CN214962053U - Low-voltage nanometer edge-covered air stone - Google Patents

Abstract

The utility model discloses a low pressure nanometer bubble stone of borduring, including integrated into one piece's shell body and bubble stone body, the shell body has opening installation cavity up, the protruding support ring that is equipped with of interior bottom surface of installation cavity, the bubble stone body is installed in the installation cavity and is erect on the top surface of support ring, and, the bottom surface of bubble stone body and the top surface of support ring laminate each other, be formed with opening encapsulating chamber up between the lateral wall of support ring and the lateral wall of sepiolite body and the inside wall of installation cavity, the pouring has the sealed glue that is used for fixing bubble stone body in the installation cavity in the encapsulating chamber, the inside wall of support ring, the interior bottom surface of installation cavity and the bottom surface surrounding structure of bubble stone body form the air cavity, the lateral surface of shell body is equipped with the air inlet that communicates with the air cavity; compared with the prior art, the utility model discloses the gas tightness is better, and the gas in the air cavity can only outwards be discharged through the bubbled stone body to improve the dispersion effect of oxygen in aqueous.

Description

Low-voltage nanometer edge-covered air stone

Technical Field

The utility model belongs to the technical field of the bubbled stone body technique and specifically relates to indicate a low pressure nanometer bubbled stone of borduring.

Background

As is known well, the low-pressure nano-bubble stone is applied to aquatic animal culture, and has the main function of refining and dispersing oxygen or oxygen-containing air pumped from the outside into water, so that the oxygen content of the culture water body is increased, and compared with the common bubble stone, the low-pressure nano-bubble stone has a better oxygen dispersion effect. At present, the structure of the low-pressure nanometer bubble stone generally comprises a base, an upper cover and a bubble stone body, wherein the base and the upper cover are in a split structure, so that the upper cover and the base need to be assembled during manufacturing, however, the structure has the following disadvantages: the connection between the upper cover and the base is not tight, so that the air tightness is poor, and the dispersion effect of oxygen in water is influenced.

Disclosure of Invention

To the not enough of existence among the above-mentioned prior art, the utility model aims at providing a low pressure nanometer bubble stone body of borduring, it can improve the dispersion effect of oxygen in aqueous.

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

the utility model provides a low pressure nanometer bubbling stone of borduring, is including integrated into one piece's shell body and the bubbling stone body of setting in the shell body, the shell body has opening installation cavity up, the protruding support ring that is equipped with of interior bottom surface of installation cavity, the bubbling stone body is installed in the installation cavity and is erect on the top surface of support ring, and, the bottom surface of bubbling stone body and the top surface laminating of support ring each other, be formed with opening encapsulating chamber up between the lateral wall of support ring and the lateral wall of sepiolite body and the inside wall of installation cavity, the pouring has the sealed glue that is used for fixing the bubbling stone body in the installation cavity in the encapsulating chamber, the inside wall of support ring, the interior bottom surface of installation cavity and the bottom surface surrounding structure of bubbling stone body become the air cavity, the lateral surface of shell body is equipped with the air inlet with the air cavity intercommunication.

Preferably, the bottom of the bubbled stone body is provided with a positioning part which is matched in the supporting ring.

Preferably, the top of the bubbled stone body is provided with an annular inclined plane which extends from bottom to top in an inclined manner towards the center of the bubbled stone body, and a clamping part for clamping the bubbled stone body is correspondingly formed on the sealant at the annular inclined plane.

Preferably, the inner bottom surface of the mounting cavity is convexly provided with a supporting part for supporting the bottom surface of the air stone body.

As a preferred scheme, the number of the supporting parts is at least two, and the at least two supporting parts are arranged in an annular and equidistant mode.

Preferably, at least two reinforcing ribs are arranged on the inner side of the support ring along the circumferential direction.

As a preferred scheme, at least two reinforcing ribs are annularly and equidistantly arranged.

Preferably, the side wall of the outer casing is provided with a convex part in a protruding manner, the upper surface of the convex part is provided with a connecting part in a protruding manner, and the air inlet is positioned on the connecting part.

Preferably, the sealant is epoxy resin.

Since the technical scheme is used, the utility model discloses mainly through the design have integrated into one piece's shell body to the cooperation is installed the bubbled stone in the installation cavity through sealed glue, thereby has improved the gas tightness of air cavity, compares prior art, and its gas tightness is better, and the gas in the air cavity can only outwards be discharged through the bubbled stone body, thereby improves the dispersion effect of oxygen in aqueous.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention.

Fig. 2 is a cross-sectional view of an embodiment of the invention.

Fig. 3 is a schematic structural diagram of an outer casing according to an embodiment of the present invention.

The attached drawings indicate the following:

10. an outer housing; 11. a mounting cavity; 12. a support ring; 13. filling a glue cavity; 14. an air cavity; 15. an air inlet; 16. a support portion; 17. reinforcing ribs; 18. a convex portion; 19. a connecting portion; 20. a bubbled stone body; 21. a positioning part; 22. an annular inclined plane; 30. sealing glue; 31 and a locking part 31.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

As shown in fig. 1 to 3, the low-pressure nanometer edge-covered bubbled stone provided in this embodiment includes an integrally formed outer casing 10 and a bubbled stone body 20 disposed in the outer casing 10, the outer casing 10 has an installation cavity 11 with an upward opening, a support ring 12 is convexly disposed on an inner bottom surface of the installation cavity 11, the bubbled stone body 20 is installed in the installation cavity 11 and is erected on a top surface of the support ring 12, a bottom surface of the bubbled stone body 20 and a top surface of the support ring 12 are attached to each other, an encapsulating cavity 13 with an upward opening is formed between an outer side wall of the support ring 12 and an outer side wall of the sepiolite body 20 and an inner side wall of the installation cavity 11, a sealant 30 for fixing the bubbled stone body 20 in the installation cavity 11 is poured in the encapsulating cavity 13, in this embodiment, the sealant 30 is an epoxy resin, and the inner side wall of the support ring 12 is an inner side wall of the support ring 12, The inner bottom surface of the mounting cavity 11 and the bottom surface of the air stone body 20 form an air cavity 14, and the outer side surface of the outer shell 10 is provided with an air inlet 15 communicated with the air cavity 14.

In the present embodiment, in order to facilitate the installation of the bubblestone body 20, the bottom of the bubblestone body 20 has a positioning portion 21, and the positioning portion 21 is fitted into the support ring 12 when installed. The top of the air bubble stone body 20 is provided with an annular inclined plane 22 which extends from bottom to top in an inclined manner towards the center of the air bubble stone body 20, when the sealant 30 is poured into the glue filling cavity 13, the sealant 30 at the annular inclined plane 22 is correspondingly provided with a clamping part 31 for clamping the air bubble stone body 20, and therefore the air bubble stone body 20 can be firmly fixed. The protruding supporting part 16 that is used for supporting 20 bottom surfaces of air stone body that is equipped with of interior bottom surface of installation cavity 11, supporting part 16 is at least two, and at least two supporting parts 16 are annular equidistance and arrange. The inboard of support ring 12 is equipped with two at least strengthening ribs 17 along circumference, at least two the strengthening rib 17 is annular equidistance and arranges, strengthening rib 17 can increase the intensity of support ring 12. The side wall of the outer shell 10 is convexly provided with a convex part 18, the upper surface of the convex part 18 is convexly provided with a connecting part 19, the air inlet 15 is positioned on the connecting part 19, and the connecting part 19 can be butted with an air pipe of an external pump body.

In operation, gas enters the air cavity 14 from the gas inlet 15, and then the gas in the air cavity 14 is discharged through the bubbled stone body 20 and dispersed into the water.

The above is only the preferred embodiment of the present invention, and not the scope of the present invention, all the equivalent structures or equivalent flow changes made by the contents of the specification and the drawings or the direct or indirect application in other related technical fields are included in the patent protection scope of the present invention.

Claims (9)

1. A low-pressure nanometer edge-covered air stone is characterized in that: including integrated into one piece's shell body and the bubbled stone body of setting in the shell body, the shell body has opening installation cavity up, the protruding support ring that is equipped with of interior bottom surface of installation cavity, the bubbled stone body is installed in the installation cavity and is erect on the top surface of support ring, and, the bottom surface of bubbled stone body and the top surface of support ring laminate mutually, be formed with opening encapsulating chamber up between the lateral wall of support ring and the lateral wall of sepiolite body and the inside wall of installation cavity, the pouring has the sealed glue that is used for fixing the bubbled stone body in the installation cavity in the encapsulating chamber, the inside wall of support ring, the interior bottom surface of installation cavity and the bottom surface surrounding structure of bubbled stone body become the air cavity, the lateral surface of shell body is equipped with the air inlet with the air cavity intercommunication.

2. A low pressure nano serging bubbled stone as claimed in claim 1, wherein: the bottom of the bubbled stone body is provided with a positioning part which is matched in the supporting ring.

3. A low pressure nano serging bubbled stone as claimed in claim 1, wherein: the top of bubbled stone body has the cyclic annular inclined plane of the central slope extension of from bottom to top to bubbled stone body, sealed glue of cyclic annular inclined plane department can be correspondingly formed with the clamping part that is used for blocking the bubbled stone body.

4. A low pressure nano serging bubbled stone as claimed in claim 1, wherein: the inner bottom surface of the mounting cavity is convexly provided with a supporting part for supporting the bottom surface of the air bubble stone body.

5. The low pressure nanometer serging bubbled stone as claimed in claim 4, wherein: the supporting parts are at least two, and at least two supporting parts are arranged in an annular equidistant mode.

6. A low pressure nano serging bubbled stone as claimed in claim 1, wherein: at least two reinforcing ribs are arranged on the inner side of the support ring along the circumferential direction.

7. The low pressure nanometer serging bubbled stone as claimed in claim 6, wherein: at least two the strengthening ribs are annular equidistance and arrange.

8. A low pressure nano serging bubbled stone as claimed in claim 1, wherein: the lateral wall of shell body is protruding to be equipped with the convex part, the upper surface of convex part is protruding to be equipped with connecting portion, and aforementioned air inlet is located connecting portion.

9. A low pressure nano serging bubbled stone as claimed in claim 1, wherein: the sealant is epoxy resin.

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