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CN-122016435-A - Container type automatic sampling and preparing system

CN122016435ACN 122016435 ACN122016435 ACN 122016435ACN-122016435-A

Abstract

The invention relates to a container type automatic sampling and preparing system, which belongs to the technical field of ore investigation, and aims to solve the problems that a large amount of dust is emitted by a crushing device during the crushing treatment of ores by the crushing device due to the effect of the crushing treatment, and the dust can only fly in the crushing container and cannot overflow out of the crushing container, so that a detection device close to the crushing device is ensured not to be interfered by the dust, the detection precision of the detection device is ensured, and the detection precision of the detection device is reduced because the detection device emits a large amount of dust during the crushing treatment of ores under the condition that the distance between the crushing device and the detection device is shortened, so that the emitted dust is easy to accumulate at the detection device.

Inventors

  • Huo Xuguang
  • DING LIWEI
  • PAN JIANMIN

Assignees

  • 青岛海亿特机电科技发展有限公司

Dates

Publication Date
20260512
Application Date
20260319

Claims (10)

  1. 1. A container type automatic sampling and sampling system is characterized by sequentially comprising a crushing assembly, a division assembly and a detection assembly which are connected with each other along the conveying direction of ores, and further comprising a crushing container, a division container and a detection container which are connected with each other and hollow in the inside, wherein the crushing container, the division container and the detection container are respectively matched with the crushing assembly, the division assembly and the detection assembly correspondingly, any one of the assemblies is arranged in the corresponding container, the crushing container is provided with a crushing output port and a crushing input port, the crushing assembly comprises a crushing input end, a crushing device and a crushing output port which are sequentially connected, the crushing device is arranged in the crushing container, the cross section shape of the crushing input end is matched with the cross section shape of the crushing input port, the joints of the crushing input end and the crushing input port are in sealing connection, the cross section shape of the crushing output end is matched with the cross section shape of the crushing output port, and the joints of the crushing output port are in sealing connection.
  2. 2. The automatic sampling system of claim 1, further comprising a dust collection device, wherein the dust collection device comprises a dust collection pump, a dust collection pipe and a dust collection box, the dust collection box is arranged outside the crushing container, two ends of the dust collection pipe are respectively communicated with the crushing container and the dust collection box, and the dust collection pump is arranged on the dust collection box.
  3. 3. The automatic sampling system of container formula, as set forth in claim 1, wherein the division assembly includes division input, division device and division output that connect gradually, the division device sets up in the division container, division input with broken output intercommunication, division output with detect assembly intercommunication, the division container is provided with division input and division delivery outlet, the transversal shape of division input with the transversal shape of division input matches, and the junction sealing connection of both, the transversal shape of division delivery end matches with the transversal shape of division delivery outlet, and the junction sealing connection of both.
  4. 4. The automated container sampling system of claim 1, further comprising a conveyor belt disposed between the reduction container and the inspection container, the inspection container having an inspection input port, the conveyor belt having a distal end connected to the inspection input port, the conveyor belt having a front end having a height lower than a height of the reduction output port.
  5. 5. The automated container-type sampling system of claim 4, wherein the distance between the conveyor belt and the dividing outlet is less than 1cm.
  6. 6. The automatic sampling system of claim 4, further comprising a hollow-inside conveying container, wherein two ends of the conveying container are respectively attached to the dividing container and the detecting container, and the conveying belt is arranged in the conveying container.
  7. 7. The automatic sampling system of claim 6, further comprising an absorption device, wherein the absorption device comprises an absorption pump, an absorption pipe and an absorption box, the absorption box is arranged outside the conveying container, two ends of the absorption pipe are respectively communicated with the conveying container and the absorption box, and the absorption pump is arranged on the absorption box.
  8. 8. The automatic sampling system of container formula, as set forth in claim 6, wherein the conveying device further comprises a plurality of vertical plates, the plurality of vertical plates are arranged at equal intervals along the surface of the conveyor belt, the vertical plates are vertically arranged on the surface of the conveyor belt, the space between two adjacent vertical plates is a placing space, and equal-quantity and equal-division ore samples are placed in the corresponding placing spaces by controlling the conveying speed of the conveyor belt and the speed of ore falling onto the conveyor belt from the dividing container.
  9. 9. The automatic sampling and sampling system of claim 8, further comprising a plurality of standing units, wherein the plurality of standing units are arranged at one end, close to the detection container, of the conveying container at equal intervals along the conveying direction of ores, the plurality of standing units are correspondingly matched with the plurality of standing spaces, close to one end of the detection container, any one standing unit is positioned on the corresponding standing space, each standing unit comprises a lifting cylinder and an internally hollow standing cover, the lifting cylinder is vertically arranged in the conveying container, the standing cover is connected with the output end of the lifting cylinder, and the standing cover is used for buckling ore samples in the corresponding standing space.
  10. 10. The automatic sampling system of container type according to claim 9, wherein the standing unit further comprises a standing box, a standing pump and a standing pipe, the standing box is arranged outside the conveying container, two ends of the standing pipe are respectively communicated with the standing box and the standing cover, and the standing pump is arranged on the standing box.

Description

Container type automatic sampling and preparing system Technical Field The invention belongs to the technical field of ore investigation, and particularly relates to a container type automatic sampling and preparing system. Background When the ore is excavated, the ore is usually firstly sampled and surveyed, so that the quality of the excavated ore is ensured. In general, sampling investigation of ores typically involves several steps, namely crushing, screening and detection. During sampling investigation of the ore, the detecting personnel usually send the ore to a crushing device for crushing, then send the crushed ore to a dividing machine for screening, and finally send the screened ore to a detecting device for detection. In the above steps, each time the ore completes a process, a detector is required to transport the ore to a designated position by using a transport device to perform the next process, which increases the overall time of the ore sampling investigation and reduces the efficiency of the ore sampling exploration. It is easy to think that the devices needed for the ore exploration are arranged in sequence according to the procedures of the ore sampling exploration, so that the step that the detection personnel transport the ore by using the transportation equipment between the adjacent procedures is saved, and the whole time of the ore sampling exploration is reduced. However, in the background that the distance between the crushing device and the detecting device becomes short, since the crushing device emits a large amount of dust during the crushing treatment of the ore, the emitted dust is easily accumulated at the detecting device, and the detecting accuracy of the detecting device is lowered. Disclosure of Invention The invention provides a container type automatic sampling and sample preparing system, which aims to solve the problem that dust generated in a crushing procedure is effectively isolated from influencing the precision of a detection device while a crushing device, a screening device and the detection device for sampling and exploring ores are sequentially and compactly arranged according to the procedure so as to improve the efficiency. The aim of the invention can be achieved by the following technical scheme: The container type automatic sampling and sampling system sequentially comprises a crushing assembly, a division assembly and a detection assembly which are connected with each other along the conveying direction of ores, and further comprises a crushing container, a division container and a detection container which are connected with each other and hollow in the inside, wherein the crushing container, the division container and the detection container are respectively matched with the crushing assembly, the division assembly and the detection assembly correspondingly, any one of the crushing container is arranged in the corresponding container, the crushing container is provided with a crushing output port and a crushing input port, the crushing assembly comprises a crushing input end, a crushing device and a crushing output port which are sequentially connected, the crushing device is arranged in the crushing container, the cross section of the crushing input end is matched with the cross section of the crushing input port, the joints of the crushing input end and the crushing input port are in sealing connection, the cross section of the crushing output port is matched with the cross section of the crushing output port, and the joints of the crushing output port are in sealing connection. As a preferable technical scheme of the invention, the dust collection device further comprises a dust collection pump, a dust collection pipe and a dust collection box, wherein the dust collection box is arranged outside the crushing container, two ends of the dust collection pipe are respectively communicated with the crushing container and the dust collection box, and the dust collection pump is arranged on the dust collection box. As a preferable technical scheme of the invention, the dividing assembly comprises a dividing input end, a dividing device and a dividing output end which are sequentially connected, the dividing device is arranged in the dividing container, the dividing input end is mutually communicated with the crushing output end, the dividing output end is mutually communicated with the detection assembly, the dividing container is provided with a dividing input port and a dividing output port, the cross section shape of the dividing input end is matched with the cross section shape of the dividing input port, the connecting parts of the dividing input port and the dividing input port are in sealing connection, the cross section shape of the dividing output end is matched with the cross section shape of the dividing output port, and the connecting parts of the dividing input port and the dividing output port are in sealing connection. As a preferable tec