CN219154966U - Squeezing quantitative reflux container - Google Patents

Abstract

The utility model discloses a squeezing quantitative reflux container, which comprises a container body capable of being squeezed and deformed, wherein a containing cavity for containing liquid is formed in the container body, an outer cover is arranged at the upper end of the container body, an interlayer is arranged at the upper part of the containing cavity in the container body, a quantitative cavity is arranged in the interlayer, and a conduit which is communicated with the bottom of the containing cavity and the top of the quantitative cavity is arranged on the interlayer; the container body or the interlayer or the guide pipe is provided with scales for displaying the volume of the liquid in the quantifying cavity, and when the container body is extruded, the liquid in the accommodating cavity flows into the quantifying cavity through the guide pipe; a reflux component is also arranged on the interlayer; through setting up the ration chamber on the upper portion of container body to set up the scale on the ration chamber, through squeezing the container body, make the liquid that holds the intracavity flow into the ration intracavity through the pipe, rethread backward flow subassembly can make the liquid backward flow of ration intracavity hold the intracavity, be convenient for accurately pour the liquid of required volume in the ration intracavity, have simple, the convenient to use's of result advantage.

Description

Squeezing quantitative reflux container

[ field of technology ]

The utility model relates to a container, in particular to a squeezing quantitative reflux container.

[ background Art ]

In the prior art, a plurality of containers need to measure quantitative liquid by means of a measuring cylinder, a beaker and the like, and the operation is troublesome, and time and labor are wasted.

The utility model is researched and proposed for overcoming the defects of the prior art.

[ utility model ]

In order to solve the technical problems, the squeezing quantitative backflow container comprises a container body which can be squeezed and deformed, wherein a containing cavity for containing liquid is formed in the container body, an outer cover is arranged at the upper end of the container body, an interlayer is arranged in the container body and positioned at the upper part of the containing cavity, a quantitative cavity is arranged in the interlayer, and a conduit which is communicated with the bottom of the containing cavity and the top of the quantitative cavity is arranged on the interlayer; when the container body is squeezed, the liquid in the containing cavity flows into the dosing cavity through the guide pipe; and a backflow component for backflow of the liquid in the quantitative cavity into the accommodating cavity is further arranged on the interlayer.

The quantitative backflow container is characterized in that the backflow component comprises a backflow channel arranged at the bottom of the interlayer, a backflow port A is arranged on the side wall of the backflow channel, a backflow pipe for opening or closing the backflow port A is rotatably connected to the backflow channel, a backflow port B matched with the backflow port A is arranged at the lower end of the backflow pipe, the backflow port B is communicated with the backflow port A through rotation of the backflow pipe, liquid in the quantitative cavity can flow back into the accommodating cavity, or the backflow port B is staggered with the backflow port A through rotation of the backflow pipe so as to close the backflow port A.

According to the squeezing quantitative reflux container, the drive column for driving the reflux tube to rotate is arranged on the outer cover.

According to the squeezing quantitative reflux container, the driving column is arranged on the inner side of the outer cover, and when the outer cover is connected to the container body in a sealing mode, the driving column stretches into the guide pipe.

According to the squeezing quantitative reflux container, the polygonal inner hole is formed in the upper end of the reflux pipe, and the driving column can be inserted into the polygonal inner hole and drives the reflux pipe to rotate.

The quantitative squeezing backflow container is characterized in that the backflow assembly comprises a backflow channel arranged at the bottom of the interlayer, a hose made of elastic materials is connected to the backflow channel in a sealing mode, the upper end of the hose extends to the upper portion of the quantitative cavity, and a driving rod used for driving an upper end opening of the hose to move downwards is arranged on the outer cover, so that liquid in the quantitative cavity flows back to the accommodating cavity.

In the squeezing quantitative reflux container, the bayonet which can be clamped into the upper edge of the hose is arranged at the lower end of the driving rod.

In the squeezing quantitative reflux container, the hose can be a straight pipe, a bent pipe or a corrugated pipe.

According to the squeezing quantitative reflux container, the container body or the interlayer or the guide pipe is provided with the scale for displaying the liquid volume in the quantitative cavity.

Compared with the prior art, the utility model has the following advantages:

1. according to the utility model, the quantitative cavity is arranged at the upper part of the container body, the scale is arranged for quantitative operation, the container body is extruded, the liquid in the accommodating cavity flows into the quantitative cavity through the guide pipe, and the liquid in the quantitative cavity flows back into the accommodating cavity through the backflow component, so that the liquid with the required volume can be conveniently and accurately poured into the quantitative cavity, and the quantitative container has the advantages of simple result and convenience in use.

[ description of the drawings ]

The following detailed description of specific embodiments of the utility model refers to the accompanying drawings, in which:

FIG. 1 is an exploded view of a first embodiment of the present utility model;

FIG. 2 is an enlarged view of portion A marked in FIG. 1;

FIG. 3 is a schematic illustration in full section of a first embodiment of the present utility model;

FIG. 4 is an enlarged view of portion B marked in FIG. 3;

FIG. 5 is a schematic illustration in full section of a first embodiment of the present utility model;

FIG. 6 is an enlarged view of portion C marked in FIG. 5;

FIG. 7 is an exploded view of a second embodiment of the present utility model;

FIG. 8 is a schematic diagram of a second embodiment of the present utility model;

FIG. 9 is a second schematic diagram of a second embodiment of the present utility model;

fig. 10 is a schematic diagram of a third embodiment of the present utility model in full section.

[ detailed description ] of the utility model

Embodiments of the present utility model will be described in detail below with reference to the accompanying drawings.

As shown in fig. 1 to 10, the present utility model has three specific embodiments, each of which will now be described.

Embodiment one:

as shown in fig. 1 to 6, a squeeze quantitative reflux container of the present embodiment includes a container body 1 capable of being deformed by squeezing, a containing cavity 101 for containing liquid is provided in the container body 1, an outer cover 3 is provided at the upper end of the container body 1, a partition layer 11 is provided in the container body 1 and located at the upper part of the containing cavity 101, a quantitative cavity 102 is provided in the partition layer 11, a scale 111 for displaying the volume of the liquid in the quantitative cavity 102 is provided on the partition layer 11, and a conduit 12 communicating the bottom of the containing cavity 101 with the top of the quantitative cavity 102 is provided on the partition layer 11; the scale 111 may be provided on the container body or on the conduit as required, and when the container body 1 is squeezed, the liquid in the accommodating chamber 101 flows into the dosing chamber 102 through the conduit 12; the interlayer 11 is also provided with a backflow component for backflow of the liquid in the dosing chamber 102 into the accommodating chamber 101. According to the utility model, the quantitative cavity is arranged at the upper part of the container body, the scales are correspondingly arranged, the liquid in the accommodating cavity flows into the quantitative cavity through the guide pipe by extruding the container body, and the liquid in the quantitative cavity can flow back into the accommodating cavity through the backflow component, so that the liquid with the required volume can be conveniently and accurately poured into the quantitative cavity, and the quantitative container has the advantages of simple result and convenience in use.

In this embodiment, the backflow assembly includes a backflow channel 201 disposed at the bottom of the partition 11, a backflow port a202 is disposed on a side wall of the backflow channel 201, a backflow pipe 21 for opening or closing the backflow port a202 is rotatably connected to the backflow channel 201, a backflow port B211 matched with the backflow port a202 is disposed at a lower end of the backflow pipe 21, and the backflow port B211 is communicated with the backflow port a202 through rotating the backflow pipe 21, so that the liquid in the dosing chamber 102 can flow back into the accommodating chamber 101, or the backflow port B211 is staggered with the backflow port a202 through rotating the backflow pipe 21 so as to close the backflow port a202. By adopting the design, the liquid in the quantitative cavity can flow back conveniently.

In order to facilitate the rotation of the return tube, a drive post 31 for driving the return tube 21 in rotation is provided on the cover 3.

In this embodiment, the driving post 31 is disposed inside the outer cap 3, and when the outer cap 3 is hermetically connected to the container body 1, the driving post 31 extends into the conduit 12. With this design, it is convenient to fully utilize the space.

In this embodiment, a polygonal inner hole 212 is provided at the upper end of the return tube 21, and the driving post 31 is inserted into the polygonal inner hole 212 and drives the return tube 21 to rotate.

Embodiment two:

as shown in fig. 7 to 9, the difference between the present embodiment and the first embodiment is that the structure of the reflow assembly is different, in this embodiment, the reflow assembly includes a reflow channel 201 disposed at the bottom of the partition 11, the reflow channel 201 is connected with a flexible tube 23 made of elastic material in a sealing manner, the upper end of the flexible tube 23 extends to the upper portion of the dosing chamber 102, and the outer cover 3 is provided with a driving rod 33 for driving the upper end opening of the flexible tube 23 to move downward so as to reflow the liquid in the dosing chamber 102 into the accommodating chamber 101. By driving the upper end opening of the hose to move downwards, the liquid level of the liquid in the dosing chamber 102 is higher than that of the hose, and the liquid in the dosing chamber 102 flows through the backflow channel from the upper end opening of the hose to flow back into the accommodating chamber.

In this embodiment, a bayonet capable of being engaged with the upper edge of the hose 23 is provided at the lower end of the driving rod 33, and the bayonet engages with the upper edge of the hose to prevent the hose from being loosened.

In this embodiment, the hose 23 may be a straight pipe, and similarly, the hose 23 may be a bent pipe or a bellows.

Embodiment III:

as shown in fig. 10, the difference between the present embodiment and the second embodiment is that in the second embodiment, the hose 23 is a straight pipe, and in the present embodiment, the hose 23 is a curved pipe.

The foregoing examples are provided to further illustrate the technical contents of the present utility model for the convenience of the reader, but are not intended to limit the embodiments of the present utility model thereto, and any technical extension or re-creation according to the present utility model is protected by the present utility model. The protection scope of the utility model is subject to the claims.

Claims (8)

1. The extrusion quantitative backflow container comprises a container body (1) capable of being extruded and deformed, and is characterized in that a containing cavity (101) for containing liquid is formed in the container body (1), an outer cover (3) is arranged at the upper end of the container body (1), an interlayer (11) is arranged at the upper part of the containing cavity (101) in the container body (1), a quantitative cavity (102) is formed in the interlayer (11), a conduit (12) for communicating the bottom of the containing cavity (101) with the top of the quantitative cavity (102) is arranged on the interlayer (11), and when the container body (1) is extruded, liquid in the containing cavity (101) flows into the quantitative cavity (102) through the conduit (12); the interlayer (11) is also provided with a reflux component for refluxing the liquid in the quantitative cavity (102) into the accommodating cavity (101); the backflow assembly comprises a backflow channel (201) arranged at the bottom of the interlayer (11), a backflow port A (202) is arranged on the side wall of the backflow channel (201), a backflow pipe (21) used for opening or closing the backflow port A (202) is rotationally connected to the backflow channel (201), a backflow port B (211) matched with the backflow port A (202) is arranged at the lower end of the backflow pipe (21), the backflow port B (211) is communicated with the backflow port A (202) through a rotary backflow pipe (21), liquid in the quantitative cavity (102) can flow back into the accommodating cavity (101), or the backflow port B (211) and the backflow port A (202) are staggered through the rotary backflow pipe (21) to close the backflow port A (202).

2. A squeeze quantitative reflux container according to claim 1, characterized in that the outer cap (3) is provided with a driving column (31) for driving the reflux tube (21) to rotate.

3. A squeeze quantitative reflux container according to claim 2, characterized in that the driving column (31) is provided inside the outer cap (3), and the driving column (31) extends into the conduit (12) when the outer cap (3) is sealingly connected to the container body (1).

4. A squeeze quantitative reflux container according to claim 2, wherein the upper end of the reflux tube (21) is provided with a polygonal inner hole (212), and the driving column (31) is inserted into the polygonal inner hole (212) and drives the reflux tube (21) to rotate.

5. The extrusion quantitative backflow container comprises a container body (1) capable of being extruded and deformed, and is characterized in that a containing cavity (101) for containing liquid is formed in the container body (1), an outer cover (3) is arranged at the upper end of the container body (1), an interlayer (11) is arranged at the upper part of the containing cavity (101) in the container body (1), a quantitative cavity (102) is formed in the interlayer (11), a conduit (12) for communicating the bottom of the containing cavity (101) with the top of the quantitative cavity (102) is arranged on the interlayer (11), and when the container body (1) is extruded, liquid in the containing cavity (101) flows into the quantitative cavity (102) through the conduit (12); the interlayer (11) is also provided with a reflux component for refluxing the liquid in the quantitative cavity (102) into the accommodating cavity (101); the backflow component comprises a backflow channel (201) arranged at the bottom of the interlayer (11), a hose (23) made of elastic materials is connected to the backflow channel (201) in a sealing mode, the upper end of the hose (23) extends to the upper portion of the quantitative cavity (102), and a driving rod (33) used for driving an upper end opening of the hose (23) to move downwards is arranged on the outer cover (3) so that liquid in the quantitative cavity (102) flows back to the accommodating cavity (101).

6. A squeeze quantitative reflux container according to claim 5, characterized in that the lower end of the driving rod (33) is provided with a bayonet which can be snapped into the upper edge of the hose (23).

7. A squeeze quantitative reflux container according to claim 5, characterized in that the hose (23) is a straight, curved or corrugated tube.

8. A squeeze quantitative reflux container according to any one of claims 1-7, characterized in that the container body (1) or the barrier (11) or the conduit (12) is provided with a scale (111) for displaying the volume of liquid in the quantitative chamber (102).

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