CN212075074U - Quantitative pouring container - Google Patents

Abstract

The utility model discloses a quantitative pouring container, which controls the opening or closing of a liquid inlet control structure by acting on a valve sleeve to ensure that a liquid storage cavity is communicated with or isolated from a quantitative cavity; when the liquid storage cavity is communicated with the quantitative cavity, the liquid in the liquid storage cavity flows into the quantitative cavity, and when the required dosage is reached, the liquid inlet control structure is controlled to be closed by the action valve sleeve, so that the liquid storage cavity and the quantitative cavity are isolated from each other, and the liquid in the quantitative cavity flows out from the liquid pouring port; the liquid storage cavity is arranged in the quantitative cavity, or the quantitative cavity is arranged in the liquid storage cavity; therefore, the utility model has the characteristics of reasonable in design, the structure is succinct, the use is convenient and the occupation space is little, still has the function that the ration was got to others simultaneously.

Description

Quantitative pouring container

[ technical field ] A method for producing a semiconductor device

The utility model relates to a packaging container, especially a can quantitative pouring container.

[ 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. The existing quantitative pouring container bottle has the defects of high manufacturing cost due to complex structure and inconvenience for people due to complex quantitative pouring operation; and the prior container bottles have various fittings, which cause the defects of large placing space, large occupied space and the like.

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 quantitative pouring container, which controls the opening or closing of a liquid inlet control structure by acting on a valve sleeve, so that a liquid storage cavity is communicated or isolated with a quantitative cavity; when the liquid storage cavity is communicated with the quantitative cavity, the liquid in the liquid storage cavity flows into the quantitative cavity, and when the required dosage is reached, the liquid inlet control structure is controlled to be closed by the action valve sleeve, so that the liquid storage cavity and the quantitative cavity are isolated from each other, and the liquid in the quantitative cavity flows out from the liquid pouring port; the liquid storage cavity is arranged in the quantitative cavity, or the quantitative cavity is arranged in the liquid storage cavity; therefore, the quantitative pouring device has the characteristics of reasonable design, simple structure, convenience in use and small occupied space, and simultaneously has the function of quantitative pouring.

In order to solve the technical problem, the utility model provides a can quantitative pouring container, including open-ended vessel 100, vessel 100 inner chamber is formed with quantitative chamber 1, be equipped with the mouth of falling liquid 11 on vessel 100's quantitative chamber 1, be connected with valve sleeve 200 in vessel 100 movablely, valve sleeve 200 inner chamber is formed with stock solution chamber 2, be equipped with between stock solution chamber 2 and the quantitative chamber 1 and make stock solution chamber 2 and quantitative chamber 1 intercommunication or isolated inlet control structure 3 when valve sleeve 200 moves about.

The quantitative pouring container is characterized in that the liquid inlet control structure 3 comprises a valve liquid inlet 31 arranged at the lower end of the valve sleeve 200 and an inner bottom wall of the quantitative cavity 1, and when the valve sleeve 200 moves upwards relative to the quantitative cavity 1, the valve liquid inlet 31 can be separated from the inner bottom wall of the quantitative cavity 1, so that the liquid in the liquid storage cavity 2 flows into the quantitative cavity 1.

The quantitative pouring container is characterized in that the liquid inlet control structure 3 comprises a valve liquid inlet 31 arranged at the lower end of the valve sleeve 200 and a groove 32 arranged at the bottom wall of the quantitative cavity 1, and when the valve sleeve 200 moves upwards relative to the quantitative cavity 1, the valve liquid inlet 31 can be separated from the groove 32 of the quantitative cavity 1, so that the liquid in the liquid storage cavity 2 flows into the quantitative cavity 1.

The quantitative pouring container is characterized in that the inner bottom wall of the quantitative cavity 1 extends upwards to form a sealing sleeve 12 for the lower part of the valve sleeve 200 to be inserted; the liquid inlet control structure 3 comprises a dynamic liquid inlet 33 arranged on the valve sleeve 200 and a static liquid inlet 34 arranged on the sealing sleeve 12, and when the valve sleeve 200 rotates or moves up and down relative to the sealing sleeve 12, the dynamic liquid inlet 33 and the static liquid inlet 34 can be aligned and communicated, so that the liquid in the liquid storage cavity 2 flows into the quantitative cavity 1.

The quantitative pouring container is characterized in that the quantitative cavity 1 is provided with a mark scale 101.

The container capable of pouring quantitatively is characterized in that the valve sleeve 200 is provided with a one-way air supplement valve 201 for controlling the liquid storage cavity 2 to be communicated or isolated from the outside, and initially, the one-way air supplement valve 201 is closed, so that the liquid storage cavity 2 is isolated and sealed from the outside; when the liquid inlet control structure 3 is opened, the one-way air supplement valve 201 can be opened, so that the liquid storage cavity 2 is communicated with the outside.

A quantitatively dispensing container as described above, characterized in that a valve sleeve sealing ring 202 is provided between the valve sleeve 200 and the recess 32, or a valve sleeve sealing ring 202 is provided between the valve sleeve 200 and the sealing sleeve 12.

The utility model provides a container can quantitative pouring, including open-ended vessel 100, vessel 100 inner chamber is formed with stock solution chamber 2, be connected with valve sleeve 200 movably in vessel 100, valve sleeve 200 inner chamber is formed with ration chamber 1, valve sleeve 200's ration chamber 1 is equipped with the mouth of draining 11, be equipped with between stock solution chamber 2 and the ration chamber 1 and make stock solution chamber 2 and ration chamber 1 intercommunication or isolated feed liquor control structure 3 when valve sleeve 200 moves about.

The container capable of pouring quantitatively is characterized in that a sealing hole sleeve 21 for inserting the valve sleeve 200 is formed at the inner bottom of the liquid storage cavity 2; the liquid inlet control structure 3 comprises a valve liquid inlet A35 arranged on the valve sleeve 200 and a liquid inlet groove 36 arranged on the sealing hole sleeve 21 and communicated with the liquid storage cavity 2, and when the valve sleeve 200 rotates or moves up and down relative to the sealing hole sleeve 21, the valve liquid inlet A35 can be aligned and communicated with the liquid inlet groove 36, so that the liquid in the liquid storage cavity 2 flows into the quantitative cavity 1.

The quantitative pouring container is characterized in that the liquid inlet control structure 3 comprises a valve liquid inlet B37 arranged at the lower end of the valve sleeve 200 and the inner bottom wall of the liquid storage cavity 2, and when the valve sleeve 200 moves upwards relative to the liquid storage cavity 2, the valve liquid inlet B37 can be separated from the inner bottom wall of the liquid storage cavity 2, so that the liquid in the liquid storage cavity 2 flows into the quantitative cavity 1.

The quantitative pouring container is characterized in that the opening of the container body 100 is connected with a base 300, the base 300 is provided with a base connecting hole sleeve 310 for the upper part of the valve sleeve 200 to penetrate through, the base 300 is connected with an upper cover 320 for covering the liquid pouring port 11, or the valve sleeve 200 is connected with an upper cover 320 for covering the liquid pouring port 11.

The quantitative pouring container is characterized in that a linkage structure 400 is arranged between the base connecting hole sleeve 310 and the upper part of the valve sleeve 200, so that the valve sleeve 200 is driven to correspondingly rotate or move up and down when the base 300 rotates, and the liquid inlet control structure 3 is used for communicating or isolating the liquid storage cavity 2 with or from the quantitative cavity 1.

The container capable of quantitative pouring is characterized in that an air inlet control structure 500 is arranged between the base connecting hole sleeve 310 and the valve sleeve 200, the liquid inlet control structure 3 is a valve liquid inlet C38 arranged on the valve sleeve 200 and communicated with the liquid storage cavity 2, and the liquid in the liquid storage cavity 2 can flow into the quantitative cavity 1 when the air inlet control structure 500 is used for opening.

The quantitative pouring container as described above, wherein the air inlet control structure 500 comprises the dynamic air inlet 510 provided on the valve sleeve 200 and the static air inlet 520 provided on the base connection hole sleeve 310, when the valve sleeve 200 is rotated or moved up and down with respect to the base connection hole sleeve 310, the dynamic air inlet 510 and the static air inlet 520 are aligned and communicated, so that the liquid in the reservoir 2 flows into the quantitative chamber 1.

A container for metered dispensing as described above, wherein the valve sleeve 200 is provided with a breakable seal 600 below the motive air inlet 510.

A container for quantitatively pouring as described above, wherein a valve sleeve sealing ring 203 is provided between the valve sleeve 200 and the sealing grommet 21.

Compared with the prior art, the utility model relates to a can quantitative pouring container has following advantage:

1. the utility model controls the liquid inlet control structure to open or close by acting on the valve sleeve, so that the liquid storage cavity is communicated or isolated with the quantitative cavity; when the liquid storage cavity is communicated with the quantitative cavity, the liquid in the liquid storage cavity flows into the quantitative cavity, and when the required dosage is reached, the liquid inlet control structure is controlled to be closed by the action valve sleeve, so that the liquid storage cavity and the quantitative cavity are isolated from each other, and the liquid in the quantitative cavity flows out from the liquid pouring port; the liquid storage cavity is arranged in the quantitative cavity, or the quantitative cavity is arranged in the liquid storage cavity; therefore, the quantitative pouring device has the characteristics of reasonable design, simple structure, convenience in use and small occupied space, and simultaneously has the function of quantitative pouring.

2. The quantitative cavity is provided with scale marks, which is beneficial to the quantitative use of people.

3. In order to reduce the placing space of the container accessories and improve the overall attractiveness, the use of a user is convenient, the liquid storage cavity is movably arranged in the quantitative cavity, or the quantitative cavity is movably arranged in the liquid storage cavity.

[ 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 a perspective view of a first embodiment of the present invention.

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

Fig. 3 is a second cross-sectional view of the first embodiment of the present invention.

Fig. 4 is a cross-sectional view of a second embodiment of the present invention.

Fig. 5 is a cross-sectional view of a third embodiment of the present invention.

Fig. 6 is a cross-sectional view of a fourth embodiment of the present invention.

Fig. 7 is a second cross-sectional view of a fourth embodiment of the present invention.

Fig. 8 is a cross-sectional view of a fifth embodiment of the present invention.

Fig. 9 is a sectional view of a sixth embodiment of the present invention.

Fig. 10 is a sectional view of a seventh embodiment of the present invention.

Fig. 11 is a second cross-sectional view of a seventh embodiment of the present invention.

Fig. 12 is a sectional view of an eighth embodiment of the present invention.

Fig. 13 is a second cross-sectional view of the eighth embodiment of the present invention.

Fig. 14 is a cross-sectional view of a ninth embodiment of the present invention.

Fig. 15 is a second cross-sectional view of the ninth embodiment of the present invention.

Fig. 16 is a cross-sectional view of a tenth embodiment of the present invention.

Fig. 17 is a second cross-sectional view of the tenth embodiment of the present invention.

Fig. 18 is a sectional view of an eleventh embodiment of the present invention.

Fig. 19 is a cross-sectional view of a twelfth embodiment of the present invention.

Fig. 20 is a second cross-sectional view of the twelfth embodiment of the present invention.

Fig. 21 is a sectional view of a thirteenth embodiment of the present invention.

Fig. 22 is a cross-sectional view of a fourteenth embodiment of the present invention.

Fig. 23 is a second cross-sectional view of the fourteenth embodiment of the present invention.

[ detailed description ] embodiments

Embodiments of the invention will be described in detail below with reference to figures 1-23.

As shown in fig. 1-9, the utility model relates to a can quantitative pouring container, including open-ended vessel 100, vessel 100 inner chamber is formed with ration chamber 1, be equipped with the mouth of falling liquid 11 on vessel 100's ration chamber 1, be connected with valve sleeve 200 in vessel 100 movablely, valve sleeve 200 inner chamber is formed with stock solution chamber 2, be equipped with between stock solution chamber 2 and the ration chamber 1 and make stock solution chamber 2 and ration chamber 1 intercommunication or isolated feed liquor control structure 3 when valve sleeve 200 moves about. When the quantitative liquid storage device is used, a user acts on the valve sleeve to move relative to the quantitative cavity, the liquid inlet control structure can be opened, liquid in the liquid storage cavity flows into the quantitative cavity, when the required dosage is reached, the liquid inlet control structure can be closed by continuously acting on the valve sleeve, the liquid storage cavity and the quantitative cavity are isolated from each other, and then the liquid in the quantitative cavity flows out from the liquid pouring port; therefore, the quantitative pouring device has the characteristics of reasonable design, simple structure, convenience in use and small occupied space, and simultaneously has the function of quantitative pouring.

As shown in fig. 2, 3, 8 and 9, according to the design requirement and the provision of multiple liquid inlet control structure manners, the liquid inlet control structure 3 includes a valve liquid inlet 31 disposed at the lower end of the valve sleeve 200 and an inner bottom wall of the quantitative cavity 1, and when the valve sleeve 200 moves upward relative to the quantitative cavity 1, the valve liquid inlet 31 can be separated from the inner bottom wall of the quantitative cavity 1, so that the liquid in the liquid storage cavity 2 flows into the quantitative cavity 1.

As shown in fig. 1, 2 and 3, in order to facilitate the user to actuate the valve sleeve, a handle portion 210 for actuating the valve sleeve 200 is connected to the valve sleeve 200. The handle part can be a pull ring or a pull plate.

Alternatively, the handle portion 210 may be formed by exposing the upper portion of the valve sleeve 200 to the opening of the container body 100.

As shown in fig. 4 and 5, according to the design requirement and the multiple liquid inlet control structure provided, the liquid inlet control structure 3 includes a valve liquid inlet 31 disposed at the lower end of the valve sleeve 200 and a groove 32 disposed at the inner bottom wall of the quantitative cavity 1, when the valve sleeve 200 moves upward relative to the quantitative cavity 1, the valve liquid inlet 31 can be separated from the groove 32 of the quantitative cavity 1, so that the liquid in the liquid storage cavity 2 flows into the quantitative cavity 1.

The embodiment of fig. 4 differs from the embodiment of fig. 5 in that: in FIG. 4, the valve sleeve and the container body are connected by sleeving and clamping; in fig. 5, the valve sleeve is connected with the container body through threads.

As shown in fig. 6 and 7, according to design requirements and various liquid inlet control structural modes, the inner bottom wall of the quantitative cavity 1 extends upwards to form a sealing sleeve 12 for the lower part of the valve sleeve 200 to be inserted; the liquid inlet control structure 3 comprises a dynamic liquid inlet 33 arranged on the valve sleeve 200 and a static liquid inlet 34 arranged on the sealing sleeve 12, and when the valve sleeve 200 rotates or moves up and down relative to the sealing sleeve 12, the dynamic liquid inlet 33 and the static liquid inlet 34 can be aligned and communicated, so that the liquid in the liquid storage cavity 2 flows into the quantitative cavity 1.

As shown in FIG. 1, in order to facilitate quantitative pouring, the quantitative cavity 1 is provided with a mark scale 101.

As shown in fig. 8 and 9, in order to facilitate the liquid in the liquid storage cavity to flow into the quantitative cavity, a one-way air supplement valve 201 for controlling the liquid storage cavity 2 to be communicated or isolated from the outside is disposed on the valve sleeve 200, initially, the one-way air supplement valve 201 is closed, so that the liquid storage cavity 2 is isolated and sealed from the outside, the sealing performance of the liquid storage cavity is ensured, and the service life of the liquid filled in the liquid storage cavity is prolonged; when the liquid inlet control structure 3 is opened, the one-way air supplement valve 201 can be opened, so that the liquid storage cavity 2 is communicated with the outside, namely, the one-way air supplement valve, the liquid storage cavity, the liquid inlet control structure, the quantitative cavity and the liquid pouring port form a ventilation passageway.

The embodiment of fig. 8 differs from the embodiment of fig. 9 in that: in fig. 8, the valve sleeve is connected with the container body through threads; in fig. 9, the valve sleeve is connected with the container body through a snap fit.

As shown in fig. 4-7, in order to further improve the sealing connection between the valve sleeve and the groove/seal sleeve, and simultaneously prevent the valve sleeve from directly contacting and rubbing against the groove/seal sleeve, so as to improve the service life of the valve sleeve and the groove/seal sleeve, a valve sleeve sealing ring 202 is provided between the valve sleeve 200 and the groove 32, or a valve sleeve sealing ring 202 is provided between the valve sleeve 200 and the seal sleeve 12.

As shown in fig. 1-9, to facilitate pouring of the liquid in the quantitative cavity and improve the overall aesthetic appearance; and in the pouring process, the liquid is prevented from scattering out, and the liquid pouring port 11 is in a horn mouth shape.

As shown in fig. 10-23, the utility model relates to a container can quantitative pouring, including open-ended vessel 100, vessel 100 inner chamber is formed with stock solution chamber 2, be connected with valve sleeve 200 in vessel 100 movablely, valve sleeve 200 inner chamber is formed with ration chamber 1, valve sleeve 200's ration chamber 1 is equipped with the mouth of draining 11, be equipped with between stock solution chamber 2 and the ration chamber 1 and make stock solution chamber 2 and ration chamber 1 intercommunication or isolated feed liquor control structure 3 when valve sleeve 200 moves about. When the quantitative liquid storage device is used, a user acts on the valve sleeve to move relative to the liquid storage cavity, the liquid inlet control structure can be opened, liquid in the liquid storage cavity flows into the quantitative cavity, when the required dosage is reached, the liquid inlet control structure can be closed by continuously acting on the valve sleeve, the liquid storage cavity and the quantitative cavity are isolated from each other, and then the liquid in the quantitative cavity flows out from the liquid pouring port; therefore, the quantitative pouring device has the characteristics of reasonable design, simple structure, convenience in use and small occupied space, and simultaneously has the function of quantitative pouring.

As shown in fig. 10-15, according to design requirements and various liquid inlet control structural modes, a sealing hole sleeve 21 for inserting the valve sleeve 200 is formed at the inner bottom of the liquid storage cavity 2; the liquid inlet control structure 3 comprises a valve liquid inlet A35 arranged on the valve sleeve 200 and a liquid inlet groove 36 arranged on the sealing hole sleeve 21 and communicated with the liquid storage cavity 2, and when the valve sleeve 200 rotates or moves up and down relative to the sealing hole sleeve 21, the valve liquid inlet A35 can be aligned and communicated with the liquid inlet groove 36, so that the liquid in the liquid storage cavity 2 flows into the quantitative cavity 1.

As shown in fig. 16-18, according to the design requirement and the provision of various liquid inlet control structures, the liquid inlet control structure 3 includes a valve liquid inlet B37 disposed at the lower end of the valve sleeve 200 and the inner bottom wall of the liquid storage cavity 2, and when the valve sleeve 200 moves upward relative to the liquid storage cavity 2, the valve liquid inlet B37 can be disengaged from the inner bottom wall of the liquid storage cavity 2, so that the liquid in the liquid storage cavity 2 flows into the quantitative cavity 1.

As shown in fig. 12 to 23, in order to stably and movably connect the valve sleeve, a base 300 is connected to the opening of the container body 100, a base connection hole sleeve 310 through which the upper portion of the valve sleeve 200 passes is disposed on the base 300, an upper cover 320 for covering the liquid pouring port 11 is connected to the base 300, or the valve sleeve 200 is connected to the upper cover 320 for covering the liquid pouring port 11.

As shown in fig. 12-18, in order to provide various connection modes and prevent the upper cover from being lost and falling off, a connection member for connecting the upper cover 320 with the base 300 in a turnover manner is not shown between the upper cover 320 and the base 300, and therefore, the upper cover has the characteristics of cleanness and sanitation.

In order to provide a plurality of connection modes and according to design requirements, the upper cover 320 and the valve sleeve 200 are connected through threads as shown in fig. 19 to 23 or are buckled or clamped.

As shown in fig. 12-21, the base 300 is snap-fitted or fastened to the opening of the container body 100 according to design requirements.

As shown in fig. 22 and 23, the base 300 is screwed with the opening of the container body 100 according to design requirements.

As shown in fig. 10 and 11, an opening sealing ring 220 is provided between the valve sleeve 200 and the opening of the container body 100 to improve the sealing performance.

As shown in fig. 10 and 11, the pouring port 11 is in a bell mouth shape to facilitate pouring of the substance in the quantitative cavity and to improve the overall appearance, and to prevent the liquid from scattering out during pouring.

As shown in fig. 12-23, a base sealing ring 330 is disposed between the base 300 and the opening of the container body 100 for improving the sealing performance.

As shown in fig. 12 to 17, in order to facilitate the use of the liquid storage device, a linkage structure 400 is provided between the base connection hole sleeve 310 and the upper portion of the valve sleeve 200, so that the base 300 rotates to drive the valve sleeve 200 to correspondingly rotate or move up and down, and acts on the liquid inlet control structure 3 to connect or isolate the liquid storage cavity 2 with or from the dosing cavity 1.

The linkage structure is a rotation stopping edge surface which is arranged on the base connecting hole sleeve and is matched and connected with the upper part of the valve sleeve as shown in figures 12-15, so that when the base is rotated, the linkage structure can be linked with the valve sleeve to rotate, and further the liquid inlet control structure can communicate or isolate the liquid storage cavity and the quantitative cavity.

The linkage structure is a thread which is arranged on the base connecting hole sleeve and is matched and connected with the upper part of the valve sleeve as shown in figures 16 and 17, so that when the base is rotated, the linkage structure can be linked with the valve sleeve to move up and down, and further the liquid inlet control structure can communicate or isolate the liquid storage cavity and the quantitative cavity.

As shown in fig. 19 to 21, an air inlet control structure 500 is disposed between the base connection hole sleeve 310 and the valve sleeve 200, the liquid inlet control structure 3 is a valve liquid inlet C38 disposed on the valve sleeve 200 and communicated with the liquid storage cavity 2, and is opened by the air inlet control structure 500, so that the liquid in the liquid storage cavity 2 flows into the quantitative cavity 1. When using, the user acts on the relative base connecting hole cover of valve sleeve pipe and rotates or up-and-down motion, can make the control structure that admits air open, and make the liquid inflow ration intracavity in stock solution chamber, when reaching required quantity, continue to act on the relative base connecting hole cover of valve sleeve pipe and rotate or up-and-down motion, can make the feed liquor control structure close, and make the liquid in stock solution chamber stop to flow into the ration intracavity, later flow from the mouth of falling the liquid.

Further, the air inlet control structure 500 includes a dynamic air inlet 510 disposed on the valve sleeve 200 and a static air inlet 520 disposed on the base connection hole sleeve 310, when the valve sleeve 200 rotates or moves up and down relative to the base connection hole sleeve 310, the dynamic air inlet 510 and the static air inlet 520 can be aligned and communicated, so that the liquid in the reservoir 2 flows into the quantitative cavity 1.

As shown in fig. 21, in order to improve the sealing performance, a sealing member 600 is disposed in the valve sleeve 200 and under the motive gas inlet 510 in a breaking manner.

To facilitate the breaking of the seal by the user, the seal 600 is provided with a seal pulling member, not shown, for pulling by the user.

As shown in fig. 10 to 15, in order to further improve the sealing connection between the valve sleeve and the sealing hole sleeve, and simultaneously prevent the valve sleeve and the sealing hole sleeve from directly contacting and rubbing, so as to improve the service life of the valve sleeve and the sealing hole sleeve, a valve sleeve sealing ring 203 is arranged between the valve sleeve 200 and the sealing hole sleeve 21.

The utility model discloses when the application is in the wine set trade, the beverage bottle can be regarded as to wine glass and stock solution chamber in ration chamber, and its both unite two into one design, can significantly reduce on the dining table wine bottle, divide the space of putting of wines such as drinking vessel, wineglass, have convenient to use simultaneously, can be as required or the arbitrary ration of hobby to what of wine volume in the wineglass is switched wantonly, no matter to the user still accomodate person or the purger has all brought very big convenience.

In addition, the utility model discloses can also be used to a lot of other trades, for example the pharmaceutical industry, get it filled and take medicine also can be accurate and convenient.

Claims (16)

1. The utility model provides a can quantitative pouring container, its characterized in that includes open-ended vessel (100), vessel (100) inner chamber is formed with quantitative chamber (1), be equipped with on quantitative chamber (1) of vessel (100) and fall liquid mouth (11), vessel (100) internalization is connected with valve sleeve pipe (200), valve sleeve pipe (200) inner chamber is formed with stock solution chamber (2), be equipped with between stock solution chamber (2) and quantitative chamber (1) and can make stock solution chamber (2) and quantitative chamber (1) intercommunication or isolated feed liquor control structure (3) when valve sleeve pipe (200) activity.

2. A container according to claim 1, wherein the liquid inlet control structure (3) comprises a valve inlet (31) provided at a lower end of the valve sleeve (200) and an inner bottom wall of the dosing chamber (1), and when the valve sleeve (200) is moved upward relative to the dosing chamber (1), the valve inlet (31) is disengaged from the inner bottom wall of the dosing chamber (1) to allow the liquid in the reservoir chamber (2) to flow into the dosing chamber (1).

3. A container according to claim 1, wherein the inlet control structure (3) comprises a valve inlet (31) at the lower end of the valve sleeve (200) and a recess (32) at the inner bottom wall of the dosing chamber (1), wherein when the valve sleeve (200) is moved upward relative to the dosing chamber (1), the valve inlet (31) is disengaged from the recess (32) of the dosing chamber (1) to allow the liquid in the reservoir chamber (2) to flow into the dosing chamber (1).

4. A quantitatively dispensing container according to claim 1, wherein the inner bottom wall of the quantitative cavity (1) is upwardly extended to form a sealing sleeve (12) for inserting the lower portion of the valve sleeve (200); the liquid inlet control structure (3) comprises a dynamic liquid inlet (33) arranged on the valve sleeve (200) and a static liquid inlet (34) arranged on the sealing sleeve (12), and when the valve sleeve (200) rotates or moves up and down relative to the sealing sleeve (12), the dynamic liquid inlet (33) and the static liquid inlet (34) can be aligned and communicated, so that liquid in the liquid storage cavity (2) flows into the quantitative cavity (1).

5. A quantitatively pourable container according to any of claims 1 to 4, characterised in that the quantitative cavity (1) is provided with a marked scale (101).

6. A container capable of pouring in a quantitative manner according to claim 5, wherein the valve sleeve (200) is provided with a one-way air supply valve (201) for controlling the liquid storage cavity (2) to be communicated with or isolated from the outside, and initially, the one-way air supply valve (201) is closed, so that the liquid storage cavity (2) is sealed from the outside; when the liquid inlet control structure (3) is opened, the one-way air supplement valve (201) can be opened, so that the liquid storage cavity (2) is communicated with the outside.

7. A dosed pouring vessel according to claim 3 or 4, wherein a valve sleeve sealing ring (202) is arranged between the valve sleeve (200) and the recess (32), or a valve sleeve sealing ring (202) is arranged between the valve sleeve (200) and the sealing sleeve (12).

8. The utility model provides a can quantitative pouring container, its characterized in that includes open-ended vessel (100), vessel (100) inner chamber is formed with stock solution chamber (2), vessel (100) internalization is connected with valve sleeve pipe (200), valve sleeve pipe (200) inner chamber is formed with ration chamber (1), ration chamber (1) of valve sleeve pipe (200) are equipped with down liquid mouth (11), be equipped with between stock solution chamber (2) and ration chamber (1) and can make stock solution chamber (2) and ration chamber (1) intercommunication or isolated feed liquor control structure (3) when valve sleeve pipe (200) activity.

9. A container as claimed in claim 8, wherein the inner bottom of the reservoir (2) is formed with a sealing hole (21) for the valve sleeve (200) to be inserted; the liquid inlet control structure (3) comprises a valve liquid inlet A (35) arranged on the valve sleeve (200) and a liquid inlet groove (36) arranged on the sealing hole sleeve (21) and communicated with the liquid storage cavity (2), and when the valve sleeve (200) rotates relative to the sealing hole sleeve (21) or moves up and down, the liquid inlet control structure can enable the valve liquid inlet A (35) to be communicated with the liquid inlet groove (36) in an aligning way, so that liquid in the liquid storage cavity (2) flows into the quantitative cavity (1).

10. A container according to claim 8, wherein the inlet control structure (3) comprises a valve inlet B (37) at the lower end of the valve sleeve (200) and an inner bottom wall of the reservoir (2), and when the valve sleeve (200) is moved upward relative to the reservoir (2), the valve inlet B (37) is disengaged from the inner bottom wall of the reservoir (2) to allow the liquid in the reservoir (2) to flow into the dosing chamber (1).

11. The quantitative pouring container according to claim 8, 9 or 10, wherein the container body (100) is connected with a base (300) through an opening, the base (300) is provided with a base connecting hole sleeve (310) for the upper part of the valve sleeve (200) to penetrate through, the base (300) is connected with an upper cover (320) for covering the pouring port (11), or the valve sleeve (200) is connected with an upper cover (320) for covering the pouring port (11).

12. A container according to claim 11, wherein a linkage structure (400) is provided between the base connecting hole sleeve (310) and the upper portion of the valve sleeve (200) to allow the valve sleeve (200) to be correspondingly rotated or moved up and down when the base (300) is rotated, and the liquid inlet control structure (3) is operated to communicate or isolate the liquid storage chamber (2) with the dosing chamber (1).

13. A container according to claim 11, wherein an air inlet control structure (500) is disposed between the base connecting hole sleeve (310) and the valve sleeve (200), and the liquid inlet control structure (3) is a valve liquid inlet C (38) disposed on the valve sleeve (200) and communicated with the liquid storage chamber (2), and is opened as the air inlet control structure (500) to allow the liquid in the liquid storage chamber (2) to flow into the quantitative chamber (1).

14. A container according to claim 13, wherein said air inlet control structure (500) comprises a movable air inlet (510) provided in said valve sleeve (200) and a static air inlet (520) provided in said base connection boss (310), said movable air inlet (510) and said static air inlet (520) being in aligned communication when said valve sleeve (200) is rotated or moved up and down relative to said base connection boss (310) to allow the liquid in said reservoir (2) to flow into said dosing chamber (1).

15. A container according to claim 14, wherein the valve sleeve (200) is provided with a breakable seal (600) within the valve sleeve and below the motive air inlet (510).

16. A container according to claim 9, wherein a valve sleeve gasket (203) is provided between the valve sleeve (200) and the sealing grommet (21).

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