CN113916592A - Ore geology sampler - Google Patents

Abstract

The invention belongs to the technical field of ore equipment, and particularly relates to an ore geological sampler, which comprises a moving frame, wherein a controller is fastened on the surface of the moving frame through bolts, a lifting assembly is fastened on the inner wall of the moving frame through bolts, a sampling support is sleeved on the outer side of the lifting assembly, a sampling assembly is arranged in the sampling support, a rotating assembly and a lifting adjusting assembly are respectively sleeved on the outer side of the sampling assembly in an up-and-down mode, a charging barrel is uniformly clamped and fixed to the top of the lifting adjusting assembly, and the top of the charging barrel is attached to the bottom of the rotating assembly; the spiral auger sampling device is novel in design and stable in structure, can ensure that the sampling angle is fixed and can perform uniform sampling, the multiple charging barrels are designed to be convenient for storing multiple samples and can be freely switched, the contact distance between the contact rod and the pressure sensor is changed by adjusting the relative position of the induction sleeve frame so as to control the sampling depth of the spiral auger, and the spiral auger sampling device is simple in integral operation, strong in practicability and good in using effect.

Description

Ore geology sampler

Technical Field

The invention belongs to the technical field of ore equipment, and particularly relates to an ore geological sampler.

Background

Ore is one of the natural resources, and is a mineral aggregate from which useful components can be extracted or which itself has some property that can be utilized, and can be divided into metal minerals and non-metal minerals, the unit content of useful components (elements or minerals) in the ore is called ore grade, precious metal ores such as gold and platinum are expressed in grams or tons, other ores are expressed in percentage, and the value of the ore is measured by the ore grade, but the ore price is also influenced by the content of gangue (useless minerals or minerals with little useful component content in the ore and unusable minerals) and harmful impurities in the same effective component ore, but the ore needs to be sampled and analyzed, so as to facilitate the development and utilization of the ore resources.

Current ore sampling equipment mostly is single handheld spiral sampling equipment, thereby needs artifical handheld during this kind of equipment operation, thereby drives spiral auger through pushing down and descends and take a sample, this kind of equipment structure is single, and the sample angle is unstable, uses to shake about getting up and shake and easily take place crooked, is not convenient for collect and be difficult to control the sample depth to the sample moreover, and the operation is got up very inconveniently, wastes time and energy, and the result of use is poor.

In order to solve the problems, the application provides an ore geological sampler.

Disclosure of Invention

To solve the problems set forth in the background art described above. The ore geological sampler provided by the invention has the advantages of stable integral structure, convenience in collecting samples and adjusting sampling depth, simplicity in operation and good use effect.

In order to achieve the purpose, the invention provides the following technical scheme: an ore geology sampler comprises a movable frame, a power supply cabinet is fastened on the surface of the movable frame through bolts, a controller is embedded in the surface of the power supply cabinet, a lifting assembly is fastened on the inner wall of the movable frame through bolts, a sampling support is sleeved on the outer side of the lifting assembly, a sampling assembly is embedded in the sampling support, one end of the sampling assembly penetrates through the bottom of the sampling support, a rotating assembly and a lifting adjusting assembly are sleeved on the outer side of the sampling assembly respectively, the rotating assembly and the lifting adjusting assembly are clamped and fixed and are located on the inner side of the sampling support, a charging barrel is clamped and fixed on the top of the lifting adjusting assembly, the top of the charging barrel is attached to the bottom of the rotating assembly, a depth adjusting assembly is fastened on one side of the lifting assembly through bolts and corresponds to the position of the sampling assembly, one end, far away from the inner wall of the movable frame, of the depth adjusting assembly is slidably connected to the inner wall of the sampling assembly, the controller is respectively and electrically connected with the lifting assembly, the sampling assembly, the rotating assembly, the lifting adjusting assembly and the depth adjusting assembly.

Preferably, the power supply cabinet is internally provided with a storage battery, the storage battery is electrically connected with the controller, and a charging interface is arranged on the surface of the power supply cabinet corresponding to the position of the storage battery.

Preferably, the ore geological sampling machine comprises a lifting assembly, wherein the lifting assembly comprises a rotating shaft seat, an A threaded screw rod, a sliding frame and an A motor, the rotating shaft seat is fastened on the inner wall of a moving frame through bolts, one end of the A threaded screw rod is rotatably connected to the inner wall of the rotating shaft seat, the other end of the A threaded screw rod penetrates through the top of the moving frame and is rotatably connected to the surface of the moving frame, the sliding frame is connected to the surface of the A threaded screw rod in a threaded mode and is slidably connected to the inner wall of the moving frame, the A motor is fastened to the top of the moving frame through bolts and corresponds to the position of the A threaded screw rod, and the output end of the A motor is fixedly connected to the outer surface of one end of the A threaded screw rod penetrating out of the top of the moving frame.

Preferably, the sampling assembly comprises an upper sleeve, a spiral auger, a motor B and a discharge pipe, wherein the upper sleeve is fastened on the inner wall of a sampling support through bolts, one end of the upper sleeve penetrates through the bottom of the sampling support, the spiral auger is rotatably connected on the inner wall of the upper sleeve, one end of the spiral auger penetrates through the bottom of the upper sleeve and extends out of the outer side of the bottom of the sampling support, the motor B is fastened on the top of the sampling support through bolts and corresponds to the position of the spiral auger, the output end of the motor B is fixedly connected to the outer surface of one end of the spiral auger, the discharge pipe is arranged in the sampling support, one end of the discharge pipe is communicated with the interior of the upper sleeve, and the other end of the discharge pipe penetrates through the surface of the sampling support and corresponds to the position of a charging barrel.

Preferably, the rotating assembly comprises a fluted disc seat, a material guiding column, a fluted bar frame and a C motor, the fluted disc seat is rotatably connected to the surface of the sampling support and sleeved outside the upper sleeve, the material guiding column is uniformly and threadedly connected to the surface of the fluted disc seat, the fluted bar frame is rotatably connected to the surface of the sampling support and positioned on one side of the fluted disc seat, the fluted bar frame is meshed with the fluted disc seat, the C motor is fastened on the inner wall of the sampling support through bolts and corresponds to the position of the fluted bar frame, and the output end of the C motor is fixedly connected to the outer surface of one end of a central shaft of the fluted bar frame.

As a preferred choice of the ore geological sampler of the invention, the lifting adjusting component comprises a material rack, a material groove, connecting seats, a B thread screw rod, a D motor and a connecting sleeve rack, the material rack is sleeved outside an upper sleeve and is attached to the bottom of a fluted disc seat, the material groove is arranged on the surface of the material rack and corresponds to the position of a material guide column, one end of the material guide column is slidably connected to the inner wall of the material groove, the connecting seats are symmetrically and tightly screwed on the surface of a sampling support seat and correspond to the position of the upper sleeve, the B thread screw rod is rotationally connected to the inner walls of two groups of connecting seats, the D motor is tightly screwed on the surface of the sampling support seat and corresponds to the position of the B thread screw rod, the output end of the D motor is fixedly connected to the outer surface of one end of the B thread screw rod, the connecting sleeve rack is in threaded connection with the outer surface of the B thread screw rod and is sleeved outside the material rack, the material rack comprises a material disc seat and a cylinder column which are arranged up and down, the bottom of the charging tray seat is rotatably connected to the top of the barrel column, the charging tray is uniformly arranged on the surface of the charging tray seat, and the connecting sleeve is sleeved on the outer side of the barrel column.

As a preferred choice of the ore geological sampler of the invention, the depth adjusting component comprises a supporting plate, an adjusting bolt, a lower sleeve, an induction sleeve frame, a touch rod, a rod groove and a pressure sensor, wherein the supporting plate is arranged on the inner wall of the movable frame and is positioned on one side of the rotating shaft seat, the adjusting bolt is symmetrically and threadedly connected to the top of the supporting plate, one end of the adjusting bolt penetrates through the bottom of the supporting plate and is threadedly connected to the inner wall of the movable frame, the lower sleeve is threadedly connected to the top of the supporting plate and corresponds to the position of the upper sleeve, one end of the lower sleeve is slidably connected to the inner wall of the upper sleeve and is sleeved outside the spiral auger, the induction sleeve frame is slidably connected to the outer side wall of the lower sleeve, the induction sleeve frame is matched with the outer dimension of the upper sleeve, the touch rod is uniformly and threadedly connected to the top of the induction sleeve frame, the rod groove is uniformly arranged at the bottom of the upper sleeve and corresponds to the position of the touch rod, the equal threaded connection of pressure sensor is at the pole inslot wall, the equal sliding connection of feeler lever one end is at the pole inslot wall and laminates mutually with the pressure sensor surface.

Preferably, the discharge pipe, the material guide column, the material groove and the material barrel are all arranged on the same axial line.

Preferably, the guide strip and the guide groove are respectively arranged at the position corresponding to the position of the inner wall of the movable frame on the surface of the sliding frame and the position corresponding to the position of the surface of the connecting sleeve frame and the surface of the sampling support, and the guide strip is connected to the inner wall of the guide groove in a sliding manner.

Preferably, the ore geological sampling machine is characterized in that the surface of the lower sleeve is provided with an adjusting groove and an adjusting block at positions corresponding to the inner wall of the induction sleeve frame, and the adjusting block is connected to the inner wall of the adjusting groove in a sliding manner and fixedly connected through a locking bolt.

Compared with the prior art, the invention has the beneficial effects that:

(1) the device is novel in design, reasonable in structure, simple in overall operation and convenient to use, the mobile frame, the controller, the lifting assembly, the sampling support and the sampling assembly are arranged, the lifting assembly is controlled by the controller to operate and the sampling support is driven to descend on the inner wall of the mobile frame at a constant speed so as to drive the sampling assembly to descend at a constant speed, compared with manual handheld operation, the device is stable in structure, can ensure that a sampling angle is fixed and can perform sampling at a constant speed, time and labor are saved, and the sampling effect is good;

(2) the portable sample storage device is provided with the material cylinder, the rotating assembly and the lifting adjusting assembly, the rotating assembly is designed to conveniently drive the material cylinder to rotate so as to realize the replacement of the material cylinder, various samples are conveniently stored, the samples are not required to be independently stored manually and are convenient to carry, the lifting adjusting assembly is designed to conveniently install and fix the material cylinder, so that the material cylinder can be attached to the bottom of the rotating assembly and can rotate together with the rotating assembly, the whole operation is simple, the practicability is high, and the using effect is good;

(3) the depth adjusting assembly is arranged, the depth adjusting assembly is designed to be convenient for protecting the spiral auger and conveying samples, the contact distance between the contact rod and the pressure sensor can be changed by adjusting the relative position of the induction sleeve frame so as to control the sampling depth of the spiral auger, and the depth adjusting assembly is simple in integral operation, stable in performance and good in using effect.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the lifting assembly of the present invention;

FIG. 3 is a schematic view of a sampling support according to the present invention;

FIG. 4 is a schematic view of a sampling assembly according to the present invention;

FIG. 5 is a schematic view of a rotating assembly according to the present invention;

FIG. 6 is a schematic view of the lift adjustment assembly of the present invention;

FIG. 7 is a schematic view of a depth adjustment assembly of the present invention;

fig. 8 is a schematic view of the pressure sensor structure of the present invention.

In the figure: 1. moving the frame; 2. a power supply cabinet; 21. a storage battery; 3. a controller; 4. a lifting assembly; 41. a rotating shaft seat; 42. a, a threaded screw rod; 43. a carriage; 431. a guide strip; 44. a, a motor; 5. a sampling support; 6. a sampling assembly; 61. sleeving a sleeve; 62. a spiral auger; 63. a motor B; 64. a discharge pipe; 7. a rotating assembly; 71. a fluted disc seat; 72. a material guiding column; 73. a rack bar frame; 74. c, a motor; 8. a lift adjustment assembly; 81. a material rack; 811. a charging tray seat; 812. a cylinder; 82. a trough; 83. a connecting seat; 84. b, a threaded screw rod; 85. a motor; 86. connecting a sleeve frame; 9. a charging barrel; 10. a depth adjustment assembly; 101. a support plate; 102. adjusting the bolt; 103. setting a sleeve; 1031. an adjustment groove; 104. an induction sleeve frame; 1041. an adjusting block; 1042. locking the bolt; 105. a feeler lever; 106. a rod groove; 107. a pressure sensor.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

Please refer to fig. 1-8;

an ore geology sampler comprises a movable frame 1, a power supply cabinet 2 is fastened on the surface of the movable frame 1 through bolts, a controller 3 is embedded in the surface of the power supply cabinet 2, a lifting component 4 is fastened on the inner wall of the movable frame 1 through bolts, a sampling support 5 is sleeved on the outer side of the lifting component 4, a sampling component 6 is embedded in the sampling support 5, one end of the sampling component 6 penetrates through the bottom of the sampling support 5, a rotating component 7 and a lifting adjusting component 8 are respectively sleeved on the outer side of the sampling component 6 from top to bottom, the rotating component 7 and the lifting adjusting component 8 are clamped and fixed and are both positioned on the inner side of the sampling support 5, a charging barrel 9 is uniformly clamped and fixed on the top of the lifting adjusting component 8, the top of the charging barrel 9 is attached to the bottom of the rotating component 7, a depth adjusting component 10 is fastened on one side of the lifting component 4 through bolts, the depth adjusting component 10 corresponds to the position of the sampling component 6, one end, far away from the inner wall of the movable frame 1, of the depth adjusting component 10 is connected to the inner wall of the sampling component 6 in a sliding manner, the controller 3 is electrically connected with the lifting assembly 4, the sampling assembly 6, the rotating assembly 7, the lifting adjusting assembly 8 and the depth adjusting assembly 10 respectively.

In this embodiment: before the device is used, the charging barrel 9 is firstly placed into the material groove 82, then the D motor 85 is controlled to be electrified and operated through the controller 3, the D motor 85 is electrified and rotated to synchronously drive the B thread screw rod 84 to rotate, the B thread screw rod 84 is rotated to synchronously drive the connecting sleeve frame 86 to ascend, the connecting sleeve frame 86 ascends to synchronously drive the material frame 81 to ascend, the material frame 81 ascends to synchronously drive the charging barrel 9 to ascend and be sleeved outside the material guide column 72 and be jointed with the bottom of the fluted disc seat 71, the charging barrel 9 is installed and fixed through the above operations, the relative position of the induction sleeve frame 104 on the surface of the lower sleeve 103 is adjusted after the charging barrel 9 is installed, the contact distance between the contact rod 105 and the pressure sensor 107 is changed through adjusting the relative position of the induction sleeve frame 104 so as to control the sampling depth of the spiral auger 62, the A motor 44 is controlled to be electrified and operated through the controller 3 after the adjustment is completed, the A motor 44 is electrified and rotated to drive the A thread screw rod 42 to rotate, the screw lead screw 42 of A rotates and drives the carriage 43 to move downwards and synchronously drives the sampling support 5 to move downwards, the sampling support 5 moves downwards so as to drive the sampling component 6 to move downwards at a constant speed, meanwhile, the controller 3 synchronously controls the motor 63 of B to operate in an electrified way, the motor 63 of B rotates in an electrified way and drives the screw auger 62 to rotate synchronously, the screw auger 62 rotates and is driven by the lifting component 4 to contact with the ground and carry out sampling operation, the sample is driven by the screw auger 62 to be conveyed upwards to the inside of the upper sleeve 61 and finally discharged into the inside of the charging barrel 9 through the discharging pipe 64 to be collected, when the contact rod 105 at the top of the induction sleeve frame 104 extends into the rod groove 106 at the bottom of the upper sleeve 61 and is contacted with the pressure sensor 107, the pressure sensor 107 transmits data information to the controller 3, the controller 3 controls the motor 44 of A and the motor 63 of B to stop operation, thereby controlling the screw auger 62 to stop descending and suspend the sampling operation, then the controller 3 controls the motor A44 to rotate reversely so as to drive the sampling support 5 to reset, and synchronously drives the sampling assembly 6 to reset, the operation is sampling operation, the whole operation is simple, the sampling is stable, the safety is high, and the using effect is good.

Further, the method comprises the following steps:

in an alternative embodiment: the power supply cabinet 2 is internally provided with a storage battery 21, the storage battery 21 is electrically connected with the controller 3, and a charging interface is arranged on the surface of the power supply cabinet 2 corresponding to the storage battery 21.

In this embodiment, it should be noted that: the storage battery 21 is designed to provide electric energy, the storage battery 21 is conveniently charged through the charging interface, the operation is simple, and the using effect is good.

Further, the method comprises the following steps:

in an alternative embodiment: lifting unit 4 is including pivot seat 41, A thread screw 42, balladeur train 43 and A motor 44, 41 bolt-up of pivot seat is at moving vehicle frame 1 inner wall, 42 one end of A thread screw is rotated and is connected at the inner wall of pivot seat 41, the other end runs through moving vehicle frame 1 top and rotate to be connected on moving vehicle frame 1 surface, balladeur train 43 threaded connection is at A thread screw 42 surface and sliding connection at moving vehicle frame 1 inner wall, A motor 44 bolt-up is at moving vehicle frame 1 top and corresponding with A thread screw 42 position, A motor 44 output fixed connection runs through the one end surface at moving vehicle frame 1 top at A thread screw 42.

In this embodiment, it should be noted that: during the use, controller 3 control A motor 44 circular telegram operation, and the rotatory A screw lead screw 42 that drives of A motor 44 circular telegram is rotatory, and the rotatory balladeur train 43 that drives of A screw lead screw 42 moves down and drives sample support 5 downstream in step, thereby sample support 5 downstream drives sample subassembly 6 at the uniform velocity downstream, whole easy operation, excellent in use effect.

Further, the method comprises the following steps:

in an alternative embodiment: sampling subassembly 6 is including going up sleeve pipe 61, spiral auger 62, B motor 63 and row material pipe 64, go up sleeve pipe 61 bolt-up at 5 inner walls of sample support, go up sleeve pipe 61 one end and run through out 5 bottoms of sample support, spiral auger 62 rotates and connects at last sleeve pipe 61 inner wall, spiral auger 62 one end runs through out sleeve pipe 61 bottom and extends the outside of 5 bottoms of sample support, B motor 63 bolt-up is at 5 tops of sample support and corresponding with spiral auger 62 positions, B motor 63 output end fixed connection is at 62 one end surfaces of spiral auger, it sets up inside 5 to arrange material pipe 64, it is linked together with interior the last sleeve pipe 61 to arrange material pipe 64 one end, the other end runs through out sample support 5 surfaces and is corresponding with feed cylinder 9 positions.

In this embodiment, it should be noted that: when the device is used, the controller 3 controls the motor B63 to be powered on and operated, the motor B63 is powered on and rotates to drive the spiral auger 62 to rotate synchronously, the spiral auger 62 rotates to be in contact with the ground under the driving of the lifting assembly 4 and perform sampling operation, a sample is upwards conveyed to the interior of the upper sleeve 61 under the driving of the spiral auger 62, and finally is discharged into the material barrel 9 through the discharge pipe 64 for collection, so that the device is simple in overall operation and good in using effect.

Further, the method comprises the following steps:

in an alternative embodiment: the rotating assembly 7 comprises a toothed disc seat 71, a material guiding column 72, a toothed bar frame 73 and a C motor 74, the toothed disc seat 71 is rotatably connected to the surface of the sampling support 5 and sleeved outside the upper sleeve 61, the material guiding column 72 is uniformly screwed on the surface of the toothed disc seat 71, the toothed bar frame 73 is rotatably connected to the surface of the sampling support 5 and positioned on one side of the toothed disc seat 71, the toothed bar frame 73 is meshed with the toothed disc seat 71, the C motor 74 is fastened on the inner wall of the sampling support 5 through bolts and corresponds to the position of the toothed bar frame 73, and the output end of the C motor 74 is fixedly connected to the outer surface of one end of the central shaft of the toothed bar frame 73.

In this embodiment, it should be noted that: when the charging device is used, the controller 3 controls the C motor 74 to operate in a power-on mode, the C motor 74 is powered on to rotate to drive the toothed bar frame 73 to rotate, the toothed bar frame 73 rotates to drive the toothed disc seat 71 meshed with the toothed bar frame to rotate synchronously, the toothed disc seat 71 rotates to drive the charging tray seat 811 clamped and fixed with the toothed disc seat to rotate synchronously, and therefore the charging barrel 9 is driven to rotate synchronously, replacement of the charging barrel 9 is achieved, and the charging device is simple in whole operation and convenient to use.

Further, the method comprises the following steps:

in an alternative embodiment: the lifting adjusting component 8 comprises a material rack 81, a material groove 82, connecting seats 83, B thread lead screws 84, D motors 85 and a connecting sleeve rack 86, the material rack 81 is sleeved outside the upper sleeve 61 and attached to the bottom of the fluted disc seat 71, the material groove 82 is arranged on the surface of the material rack 81 and corresponds to the position of the material guide column 72, one ends of the material guide columns 72 are connected to the inner wall of the material groove 82 in a sliding mode, the connecting seats 83 are symmetrically bolted and fastened on the surface of the sampling support 5 and correspond to the position of the upper sleeve 61, the B thread lead screws 84 are rotatably connected to the inner walls of the two groups of connecting seats 83, the D motors 85 are bolted and fastened on the surface of the sampling support 5 and correspond to the position of the B thread lead screws 84, the output ends of the D motors 85 are fixedly connected to the outer surface of one end of the B thread lead screws 84, the connecting sleeve rack 86 is in threaded connection with the outer surface of the B thread lead screws 84 and sleeved outside the material rack 81, the material rack 81 comprises a material disk seat 811 and a barrel column 812 which are arranged up and down, the bottom of the charging tray seat 811 is rotatably connected to the top of the column 812, the charging troughs 82 are uniformly arranged on the surface of the charging tray seat 811, and the connecting sleeve frame 86 is sleeved outside the column 812.

In this embodiment, it should be noted that: during the use, put into silo 82 with feed cylinder 9, then through controller 3 control D motor 85 circular telegram operation, D motor 85 circular telegram is rotatory to drive B screw lead screw 84 rotatory in step, B screw lead screw 84 is rotatory to drive in step and connects set frame 86 to rise, it rises to connect set frame 86 to rise to drive work or material rest 81 in step, work or material rest 81 rises to drive feed cylinder 9 to rise in step and overlap and establish in the guide post 72 outside, and laminate mutually with fluted disc seat 71 bottom, realize the installation and the fixed of feed cylinder 9 through above operation, whole easy operation, the practicality is strong and excellent in use effect.

Further, the method comprises the following steps:

in an alternative embodiment: the depth adjusting assembly 10 comprises a supporting plate 101, an adjusting bolt 102, a lower sleeve 103, an induction sleeve holder 104, a contact rod 105, a rod groove 106 and a pressure sensor 107, wherein the supporting plate 101 is arranged on the inner wall of the moving frame 1 and positioned on one side of the rotating shaft seat 41, the adjusting bolt 102 is symmetrically and threadedly connected to the top of the supporting plate 101, one end of the adjusting bolt 102 penetrates through the bottom of the supporting plate 101 and is threadedly connected to the inner wall of the moving frame 1, the lower sleeve 103 is threadedly connected to the top of the supporting plate 101 and corresponds to the upper sleeve 61 in position, one end of the lower sleeve 103 is slidably connected to the inner wall of the upper sleeve 61 and is sleeved outside the spiral auger 62, the induction sleeve holder 104 is slidably connected to the outer side wall of the lower sleeve 103, the induction sleeve holder 104 is matched with the outer dimension of the upper sleeve 61, the contact rod 105 is uniformly and threadedly connected to the top of the induction sleeve holder 104, the rod groove 106 is uniformly arranged at the bottom of the upper sleeve 61 and corresponds to the position of the contact rod 105, the pressure sensor 107 is threadedly connected to the inner wall of the rod groove 106, one end of the feeler lever 105 is slidably connected to the inner wall of the lever groove 106 and is attached to the surface of the pressure sensor 107.

In this embodiment, it should be noted that: when the lifting device is used, the height between the supporting plate 101 and the inner wall of the moving frame 1 can be adjusted through the adjusting bolt 102, so that the ground clearance of the lower sleeve 103 is adjusted, when the lifting component 4 drives the sampling support 5 to descend, the sampling support 5 synchronously drives the sampling component 6 to descend, the upper sleeve 61 is driven by the sampling support 5 to descend along the lower sleeve 103, when the contact rod 105 at the top of the induction sleeve frame 104 extends into the rod groove 106 and is in contact with the pressure sensor 107, the pressure sensor 107 transmits data information to the controller 3, the controller 3 controls the motor A44 and the motor B63 to stop running, so that the spiral auger 62 is controlled to stop descending and suspend sampling operation, then the controller 3 controls the motor A44 to rotate reversely so as to drive the sampling support 5 to reset, and synchronously drives the sampling component 6 to reset, wherein the contact distance between the contact rod 105 and the pressure sensor 107 can be changed by adjusting the relative position of the induction sleeve frame 104 so as to control the sampling depth of the spiral auger 62, the whole operation is simple, the performance is stable, and the using effect is good.

Further, the method comprises the following steps:

in an alternative embodiment: the discharging pipe 64, the material guiding column 72, the material groove 82 and the charging barrel 9 are all positioned on the same axial line.

In this embodiment, it should be noted that: the material discharging pipe 64, the material guiding column 72, the material groove 82 and the material barrel 9 are designed on the same axial lead, so that the blanking position is accurate, the practicability is high, and the using effect is good.

Further, the method comprises the following steps:

in an alternative embodiment: the surface of the sliding frame 43 corresponding to the position of the inner wall of the moving frame 1 and the surface of the connecting sleeve frame 86 corresponding to the position of the surface of the sampling support 5 are respectively provided with a guide strip 431 and a guide groove, and the guide strip 431 is slidably connected with the inner wall of the guide groove.

In this embodiment, it should be noted that: the guide strip 431 and the guide groove are designed to play a role in guiding and limiting, the structural stability of the sliding frame 43 and the connecting sleeve frame 86 during lifting is improved respectively, the operation is simple, and the using effect is good.

Further, the method comprises the following steps:

in an alternative embodiment: an adjusting groove 1031 and an adjusting block 1041 are respectively arranged on the surface of the lower sleeve 103 corresponding to the inner wall of the induction sleeve frame 104, and the adjusting block 1041 is connected to the inner wall of the adjusting groove 1031 in a sliding manner and fixedly connected through a locking bolt 1042.

In this embodiment, it should be noted that: the design of adjusting groove 1031 and regulating block 1041 is convenient for adjust response set frame 104 position, thereby adjusts the sample depth through the position of adjusting response set frame 104, easy operation, excellent in use effect.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides an ore geology sampler, includes travelling carriage (1), its characterized in that: the power supply cabinet (2) is fastened by bolts on the surface of the movable frame (1), the controller (3) is embedded in the surface of the power supply cabinet (2), the lifting assembly (4) is fastened by bolts on the inner wall of the movable frame (1), the sampling support (5) is sleeved on the outer side of the lifting assembly (4), the sampling support (5) is internally provided with the sampling assembly (6), one end of the sampling assembly (6) penetrates through the bottom of the sampling support (5), the outer side of the sampling assembly (6) is respectively sleeved with the rotating assembly (7) and the lifting adjusting assembly (8) up and down, the rotating assembly (7) is connected with the lifting adjusting assembly (8) in a clamping manner and is positioned at the inner side of the sampling support (5), the charging barrel (9) is fixed on the top of the lifting adjusting assembly (8) in an even clamping manner, and the top of the charging barrel (9) is attached to the bottom of the rotating assembly (7), lifting unit (4) one side bolt-up has degree of depth adjusting part (10), just degree of depth adjusting part (10) is corresponding with sampling subassembly (6) position, the one end sliding connection that moving vehicle frame (1) inner wall was kept away from in degree of depth adjusting part (10) is at sampling subassembly (6) inner wall, controller (3) respectively with lifting unit (4), sampling subassembly (6), rotating assembly (7), lifting adjusting part (8) and degree of depth adjusting part (10) electric connection.

2. An ore geology sampler as defined in claim 1, wherein: the power supply cabinet (2) is internally provided with a storage battery (21), the storage battery (21) is electrically connected with the controller (3), and a charging interface is arranged on the surface of the power supply cabinet (2) corresponding to the position of the storage battery (21).

3. An ore geology sampler as defined in claim 2, wherein: lifting unit (4) is including pivot seat (41), A thread screw (42), balladeur train (43) and A motor (44), pivot seat (41) bolt-up is at moving vehicle frame (1) inner wall, A thread screw (42) one end is rotated and is connected at pivot seat (41) inner wall, and the other end runs through moving vehicle frame (1) top and rotation connection on moving vehicle frame (1) surface, balladeur train (43) threaded connection is on A thread screw (42) surface and sliding connection is at moving vehicle frame (1) inner wall, A motor (44) bolt-up is at moving vehicle frame (1) top and corresponding with A thread screw (42) position, A motor (44) output end fixed connection runs through the one end surface at moving vehicle frame (1) top at A thread screw (42).

4. An ore geology sampler as defined in claim 3, wherein: the sampling component (6) is including last sleeve pipe (61), spiral auger (62), B motor (63) and row's material pipe (64), go up sleeve pipe (61) bolt-up at sample support (5) inner wall, go up sleeve pipe (61) one end and run through out sample support (5) bottom, spiral auger (62) rotate to be connected at last sleeve pipe (61) inner wall, spiral auger (62) one end runs through out sleeve pipe (61) bottom and extends sample support (5) bottom outside, B motor (63) bolt-up is corresponding at sample support (5) top and with spiral auger (62) position, B motor (63) output end fixed connection is at spiral auger (62) one end surface, arrange material pipe (64) and set up inside sample support (5), it is linked together to arrange material pipe (64) one end and last sleeve pipe (61) inside, the other end penetrates through the surface of the sampling support (5) and corresponds to the position of the charging barrel (9).

5. An ore geology sampler as defined in claim 4 wherein: rotating assembly (7) is including fluted disc seat (71), guide post (72), rack (73) and C motor (74), fluted disc seat (71) rotate to be connected on sample support (5) surface and cup joint in last sleeve pipe (61) outside, the even threaded connection of guide post (72) is on fluted disc seat (71) surface, rack (73) rotate to be connected on sample support (5) surface and lie in fluted disc seat (71) one side, rack (73) are connected with fluted disc seat (71) meshing, C motor (74) bolt-up is corresponding at sample support (5) inner wall and with rack (73) position, C motor (74) output end fixed connection is in rack (73) center pin one end surface.

6. An ore geology sampler as defined in claim 5, wherein: the lifting adjusting assembly (8) comprises a material rack (81), a material groove (82), connecting seats (83), a B thread screw rod (84), a D motor (85) and a connecting sleeve frame (86), the material rack (81) is sleeved outside the upper sleeve (61) and is attached to the bottom of the gear plate seat (71), the material groove (82) is formed in the surface of the material rack (81) and corresponds to the position of the material guide column (72), one end of the material guide column (72) is connected to the inner wall of the material groove (82) in a sliding mode, the connecting seats (83) are symmetrically fastened on the surface of the sampling support (5) through bolts and correspond to the position of the upper sleeve (61), the B thread screw rod (84) is rotatably connected to the inner walls of the two groups of connecting seats (83), the D motor (85) is fastened on the surface of the sampling support (5) through bolts and corresponds to the position of the B thread screw rod (84), and the output end of the D motor (85) is fixedly connected to the outer surface of one end of the B thread screw rod (84), connecting sleeve frame (86) threaded connection is in B screw lead screw (84) surface and cup joints in the work or material rest (81) outside, work or material rest (81) are including feed tray seat (811) and section of thick bamboo post (812) that set up from top to bottom, rotate to connect in section of thick bamboo post (812) top in feed tray seat (811) bottom, silo (82) are evenly seted up on feed tray seat (811) surface, connecting sleeve frame (86) cup joint in section of thick bamboo post (812) outside.

7. An ore geology sampler as defined in claim 6, wherein: the depth adjusting component (10) comprises a support plate (101), an adjusting bolt (102), a lower sleeve (103), an induction sleeve frame (104), a feeler lever (105), a lever groove (106) and a pressure sensor (107), wherein the support plate (101) is arranged on the inner wall of the movable frame (1) and positioned on one side of the rotating shaft seat (41), the adjusting bolt (102) is symmetrically and threadedly connected to the top of the support plate (101), one end of the adjusting bolt (102) penetrates through the bottom of the support plate (101) and is threadedly connected to the inner wall of the movable frame (1), the lower sleeve (103) is threadedly connected to the top of the support plate (101) and corresponds to the upper sleeve (61), one end of the lower sleeve (103) is slidably connected to the inner wall of the upper sleeve (61) and is sleeved on the outer side of the spiral auger (62), the induction sleeve frame (104) is slidably connected to the outer side wall of the lower sleeve (103), and the induction sleeve frame (104) is matched with the outer size of the upper sleeve (61), the even threaded connection of feeler lever (105) is at response set frame (104) top, pole groove (106) are evenly seted up in last sleeve pipe (61) bottom and are corresponding with feeler lever (105) position, the equal threaded connection of pressure sensor (107) is in pole groove (106) inner wall, the equal sliding connection of feeler lever (105) one end is in pole groove (106) inner wall and with pressure sensor (107) surface laminating mutually.

8. An ore geology sampler as defined in claim 7, wherein: the discharging pipe (64), the material guiding column (72), the material groove (82) and the material barrel (9) are all arranged on the same axial line.

9. An ore geology sampler as defined in claim 8, wherein: the surface of the sliding frame (43) is provided with a guide strip (431) and a guide groove at the position corresponding to the position of the inner wall of the moving frame (1) and the surface of the connecting sleeve frame (86) is provided with a position corresponding to the position of the surface of the sampling support (5), and the guide strip (431) is connected to the inner wall of the guide groove in a sliding manner.

10. An ore geology sampler as defined in claim 9, wherein: the surface of the lower sleeve (103) is provided with an adjusting groove (1031) and an adjusting block (1041) at the position corresponding to the inner wall of the induction sleeve frame (104), and the adjusting block (1041) is connected to the inner wall of the adjusting groove (1031) in a sliding mode and is fixedly connected through a locking bolt (1042).

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