CN219084743U - Gold and silver ore component analysis and detection equipment - Google Patents

Abstract

The utility model relates to the technical field of ore component analysis, in particular to a gold and silver ore component analysis and detection device. Through setting up the frame of placing, the atomic absorption spectrometer of displacement has about having set up in the standing groove of this frame of placing, the elevating platform in the standing groove promotes alternately the crane by electric putter and realizes going up and down, can adjust the height of atomic absorption spectrometer as required, the operating personnel operation of being convenient for, all be provided with down open-ended lifting groove on the four corners of placing the frame, and all be provided with the slide rail on the left and right sides inner wall of lifting groove, slider between two sets of slide rails, the slider bottom is provided with the universal wheel, four sets of universal wheels release lifting groove outside with ground contact under electric telescopic handle's drive, can realize the transport to atomic absorption spectrometer, the levelness of the level sensor detectable elevating platform of setting, and with the detection information transmission to the PLC controller, the PLC controller is according to the length that this information control corresponds electric telescopic handle extension, can realize the level adjustment to atomic absorption spectrometer.

Description

Gold and silver ore component analysis and detection equipment

Technical Field

The utility model relates to the technical field of ore component analysis, in particular to a gold and silver ore component analysis and detection device.

Background

The method is characterized in that before and during the exploitation of the gold and silver ore, the components of the ore need to be detected in stages, the common detection equipment is an atomic absorption spectrometer, the existing atomic absorption spectrometer is high and certain, because the atomic absorption spectrometer has long operation time, if the operation height is not comfortable, workers are easy to fatigue in uncomfortable states for a long time, and meanwhile, the existing atomic absorption spectrometer is inconvenient to carry and move, so that the gold and silver ore component analysis detection equipment is provided for solving the problems.

Disclosure of Invention

The utility model aims to provide a gold and silver ore component analysis and detection device, a placing frame is arranged, an atomic absorption spectrometer which moves up and down is arranged in a placing groove of the placing frame, a lifting table in the placing groove is pushed by an electric push rod to lift by a cross lifting frame, the height of the atomic absorption spectrometer can be adjusted according to requirements, the operation of operators is convenient, lifting grooves which are downwards opened are arranged at four corners of the placing frame, sliding rails are arranged on the inner walls of the left side and the right side of the lifting groove, sliding blocks between the two groups of sliding rails are arranged at the bottom of the sliding blocks, universal wheels are arranged at the bottoms of the four groups of universal wheels, the four groups of universal wheels are pushed out of the lifting groove to contact with the ground under the driving of the electric telescopic rods, the carrying of the atomic absorption spectrometer can be realized, the arranged level sensor can detect the levelness of the lifting table and transmit detection information to a PLC controller, and the PLC controller controls the length corresponding to the extension of the electric telescopic rod according to the information, so that the level adjustment of the atomic absorption spectrometer can be realized, and the problem in the background technology is solved.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

a gold and silver ore constituent analysis and detection apparatus comprising:

the placing frame is internally provided with a placing groove with an upward opening;

the lifting mechanism comprises a lifting table arranged on the bottom plate of the placing groove, a cross lifting frame is arranged between the lifting table and the bottom plate of the placing groove, and an atomic absorption spectrometer is fixedly arranged on the lifting table;

the horizontal adjustment mechanism is provided with downward opening lifting grooves on four corners of the placing frame, sliding rails are arranged on inner walls of the left side and the right side of the lifting grooves, the horizontal adjustment mechanism comprises sliding blocks arranged between the two groups of sliding rails, universal wheels are arranged at the bottoms of the sliding blocks, electric telescopic rods are fixedly arranged on top plates inside the lifting grooves, and the bottoms of the electric telescopic rods are fixedly connected with the sliding blocks.

As a preferable scheme, two groups of rotation mounting seats on the cross arm at the left end of the cross lifting frame are respectively mounted on the bottom plates of the lifting table and the placing groove, the right half areas of the bottom plates of the lifting table and the placing groove are respectively provided with a sliding groove, and two groups of rotation mounting seats on the cross arm at the left end of the cross lifting frame are respectively arranged on the sliding grooves of the lifting table and the placing groove bottom plate in a sliding way.

As a preferable scheme, an electric push rod connected with the bottom plate of the placing groove is arranged on the cross shaft of the cross lifting frame, and two ends of the electric push rod are respectively connected with the bottom plate of the placing groove and the cross shaft of the cross lifting frame in a rotating way through rotating heads.

As a preferable scheme, the inner walls of the left side and the right side of the placing groove are respectively provided with a sliding groove, and the panels of the left side and the right side of the atomic absorption spectrometer are respectively provided with a sliding rod which is arranged in the sliding grooves in a sliding way.

As a preferred scheme, the front side panel of the placement frame is fixedly provided with a control box, an electric push rod controller and a forward and reverse rotation motor controller group are sequentially arranged on a bottom plate inside the control box from left to right, a PLC controller is arranged on the inner wall of the right side of the control box, control signal access ends of the electric push rod controller and the forward and reverse rotation motor controller group are respectively connected with control signal output ends of the PLC controller through electric signals, positive and negative electrode electric energy output ends of the electric push rod controller are connected with electric energy access ends of an electric push rod driving motor through wires, and positive and negative electrode electric energy output ends of four groups of forward and reverse rotation motor controllers in the forward and reverse rotation motor controller group are respectively connected with electric energy access ends of the electric telescopic rod driving motor through wires.

As a preferable scheme, a horizontal sensor is fixedly arranged on the lifting table, and a detection signal output end of the horizontal sensor is connected with a detection signal access end of the PLC through an electric signal.

According to the technical scheme provided by the utility model, the gold and silver ore component analysis and detection equipment provided by the utility model has the beneficial effects that: through setting up the frame of placing, the atomic absorption spectrometer of displacement has about having set up in the standing groove of this frame of placing, the elevating platform in the standing groove promotes alternately the crane by electric putter and realizes going up and down, can adjust the height of atomic absorption spectrometer as required, the operating personnel operation of being convenient for, all be provided with down open-ended lifting groove on the four corners of placing the frame, and all be provided with the slide rail on the left and right sides inner wall of lifting groove, slider between two sets of slide rails, the slider bottom is provided with the universal wheel, four sets of universal wheels release lifting groove outside with ground contact under electric telescopic handle's drive, can realize the transport to atomic absorption spectrometer, the levelness of the level sensor detectable elevating platform of setting, and with the detection information transmission to the PLC controller, the PLC controller is according to the length that this information control corresponds electric telescopic handle extension, can realize the level adjustment to atomic absorption spectrometer.

Drawings

FIG. 1 is a schematic diagram of the whole structure of a gold and silver ore component analysis and detection device;

FIG. 2 is a schematic cross-sectional view of a placement frame according to the present utility model;

FIG. 3 is a schematic view of the internal structure of the control box according to the present utility model.

In the figure: 1. placing a frame; 11. a placement groove; 12. a chute; 2. an atomic absorption spectrometer; 21. a slide bar; 3. a lifting table; 31. a cross lifting frame; 32. a chute; 33. an electric push rod; 34. a level sensor; 35. rotating the mounting seat; 4. a lifting groove; 41. a slide rail; 42. a slide block; 43. an electric telescopic rod; 44. a universal wheel; 5. a control box; 51. an electric push rod controller; 52. a forward and reverse rotation motor controller group; 53. and a PLC controller.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

It will be understood that when an element is referred to as being "mounted" or "disposed" on another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

In the description of the present utility model, it should be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present utility model and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present utility model.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present utility model, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In order to better understand the above technical solutions, the following detailed description will be given with reference to the accompanying drawings and the specific embodiments.

As shown in fig. 1 to 3, an embodiment of the present utility model provides a gold and silver ore component analysis and detection apparatus, including:

the device comprises a placement frame 1, wherein a placement groove 11 with an upward opening is formed in the placement frame 1;

the lifting mechanism comprises a lifting table 3 arranged on a bottom plate of the placing groove 11, a cross lifting frame 31 is arranged between the lifting table 3 and the bottom plate of the placing groove 11, an atomic absorption spectrometer 2 is fixedly arranged on the lifting table 3, two groups of rotating mounting seats 35 on cross arms at the left end of the cross lifting frame 31 are respectively arranged on the lifting table 3 and the bottom plate of the placing groove 11, sliding grooves 32 are respectively arranged in the right half areas of the lifting table 3 and the bottom plate of the placing groove 11, two groups of rotating mounting seats 35 on cross arms at the left end of the cross lifting frame 31 are respectively arranged on the sliding grooves 32 of the lifting table 3 and the bottom plate of the placing groove 11 in a sliding manner, an electric push rod 33 connected with the bottom plate of the placing groove 11 is arranged on a cross shaft of the cross lifting frame 31, and two ends of the electric push rod 33 are respectively connected with the bottom plate of the placing groove 11 and the cross lifting frame 31 in a cross shaft rotation manner through rotating heads;

the horizontal adjustment mechanism is provided with lifting grooves 4 which are downwards opened on four corners of the placement frame 1, sliding rails 41 are arranged on the inner walls of the left side and the right side of the lifting grooves 4, the horizontal adjustment mechanism comprises sliding blocks 42 which are arranged between the two groups of sliding rails 41 in a sliding manner, universal wheels 44 are arranged at the bottoms of the sliding blocks 42, electric telescopic rods 43 are fixedly arranged on top plates inside the lifting grooves 4, and the bottoms of the electric telescopic rods 43 are fixedly connected with the sliding blocks 42.

In the above device, the inner walls of the left and right sides of the placing groove 11 are respectively provided with a sliding groove 12, and the panels of the left and right sides of the atomic absorption spectrometer 2 are respectively provided with a sliding rod 21 which is arranged in the sliding groove 12 in a sliding way.

In the device, a control box 5 is fixedly arranged on the front side panel of the placement frame 1, an electric push rod controller 51 and a forward and backward rotation motor controller group 52 are sequentially arranged on a bottom plate inside the control box 5 from left to right, a PLC controller 53 is arranged on the right side inner wall of the control box 5, control signal access ends of the electric push rod controller 51 and the forward and backward rotation motor controller group 52 are respectively connected with control signal output ends of the PLC controller 53 through electric signals, positive and negative electrode electric energy output ends of the electric push rod controller 51 are connected with electric energy access ends of an electric push rod 33 driving motor through wires, and positive and negative electrode electric energy output ends of four groups of forward and backward rotation motor controllers in the forward and backward rotation motor controller group 52 are respectively connected with electric energy access ends of an electric telescopic rod 43 driving motor through wires.

In the above device, the lifting platform 3 is fixedly provided with the level sensor 34, and the detection signal output end of the level sensor 34 is connected with the detection signal access end of the PLC controller 53 through an electrical signal.

Embodiments of the present utility model will be described in further detail below with reference to the attached drawings:

referring to fig. 1-3, the device comprises a placing frame 1, a placing groove 11 with an upward opening is arranged in the placing frame 1, a lifting table 3 is arranged on a bottom plate of the placing groove 11, a cross lifting frame 31 is arranged between the lifting table 3 and the bottom plate of the placing groove 11, an atomic absorption spectrometer 2 is fixedly arranged on the lifting table 3, two groups of rotating mounting seats 35 on cross arms at the left end of the cross lifting frame 31 are respectively arranged on the lifting table 3 and the bottom plate of the placing groove 11, sliding grooves 32 are respectively arranged in the right half areas of the lifting table 3 and the bottom plate of the placing groove 11, two groups of rotating mounting seats 35 on the cross arms at the left end of the cross lifting frame 31 are respectively arranged on the sliding grooves 32 of the lifting table 3 and the bottom plate of the placing groove 11 in a sliding manner, electric pushing rods 33 connected with the bottom plate of the placing groove 11 are respectively arranged on the cross axes of the cross lifting frame 31, two ends of the electric pushing rods 33 are respectively connected with the bottom plate of the placing groove 11 through cross axes of a rotating head, the placing frame 1 is arranged in the placing groove 11, an atomic absorption spectrometer 2 which is vertically displaced in the placing groove 11, and the lifting table 3 in the placing frame 11 is pushed by the electric pushing rods in the cross lifting frame 31, and the atomic absorption spectrometer 33 can be conveniently adjusted by a worker according to the requirements of atomic absorption spectrometer 2.

Referring to fig. 2, lifting grooves 4 with downward openings are respectively arranged at four corners of the placement frame 1, sliding rails 41 are respectively arranged on inner walls of the left side and the right side of the lifting grooves 4, sliding blocks 42 are slidably arranged between the two groups of sliding rails 41, universal wheels 44 are arranged at the bottoms of the sliding blocks 42, electric telescopic rods 43 are fixedly arranged on top plates inside the lifting grooves 4, and the bottoms of the electric telescopic rods 43 are fixedly connected with the sliding blocks 42.

Referring to fig. 1, sliding grooves 12 are formed on the inner walls of the left and right sides of the placement groove 11, and sliding rods 21 slidably disposed in the sliding grooves 12 are formed on the panels of the left and right sides of the atomic absorption spectrometer 2.

Referring to fig. 3, a control box 5 is fixedly arranged on a front panel of the placement frame 1, an electric push rod controller 51 and a forward and backward rotation motor controller group 52 are sequentially arranged on a bottom plate inside the control box 5 from left to right, a PLC controller 53 is arranged on the inner wall of the right side of the control box 5, control signal access ends of the electric push rod controller 51 and the forward and backward rotation motor controller group 52 are respectively connected with control signal output ends of the PLC controller 53 through electric signals, positive and negative electrode electric energy output ends of the electric push rod controller 51 are connected with electric energy access ends of an electric push rod 33 driving motor through wires, positive and negative electrode electric energy output ends of four groups of forward and backward rotation motor controllers in the forward and backward rotation motor controller group 52 are respectively connected with electric energy access ends of an electric telescopic rod 43 driving motor through wires, a horizontal sensor 34 is fixedly arranged on the lifting table 3, and detection signal output ends of the horizontal sensor 34 are connected with detection signal access ends of the PLC controller 53 through electric signals;

when the atomic absorption spectrometer is specifically used, lifting grooves 4 with downward openings are formed in four corners of the placing frame 1, sliding rails 41 are arranged on inner walls of the left side and the right side of the lifting grooves 4, sliding blocks 42 between the two groups of sliding rails 41 are arranged at the bottoms of the sliding blocks 42, universal wheels 44 are arranged at the bottoms of the four groups of the universal wheels 44, the four groups of the universal wheels 44 are driven by the electric telescopic rods 43 to push out of the lifting grooves 4 to be in contact with the ground, the atomic absorption spectrometer 2 can be carried, the set level sensor 34 can detect the levelness of the lifting table 3, detection information is transmitted to the PLC 53, and the PLC 53 controls the corresponding electric telescopic rods 43 to extend corresponding lengths according to the information, so that the atomic absorption spectrometer 2 can be horizontally adjusted.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a gold and silver ore stone composition analysis check out test set which characterized in that: comprising the following steps:

the device comprises a placement frame (1), wherein a placement groove (11) with an upward opening is formed in the placement frame (1);

the lifting mechanism comprises a lifting table (3) arranged on a bottom plate of the placing groove (11), a cross lifting frame (31) is arranged between the lifting table (3) and the bottom plate of the placing groove (11), and an atomic absorption spectrometer (2) is fixedly arranged on the lifting table (3);

the horizontal adjusting mechanism is characterized in that lifting grooves (4) with downward openings are formed in four corners of the placing frame (1), sliding rails (41) are arranged on inner walls of the left side and the right side of the lifting grooves (4), the horizontal adjusting mechanism comprises sliding blocks (42) arranged between the two groups of sliding rails (41) in a sliding mode, universal wheels (44) are arranged at the bottoms of the sliding blocks (42), electric telescopic rods (43) are fixedly arranged on top plates inside the lifting grooves (4), and the bottoms of the electric telescopic rods (43) are fixedly connected with the sliding blocks (42).

2. The gold and silver ore component analysis and detection apparatus according to claim 1, wherein: two sets of rotation mount pads (35) on the crossing arm of crossing crane (31) left end are installed respectively on the bottom plate of elevating platform (3) and standing groove (11), the right half district of the bottom plate of elevating platform (3) and standing groove (11) all is provided with sliding tray (32), two sets of rotation mount pads (35) on the crossing arm of crossing crane (31) left end slide respectively and set up on sliding tray (32) of elevating platform (3) and standing groove (11) bottom plate.

3. The gold and silver ore component analysis and detection apparatus according to claim 1, wherein: an electric push rod (33) connected with the bottom plate of the placing groove (11) is arranged on the cross shaft of the cross lifting frame (31), and two ends of the electric push rod (33) are respectively connected with the bottom plate of the placing groove (11) and the cross lifting frame (31) in a cross shaft rotating mode through rotating heads.

4. The gold and silver ore component analysis and detection apparatus according to claim 1, wherein: sliding grooves (12) are formed in the inner walls of the left side and the right side of the placing groove (11), and sliding rods (21) which are arranged in the sliding grooves (12) in a sliding mode are arranged on the panels of the left side and the right side of the atomic absorption spectrometer (2).

5. The gold and silver ore component analysis and detection apparatus according to claim 1, wherein: the electric telescopic device is characterized in that a control box (5) is fixedly arranged on the front side panel of the placement frame (1), an electric push rod controller (51) and a forward and backward rotation motor controller group (52) are sequentially arranged on a bottom plate inside the control box (5) from left to right, a PLC (programmable logic controller) controller (53) is arranged on the inner wall of the right side of the control box (5), control signal access ends of the electric push rod controller (51) and the forward and backward rotation motor controller group (52) are respectively connected with control signal output ends of the PLC controller (53) through electric signals, positive and negative electric energy output ends of the electric push rod controller (51) are connected with electric energy access ends of an electric push rod (33) driving motor through wires, and positive and negative electric energy output ends of four groups of forward and backward rotation motor controllers in the forward and backward rotation motor controller group (52) are respectively connected with electric energy access ends of the electric telescopic rod (43) driving motor through wires.

6. The gold and silver ore component analysis and detection apparatus according to claim 1, wherein: the lifting table (3) is fixedly provided with a horizontal sensor (34), and a detection signal output end of the horizontal sensor (34) is connected with a detection signal access end of the PLC (53) through an electric signal.

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