CN212133612U - Multi-kinetic energy observation mirror for geological exploration - Google Patents

Abstract

The utility model discloses a many kinetic energy sight glasses of prospecting, including sight glass, distancer, fixed station, spirit level and adjustable support. The right side of sight glass is fixed with the distancer, and there is the fixed station the below of sight glass, and there is the spirit level one side of fixed station, installs adjustable support below the fixed station, the utility model relates to a geological exploration's technical field. The invention solves the problems that the terrain to be observed can not be clearly explored in the geological exploration process, the exploration position distance can not be accurately known in the exploration process, and the exploration instrument can not be fixedly adjusted in the complex terrain. Can be fine fixed to the observation instrument through the regulation to adjustable support, shimmer night-vision mirror and illumination in the observation mirror make also can be fine exploration to the topography night, and the distancer then can carry out the measurement of distance to the topography of exploration.

Description

Multi-kinetic energy observation mirror for geological exploration

Technical Field

The utility model relates to a technical field of geological exploration specifically is a many kinetic energy sight glasses of geological exploration.

Background

The "geology" is exactly called geology and is used to be called geology. Geology is one of seven natural sciences, and is mainly used for researching the earth and the cause and evolution development of the earth. The practical application is very extensive: earthquake prediction, search and exploration of various mineral products, disastrous landslide and evolution of ancient creatures. All objects built on the ground have to be known in advance about the underground situation. Geological exploration is to find an industrially significant mineral deposit in mineral census, provide mineral reserves and geological data required by mine construction design for finding out the quality and quantity of mineral products and technical conditions of mining and utilization, and carry out investigation and research work on geological conditions such as rocks, strata, structures, mineral products, hydrology, landforms and the like in a certain area. The existing geological exploration mostly adopts a manual observation mode, and the problems that the traditional geological exploration process is effectively observed through equipment such as a magnifying glass in the existing mode, the terrain to be observed can not be clearly explored, the exploration position distance can not be accurately known in the exploration process, and an exploration instrument can not be fixedly adjusted in the complex terrain due to the influence of the used equipment.

Disclosure of Invention

Technical problem to be solved

The utility model provides a not enough to prior art, the utility model provides a many kinetic energy of geological exploration sight glass has solved the topography that the exploration that can not be clear will observe in the geological exploration process, can not know the exploration position distance at the exploration in-process accuracy and can not fix the problem of adjusting the exploration instrument in the topography of complicacy.

(II) technical scheme

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: the utility model provides a many kinetic energy sight glasses of prospecting, includes sight glass, folded cascade board and vertical rod, its characterized in that: the middle position of the right side of the outer surface of the observation mirror is fixedly connected with a distance measuring instrument, and through the arrangement of an arrangement button on the distance measuring instrument, the survey terrain may be measured for distance, the measured data being displayed on a display screen of the survey meter, the middle position of the bottom of the outer surface of the observation mirror is movably connected with an observation mirror supporting rod, the bottom of the supporting rod is provided with a fixed platform, a level meter is embedded in the top of the fixed table at the right side of the supporting rod and used for detecting whether the mounting surface or the flat plate of the measuring instrument is horizontal or not and measuring the size of the inclination direction and the angle, the shape of the frame seat is made of high-grade steel material, after precision machining, the base of the frame seat must be flat, the center of the seat surface is provided with a long and round glass tube, the left end is also provided with a transverse small horizontal glass tube, the inside of the glass tube is filled with ether or alcohol, and a small bubble is left, and the small bubble is always positioned at the highest point in the glass tube. The utility model discloses a foldable plate, including folded cascade board, vertical pole, but the top fixed connection folded cascade board of vertical pole, the surface cover of vertical pole is equipped with vertical pole wrapping cover, but the top of vertical pole wrapping cover is fixed with adjusting bracket, but the top right side screw in of vertical pole wrapping cover is provided with vertical pole adjusting screw, the surface cover of vertical pole wrapping cover is equipped with the slide bar, the surface right side intermediate position of slide bar is provided with slide bar adjusting screw, but adjusting bracket's mid-mounting has the telescopic link slider, be provided with the telescopic link between telescopic link slider and the slide bar.

Preferably, the observation mirror comprises a protective shell, and a low-light night vision mirror, an eyepiece group, a focusing lens, an objective group and a lighting device are sequentially arranged in an inner cavity of the protective shell from left to right.

Preferably, the number of the adjustable supports is 3, and the adjustable supports are distributed in an equilateral triangle shape.

Preferably, the number of the telescopic rods is 3.

Preferably, the vertical pole parcel cover is slightly less than the vertical pole, and gliding realization is through rotatory slide bar adjusting screw, when the slide bar adjusting screw moved outward, just can adjust the height of vertical pole, when the slide bar adjusting screw moved inward, slide bar adjusting screw will be supported the vertical pole, just at this moment by fixed between vertical pole parcel cover and the vertical pole, the slide bar slightly is less than vertical pole parcel cover.

Preferably, the length of the extension rod after extension is smaller than that of the adjustable support, and the length of the extension rod after extension is larger than that of the sliding rod.

(III) advantageous effects

The utility model provides a many kinetic energy sight glasses of prospecting. The method has the following beneficial effects:

the multifunctional observation mirror can clearly observe under the condition that the illumination brightness of exploration terrain is not good through the low-light night vision goggles and the lighting device on the observation mirror. Before observing, at first fix adjustable support, fix the instrument on stable position, open the illumination on the sight glass, make the illumination correspond the position of observing, observe, if open the illumination utensil after the effect of observing still not good time, we can adjust low light night vision mirror, increase the definition of observing.

When the multi-kinetic-energy observation mirror is used for observing geology in different directions, the observation can be carried out without changing the position of an instrument. The vertical rod is separated from the vertical rod wrapping sleeve by rotating the vertical rod rotating screw, the vertical rod is rotated and lifted, the direction and the height of the vertical rod can be adjusted, the observation direction is adjusted by the observation mirror, the vertical rod rotating screw is rotated inwards, the vertical rod rotating screw abuts against the vertical rod, and the adjustment is completed at the moment.

The multifunctional observation mirror is characterized in that a gradienter is embedded in one end of a fixed table connected with a foldable plate, the gradienter is used for detecting whether a mounting surface or a flat plate of the measuring instrument is horizontal or not and detecting the inclination direction and the angle of the measuring instrument, the appearance of the observation mirror is that a frame base is made of high-grade steel materials, after precision machining, the base of the frame base needs to be flat, a long and round glass tube is arranged in the center of a seat surface, a transverse small horizontal glass tube is also arranged at the left end of the seat surface, the inside of the tube is filled with ether or alcohol, a small bubble is left, and the small bubble is always positioned at the highest.

(IV), this multi-kinetic energy sight glass, right-hand member fixedly connected with distancer sets up through setting up the button on the distancer, can carry out measuring distance to the topography of exploration, and measured data shows in the display screen of measuring apparatu.

(five), this many kinetic energy sight glass, there is the clearance between vertical rod parcel cover and the vertical rod, the clearance between vertical rod parcel cover and the vertical rod can make and to slide between the two, gliding realization is through rotatory vertical rod adjusting screw, when vertical rod adjusting screw toward outer the removal, space between vertical rod parcel cover and the vertical rod will produce, just can adjust the height of vertical rod this moment, when vertical rod adjusting screw toward the interior removal, vertical rod adjusting screw will support the vertical rod, just at this moment by fixed between vertical rod parcel cover and the vertical rod.

Drawings

FIG. 1 is a schematic view of the overall structure of the multi-kinetic energy observation mirror of the present invention;

FIG. 2 is a schematic structural view of the observation mirror of the present invention;

FIG. 3 is a schematic structural view of the level device of the present invention;

FIG. 4 is a schematic structural view of the vertical rod adjusting screw of the present invention;

FIG. 5 is a schematic structural view of the telescopic rod of the present invention;

in the figure: 1 sight glass, 2 distancers, 3 sight glass bracing pieces, 4 fixed stations, 5 spirit levels, 6 folded cascade boards, 7 folded cascade board adjusting screws, 8 vertical poles, 9 vertical pole adjusting screws, 10 vertical pole wrapping covers, 11 slide bars, 12 adjustable supports, 13 slide bar adjusting screws, 14 telescopic links, 15 telescopic link sliders, 101 shimmer night-vision goggles, 102 eyepiece group, 103 focusing lens, 104 objective group, 105 lighting apparatus, 106 protective housing.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example (b):

referring to fig. 1-5, the present invention provides a technical solution: a multi-kinetic energy observation mirror for geological exploration comprises an observation mirror 1, a foldable plate 6 and a vertical rod 8, wherein a distance measuring instrument 2 is fixedly connected to the middle position of the right side of the outer surface of the observation mirror 1, an observation mirror supporting rod is movably connected to the middle position of the bottom of the outer surface of the observation mirror 1, a fixed table 4 is installed at the bottom of the supporting rod 3, a level meter 5 is embedded into the top of the fixed table 4, which is positioned on the right side of the supporting rod 3, a foldable plate adjusting screw 7 is arranged at the middle position of the foldable plate 6, the foldable plate 6 is fixedly connected to the top of the vertical rod 8, a vertical rod wrapping sleeve 10 is sleeved on the outer surface of the vertical rod 8, an adjustable support 12 is fixed at the top of the vertical rod wrapping sleeve 10, a vertical rod adjusting screw 9 is screwed into the right side of the top of the vertical rod wrapping sleeve 10, a sliding rod 11 is sleeved on the, the middle part of the adjustable bracket 12 is provided with a telescopic rod slider 15, and a telescopic rod 14 is arranged between the telescopic rod slider 15 and the sliding rod 11.

The observation mirror 1 comprises a protective casing 106, and a low-light night vision goggles 101, an eyepiece group 102, a focusing lens 103, an objective lens group 104 and a lighting device 105 are sequentially arranged in an inner cavity of the protective casing 106 from left to right.

The number of the adjustable supports 12 is 3, and the adjustable supports are distributed in an equilateral triangle shape.

The telescopic rod 14 is provided with 3.

The vertical pole wrapping sheath 10 is slightly shorter than the vertical pole 8, and the sliding pole 11 is slightly shorter than the vertical pole wrapping sheath 10.

The extended length of the telescopic rod 14 is less than that of the adjustable bracket 12, and the extended length of the telescopic rod 14 is greater than that of the sliding rod 11.

The using method comprises the following steps:

firstly, an adjustable support 12 is fixed, a gap exists between a sliding rod 11 and a vertical rod wrapping sleeve 10, the sliding rod 11 and the vertical rod wrapping sleeve 10 can slide through the gap, the sliding is realized by rotating a sliding rod adjusting screw 13, when the sliding rod adjusting screw 13 moves outwards, a gap between the sliding rod 11 and the vertical rod wrapping sleeve 10 is generated, at the moment, the height of the sliding rod 11 can be adjusted, the sliding rod 11 can be changed to drive the adjustable support 12 to change, when the sliding rod adjusting screw 13 moves inwards, the sliding rod adjusting screw 13 abuts against the vertical rod wrapping sleeve 10, at the moment, the vertical rod wrapping sleeve 10 and the sliding rod 11 are fixed, then, the telescopic rod 14 is adjusted, and the instrument fixing is completed. After fixing the instrument in stable position, open lighting apparatus 105 on the sight glass, make lighting apparatus 105 correspond the position observed, observe, if open the effect of observing after illumination 105 still not good, we can adjust shimmer night-vision goggles 101, increase the definition of observing, when observing different position, through rotatory vertical pole swivel screw 9, because there is the space between vertical pole 8 and the vertical pole wrapping sheath 10, at this moment vertical pole 8 and the separation of vertical pole wrapping sheath 10, rotatory and lift vertical pole 8, can adjust the direction and the height of vertical pole 8, when the sight glass adjusts the position observed, rotatory screw 9 of the vertical pole of inwards rotation, make vertical pole swivel screw 9 support vertical pole 8, just at this moment, accomplished the regulation. The right-hand member fixedly connected with distancer 2 of sight glass 1 sets up through setting up the button on distancer 2, can carry out measuring distance to the topography of exploration, and measured data shows in distancer 2's display screen.

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

Claims (6)

1. A multi-kinetic energy observation mirror for geological exploration, which comprises an observation mirror (1), a foldable plate (6) and a vertical rod (8), and is characterized in that: the range finder (2) is fixedly connected to the middle position of the right side of the outer surface of the observation mirror (1), the observation mirror supporting rod (3) is movably connected to the middle position of the bottom of the outer surface of the observation mirror (1), the fixing table (4) is installed at the bottom of the supporting rod (3), the level meter (5) is embedded into the top of the fixing table (4) and positioned on the right side of the supporting rod (3), the foldable plate adjusting screw (7) is arranged at the middle position of the foldable plate (6), the foldable plate (6) is fixedly connected to the top of the vertical rod (8), the vertical rod wrapping sleeve (10) is sleeved on the outer surface of the vertical rod (8), the adjustable support (12) is fixed to the top of the vertical rod wrapping sleeve (10), the vertical rod adjusting screw (9) is screwed into the top right side of the vertical rod wrapping sleeve (10), the sliding rod (11) is sleeved on the outer surface of the vertical rod, a sliding rod adjusting screw (13) is arranged in the middle of the right side of the outer surface of the sliding rod (11), a telescopic rod slider (15) is installed in the middle of the adjustable support (12), and a telescopic rod (14) is arranged between the telescopic rod slider (15) and the sliding rod (11).

2. The multi-kinetic energy viewer of geological exploration, as defined by claim 1, wherein: the observation mirror (1) comprises a protective shell (106), and a low-light night vision mirror (101), an eyepiece group (102), a focusing lens (103), an objective group (104) and a lighting device (105) are sequentially arranged in an inner cavity of the protective shell (106) from left to right.

3. The multi-kinetic energy viewer of geological exploration, as defined by claim 1, wherein: the number of the adjustable supports (12) is 3, and the adjustable supports are distributed in an equilateral triangle shape.

4. The multi-kinetic energy viewer of geological exploration, as defined by claim 1, wherein: the number of the telescopic rods (14) is 3.

5. The multi-kinetic energy viewer of geological exploration, as defined by claim 1, wherein: the vertical rod wrapping sleeve (10) is slightly shorter than the vertical rod (8), and the sliding rod (11) is slightly shorter than the vertical rod wrapping sleeve (10).

6. The multi-kinetic energy viewer of geological exploration, as defined by claim 1, wherein: the length of the extension rod (14) after extension is smaller than that of the adjustable support (12), and the length of the extension rod (14) after extension is larger than that of the sliding rod (11).

Images