechanism by changing the relative position of the falling pull plate and the transition hole. A function of automatically feeding and loading the cutter head is fulfilled, the scattered blades are loaded into the cutter heads in batches instead of manually completing repeated work in a process of loading the blade into the cutter head. Therefore, the labor intensity of workers is reduced, the production efficiency is improved, and the blade production cost is reduced.

A system for automatic feedback and adjust transmittal pulling force of the glass fragment comprises a delivery machine, a glass broken machine and a recycle box, the glass fragment is transmitted by the delivery machine and triturated by the glass broken machine, and then transported them to the recycle box, the delivery machine comprises a driving motor, a conveyer belt and a driving roller, the conveyer belt is surrounded between the driving rollers, the driving roller is turn round by the driving of the driving motor to lead the conveyer belt rotating at the same time, and then the glass fragment on the conveyer belt could be transported into the glass broken machine for triturating and recycling. Additional, an electromagnetic control system is provided for automatic adjusting transmittal pulling force of the conveyer belt depends on the distance between the two driving rollers, which is connecting with the driving roller.

A method for filling carbide blades in cutter head by using a carbide blade cutter head filling device. The carbide blade cutter head filling device includes a feeding unit, a storage unit, a loading unit and a discharging unit which are arranged successively. The output end of the feeding unit is matched with the input end of the storage unit through the guide mechanism. The output end of the storage unit faces a conveying tray of the loading unit. The conveying tray is provided with a plurality of group of transition holes for accommodating blades. A receiving mechanism for accommodating a cutter head is arranged below the falling pull plate of the discharging unit. The falling pull plate adjusts the communication and isolation between the transition hole and the cutter head in the receiving mechanism by changing the relative position of the falling pull plate and the transition hole.

A method and apparatus for disposing of drill cuttings 500 from an oil and/or gas well drilling platform 510, comprising (a) transporting the drill cuttings 520 to a cuttings collection area 530 on the platform 510; (b) providing a barge 10, the barge 10 having at least one storage area 30, a cover 100 operably connected to the at least one storage area 30, and covering the at least one storage area 30; (c) placing the cover 100 in a first open state so that cuttings 500 can be placed in the at least one storage area 30; (d) transporting the drill cuttings 500 from the cuttings collection area 530 to the at least one storage area of the barge10; (e) placing the cover 100 in a closed state so that the cuttings 520 in the storage area 30 of the barge 10 are contained; (f) transporting the barge 10 from the drilling platform 510 to a collection site 540; (g) placing the cover 100 in a second open state so that the cuttings 520 in the storage area 30 can be removed; and (h) removing the cuttings 520 from the storage area 30.

Provided is a product manufacturing method including: first transport step of transporting an enclosure container enclosing a cleaning target to a first storage position in an automated warehouse; second transport step of transporting the enclosure container from the first storage position to a first clean room; cleaning step of cleaning the cleaning target by a cleaning device and accommodating the cleaned cleaning target in an airtight container; third transport step of transporting the enclosure container enclosing the airtight container from the first clean room to a second storage position in the automated warehouse; fourth transport step of transporting the enclosure container from the second storage position to a second clean room; and assembly step of assembling the cleaning target taken out of the airtight container transported to the second clean room in an assembly region to manufacture a product.