CN213544073U - Soil environment monitoring facilities based on new forms of energy - Google Patents

Abstract

The utility model discloses a soil environment monitoring facilities based on new forms of energy, settle the subassembly including fixed plate and sample, fixed plate one side welded fastening has the limiting plate, and fixed plate lower extreme welded fastening has the fixed bearing cover, fixed bearing cover inboard is provided with rotates the axostylus axostyle, and rotates axostylus axostyle lower extreme welded fastening and have the bracing piece, the sample settles the subassembly and sets up in the fixed plate upper end, and the sample settles the subassembly inboard and be provided with movable sampling subassembly. This soil environment monitoring facilities based on new forms of energy, settle the ice bag in the inboard of settling the box interior division board, the ice bag can reduce the temperature of settling the box, the sample test tube that will be equipped with the soil sample is settled in block arrangement frame inboard, with the block stopper in the sample test tube, again with the block lid on settling the box, a plurality of soil samples of portability monitor, the soil sample is carried to the low temperature of being convenient for, avoid destroying the organic matter in the soil, ensure the accuracy of monitoring result.

Description

Soil environment monitoring facilities based on new forms of energy

Technical Field

The utility model relates to a soil environment monitoring technology field specifically is a soil environment monitoring facilities based on new forms of energy.

Background

Soil environment monitoring equipment for detecting soil environment, the present moisture measurement mainly adopts the drying weighing method, its characteristics are to measure accurately, it is not high to the requirement of equipment, but measuring time is longer and must measure at the laboratory, can not carry out continuous, long-term ground on-line measurement to the soil moisture content of soil, be difficult to satisfy the measurement requirement of meticulous agriculture, in addition, traditional soil moisture measuring apparatu generally can only measure the moisture content of soil, can not directly measure the positional information of sampling point, therefore, can not reflect the spatial difference of soil moisture.

Soil environment monitoring facilities in market when taking a sample to soil, need artifical excavation to take a sample to the soil of the different degree of depth, comparatively waste time and energy, and the soil of getting, can not transport by the low temperature, and the easy problem that influences the accuracy of monitoring result that is destroyed to organic matter etc. in the soil, for this reason, we provide a soil environment monitoring facilities based on the new forms of energy.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a soil environment monitoring facilities based on new forms of energy to solve the soil environment monitoring facilities on the market that proposes in the above-mentioned background art, when taking a sample to soil, need the manual work to excavate and take a sample to the soil of the different degree of depth, comparatively waste time and energy, and the soil of getting, can not transport at low temperature, the easy problem that influences the accuracy of monitoring result that is destroyed of organic matter etc. in the soil.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a soil environment monitoring facilities based on new forms of energy, settles the subassembly including fixed plate and sample, fixed plate one side welded fastening has a limiting plate, and fixed plate lower extreme welded fastening has a fixed bearing cover, fixed bearing cover inboard is provided with the rotation axostylus axostyle, and rotates axostylus axostyle lower extreme welded fastening and have the bracing piece, the sample is settled the subassembly and is set up in the fixed plate upper end, and the sample is settled subassembly inboard and is provided with movable sampling subassembly.

Preferably, the spacing plates are symmetrical about the transverse center line of the fixing plate, and the fixing plate is of a hollow structure.

Preferably, the support rod and the fixed bearing sleeve form a rotating structure through a rotating shaft rod, and the fixed bearing sleeve and the fixed plate form an integrated structure through welding.

Preferably, the sample arrangement component comprises an arrangement box, a partition plate, an ice bag, a clamping arrangement frame, a sample test tube, a clamping plug and a clamping cover, wherein the partition plate is welded and fixed on the inner side of the arrangement box, the ice bag is arranged on one side of the partition plate, the clamping arrangement frame is arranged on the other side of the partition plate, the sample test tube is arranged on the inner side of the clamping arrangement frame, the clamping plug is arranged at the upper end of the sample test tube in a clamping mode, and the clamping cover is arranged at the upper end of the clamping arrangement frame in a clamping mode.

Preferably, the outside of sample test tube and the inboard of block mount shelf are closely laminated, and the outside of block mount shelf and the inboard of settling the box are closely laminated.

Preferably, the movable sampling assembly comprises a connecting frame sleeve, a handheld handle, a servo motor, a coupler and a spiral sampling rod, the handheld handle is fixed to the upper end of the connecting frame sleeve in a welded mode, the servo motor is fixed to the inner side of the connecting frame sleeve in a welded mode, the lower end of the servo motor is connected with the coupler, and the spiral sampling rod is fixed to the lower end of the coupler in a welded mode.

Preferably, the spiral sampling rod and the servo motor form a rotating structure through a coupler, and the servo motor and the handheld handle form a fixing structure through a connecting frame sleeve.

Compared with the prior art, the beneficial effects of the utility model are as follows:

1. settle the ice bag in the inboard of settling the interior division board of box, the ice bag can reduce the temperature of settling the box, and the sample test tube that will be equipped with soil sample settles in block arrangement frame inboard, plugs the block stopper in the sample test tube, covers the block lid on settling the box again, and a plurality of soil samples of portability are monitored, and the soil sample is carried to the low temperature of being convenient for, avoids destroying the organic matter in the soil, ensures the accuracy of monitoring result.

2. Start servo motor, servo motor operation drives shaft coupling and spiral sampling rod and rotates, and in the soil was gone into to the rotatable brill of spiral sampling rod rotation, be convenient for take a sample to the soil of the different degree of depth, need not artifical the excavation, very convenient laborsaving.

Drawings

FIG. 1 is a front view of the semi-sectional structure of the present invention;

FIG. 2 is a schematic view of the front view of the analyzing structure of the present invention;

FIG. 3 is an enlarged schematic view of the structure at A in FIG. 2 according to the present invention;

fig. 4 is the structure schematic diagram of the movable rear connecting frame sleeve and the support of the utility model.

In the figure: 1. a fixing plate; 2. a limiting plate; 3. fixing a bearing sleeve; 4. rotating the shaft lever; 5. a support bar; 6. a sample placement assembly; 601. placing a box; 602. a partition plate; 603. an ice bag; 604. clamping the placing frame; 605. a sample tube; 606. clamping a plug; 607. a snap-fit cover; 7. a movable sampling assembly; 701. a connecting frame sleeve; 702. a hand-held grip; 703. a servo motor; 704. a coupling; 705. a spiral sampling rod.

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.

Referring to fig. 1-4, the present invention provides a technical solution: the utility model provides a soil environment monitoring facilities based on new forms of energy, settles subassembly 6 including fixed plate 1 and sample, and 1 one side welded fastening of fixed plate has spacing board 2, and 1 lower extreme welded fastening of fixed plate has fixed bearing cover 3, and 3 inboards of fixed bearing cover are provided with rotation axostylus axostyle 4, and rotates 4 lower extreme welded fastening of axostylus axostyle and have bracing piece 5, and the sample is settled subassembly 6 and is set up in 1 upper ends of fixed plate, and 6 inboards of sample settlement subassembly are provided with movable sampling subassembly 7.

The utility model discloses in: the spacing plates 2 are symmetrical about the transverse center line of the fixing plate 1, and the fixing plate 1 is of a hollow structure.

The utility model discloses in: bracing piece 5 constitutes revolution mechanic through rotating shaft 4 and fixed bearing housing 3, and fixed bearing housing 3 constitutes the integral structure through welding and fixed plate 1, through rotating shaft 4 in the inboard rotation of fixed bearing housing 3, can rotate bracing piece 5 and open, the limiting plate 2 of 1 one side of bracing piece 5 contact fixed plate, can restrict the position of bracing piece 5, bracing piece 5 stands on ground, can fix the position of this soil environment monitoring equipment, be convenient for fixed use and accomodate and carry, improve this soil environment monitoring equipment's use flexibility.

The utility model discloses in: the sample arranging assembly 6 comprises an arranging box 601, a partition plate 602, an ice bag 603, a clamping arranging frame 604, a sample test tube 605, a clamping plug 606 and a clamping cover 607, wherein the inner side of the arranging box 601 is fixedly welded with the partition plate 602, one side of the partition plate 602 is provided with the ice bag 603, the other side of the partition plate 602 is provided with the clamping arranging frame 604, the inner side of the clamping arranging frame 604 is provided with the sample test tube 605, the upper end of the sample test tube 605 is clamped with the clamping plug 606, and the upper end of the clamping arranging frame 604 is clamped with the clamping cover 607.

The utility model discloses in: the outside of sample test tube 605 closely laminates with the inboard of block mount 604, and the outside of block mount 604 closely laminates with the inboard of settling the box 601, settle ice bag 603 in settling the inboard of partition board 602 in the box 601, ice bag 603 can reduce the temperature in settling the box 601, settle the sample test tube 605 that is equipped with the soil sample in block mount 604 inboard, jam the block stopper 606 in sample test tube 605, again with block lid 607 lid on settling the box 601, a plurality of soil samples of portability are monitored, be convenient for carry the soil sample at low temperature, avoid destroying the organic matter in the soil, ensure the accuracy of monitoring result.

The utility model discloses in: the movable sampling assembly 7 comprises a connecting frame sleeve 701, a handheld grip 702, a servo motor 703, a coupler 704 and a spiral sampling rod 705, the handheld grip 702 is welded and fixed at the upper end of the connecting frame sleeve 701, the servo motor 703 is welded and fixed on the inner side of the connecting frame sleeve 701, the coupler 704 is connected to the lower end of the servo motor 703, and the spiral sampling rod 705 is welded and fixed at the lower end of the coupler 704.

The utility model discloses in: spiral sampling rod 705 passes through shaft coupling 704 and servo motor 703 and constitutes revolution mechanic, and servo motor 703 passes through link cover 701 and constitutes fixed knot with handheld handle 702 and construct, starts servo motor 703, and servo motor 703 operation drives shaft coupling 704 and spiral sampling rod 705 and rotates, and spiral sampling rod 705 rotates in the rotatable soil of boring into of rotation, is convenient for sample the soil of the different degree of depth, need not artifical the excavation, very convenient laborsaving.

The working principle is as follows: for the soil environment monitoring equipment based on new energy, firstly, the support rod 5 can be rotated and opened through the rotation of the rotating shaft rod 4 at the inner side of the fixed bearing sleeve 3, the support rod 5 contacts the limiting plate 2 at one side of the fixed plate 1, the position of the support rod 5 can be limited, the support rod 5 stands on the ground, the position of the soil environment monitoring equipment can be fixed, the soil environment monitoring equipment is convenient to fix, use, store and carry, the use flexibility of the soil environment monitoring equipment is improved, the sample arrangement component 6 is arranged at the upper end of the fixed plate 1, the ice bag 603 is arranged at the inner side of the partition plate 602 in the arrangement box 601, the ice bag 603 can reduce the temperature in the arrangement box 601, the sample test tube 605 containing soil samples is arranged at the inner side of the clamping arrangement frame 604, the clamping plug 606 is plugged in the sample test tube 605, the clamping cover 607 is covered on the arrangement box 601, a plurality, avoid destroying the organic matter in the soil, ensure the accuracy of monitoring result, and the sample is settled 6 inboards and is provided with movable sampling subassembly 7, start servo motor 703 (the model is 3I RK15A-C), servo motor 703 operation drives shaft coupling 704 and spiral sampling rod 705 and rotates, spiral sampling rod 705 rotates in the rotatable soil of boring into of rotation, be convenient for take a sample to the soil of the different degree of depth, need not artifical the excavation, very convenient laborsaving just so accomplishes the use of whole soil environment monitoring equipment based on the new forms of energy.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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 (7)

1. The utility model provides a soil environment monitoring facilities based on new forms of energy, includes that fixed plate (1) and sample settle subassembly (6), its characterized in that: fixed plate (1) one side welded fastening has limiting plate (2), and fixed plate (1) lower extreme welded fastening has fixed bearing cover (3), fixed bearing cover (3) inboard is provided with rotation axostylus axostyle (4), and rotates axostylus axostyle (4) lower extreme welded fastening and have bracing piece (5), sample arrangement component (6) set up in fixed plate (1) upper end, and sample arrangement component (6) inboard is provided with movable sampling subassembly (7).

2. The new energy based soil environment monitoring device as claimed in claim 1, wherein: the limiting plates (2) are symmetrical about the transverse center line of the fixing plate (1), and the fixing plate (1) is of a hollow structure.

3. The new energy based soil environment monitoring device as claimed in claim 1, wherein: the support rod (5) and the fixed bearing sleeve (3) form a rotating structure through the rotating shaft rod (4), and the fixed bearing sleeve (3) and the fixed plate (1) form an integrated structure through welding.

4. The new energy based soil environment monitoring device as claimed in claim 1, wherein: the sample placement assembly (6) comprises a placement box (601), a separation plate (602), an ice bag (603), a clamping placement frame (604), a sample test tube (605), a clamping plug (606) and a clamping cover (607), wherein the separation plate (602) is welded and fixed on the inner side of the placement box (601), the ice bag (603) is arranged on one side of the separation plate (602), the clamping placement frame (604) is arranged on the other side of the separation plate (602), the sample test tube (605) is placed on the inner side of the clamping placement frame (604), the clamping plug (606) is arranged at the upper end of the sample test tube (605), and the clamping cover (607) is arranged at the upper end of the clamping placement frame (604).

5. The new energy based soil environment monitoring device as claimed in claim 4, wherein: the outer side of the sample test tube (605) is tightly attached to the inner side of the clamping placement frame (604), and the outer side of the clamping placement frame (604) is tightly attached to the inner side of the placement box (601).

6. The new energy based soil environment monitoring device as claimed in claim 1, wherein: the movable sampling assembly (7) comprises a connecting frame sleeve (701), a handheld grip (702), a servo motor (703), a coupler (704) and a spiral sampling rod (705), the upper end of the connecting frame sleeve (701) is fixedly welded with the handheld grip (702), the inner side of the connecting frame sleeve (701) is fixedly welded with the servo motor (703), the lower end of the servo motor (703) is connected with the coupler (704), and the lower end of the coupler (704) is fixedly welded with the spiral sampling rod (705).

7. The new energy based soil environment monitoring device as claimed in claim 6, wherein: the spiral sampling rod (705) and the servo motor (703) form a rotating structure through the coupler (704), and the servo motor (703) and the handheld grip (702) form a fixed structure through the connecting frame sleeve (701).

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