CN215380134U - Combined plant growth vessel for soil culture experiment - Google Patents

Abstract

The utility model provides a combined plant growth vessel for a soil culture experiment, and belongs to the technical field of simulated environmental condition experiments. The vessel comprises a vessel body, a height-adjustable intermediate nesting structure and a top side bar, wherein the intermediate nesting structure comprises a base side bar or a base side bar and a side bar assembly; the side edge strip assembly is formed by alternately arranging a plurality of outer side edge strips and inner side edge strips; the upper edge of the vessel body is provided with an annular groove with an inward opening; the edge of the lower surface of the annular groove of the side edge strip of the base part is bent outwards and extends into the groove of the upper edge of the vessel body to form clamping connection; the inner side edge strip and the outer side edge strip are respectively of annular groove structures with outward openings and inward openings; the uppermost layer of the middle nested structure is clamped with the top side edge strip. The plug-in type flowerpot can realize the quantitative change of the volume of the soil filled in the flowerpot through splicing and combining.

Description

Combined plant growth vessel for soil culture experiment

Technical Field

The utility model belongs to the technical field of simulated environmental condition experiments, and particularly relates to a combined plant growth vessel.

Background

The most commonly used plant growth vessel in plant science research is widely used in soil culture experiments. At present, plant growth vessels on the market are various in styles and materials, and have hunting in special functions, such as automatic watering, water storage and the like.

However, while there are few structural and functional breakthroughs, some designs have been developed, such as CN211960226U plug-in pots, which can change the volume of the pot by increasing the side strips, but the design of the threaded holes and the threaded rods of the upright posts makes the whole pot more tightly connected, but makes the assembly and disassembly of the whole pot very cumbersome. In the scientific experiment process for simulating the change of the natural environment, quantitative soil filling is sometimes required besides the requirement on the volume of the plant growth vessel, but most of the plant growth vessels on the market draw a line in the vessel to remind the soil filling amount, so that the accurate estimation is difficult in practice, and a large amount of mechanical workload is increased for scientific research in the initial stage of the experiment.

SUMMERY OF THE UTILITY MODEL

In view of the above problems, the present invention provides a combined plant growth vessel for soil cultivation experiments, which achieves the purposes of volume change and quantitative soil loading of the vessel by splicing and combining structures at different positions.

In order to achieve the purpose, the utility model adopts the following technical scheme:

the combined plant growth vessel for the soil culture experiment comprises a vessel body, a height-adjustable middle nesting structure and a top side edge strip, wherein the middle nesting structure comprises a base side edge strip, or the middle nesting structure comprises a base side edge strip and a side edge strip assembly; the side edge strip assembly is formed by alternately arranging a plurality of outer side edge strips and inner side edge strips; the adjacent outer side edge strips and the inner side edge strips are clamped; wherein: the vessel body is of a cylindrical structure with a closed bottom, and the upper edge of the vessel body extends outwards horizontally and then bends inwards to form an annular groove with an inward opening; the base side edge strip is of an annular groove structure with an inward opening, the annular groove of the base side edge strip is sleeved outside the upper edge of the vessel body, and the edge of the lower surface of the annular groove structure of the base side edge strip is bent outwards and extends into the annular groove of the upper edge of the vessel body to be connected with the upper edge of the vessel body in a clamping manner; the inner side edge strip and the outer side edge strip are respectively of annular groove structures with outward openings and inward openings; the uppermost layer of the middle nested structure is clamped with the top side edge strip.

The top side edge strip is an inner top side edge strip or an outer top side edge strip, and the outer top side edge strip and the inner top side edge strip are respectively of annular groove structures with inward openings and outward openings.

When only the base side edge strip is arranged in the middle nested structure, the top side edge strip is an inner top side edge strip, and the base side edge strip is directly connected with the inner top side edge strip in a clamping mode.

When the base side edge strip is directly clamped and connected with the inner top side edge strip, the upper surface of the base side edge strip extends into the annular groove of the inner top side edge strip.

When middle nested structure includes base side strake and side strake subassembly, the outside strake or the inboard strake of side strake subassembly the top side strake joint is connected.

If the uppermost side of the side edge assembly is the inner side edge, the top side edge is the outer top side edge, and the uppermost inner side edge is clamped with the outer top side edge; if the side strip subassembly top is outside edging, then top edging is interior top edging, and the outside edging of top is connected with interior top edging looks joint.

When the middle nested structure comprises a base side edge strip and a side edge strip assembly, the lowest part of the side edge strip assembly is an inner side edge strip; the upper surface of the side edge strip of the base part extends into the annular groove of the inner side edge strip at the lowest part to form clamping connection; the joint mode of the inner side edge strip and the outer side edge strip in the side edge strip assembly is as follows: one surface of the inner edge strip extends into the annular groove of the outer edge strip and/or one surface of the outer edge strip extends into the annular groove of the inner edge strip.

The width of the upper surface of the base side edge strip, the width of the upper surface and the lower surface of the inner side edge strip, the width of the upper surface and the lower surface of the outer side edge strip and the width of the upper surface and the lower surface of the top side edge strip are the same.

The inner diameters of the height-adjustable middle nesting structure and the top side edge strip are the same as the inner diameter of the vessel body; the height of the middle nesting structure is adjusted by adjusting the number of the outer side edge strips and the inner side edge strips in the side edge strip assembly, so that the height of the whole vessel is adjusted.

The opening width of the inner side edge strip and the outer side edge strip is 2 times of the thickness of the inner side edge strip, and the thickness of the inner side edge strip is the same as that of the outer side edge strip.

The utility model has the following beneficial effects:

1. the utility model can realize the expansion and reduction of the volume of the vessel by the way of assembling and combining, can mark by assembling and combining different colors, and is convenient and simple.

2. In scientific experiments, the soil is filled in a certain layer to be horizontal, then the vessel is continuously assembled to the required height, quantitative soil filling in a certain range can be realized under the condition of uniform soil quality, and mechanical labor for repeatedly weighing the soil is saved in the experimental process.

3. The combined plant growth vessel is detachable, can be assembled and can be used repeatedly, when part of parts are damaged, only corresponding parts are replaced, and the combined plant growth vessel is economical and environment-friendly.

Drawings

FIG. 1 is an overall structure view of a combined vegetation vessel;

fig. 2 is a schematic diagram of the splicing of the components of the combined plant growth vessel.

FIG. 3 is a structure of a vessel body in the combined plant growth vessel; wherein: (a) a perspective view; (b) axial sectional view.

FIG. 4 is a side edge structure of a base part in the combined plant growth vessel; wherein: (a) a perspective view; (b) axial sectional view.

FIG. 5 is a structure of an inside edge strip in the combined vegetation vessel; wherein: (a) a perspective view; (b) axial sectional view.

FIG. 6 shows the outer side edge, outer top side edge and inner top side edge of the combined plant growth vessel; wherein: (a) an outer side edge strip; (b) an outer top side bar; (c) an inner top side bar.

Fig. 7 is a schematic view of the connection between the side edge of the base and the inner side edge of the combined plant growth vessel.

FIG. 8 is a schematic view of the connection between the inner side edge and the outer side edge of the combined plant growth vessel.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The utility model provides a combined plant growth vessel for soil culture experiments, which is shown in figures 1-8. The plant growth vessel comprises a vessel body 1, a height-adjustable intermediate nesting structure and a top side bar, wherein the intermediate nesting structure comprises a base side bar 2, or the intermediate nesting structure comprises a base side bar 2 and a side bar assembly 4; the side edge strip assembly is formed by alternately arranging a plurality of outer side edge strips 3 and inner side edge strips 4; the adjacent outer side edge strips 3 are clamped with the inner side edge strips 4; wherein: the vessel body 1 is of a cylindrical structure with a closed bottom, and the upper edge of the vessel body 1 is bent inwards after extending outwards and horizontally to form an annular groove with an inward opening; the base side edge strip 2 is of an annular groove structure with an inward opening, the annular groove of the base side edge strip 2 is sleeved outside the upper edge of the vessel body 1, and the edge of the lower surface of the annular groove structure of the base side edge strip 2 is bent outwards and extends into the annular groove of the upper edge of the vessel body 1 to form clamping connection with the upper edge of the vessel body 1; the inner side edge strips 3 and the outer side edge strips 4 are respectively of annular groove structures with outward openings and inward openings; the uppermost layer of the middle nested structure is clamped with the top side edge strip.

The top side edge strip is an inner top side edge strip 6 or an outer top side edge strip 5, and the outer top side edge strip 5 and the inner top side edge strip 6 are annular groove structures with inward openings and outward openings respectively.

When only base side strake 2 is of middle nested structure, top side strake is interior top side strake 6, base side strake 2 is connected with interior top side strake 6 direct joint.

When base side strake 2 is connected with interior top side strake 6 direct joint, the upper surface of base side strake 2 stretches into in the annular groove of interior top side strake 6.

When middle nested structure includes base side strip and side strip subassembly 4, the outside 3 or the inboard 4 of side strip subassembly 4 the top side strip joint is connected.

If the uppermost side of the side edge assembly is the inner side edge 3, the top side edge is the outer top side edge 5, and the uppermost inner side edge 3 is clamped with the outer top side edge 5; if the side strip subassembly top is outside edging 4, then the top edging is interior top edging 6, and the outside edging 4 and the 6 looks joints in top edging of top of the top.

When the intermediate nesting structure comprises a base side bar and a side bar assembly 4, the inner side bar 3 is arranged at the lowest part of the side bar assembly 4; the upper surface of the base side edge strip 2 extends into the annular groove of the inner side edge strip 3 at the lowest part to form clamping connection; the inboard edge 3 in the side strip subassembly and the joint mode of outside edge 4 do: one surface of the inner edge strip 3 projects into the annular groove of the outer edge strip 4 and/or one surface of the outer edge strip 4 projects into the annular groove of the inner edge strip 3.

The width of the upper surface of the base side edge strip 2, the width of the upper surface and the lower surface of the inner side edge strip 3, the width of the upper surface and the lower surface of the outer side edge strip 4 and the width of the upper surface and the lower surface of the top side edge strip are the same.

The inner diameters of the height-adjustable middle nesting structure and the top side edge strip are the same as the inner diameter of the vessel body; the height of the middle nesting structure is adjusted by adjusting the number of the outer side edge strips 3 and the inner side edge strips 4 in the side edge strip assembly, so that the height of the whole vessel is adjusted.

The opening width of the inner side edge strip and the outer side edge strip is 2 times of the thickness of the inner side edge strip, and the thickness of the inner side edge strip is the same as that of the outer side edge strip.

When the utility model is adopted for soil culture of plants, the change of the volume of the container is realized by splicing and combining under the condition of certain density of the soil, thereby realizing the purpose of quantitative soil loading. Quantitative soil loading can be realized in a certain range in the outdoor scientific experiment process of simulating environmental change, and partial mechanical workload of scientific research is reduced; the detachable and assembled parts can be used repeatedly, and when some parts are damaged, only the corresponding parts can be replaced, so that the detachable and assembled parts are economical and environment-friendly.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, the present invention is not limited to the above-described embodiments, which are merely illustrative, instructive, and not restrictive. It will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made herein without departing from the scope of the utility model as defined by the appended claims.

Claims (10)

1. A combined plant growth vessel for soil culture experiments is characterized in that: the vessel comprises a vessel body, a height-adjustable intermediate nesting structure and a top side bar, wherein the intermediate nesting structure comprises a base side bar, or the intermediate nesting structure comprises a base side bar and a side bar assembly; the side edge strip assembly is formed by alternately arranging a plurality of outer side edge strips and inner side edge strips; the adjacent outer side edge strips and the inner side edge strips are clamped; wherein: the vessel body is of a cylindrical structure with a closed bottom, and the upper edge of the vessel body extends outwards horizontally and then bends inwards to form an annular groove with an inward opening; the base side edge strip is of an annular groove structure with an inward opening, the annular groove of the base side edge strip is sleeved outside the upper edge of the vessel body, and the edge of the lower surface of the annular groove structure of the base side edge strip is bent outwards and extends into the annular groove of the upper edge of the vessel body to be connected with the upper edge of the vessel body in a clamping manner; the inner side edge strip and the outer side edge strip are respectively of annular groove structures with outward openings and inward openings; the uppermost layer of the middle nested structure is clamped with the top side edge strip.

2. The combined plant growth vessel for soil culture experiments as claimed in claim 1, wherein: the top side edge strip is an inner top side edge strip or an outer top side edge strip, and the outer top side edge strip and the inner top side edge strip are respectively of annular groove structures with inward openings and outward openings.

3. The combined plant growth vessel for soil culture experiments as claimed in claim 2, wherein: when only the base side edge strip is arranged in the middle nested structure, the top side edge strip is an inner top side edge strip, and the base side edge strip is directly connected with the inner top side edge strip in a clamping mode.

4. The combined plant growth vessel for soil culture experiments as claimed in claim 3, wherein: when the base side edge strip is directly clamped and connected with the inner top side edge strip, the upper surface of the base side edge strip extends into the annular groove of the inner top side edge strip.

5. The combined plant growth vessel for soil culture experiments as claimed in claim 2, wherein: when middle nested structure includes base side strake and side strake subassembly, the outside strake or the inboard strake of side strake subassembly the top side strake joint is connected.

6. The combined plant growth vessel for soil culture experiments as claimed in claim 5, wherein: if the uppermost side of the side edge assembly is the inner side edge, the top side edge is the outer top side edge, and the uppermost inner side edge is clamped with the outer top side edge; if the side strip subassembly top is outside edging, then top edging is interior top edging, and the outside edging of top is connected with interior top edging looks joint.

7. The combined plant growth vessel for soil culture experiments as claimed in claim 5, wherein: when the middle nested structure comprises a base side edge strip and a side edge strip assembly, the lowest part of the side edge strip assembly is an inner side edge strip; the upper surface of the side edge strip of the base part extends into the annular groove of the inner side edge strip at the lowest part to form clamping connection; the joint mode of the inner side edge strip and the outer side edge strip in the side edge strip assembly is as follows: one surface of the inner edge strip extends into the annular groove of the outer edge strip and/or one surface of the outer edge strip extends into the annular groove of the inner edge strip.

8. The combined plant growth vessel for soil culture experiments as claimed in claim 1, wherein: the width of the upper surface of the base side edge strip, the width of the upper surface and the lower surface of the inner side edge strip, the width of the upper surface and the lower surface of the outer side edge strip and the width of the upper surface and the lower surface of the top side edge strip are the same.

9. The combined plant growth vessel for soil culture experiments as claimed in claim 1, wherein: the inner diameters of the height-adjustable middle nesting structure and the top side edge strip are the same as the inner diameter of the vessel body; the height of the middle nesting structure is adjusted by adjusting the number of the outer side edge strips and the inner side edge strips in the side edge strip assembly, so that the height of the whole vessel is adjusted.

10. The combined plant growth vessel for soil culture experiments as claimed in claim 1, wherein: the opening width of the inner side edge strip and the outer side edge strip is 2 times of the thickness of the inner side edge strip, and the thickness of the inner side edge strip is the same as that of the outer side edge strip.

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