CN113086410B - Stratum soil sample storage device for geological exploration and use method thereof - Google Patents

Abstract

The invention discloses a stratum soil sample storage device for geological exploration and a use method thereof, belonging to the technical field of geological exploration.

Description

Stratum soil sample storage device for geological exploration and application method thereof

Technical Field

The invention relates to the technical field of geological exploration, in particular to a stratum soil sample storage device for geological exploration and a using method thereof.

Background

The geological exploration is an investigation and research activity of surveying and exploring geology by various means and methods, determining a proper bearing stratum, determining a foundation type according to the foundation bearing capacity of the bearing stratum and calculating basic parameters. The method 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 the mineral 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.

Among the prior art, when carrying out the geological survey to soil, need gather partial soil sample, the convenience carries out subsequent research to soil sample, but in the storage process of soil, although put into sealed storage jar with it, when depositing, probably residual part's air in the storage jar, consequently can accelerate the oxidation of the interior material of soil.

Disclosure of Invention

1. Technical problem to be solved

The invention aims to provide a stratum soil sample storage device for geological exploration and a using method thereof, the stratum soil sample storage device can drive a piston plate to move upwards along the inner wall of a buffer guide pipe by rotating a threaded rotating rod, so that the air pressure in a built-in cavity is reduced, the air remained in a soil sample storage tank enters the built-in cavity after ejecting a rubber sealing sheet, a large amount of heat can be generated by means of contact of heating powder and the air, on one hand, the possibility that the soil in the soil sample storage tank is gradually oxidized can be reduced by sucking the air, on the other hand, the gas flowing efficiency in a sealing plug cover can be improved by means of the heat generated in the reaction process, so that the absorption effect of the air in the soil sample storage tank is improved, and meanwhile, the heating powder can be scattered, so that the reaction efficiency of the heating powder and the air is improved, and the consumption speed of the air is improved.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

A stratum soil sample storage device for geological exploration comprises a soil sample storage tank, a sealing plug cover is connected to the upper end of the soil sample storage tank in a threaded mode, a built-in cavity is formed in the sealing plug cover in a chiseled mode, an exchange hole communicated with the built-in cavity is formed in the bottom end of the sealing plug cover in a chiseled mode, a filter screen is connected to the inner wall of the exchange hole, two rubber sealing pieces which are abutted to each other and located on the upper side of the filter screen are connected to the inner wall of the exchange hole, a buffer guide pipe communicated with the built-in cavity is mounted at the upper end of the sealing plug cover in an embedded mode, a threaded rotating rod is connected to the buffer guide pipe in a threaded mode, a piston plate in contact with the inner wall of the buffer guide pipe is connected to the bottom end of the threaded rotating rod in a rotating mode, a pair of heat transfer carriers is connected to the inner top end of the built-in cavity, the piston plate can be driven to move upwards along the inner wall of the buffer guide pipe through the rotating of the threaded rotating rod, accordingly, air pressure in the built-in cavity is reduced, residual air in the soil sample storage tank is pushed out of the rubber sealing pieces and then enters the built-in cavity, a heating powder storage tank, a large amount of heat can be generated through contact with the air absorption effect of the air absorption in the sealing plug cover can be improved, and the air absorption efficiency of the air storage tank can be improved, and the air absorption efficiency of the air storage tank.

Furthermore, the heat transfer carrier comprises an upper heat conducting rod penetrating through the sealing plug cover, the bottom end of the upper heat conducting rod is connected with a heat change ball bag, a built-in magnetic ball is arranged in the heat change ball bag, the bottom end of the heat change ball bag is connected with a lower heat conducting rod, and the heat change ball bag can be expanded by means of heat generated in the reaction process of air and heating powder through the reaction of the air and the heating powder, so that the magnetic shielding of the built-in magnetic ball is removed, on one hand, the scattering effect of the heating powder can be improved by means of the expansion of the built-in magnetic ball, and on the other hand, the ferroferric oxide powder generated after the heating powder reacts with the air can be adsorbed by means of the adsorption effect of the built-in magnetic ball.

Furthermore, the opening of sealed gag upper end has the label to paste the groove, go up the heat-conducting rod inlay establish with the label paste inslot bottom, through setting up the label subsides groove, can make things convenient for the record person to paste the sticker of the information of record soil sample at the label pastes the inslot to with the help of the heat of last heat-conducting rod transmission, can improve the viscidity that improves sticker bottom glue.

Furthermore, the built-in cavity is filled with heating powder, the heating powder is made of reducing iron powder materials, and the heating powder can consume air in the soil sample storage tank through reaction of the heating powder and the air.

Further, the upper and lower heat conduction rods are made of an aluminum material, and the efficiency of transferring heat can be improved by manufacturing the upper and lower heat conduction rods using an aluminum material.

Furthermore, a plurality of uniformly distributed magnetic insulation powder is embedded in the thermal change balloon, the magnetic insulation powder is made of iron-nickel alloy material with the nickel content of 80%, and the arrangement of the magnetic insulation powder can promote the increase of the distance between the magnetic insulation powder after the thermal change balloon is expanded, so that the magnetic shielding of the built-in magnetic ball is eliminated.

Furthermore, the outer end of the thermal change balloon is connected with a plurality of capillary fiber spines which are uniformly distributed, the distance between the capillary fiber spines is 50 mu m, and the stirring effect of the thermal change balloon on the heating powder can be improved by arranging the capillary fiber spines.

Further, two be connected with the screening rope down between the heat conduction pole, be connected with a plurality of evenly distributed's screening disc between the screening rope, through setting up screening rope and screening disc, can be after the thermal change sacculus inflation, can improve the effect of scattering of stirring to the powder that heats.

A use method of a stratum soil sample storage device for geological exploration comprises the following steps:

s1, a piston plate can be driven to move upwards along the inner wall of a buffer guide pipe by rotating a threaded rotating rod, so that the air pressure in a built-in cavity is reduced, and the air remained in a soil sample storage tank pushes open a rubber sealing sheet and then enters the built-in cavity;

s2, a large amount of heat can be generated by means of contact between the heating powder and air, and the possibility that soil in the soil sample storage tank is gradually oxidized can be reduced by sucking air;

s3, by means of heat generated in the reaction process, the gas flow efficiency in the sealing plug cover can be improved, so that the absorption effect of air in the soil sample storage tank is improved, and meanwhile, the heating powder can be scattered, so that the reaction efficiency of the heating powder and the air is improved, and the consumption speed of the air is increased.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) This scheme can drive the piston board through rotatory screw bull stick and move on along the buffering pipe inner wall, with this atmospheric pressure in reducing built-in cavity, thereby make remaining air in the soil sample holding vessel push up and enter into to built-in cavity behind the rubber mounting, with the help of the contact of heating powder and air, can produce a large amount of heats, on the one hand through inhaling the possibility that can reduce soil in the soil sample holding vessel by oxidation gradually with the air, on the other hand is with the help of the heat that produces in the reaction sequence, can improve the gas flow efficiency in the sealed gag, with this absorption effect to the interior air of soil sample holding vessel that improves, the powder of also can will heating is broken up simultaneously, thereby improve the reaction efficiency of heating powder and air, with this consumption speed to the air that improves.

(2) The heat transfer carrier includes with the last heat conduction pole that runs through sealed gag, it is connected with the heat altered sacculus to go up the heat conduction pole bottom, be equipped with built-in magnetism ball in the heat altered sacculus, heat altered sacculus bottom is connected with down the heat conduction pole, through the reaction of air with the powder of heating, can be with the help of the heat that produces in its reaction process, make the heat altered sacculus inflation, thereby remove the magnetic screen to built-in magnetism ball, on the one hand with the help of its inflation, can improve the effect of breaing up the powder of heating, on the other hand with the help of the adsorption of built-in magnetism ball, can adsorb the ferroferric oxide powder that produces after the powder of heating reacts with the air.

(3) The upper end of the sealing plug cover is provided with a label sticking groove, the upper heat conducting rod is embedded in the bottom end of the label sticking groove, and the label sticking groove is arranged, so that a recorder can conveniently stick a sticker for recording information of a soil sample in the label sticking groove, and the stickiness of the bottom glue of the sticker can be improved by means of the heat transferred by the upper heat conducting rod.

(4) The built-in cavity is filled with heating powder, the heating powder is made of reducing iron powder materials, and the heating powder can consume air in the soil sample storage tank through reaction of the heating powder and the air.

(5) The upper and lower heat conduction rods are made of an aluminum material, and the efficiency of transferring heat can be improved by making the upper and lower heat conduction rods of an aluminum material.

(6) A plurality of uniformly distributed magnetism-insulating powder are embedded in the heat-variable saccule and made of iron-nickel alloy material with nickel content of 80%, and the magnetism-insulating powder can promote the expansion of the heat-variable saccule and increase the distance between the magnetism-insulating powder, so that the magnetic shielding of the built-in magnetic ball is removed.

(7) The outer end of the thermal change balloon is connected with a plurality of capillary fiber spines which are uniformly distributed, the distance between the capillary fiber spines is 50 mu m, and the stirring effect of the thermal change balloon on heating powder can be improved by arranging the capillary fiber spines.

(8) Be connected with the screening rope under two between the heat conduction pole, be connected with a plurality of evenly distributed's screening disc between the screening rope, through setting up screening rope and screening disc, can be after the thermal change sacculus inflation, can improve the effect of scattering to the stirring of heating the powder.

Drawings

FIG. 1 is a cross-sectional view of a portion of a soil sample storage tank of the present invention;

FIG. 2 is a schematic view of the structure at A in FIG. 1;

FIG. 3 is a cross-sectional view of a portion of the buffer tube of the present invention;

FIG. 4 is a cross-sectional view of a heat transfer carrier portion of the present invention;

fig. 5 is a cross-sectional view of the expansion of the heat transfer carriers of the present invention.

The reference numbers in the figures illustrate:

the soil sample screening device comprises a soil sample storage tank 1, a sealing plug cover 2, a label sticking groove 201, a built-in cavity 3, heating powder 301, an exchange hole 4, a filter screen 5, a rubber sealing piece 6, a buffer conduit 7, a threaded rotating rod 8, a piston plate 9, a heat transfer carrier 10, an upper heat conducting rod 11, a heat change balloon 12, capillary fiber pricks 1201, a built-in magnetic ball 13, a lower heat conducting rod 14, a 1401 screening rope and a 1402 screening disc.

Detailed Description

The drawings in the embodiments of the invention will be combined; the technical scheme in the embodiment of the invention is clearly and completely described; obviously; the described embodiments are only some of the embodiments of the present invention; but not all embodiments, are based on the embodiments of the invention; all other embodiments obtained by a person skilled in the art without making any inventive step; all fall within the scope of protection of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", etc. indicate orientations or positional relationships based on orientations or positional relationships shown in the drawings, which are merely for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1:

referring to fig. 1-3, a stratum soil sample storage device for geological exploration comprises a soil sample storage tank 1, wherein the upper end of the soil sample storage tank 1 is in threaded connection with a sealing plug cap 2, a built-in cavity 3 is drilled in the sealing plug cap 2, an exchange hole 4 communicated with the built-in cavity 3 is drilled at the bottom end of the sealing plug cap 2, a filter screen 5 is connected to the inner wall of the exchange hole 4, two rubber sealing sheets 6 which are mutually abutted and positioned at the upper side of the filter screen 5 are connected to the inner wall of the exchange hole 4, a buffer conduit 7 communicated with the built-in cavity 3 is embedded and installed at the upper end of the sealing plug cap 2, a threaded rotating rod 8 is in threaded connection with the buffer conduit 7 through a thread, a piston plate 9 which is in mutual contact with the inner wall of the buffer conduit 7 is rotatably connected to the bottom end of the threaded rotating rod 8, and a pair of heat transfer carriers 10 is connected to the top end of the built-in cavity 3, the piston plate 9 can be driven to move upwards along the inner wall of the buffer guide pipe 7 by rotating the threaded rotating rod 8, so that the air pressure in the built-in cavity 3 is reduced, the residual air in the soil sample storage tank 1 jacks the rubber sealing sheet 6 and then enters the built-in cavity 3, a large amount of heat can be generated by means of contact of the heating powder 301 and the air, on one hand, the possibility that the soil in the soil sample storage tank 1 is gradually oxidized can be reduced by sucking the air, on the other hand, the gas flowing efficiency in the sealing plug cover 2 can be improved by means of the heat generated in the reaction process, the absorption effect on the air in the soil sample storage tank 1 is improved, meanwhile, the heating powder 301 can be scattered, the reaction efficiency of the heating powder 301 and the air is improved, and the air consumption speed is improved.

Referring to fig. 4-5, the heat transfer carrier 10 includes an upper heat conducting rod 11 penetrating through the sealing plug 2, the bottom end of the upper heat conducting rod 11 is connected to a thermal change balloon 12, a built-in magnetic ball 13 is disposed in the thermal change balloon 12, and the bottom end of the thermal change balloon 12 is connected to a lower heat conducting rod 14, so that the thermal change balloon 12 can be expanded by heat generated in the reaction process through the reaction between air and the heating powder 301, thereby removing the magnetic shielding of the built-in magnetic ball 13, on one hand, the scattering effect of the heating powder 301 can be improved by the expansion, and on the other hand, the ferroferric oxide powder generated after the heating powder 301 reacts with air can be adsorbed by the adsorption of the built-in magnetic ball 13.

Referring to fig. 1, a label attaching groove 201 is formed in the upper end of a sealing plug cover 2, an upper heat conducting rod 11 is embedded in the bottom end of the label attaching groove 201, a recorder can attach a sticker for recording information of a soil sample to the label attaching groove 201 conveniently by arranging the label attaching groove 201, the viscosity of glue at the bottom of the sticker can be improved by means of heat transferred by the upper heat conducting rod 11, heating powder 301 is filled in a built-in cavity 3, the heating powder 301 is made of a reducing iron powder material, and the heating powder 301 can react with air by means of the reaction of the heating powder 301, so that air in the soil sample storage tank 1 is consumed.

Referring to fig. 4 to 5, the upper heat conducting rod 11 and the lower heat conducting rod 14 are made of aluminum materials, so that the heat transfer efficiency of the heat conducting rod can be improved, a plurality of uniformly distributed magnetic insulation powder is embedded in the heat variable balloon 12, the magnetic insulation powder is made of iron-nickel alloy material with the nickel content of 80%, and the magnetic insulation powder is arranged to promote the expansion of the heat variable balloon 12 and increase the distance between the magnetic insulation powder, so that the magnetic shielding of the built-in magnetic ball 13 is eliminated.

Referring to fig. 2-5, the outer end of the thermal change balloon 12 is connected with a plurality of capillary fiber spines 1201 which are uniformly distributed, the distance between the capillary fiber spines 1201 is 50 μm, the stirring effect of the thermal change balloon 12 on the heating powder 301 can be improved by arranging the capillary fiber spines 1201, a screening rope 1401 is connected between the two lower heat conducting rods 14, a plurality of screening disks 1402 which are uniformly distributed are connected between the screening ropes 1401, and the stirring effect of the heating powder 301 can be improved by arranging the screening ropes 1401 and the screening disks 1402 after the thermal change balloon 12 is expanded.

A use method of a stratum soil sample storage device for geological exploration comprises the following steps:

s1, a piston plate 9 can be driven to move upwards along the inner wall of a buffer conduit 7 by rotating a threaded rotating rod 8, so that the air pressure in the built-in cavity 3 is reduced, and the residual air in the soil sample storage tank 1 pushes open a rubber sealing sheet 6 and then enters the built-in cavity 3;

s2, a large amount of heat can be generated by means of contact of the heating powder 301 and air, and the possibility that soil in the soil sample storage tank 1 is gradually oxidized can be reduced by sucking air;

s3, by means of heat generated in the reaction process, the gas flowing efficiency in the sealing plug cover 2 can be improved, so that the absorption effect of air in the soil sample storage tank 1 is improved, meanwhile, the heating powder 301 can be scattered, the reaction efficiency of the heating powder 301 and the air is improved, and the air consumption speed is improved.

The above; are merely preferred embodiments of the invention; the scope of the invention is not limited thereto; any person skilled in the art is within the technical scope of the present disclosure; the technical scheme and the improved concept of the invention are equally replaced or changed; are intended to be covered by the scope of the present invention.

Claims (6)

1. The utility model provides a geological survey is with stratum soil sample storage device, includes soil sample storage jar (1), its characterized in that: the soil sample storage tank (1) is provided with a sealing plug cover (2) at the upper end in a threaded manner, a built-in cavity (3) is formed in the sealing plug cover (2), an exchange hole (4) communicated with the built-in cavity (3) is formed in the bottom end of the sealing plug cover (2), a filter screen (5) is connected to the inner wall of the exchange hole (4), two rubber sealing pieces (6) which are mutually abutted and are positioned on the upper side of the filter screen (5) are connected to the inner wall of the sealing plug cover (2), a buffer conduit (7) communicated with the built-in cavity (3) is embedded at the upper end of the sealing plug cover (2), a thread rotating rod (8) is connected to the inner thread of the buffer conduit (7), a piston plate (9) in mutual contact with the inner wall of the buffer conduit (7) is rotatably connected to the bottom end of the thread rotating rod (8), a pair of heat transfer carriers (10) is connected to the top end of the built-in cavity (3), the heat transfer carriers (10) comprise an upper heat conducting rod (11) penetrating through the sealing plug cover (2), a heat conducting rod (11) is connected to the bottom end of the heat transfer balloon (12), a magnetic heat transfer ball (12) is arranged in the built-in the magnetic heat transfer ball (13), and the heat transfer ball (3) is filled with heat transfer powder (301) and the heat transfer powder (13) and the heat transfer powder (301) is filled in the heat transfer powder, a plurality of uniformly distributed magnetic isolation powder is embedded in the thermal change balloon (12), and the magnetic isolation powder is made of an iron-nickel alloy material with the nickel content of 80%.

2. A formation soil sample storage device for geological exploration according to claim 1, characterized in that: the upper end of the sealing plug cover (2) is provided with a label sticking groove (201), and the upper heat conducting rod (11) is embedded at the bottom end in the label sticking groove (201).

3. A formation soil sample storage device for geological exploration according to claim 1, characterized in that: the upper heat conducting rod (11) and the lower heat conducting rod (14) are both made of aluminum materials.

4. A formation soil sample storage device for geological exploration according to claim 1, characterized in that: the outer end of the heat-changing saccule (12) is connected with a plurality of capillary fiber spines (1201) which are uniformly distributed, and the distance between the capillary fiber spines (1201) is 50 mu m.

5. A formation soil sample storage device for geological exploration according to claim 1, characterized in that: a screening rope (1401) is connected between the two lower heat conducting rods (14), and a plurality of screening discs (1402) which are uniformly distributed are connected between the screening ropes (1401).

6. The use method of a formation soil sample storage device for geological exploration according to any one of claims 1 to 5, characterized by comprising the steps of: the method comprises the following steps:

s1, a piston plate (9) can be driven to move upwards along the inner wall of a buffer guide pipe (7) by rotating a threaded rotating rod (8), so that the air pressure in a built-in cavity (3) is reduced, and residual air in a soil sample storage tank (1) pushes a rubber sealing sheet (6) open and then enters the built-in cavity (3);

s2, a large amount of heat can be generated by means of contact between the heating powder (301) and air, and the possibility that soil in the soil sample storage tank (1) is gradually oxidized can be reduced by sucking air;

s3, by means of heat generated in the reaction process, the gas flow efficiency in the sealing plug cover (2) can be improved, so that the absorption effect on air in the soil sample storage tank (1) is improved, meanwhile, the heating powder (301) can be scattered, the reaction efficiency of the heating powder (301) and the air is improved, and the air consumption speed is improved.

Images