CN219369186U - Engineering detects soil property detection machine - Google Patents

Abstract

The utility model discloses an engineering detection soil texture detector, which relates to the technical field of engineering detection and comprises a storage box and a disassembly and assembly component, wherein a front bracket and a back bracket are fixedly arranged at the bottom of the storage box, a first bolt is inserted in the middle of the front of the bracket in a sliding manner, shaft rods are fixedly arranged on opposite surfaces of the bottom of the bracket at two sides, a turntable is rotatably arranged in the middle of the shaft rods, the disassembly and assembly component for facilitating the transfer of sampled soil is fixedly arranged on the circumference of the turntable, and the disassembly and assembly component comprises a column casing, a jack, a T-shaped groove and a positioning hole. The utility model provides an engineering detects soil property detects machine, the straight pushing type sampler of this application simple structure and skin are real durable, be convenient for use for a long time in the adverse circumstances of engineering job site, and the multisampling bucket that possesses can be used for sampling respectively in multisampling place, avoids the soil in last sampling place to mix in the next sampling, and the soil of taking can be located the classifying temporary storage in the bin, need not to carry extra storage device, uses more convenient.

Description

Engineering detects soil property detection machine

Technical Field

The utility model relates to the technical field of engineering detection, in particular to an engineering detection soil texture detector.

Background

The engineering detection is an important work for guaranteeing the safety of the established, built and to-be-built building engineering and testing the foundation, building materials, construction process and building structure related to the building in the whole construction process, wherein the soil quality detection of the engineering is extremely important, and whether the soil quality is qualified directly influences whether the engineering can be constructed or not.

After the soil property detection device in the prior art drills into the soil in the detection area through the drill bit, the soil property can be preliminarily detected, and if the soil is required to be further detected, sampling analysis is required to be carried out on the soil, the sampled soil is required to be sent to a laboratory for further detection, temporary storage of the sampled soil cannot be realized by the existing soil sampler, and the soil can be stored when a storage box is required to be additionally carried for multi-place sampling.

In view of the above, an engineering soil texture detecting machine has been proposed to solve the problems of the conventional structure.

Disclosure of Invention

The utility model aims to provide an engineering detection soil texture detector for solving the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: including bin and dismouting subassembly, bin bottom fixed mounting has two positive and negative supports, and the positive middle part slip grafting of support has bolt one, both sides the opposite face fixed mounting of support bottom has the axostylus axostyle, and the axostylus axostyle middle part rotates and installs the carousel for make things convenient for sample soil to shift dismouting subassembly fixed mounting is in the carousel circumference, dismouting subassembly includes a section of thick bamboo, jack, T groove and locating hole, four annular arrays altogether distribute in the carousel circumference of section of thick bamboo, and the jack has been seted up at the positive top of section of thick bamboo, the section of thick bamboo is fixed in the opposite face middle part grafting of both sides support through bolt one, and the T groove has been seted up to the section of thick bamboo bottom, the locating hole has been seted up at T groove perpendicular partial middle part.

Further, the dismouting subassembly still includes sample bucket and broken earth awl, the section of thick bamboo bottom links up there is the sample bucket, and the broken earth awl has been seted up to the sample bucket bottom.

Further, the disassembly and assembly further comprises a piston rod and a pressing rod, the piston rod is slidably mounted in the sampling barrel, the pressing rod is fixedly mounted at the top of the piston rod in an integrated mode, and the shape of the pressing rod is matched with the size of the T-shaped groove.

Furthermore, the dismounting assembly further comprises a second bolt, the middle part of the vertical surface of the compression bar is connected with the second bolt in a sliding manner, and the second bolt corresponds to the position where the positioning hole is formed.

Further, wing rods are fixedly arranged on two sides of the storage box, and rubber handles are sleeved at the tail ends of the wing rods.

Further, a hinge is fixedly arranged on the side face of the opening of the top of the storage box, and the top of the hinge is rotationally connected with a box cover.

Further, a handle is fixedly arranged on the left side of the top of the box cover, and the handle is of a -shaped structure as a whole.

Furthermore, a plurality of partitions are fixedly arranged in the storage box, and gaps between adjacent partition structures form a storage cavity.

Compared with the prior art, the utility model has the beneficial effects that: the utility model provides an engineering detects soil property detects machine, the straight pushing type sampler of this application simple structure and skin are real durable, be convenient for use for a long time in the adverse circumstances of engineering job site, and the multisampling bucket that possesses can be used for sampling respectively in multisampling place, avoids the soil in last sampling place to mix in the next sampling, and the soil of taking can be located the classifying temporary storage in the bin, need not to carry extra storage device, uses more convenient.

1. According to the utility model, through the arrangement of the dismounting component, the soil sample taken in the sampling tube can be transferred into the storage box of the machine body by extruding the piston rod, so that the operation is simple, and the defect of incomplete sample discharge in the sampling tube in the prior art is overcome;

2. the storage box is arranged, so that the storage box can be used for classifying and storing soil sampled at multiple places, and the separated storage cavities formed by the multiple partitions can be used for avoiding cross contamination among samples, so that an additional storage device is not required to be carried, and the use is more convenient;

3. according to the utility model, through the arrangement of the rotary table, the multi-sampling bucket can be used for sampling at multiple sampling sites respectively, so that soil at the previous sampling site is prevented from being mixed into the next sampling, and the rotary adjustment mode is more convenient to use.

Drawings

FIG. 1 is a schematic diagram of the overall front view of the present utility model;

FIG. 2 is a schematic perspective view of a storage box according to the present utility model;

FIG. 3 is a schematic view of the internal structure of the assembly and disassembly assembly of the present utility model.

In the figure: 1. a storage tank; 2. a wing lever; 3. a rubber grip; 4. a hinge; 5. a case cover; 6. a handle; 7. partition; 8. a separate storage cavity; 9. a bracket; 10. a first bolt; 11. a shaft lever; 12. a turntable; 13. disassembling and assembling the assembly; 1301. a column casing; 1302. a jack; 1303. a T-shaped groove; 1304. positioning holes; 1305. a sampling tube; 1306. a broken earth cone; 1307. a piston rod; 1308. a compression bar; 1309. and a second bolt.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples. The following examples are illustrative of the utility model but are not intended to limit the scope of the utility model.

As shown in fig. 1-2, wing rods 2 are fixedly arranged on two sides of a storage box 1, rubber handles 3 are sleeved at the tail ends of the wing rods 2, hinges 4 are fixedly arranged on the side surfaces of openings of the top of the storage box 1, a box cover 5 is rotatably connected to the top of each hinge 4, a handle 6 is fixedly arranged on the left side of the top of each box cover 5, the handles 6 are of -shaped structures as a whole, a plurality of partitions 7 are fixedly arranged in the storage box 1, and the structures of adjacent partitions 7 form component storage cavities 8 in a clearance manner, the direct-push sampler is arranged in the structure with the storage box 1 and can be used for classifying and storing soil sampled at multiple places, the component storage cavities 8 formed by the partitions 7 can be used for avoiding cross contamination among samples without carrying additional storage devices, the direct-push sampler is more convenient to use, the bottom of the storage box 1 is fixedly provided with a front bracket 9 and a back bracket 9, the middle part of the front surface of the bracket 9 is slidably inserted with a first bolt 10, a column 1301 positioned at the top of the circumference of a rotary table 12 is firstly fixed at the middle part of the opposite surface of the bracket 9 through the first bolt 10, so that the column 1301 positioned at the bottom of the circumference of the rotary table 12 is vertical to the ground, the opposite surfaces of the bottoms of the brackets 9 at the two sides are fixedly provided with shaft rods 11, the middle part of the shaft rods 11 is rotatably provided with the rotary table 12, and the rotary table 12 can be positioned at different sampling positions to rotatably switch different sampling cylinders 1305 through the rotation of the shaft rods 11, so that the soil at the previous sampling position is prevented from being mixed into the next sampling, the rotation adjustment mode is more convenient, and the rotary table is applicable to the sampling requirements of the four places at most;

as shown in fig. 3, a dismounting component 13 for facilitating sample soil transfer is fixedly installed on the circumference of a turntable 12, dismounting component 13 includes a column casing 1301, a jack 1302, a T-shaped groove 1303 and a positioning hole 1304, four annular arrays are distributed on the circumference of turntable 12 in total, jack 1302 is provided at the top of the front of column casing 1301, column casing 1301 is fixedly inserted in the middle of opposite surfaces of two side brackets 9 through a first bolt 10, T-shaped groove 1303 is provided at the bottom of column casing 1301, positioning hole 1304 is provided in the middle of the vertical part of T-shaped groove 1303, dismounting component 13 further includes a sample barrel 1305 and a broken cone 1306, the bottom of column casing 1301 is connected with sample barrel 1305, and the bottom of sample barrel 1305 is provided with broken cone 1306, dismounting component 13 further includes a piston rod 1307 and a pressure rod 1308, the inside of sample barrel 1305 is slidably installed with piston rod 1307, and the top of piston rod 1307 is integrally and fixedly installed with pressure rod 1308, the shape of 1308 is matched with the size of T-shaped groove 1303, bolt two bolts 1309 are slidably inserted in the middle of the vertical surface of pressure rod 1308, two bolts 1309 are corresponding to the position of positioning hole 1304, after sampling is completed, sample soil is not completely removed from the inside of column casing 1305, sample can be easily removed from the sample casing 1305 by pulling out the sample casing by the sample casing 1305, and the sample soil is not completely removed from the sample casing by simply being connected with the sample casing 1305.

Working principle: when the engineering soil texture detection machine is used, firstly, the column 1301 positioned at the top of the circumference of the rotary table 12 is fixed at the middle part of the opposite surface of the support 9 through the first bolt 10, so that the column 1301 positioned at the bottom of the circumference of the rotary table 12 is ensured to be perpendicular to the ground, when the engineering soil texture detection machine is used, a user holds the rubber handles 3 at the tail ends of the wing rods 2 with two hands and applies downward force, the sampling tube 1305 stretches into soil to complete sampling under the action of the soil breaking cone 1306, the rotary table 12 is positioned at the rotation of the shaft rod 11, the sampling tube 1305 can be rotated and switched at different sampling positions, the soil at the last sampling position is prevented from being mixed into the next sampling, the rotation adjustment mode is more convenient to use, and the engineering soil texture detection machine can be suitable for sampling requirements of four positions at most, the bolt two 1309 is pulled out to take out the pressure handle in the T-shaped groove 1303 that the column casing 1301 end was offered, break off the connection of sampling tube 1305 and column casing 1301 this moment, the user makes piston rod 1307 be located sampling tube 1305 inside slip through pressing the pressure handle, can shift the soil sample of taking in the sampling tube 1305 to the organism from the bin 1 of taking, easy operation, solve the not clean not enough of sample discharge in the prior art sampling tube 1305, the structure setting of this application direct push type sampler from the bin 1 of taking, can be used to the classified storage of the soil of multiple spot sampling, the branch storage chamber 8 that the multiple separation 7 formed can be used to avoid cross contamination between the sample, need not to carry extra storage device, it is more convenient to use, conveniently send the soil sample of taking to the laboratory and carry out the composition detection in order to promote engineering detection quality.

The embodiments of the utility model have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the utility model in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, and to enable others of ordinary skill in the art to understand the utility model for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (8)

1. The utility model provides an engineering detects soil property detection machine, its characterized in that, including bin (1) and dismouting subassembly (13), bin (1) bottom fixed mounting has positive and negative two places support (9), and the positive middle part slip grafting of support (9) has bolt one (10), both sides support (9) bottom opposite face fixed mounting has axostylus axostyle (11), and axostylus axostyle (11) mid-rotation installs carousel (12) for make things convenient for sample soil to shift dismouting subassembly (13) fixed mounting is in carousel (12) circumference, dismouting subassembly (13) include barrel (1301), jack (1302), T-shaped groove (1303) and locating hole (1304), four annular arrays altogether distribute in carousel (12) circumference, and barrel (1301) openly top has seted up jack (1302), barrel (1301) are fixed in the middle part grafting of the opposite face of both sides support (9) through bolt one (10), and barrel (1301) bottom has seted up T-shaped groove (1303), T-shaped groove (1303) perpendicular part middle part has seted up locating hole (1304).

2. The machine according to claim 1, wherein the assembly and disassembly component (13) further comprises a sampling barrel (1305) and a broken cone (1306), the bottom of the column casing (1301) is connected with the sampling barrel (1305), and the bottom of the sampling barrel (1305) is provided with the broken cone (1306).

3. The engineering detection soil property detector according to claim 2, wherein the dismounting component (13) further comprises a piston rod (1307) and a pressing rod (1308), the piston rod (1307) is slidably mounted in the sampling barrel (1305), the pressing rod (1308) is fixedly mounted at the top of the piston rod (1307) in an integral mode, and the shape of the pressing rod (1308) is matched with the opening size of the T-shaped groove (1303).

4. An engineering detection soil property detector according to claim 3, wherein the dismounting component (13) further comprises a second bolt (1309), the middle part of the vertical surface of the pressing rod (1308) is slidably inserted with the second bolt (1309), and the second bolt (1309) corresponds to the opening position of the positioning hole (1304).

5. The engineering detection soil property detector according to claim 1, wherein wing rods (2) are fixedly arranged on two sides of the storage box (1), and rubber grips (3) are sleeved at the tail ends of the wing rods (2).

6. The engineering detection soil property detector according to claim 1, wherein a hinge (4) is fixedly arranged on the side surface of the opening at the top of the storage box (1), and a box cover (5) is rotatably connected to the top of the hinge (4).

7. The engineering detection soil property detector according to claim 6, wherein a handle (6) is fixedly arranged on the left side of the top of the box cover (5), and the handle (6) is of a -shaped structure as a whole.

8. An engineering detection soil property detector as claimed in claim 1, wherein a plurality of partitions (7) are fixedly arranged in the storage box (1), and the gaps between adjacent partitions (7) are formed into storage cavities (8).