CN211443316U - Container convenient for quantitative pouring - Google Patents

Abstract

The utility model discloses a container convenient for quantitative pouring, when the valve sleeve moves, the liquid inlet control structure can communicate the liquid storage cavity with the quantitative cavity and the liquid outlet control structure isolates the quantitative cavity from the outside, namely, the liquid in the liquid storage cavity flows into the quantitative cavity, after the required dosage is reached, the valve sleeve moves continuously to isolate the liquid storage cavity from the quantitative cavity and the liquid outlet control structure communicates the quantitative cavity with the outside, then the liquid in the quantitative cavity flows out of the outside, after the use, the liquid inlet control structure isolates the liquid storage cavity from the quantitative cavity and the liquid outlet control structure isolates the quantitative cavity from the outside; therefore, the utility model has the characteristics of reasonable in design, the structure is succinct, the use is convenient, simultaneously, still has better leakproofness.

Description

Container convenient for quantitative pouring

[ technical field ] A method for producing a semiconductor device

The utility model relates to a packaging container, especially a container of being convenient for ration is got by others.

[ background of the invention ]

The packaging container is designed for various industries to protect commodities, has the functions of convenient storage and use, facilitating transportation, promoting sales, preventing environmental pollution, safety accidents and the like, and adopts corresponding packaging containers according to certain technical specifications for different industries and different products.

However, the existing quantitative pouring container has the defects of high manufacturing cost due to complex structure and inconvenient use due to complex quantitative pouring operation.

The utility model discloses research and development is carried out to the defect that prior art exists promptly and propose.

[ Utility model ] content

The technical problem to be solved by the utility model is to provide a container convenient for quantitative pouring, which comprises a liquid storage cavity, a quantitative cavity and a valve sleeve; a liquid inlet control structure which can enable the liquid storage cavity to be communicated or isolated with the quantitative cavity when the valve sleeve is moved is arranged between the liquid storage cavity and the quantitative cavity; one end of the valve sleeve is communicated with the quantitative cavity, a liquid outlet control structure which can enable the quantitative cavity to be communicated or isolated with the outside when the valve sleeve moves is arranged between the other end of the valve sleeve and the liquid storage cavity, or a liquid outlet control structure which can enable the quantitative cavity to be communicated or isolated with the outside when the valve sleeve moves is arranged between the other end of the valve sleeve and the quantitative cavity; at the beginning or after the use is finished, the liquid inlet control structure isolates the liquid storage cavity from the quantitative cavity, and the liquid outlet control structure isolates the quantitative cavity from the outside, so that the quality guarantee effect is achieved; when the action valve sleeve moves, the liquid inlet control structure can communicate the liquid storage cavity with the quantitative cavity and the liquid outlet control structure isolates the quantitative cavity from the outside, namely, the liquid in the liquid storage cavity flows into the quantitative cavity, after the required using amount is reached, the action valve sleeve moves continuously, the liquid inlet control structure can isolate the liquid storage cavity from the quantitative cavity and communicate the quantitative cavity with the outside, and then the liquid in the quantitative cavity flows out of the outside. Therefore, the utility model has the characteristics of reasonable in design, the structure is succinct, the use is convenient, simultaneously, still has better leakproofness.

In order to solve the technical problem, the utility model provides a container convenient for quantitative pouring, which comprises a liquid storage cavity 1, a quantitative cavity 2 and a valve sleeve 3; a liquid inlet control structure 4 which can enable the liquid storage cavity 1 to be communicated with or isolated from the quantitative cavity 2 when the valve sleeve 3 moves is arranged between the liquid storage cavity 1 and the quantitative cavity 2; one end of the valve sleeve 3 is communicated with the quantitative cavity 2, a liquid outlet control structure 5 which can enable the quantitative cavity 2 to be communicated or isolated with the outside when the valve sleeve 3 moves is arranged between the other end of the valve sleeve 3 and the liquid storage cavity 1, or a liquid outlet control structure 5 which can enable the quantitative cavity 2 to be communicated or isolated with the outside when the valve sleeve 3 moves is arranged between the other end of the valve sleeve 3 and the quantitative cavity 2; at the beginning or after the end of use, the liquid inlet control structure 4 isolates the liquid storage cavity 1 from the quantitative cavity 2, and the liquid outlet control structure 5 isolates the quantitative cavity 2 from the outside; when the action valve sleeve 3 moves, the liquid inlet control structure 4 can communicate the liquid storage cavity 1 with the quantitative cavity 2, and the liquid outlet control structure 5 isolates the quantitative cavity 2 from the outside, after the required dosage is reached, the action valve sleeve 3 continues to move, so that the liquid inlet control structure 4 isolates the liquid storage cavity 1 from the quantitative cavity 2, and the liquid outlet control structure 5 communicates the quantitative cavity 2 with the outside.

The container convenient for quantitative pouring is characterized in that the quantitative cavity 2 is provided with identification scales.

The container convenient for quantitative pouring is characterized in that the liquid storage cavity 1 and the quantitative cavity 2 are formed by separating a container body 10 through a partition plate 101, the liquid storage cavity 1 and the quantitative cavity 2 are respectively arranged up and down, the quantitative cavity 2 is provided with a connecting hole sleeve 21 for movably connecting a valve sleeve 3, one end of the valve sleeve 3 penetrates through the connecting hole sleeve 21 and is communicated with the quantitative cavity 2, the other end of the valve sleeve 3 is arranged outside the quantitative cavity 2, the liquid inlet control structure 4 comprises a static liquid inlet 41 and a dynamic liquid inlet 42 which are respectively arranged on the partition plate 101 and the valve sleeve 3, and the liquid outlet control structure 5 comprises a static liquid outlet 51 and a dynamic liquid outlet 52 which are respectively arranged on the connecting hole sleeve 21 and the valve sleeve 3; when the acting valve sleeve 3 rotates or moves telescopically relative to the connecting hole sleeve 21, the acting valve sleeve 3 can be enabled to be aligned and communicated with the static liquid inlet 41 and the dynamic liquid outlet 52 and the static liquid outlet 51 are blocked in a staggered mode, so that liquid in the liquid storage cavity 1 flows into the quantitative cavity 2, after the required using amount is achieved, the acting valve sleeve 3 continues to rotate or move telescopically relative to the connecting hole sleeve 21, the acting valve sleeve 42 and the static liquid inlet 41 are blocked in a staggered mode and the dynamic liquid outlet 52 and the static liquid outlet 51 are aligned and communicated, and liquid in the quantitative cavity 2 flows out of the outside through the valve sleeve 3.

The container convenient for quantitative pouring is characterized in that the liquid storage cavity 1 is formed by an inner cavity of the container body 10, the quantitative cavity 2 is formed by an inner cavity of the valve sleeve 3, the bottom of the liquid storage cavity 1 is provided with the connecting hole sleeve 21 for movably connecting the valve sleeve 3, the liquid inlet control structure 4 comprises a static liquid inlet 41 and a dynamic liquid inlet 42 which are respectively arranged on the liquid storage cavity 1 and the valve sleeve 3, the liquid outlet control structure 5 comprises a static liquid outlet 51 and a dynamic liquid outlet 52 which are respectively arranged on the connecting hole sleeve 21 and the valve sleeve 3, when the valve sleeve 3 rotates or moves telescopically relative to the connecting hole sleeve 21, the dynamic liquid inlet 42 and the static liquid inlet 41 can be aligned and communicated, and the dynamic liquid outlet 52 and the static liquid outlet 51 can be plugged in a staggered way, so that the liquid in the liquid storage cavity 1 flows into the quantitative cavity 2, and when the required dosage is reached, the valve sleeve 3 continues to rotate or move telescopically, the movable liquid inlet 42 and the static liquid inlet 41 can be blocked off in a staggered way, and the movable liquid outlet 52 and the static liquid outlet 51 are communicated in an aligned way, so that the liquid in the quantitative cavity 2 flows out of the outside through the valve sleeve 3.

The container convenient for quantitative pouring is characterized in that the outer end of the connecting hole sleeve 21 is detachably connected with a valve cover 211, the valve cover 211 is connected with the valve sleeve 3, a valve cover notch 2111 used for matching with the static liquid outlet 51 is arranged on the valve cover 211, and when the movable liquid outlet 52 is aligned and communicated with the static liquid outlet 51, the valve cover notch 2111 is aligned with the static liquid outlet 51; when the movable liquid outlet 52 and the static liquid outlet 51 are sealed in a staggered manner, the valve cover notch 2111 and the static liquid outlet 51 are sealed in a staggered manner.

The utility model also provides a container of being convenient for ration is got backward, including hollow vessel 10 and valve sleeve 3, vessel 10's inner chamber is formed with stock solution chamber 1, be equipped with the connecting hole cover 21 with the mobile telescopic connection of valve sleeve 3 on the stock solution chamber 1, valve sleeve 3 cavity and both ends shutoff, valve sleeve 3's inner chamber is formed with ration chamber 2, be equipped with on the valve sleeve 3 and can make stock solution chamber 1 and ration chamber 2 intercommunication or ration chamber 2 and the entering/going out liquid control structure 6 of outside intercommunication when valve sleeve 3 relative connecting hole cover 21 moves about, when entering/going out liquid control structure 6 activity to stock solution chamber 1 inboard, can make stock solution chamber 1 and ration chamber 2 intercommunication, when entering/going out liquid control structure 6 activity to the stock solution chamber 1 outside, can make ration chamber 2 and outside intercommunication.

A container for facilitating quantitative pouring as described above, characterized in that said inlet/outlet control structure 6 is an inlet/outlet port provided on the valve sleeve 3.

A container for facilitating the quantitative pouring as described above, wherein the valve sleeve 3 is connected with a handle portion 31 for a user to operate the valve sleeve 3.

The container convenient for quantitative pouring is characterized in that a limiting column 11 is arranged in the liquid storage cavity 1 relative to the valve sleeve 3, and a limiting groove 32 used for being movably connected with the limiting column 11 is arranged on the valve sleeve 3.

The container convenient for quantitative pouring is characterized in that the outer end of the connecting hole sleeve 21 is detachably connected with a valve cover 211.

The container convenient for quantitative pouring is characterized in that the container body 10 is provided with an opening, and the upper cover 7 is detachably connected to the opening of the container body 10.

The container convenient for quantitative pouring is characterized in that the blocking end of the valve sleeve 3 positioned in the liquid storage cavity 1 is formed by an opening of the valve sleeve 3 and a sealing sleeve 12 arranged in the liquid storage cavity 1.

Compared with the prior art, the utility model relates to a container is got to ration of being convenient for has following advantage:

1. at the beginning or after the use is finished, the liquid inlet control structure isolates the liquid storage cavity from the quantitative cavity, and the liquid outlet control structure isolates the quantitative cavity from the outside, so that the quality guarantee effect is achieved; when the action valve sleeve moves, the liquid inlet control structure can communicate the liquid storage cavity with the quantitative cavity and the liquid outlet control structure isolates the quantitative cavity from the outside, namely, the liquid in the liquid storage cavity flows into the quantitative cavity, after the required using amount is reached, the action valve sleeve moves continuously, the liquid inlet control structure can isolate the liquid storage cavity from the quantitative cavity and communicate the quantitative cavity with the outside, and then the liquid in the quantitative cavity flows out of the outside. Therefore, the utility model has the characteristics of reasonable in design, the structure is succinct, the use is convenient, simultaneously, still has better leakproofness.

2. The quantitative cavity is provided with a scale mark, so that a user can conveniently carry out quantification.

3. In order to facilitate a user to drive the valve sleeve to move so as to pour liquid quantitatively, the valve sleeve is connected with a valve cover or a handle part.

[ description of the drawings ]

The following detailed description of embodiments of the present invention is provided with reference to the accompanying drawings, in which:

FIG. 1 is one of the schematic cross-sectional views of the first embodiment of the present invention;

FIG. 2 is a second schematic cross-sectional view of the first embodiment of the present invention;

FIG. 3 is one of the schematic cross-sectional views of a second embodiment of the present invention;

FIG. 4 is a second schematic cross-sectional view of a second embodiment of the present invention;

FIG. 5 is one of the schematic cross-sectional views of a third embodiment of the present invention;

FIG. 6 is a second schematic cross-sectional view of a third embodiment of the present invention;

FIG. 7 is a schematic cross-sectional view of a fourth embodiment of the present invention;

fig. 8 is a schematic cross-sectional view of a fifth embodiment of the present invention;

fig. 9 is a schematic cross-sectional view of a sixth embodiment of the present invention;

fig. 10 is a schematic cross-sectional view of a seventh embodiment of the present invention;

fig. 11 is one of schematic cross-sectional views of an eighth embodiment of the present invention;

fig. 12 is a second schematic cross-sectional view of an eighth embodiment of the present invention;

fig. 13 is one of schematic cross-sectional views of a ninth embodiment of the present invention;

fig. 14 is a second schematic cross-sectional view of a ninth embodiment of the present invention;

fig. 15 is a schematic cross-sectional view of a tenth embodiment of the present invention.

[ detailed description ] embodiments

Embodiments of the present invention will be described in detail below with reference to fig. 1 to 15.

As shown in fig. 1-4, the container convenient for quantitative pouring of the present invention comprises a liquid storage cavity 1, a quantitative cavity 2 and a valve sleeve 3; a liquid inlet control structure 4 which can enable the liquid storage cavity 1 to be communicated with or isolated from the quantitative cavity 2 when the valve sleeve 3 moves is arranged between the liquid storage cavity 1 and the quantitative cavity 2; one end of the valve sleeve 3 is communicated with the quantitative cavity 2, a liquid outlet control structure 5 which can enable the quantitative cavity 2 to be communicated or isolated with the outside when the valve sleeve 3 moves is arranged between the other end of the valve sleeve 3 and the liquid storage cavity 1, or a liquid outlet control structure 5 which can enable the quantitative cavity 2 to be communicated or isolated with the outside when the valve sleeve 3 moves is arranged between the other end of the valve sleeve 3 and the quantitative cavity 2; at the beginning or after the use is finished, the liquid inlet control structure 4 isolates the liquid storage cavity 1 from the quantitative cavity 2, and the liquid outlet control structure 5 isolates the quantitative cavity 2 from the outside, so that the quality guarantee effect is achieved; when acting on valve sleeve 3 activity, can make feed liquor control structure 4 with stock solution chamber 1 with quantitative chamber 2 intercommunication and go out liquid control structure 5 with quantitative chamber 2 with outside isolated, the liquid inflow quantitative intracavity in stock solution chamber promptly, after reaching required quantity, continue to act on valve sleeve 3 activity and can make feed liquor control structure 4 with stock solution chamber 1 with quantitative chamber 2 isolated and go out liquid control structure 5 with quantitative chamber 2 with outside intercommunication, then the liquid inflow outside in quantitative chamber. Therefore, the utility model has the characteristics of reasonable in design, the structure is succinct, the use is convenient, simultaneously, still has better leakproofness.

In order to facilitate quantitative pouring of a user, the quantitative cavity 2 is provided with a mark scale which is not shown in the drawing.

As shown in fig. 1 and 2, the liquid storage cavity 1 and the quantitative cavity 2 are formed by a container body 10 separated by a partition plate 101, the liquid storage cavity 1 and the quantitative cavity 2 are respectively arranged up and down, the quantitative cavity 2 is provided with a connecting hole sleeve 21 for movably connecting the valve sleeve 3, one end of the valve sleeve 3 penetrates through the connecting hole sleeve 21 and is communicated with the quantitative cavity 2, the other end of the valve sleeve 3 is arranged outside the quantitative cavity 2, the liquid inlet control structure 4 comprises a static liquid inlet 41 and a dynamic liquid inlet 42 respectively arranged on the partition plate 101 and the valve sleeve 3, and the liquid outlet control structure 5 comprises a static liquid outlet 51 and a dynamic liquid outlet 52 respectively arranged on the connecting hole sleeve 21 and the valve sleeve 3; when the action valve sleeve 3 rotates or telescopically moves relative to the connecting hole sleeve 21, the action valve sleeve 42 can be aligned and communicated with the static liquid inlet 41 and the movable liquid outlet 52 and the static liquid outlet 51 are blocked in a staggered mode, so that liquid in the liquid storage cavity 1 flows into the quantitative cavity 2, after the required using amount is reached, the action valve sleeve 3 continues to rotate or telescopically move relative to the connecting hole sleeve 21, the action valve sleeve 42 can be aligned and blocked with the static liquid inlet 41 in a staggered mode and the movable liquid outlet 52 is aligned and communicated with the static liquid outlet 51, so that the liquid in the quantitative cavity 2 flows out of the external part through the valve sleeve 3.

As shown in fig. 3 and 4, the liquid storage cavity 1 is formed by an inner cavity of the container body 10, the quantitative cavity 2 is formed by an inner cavity of the valve sleeve 3, a connecting hole sleeve 21 for movably connecting the valve sleeve 3 is arranged at the bottom of the liquid storage cavity 1, the liquid inlet control structure 4 comprises a static liquid inlet 41 and a dynamic liquid inlet 42 respectively arranged on the liquid storage cavity 1 and the valve sleeve 3, the liquid outlet control structure 5 comprises a static liquid outlet 51 and a dynamic liquid outlet 52 respectively arranged on the connecting hole sleeve 21 and the valve sleeve 3, when the valve sleeve 3 rotates or telescopically moves relative to the connecting hole sleeve 21, the dynamic liquid inlet 42 and the static liquid inlet 41 can be aligned and communicated, and the dynamic liquid outlet 52 and the static liquid outlet 51 can be misaligned and blocked, so that the liquid in the liquid storage cavity 1 flows into the quantitative cavity 2, after the required amount is reached, the valve sleeve 3 continues to act on the rotating or telescopically moves relative to the connecting hole sleeve 21, so that the dynamic liquid inlet 42 and the static liquid, and make the liquid in ration chamber 2 flow out the outside through valve sleeve 3, for this reason, have reasonable in design, the characteristics that the structure is succinct, the use is convenient, simultaneously, still have better leakproofness.

As shown in fig. 3 and 4, the dosing chamber 2 is arranged on the valve sleeve 3 according to design and usage requirements.

Furthermore, in order to facilitate a user to drive the valve sleeve to move for quantitative liquid pouring, and meanwhile, to further improve the sealing performance of the quantitative cavity, the outer end of the connecting hole sleeve 21 is detachably connected with a valve cover 211, the valve cover 211 is connected with the valve sleeve 3, a valve cover notch 2111 used for matching with the static liquid outlet 51 is arranged on the valve cover 211, and when the movable liquid outlet 52 is aligned and communicated with the static liquid outlet 51, the valve cover notch 2111 is aligned with the static liquid outlet 51; when the movable liquid outlet 52 and the static liquid outlet 51 are sealed in a staggered manner, the valve cover notch 2111 and the static liquid outlet 51 are sealed in a staggered manner.

As shown in fig. 1 to 4, the vessel body 10 is integrally formed with the partition plate 101 in order to simplify the structure and reduce the manufacturing cost.

As shown in fig. 1 to 4, in order to provide a plurality of connection modes and meet different scene requirements, the connection hole sleeve 21 and the valve cover 211 are connected by a snap connection or a thread connection.

As shown in fig. 5-15, the utility model relates to a container convenient for quantitative pouring, which comprises a hollow container body 10 and a valve sleeve 3, a liquid storage cavity 1 is formed in the inner cavity of the container body 10, a connecting hole sleeve 21 which is movably and telescopically connected with the valve sleeve 3 is arranged on the liquid storage cavity 1, the valve sleeve 3 is hollow and two ends are blocked, a quantitative cavity 2 is formed in the inner cavity of the valve sleeve 3, the valve sleeve 3 is provided with a liquid inlet/outlet control structure 6 which can lead the liquid storage cavity 1 to be communicated with the quantitative cavity 2 or lead the quantitative cavity 2 to be communicated with the outside when the valve sleeve 3 moves relative to the connecting hole sleeve 21, when the liquid inlet/outlet control structure 6 moves to the inner side of the liquid storage cavity 1, the liquid storage cavity 1 can be communicated with the quantitative cavity 2, and when the liquid inlet/outlet control structure 6 moves to the outer side of the liquid storage cavity 1, the quantitative cavity 2 can be communicated with the outside. Therefore, the utility model has the characteristics of reasonable in design, the structure is succinct, the use is convenient.

According to the design requirement, the liquid inlet/outlet control structure 6 is a liquid inlet/outlet arranged on the valve sleeve 3.

As shown in fig. 5-15, in order to facilitate the user to actuate the valve sleeve to perform quantitative liquid pouring, a handle portion 31 for the user to actuate the valve sleeve 3 is connected to the valve sleeve 3. Wherein the pull tab portion 31 may be a pull tab or a wrench.

Further, the handle portion 31 is integrally formed with the valve sleeve 3 for the sake of simplicity and production cost reduction.

As shown in fig. 5 and 6, in order to enable the valve sleeve to move horizontally and stably, i.e. to prevent the valve sleeve from tilting when being pulled out relative to the connecting hole, a limiting column 11 is arranged in the liquid storage cavity 1 relative to the valve sleeve 3, and a limiting groove 32 for movably connecting with the limiting column 11 is arranged on the valve sleeve 3. Or the outer end of the connecting hole sleeve 21 is detachably connected with a valve cover 211.

As shown in fig. 13 to 15, in order to provide a plurality of connection modes and meet different scene requirements, the connection hole sleeve 21 and the valve cover 211 are connected by a snap connection or a thread connection.

Further, the limiting groove 32 is provided integrally with the valve sleeve 3 for the sake of simplicity of construction and reduction of production cost.

Further, in order to simplify the structure and reduce the production cost, the limiting column 11 is integrally formed with the container body 10.

As shown in fig. 13 and 14, according to design requirements and multiple use modes, the container body 10 has an opening, and the upper cover 7 is detachably connected to the opening of the container body 10, so that dust and flying insects can be prevented from entering the inner cavity of the container body 10, the use safety of the liquid filled in the liquid storage cavity can be guaranteed, and sanitation and cleanness can be achieved.

As shown in fig. 13 and 14, in order to provide a plurality of connection modes and meet different scene requirements, the opening of the container body and the upper cover are connected through a snap connection or a buckling connection or a threaded connection.

As shown in fig. 11-15, according to the design requirement, in order to ensure that the valve sleeve can move horizontally and stably when the valve sleeve is used, i.e. to prevent the valve sleeve from tilting when the valve sleeve is pulled out relative to the connecting hole, the plugging end of the valve sleeve 3 located in the liquid storage chamber 1 is formed by the opening of the valve sleeve 3 and the sealing sleeve 12 arranged in the liquid storage chamber 1.

Claims (12)

1. A container convenient for quantitative pouring is characterized by comprising a liquid storage cavity (1), a quantitative cavity (2) and a valve sleeve (3); a liquid inlet control structure (4) which can enable the liquid storage cavity (1) to be communicated with or isolated from the quantitative cavity (2) when the valve sleeve (3) moves is arranged between the liquid storage cavity (1) and the quantitative cavity (2); one end of the valve sleeve (3) is communicated with the quantitative cavity (2), a liquid outlet control structure (5) which can enable the quantitative cavity (2) to be communicated or isolated with the outside when the valve sleeve (3) moves is arranged between the other end of the valve sleeve (3) and the liquid storage cavity (1), or a liquid outlet control structure (5) which can enable the quantitative cavity (2) to be communicated or isolated with the outside when the valve sleeve (3) moves is arranged between the other end of the valve sleeve (3) and the quantitative cavity (2); at the beginning or after the use is finished, the liquid inlet control structure (4) isolates the liquid storage cavity (1) from the quantitative cavity (2), and the liquid outlet control structure (5) isolates the quantitative cavity (2) from the outside; when the acting valve sleeve (3) moves, the liquid inlet control structure (4) can communicate the liquid storage cavity (1) with the quantitative cavity (2) and the liquid outlet control structure (5) isolates the quantitative cavity (2) from the outside, and after the required dosage is reached, the liquid inlet control structure (4) can isolate the liquid storage cavity (1) from the quantitative cavity (2) and the liquid outlet control structure (5) can communicate the quantitative cavity (2) with the outside by continuing to act on the movement of the valve sleeve (3).

2. A container for facilitating the dosed pouring of a substance according to claim 1, characterized in that the dosing chamber (2) is provided with a marked scale.

3. A container for facilitating the quantitative pouring of a product according to claim 1 wherein said reservoir (1) and said quantitative chamber (2) are formed by a container body (10) separated by a partition (101), the liquid storage cavity (1) and the quantitative cavity (2) are respectively arranged up and down, a connecting hole sleeve (21) for movably connecting the valve sleeve (3) is arranged on the quantitative cavity (2), one end of the valve sleeve (3) penetrates through the connecting hole sleeve (21) to be communicated with the quantitative cavity (2), the other end of the valve sleeve (3) is arranged outside the quantitative cavity (2), the liquid inlet control structure (4) comprises a static liquid inlet (41) and a dynamic liquid inlet (42) which are respectively arranged on the clapboard (101) and the valve sleeve (3), the liquid outlet control structure (5) comprises a static liquid outlet (51) and a dynamic liquid outlet (52) which are respectively arranged on the connecting hole sleeve (21) and the valve sleeve (3); when the acting valve sleeve (3) rotates or moves in a telescopic mode relative to the connecting hole sleeve (21), the acting valve sleeve (3) can be enabled to be aligned and communicated with the static liquid inlet (41) and the moving liquid outlet (52) and the static liquid outlet (51) are plugged in a staggered mode, liquid in the liquid storage cavity (1) flows into the quantitative cavity (2), after the required using amount is achieved, the acting valve sleeve (3) continues to rotate or move in a telescopic mode relative to the connecting hole sleeve (21), the acting valve sleeve (42) can be enabled to be plugged in a staggered mode relative to the static liquid inlet (41) and the moving liquid outlet (52) and the static liquid outlet (51) are aligned and communicated, and liquid in the quantitative cavity (2) flows out of the outside through the valve sleeve (3).

4. The container convenient for quantitative pouring and taking as claimed in claim 1, wherein the liquid storage cavity (1) is formed by an inner cavity of the container body (10), the quantitative cavity (2) is formed by an inner cavity of the valve sleeve (3), a connecting hole sleeve (21) for movably connecting the valve sleeve (3) is arranged at the bottom of the liquid storage cavity (1), the liquid inlet control structure (4) comprises a static liquid inlet (41) and a dynamic liquid inlet (42) which are respectively arranged on the liquid storage cavity (1) and the valve sleeve (3), the liquid outlet control structure (5) comprises a static liquid outlet (51) and a dynamic liquid outlet (52) which are respectively arranged on the connecting hole sleeve (21) and the valve sleeve (3), when the valve sleeve (3) rotates or telescopically moves relative to the connecting hole sleeve (21), the dynamic liquid inlet (42) can be aligned and communicated with the static liquid inlet (41) and the dynamic liquid outlet (52) and the static liquid outlet (51) can be blocked in a staggered way, and the liquid in the liquid storage cavity (1) flows into the quantitative cavity (2), after the required dosage is reached, the valve sleeve (3) continues to act to rotate or stretch and move relative to the connecting hole sleeve (21), so that the movable liquid inlet (42) and the static liquid inlet (41) are blocked in a staggered mode, the movable liquid outlet (52) and the static liquid outlet (51) are aligned and communicated, and the liquid in the quantitative cavity (2) flows out of the quantitative cavity through the valve sleeve (3).

5. The container convenient for quantitative pouring according to claim 3 or 4, characterized in that the outer end of the connecting hole sleeve (21) is detachably connected with a valve cover (211), the valve cover (211) is connected with the valve sleeve (3), the valve cover (211) is provided with a valve cover notch (2111) for matching with the static liquid outlet (51), when the movable liquid outlet (52) is aligned and communicated with the static liquid outlet (51), the valve cover notch (2111) is aligned with the static liquid outlet (51); when the movable liquid outlet (52) and the static liquid outlet (51) are blocked in a staggered way, the notch (2111) of the valve cover and the static liquid outlet (51) are blocked in a staggered way.

6. A container convenient for quantitative pouring is characterized by comprising a hollow container body (10) and a valve sleeve (3), wherein a liquid storage cavity (1) is formed in an inner cavity of the container body (10), a connecting hole sleeve (21) movably and telescopically connected with the valve sleeve (3) is arranged on the liquid storage cavity (1), the valve sleeve (3) is hollow, two ends of the valve sleeve are sealed, a quantitative cavity (2) is formed in the inner cavity of the valve sleeve (3), a liquid inlet/outlet control structure (6) which can enable the liquid storage cavity (1) to be communicated with the quantitative cavity (2) or the quantitative cavity (2) to be communicated with the outside when the valve sleeve (3) moves relative to the connecting hole sleeve (21) is arranged on the valve sleeve (3), when the liquid inlet/outlet control structure (6) moves to the inner side of the liquid storage cavity (1), the liquid storage cavity (1) can be communicated with the quantitative cavity (2), and when the liquid inlet/outlet control structure (6) moves to the outer side of the liquid storage cavity (1), the dosing chamber (2) can be put in communication with the outside.

7. Container facilitating dosed pouring according to claim 6, characterized in that the inlet/outlet control structure (6) is an inlet/outlet port provided in the valve sleeve (3).

8. A container for facilitating the dosed pouring of a substance according to claim 6, characterized in that the valve sleeve (3) is connected to a handle portion (31) for the user to actuate the valve sleeve (3).

9. A container convenient for quantitative pouring according to claim 6 characterized in that a limiting column (11) is arranged in the reservoir (1) opposite to the valve sleeve (3), and a limiting groove (32) for movably connecting with the limiting column (11) is arranged on the valve sleeve (3).

10. A container for facilitating the quantitative pouring of a substance according to any of claims 6 to 9, wherein a valve cover (211) is detachably attached to the outer end of the connection hole sleeve (21).

11. A container for facilitating the quantitative pouring of a product according to any of claims 6 to 9, wherein said container body (10) has an opening, and said container body (10) has an upper lid (7) removably attached to the opening.

12. A container for facilitating dosed pouring according to any of claims 6-9, wherein the blocking end of the valve sleeve (3) in the reservoir (1) is formed by an opening in the valve sleeve (3) and a sealing sleeve (12) arranged in the reservoir (1).

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