CN214383472U

CN214383472U - Squeezing container

Info

Publication number: CN214383472U
Application number: CN202120276642.XU
Authority: CN
Inventors: 李红彪
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-01-30
Filing date: 2021-01-30
Publication date: 2021-10-12
Anticipated expiration: 2031-01-30

Abstract

The utility model discloses a squeeze container, which comprises a container body capable of being squeezed and deformed, wherein a liquid outlet pipe is connected on the container body, the liquid outlet pipe comprises a first pipeline and a second pipeline which is communicated with the first pipeline and is bent and circuitous relative to the first pipeline, the inlet of the first pipeline is positioned in the container body and is communicated with the inner cavity of the container body, and the outlet of the second pipeline is positioned outside the container body; when this integument of container is knocked over, can prevent the unrestrained outside of liquid of container body inner chamber, simultaneously, when liquid is got to needs, only need squeeze according to the user demand and hold between the fingers the container body and can extrude the liquid of container body inner chamber, make liquid get into first pipeline from first pipeline entry, the second pipeline, flow from the export of second pipeline at last, when loosening container body, outside gas gets into container body inner chamber and tonifying qi from the drain pipe, can repeat squeeze and hold between the fingers the container body and carry out the liquid of repeated squeeze and hold between the fingers, have the characteristics of taking convenience and ration and taking.

Description

Squeezing container

[ technical field ] A method for producing a semiconductor device

The utility model relates to a packaging container, especially a squeeze container.

[ background of the invention ]

The existing container is easy to overturn to cause liquid in the inner cavity of the container to spill to the outside in the using process, and the problems of waste and insanitation exist; therefore, the container is provided with the anti-spilling structure which can prevent liquid in the inner cavity of the container from spilling outside when the container is overturned, but the container with the anti-spilling structure has the problems of inconvenient use, complex structure and high manufacturing cost.

Therefore, the present invention has been made in view of the above problems.

[ Utility model ] content

The utility model aims at overcoming the not enough of prior art, providing a crowded container of holding between fingers, can improve the problem that prior art exists, when the vessel overturns, can prevent the unrestrained outside of liquid of vessel inner chamber, it is succinct to have a structure, safety and sanitation, convenient to use and low in manufacturing cost's characteristics.

The utility model discloses a realize through following technical scheme:

the utility model provides a squeeze container, is including the container body 1 that can squeeze deformation, be connected with drain pipe 2 on the container body 1, drain pipe 2 include first pipeline 21 and communicate with each other and the second pipeline 22 of circuitous relatively first pipeline 21 with first pipeline 21, the entry of first pipeline 21 is located container body 1 and communicates with container body 1 inner chamber, the export of second pipeline 22 is located the container body 1 outside.

The kneading vessel described above is characterized in that the first duct 21 and the second duct 22 are connected in a U-shape or a V-shape.

The kneading container as described above is characterized in that the inlet of the first duct 21 is located at the inner top end position of the container body 1, and the junction of the first duct 21 and the second duct 22 is located at the inner bottom end position of the container body 1.

A kneading container as described above, characterized in that the outlet of the second duct 22 is arranged vertically upward.

The squeeze container is characterized in that the liquid outlet pipe 2 is provided with a liquid outlet control structure 3 which can control liquid in the inner cavity of the container body 1 to directly flow out of the second pipeline 22 when the container body 1 is erected.

The squeeze container is characterized in that the liquid outlet control structure 3 comprises a valve tube 31, a liquid outlet hole 311 which connects the inner cavity of the valve tube 31 with the first pipeline 21 and the second pipeline 22 is arranged on the valve tube 31, a liquid inlet hole 312 which connects the inner cavity of the valve tube 31 with the inner cavity of the container body 1 is arranged on the valve tube 31, and a valve block 32 which can open the liquid inlet hole 312 and the liquid outlet hole 311 when the container body 1 is erected and can close the liquid inlet hole 312 and the liquid outlet hole 311 when the container body 1 is inclined is movably arranged on the valve tube 31.

The squeeze container is characterized in that the liquid outlet control structure 3 includes a valve pipe 31 communicated with the second pipeline 22, the valve pipe 31 is provided with a first valve port 313 capable of communicating an inner cavity of the valve pipe 31 with the first pipeline 21, the valve pipe 31 is further provided with a second valve port 314 communicating an inner cavity of the valve pipe 31 with an inner cavity of the container body 1, the valve pipe 31 is provided with a valve block 32 capable of plugging the first valve port 313 and opening the second valve port 314 when the container body 1 is erected, and when the container body 1 is inclined, the valve block 32 can open the first valve port 313 and plug the second valve port 314.

The squeezing and pinching container is characterized in that the liquid outlet pipe 2 is provided with a one-way liquid outlet valve 23 which can enable liquid in the inner cavity of the container body 1 to flow out of the outer side in a one-way manner.

The squeeze container is characterized in that the liquid outlet pipe 2 is provided with a liquid outlet control chamber 24, the liquid outlet control chamber 24 is provided with a third valve port 241 for communicating the first pipeline 21 with the liquid outlet control chamber 24, the liquid outlet control chamber 24 is further provided with a fourth valve port 242 for communicating the liquid outlet control chamber 24 with the second pipeline 22, and the liquid outlet control chamber 24 is movably provided with a ball 243 for plugging the fourth valve port 242 when the container body 1 is erected and plugging the third valve port 241 when the container body 1 is inclined.

Compared with the prior art, the utility model has the advantages of as follows:

1. the utility model discloses a can squeeze container body of holding between fingers deformation, the last drain pipe that is connected with of container body, the drain pipe include first pipeline and communicate with each other and the circuitous second pipeline of relative first pipeline bending with first pipeline, the entry of first pipeline is located the container originally internally and communicates with the container body inner chamber, the export of second pipeline is located the container body outside, consequently the utility model discloses when the container body is overturned, because the drain pipe includes first pipeline and the circuitous second pipeline of relative first pipeline bending with first pipeline communicating with each other, can prevent the liquid of container body inner chamber to spill the outside, have the succinct structure, safety and sanitation, low in manufacturing cost's characteristics, simultaneously, when needing to get liquid, only need according to the user's demand squeeze the container body and can extrude the liquid of container body inner chamber for liquid gets into first pipeline from first pipeline entry, The second pipeline flows out from the second pipeline export at last, and when loosening the vessel body, the external gas gets into the vessel body inner chamber and the tonifying qi from the drain pipe, can repeat crowded pinching the vessel body and carry out the crowded liquid of pinching repeatedly, has the characteristics of taking convenience and ration and taking.

2. In order to take the convenience and improve and take efficiency, be equipped with on the drain pipe and can control the liquid of container body inner chamber directly from the play liquid control structure of second pipeline outflow when the container body erects.

[ 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 cross-sectional views of a first embodiment of the present invention;

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

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

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

[ detailed description ] embodiments

The following describes embodiments of the present invention in detail with reference to fig. 1 to 7.

Example 1:

as shown in fig. 1 and 2, the utility model relates to a squeeze container, including squeeze container 1 who holds between the fingers deformation, container 1 is last to be connected with drain pipe 2, drain pipe 2 include first pipeline 21 and communicate with each other and relative first pipeline 21 second pipeline 22 circuitous of buckling with first pipeline 21, the entry of first pipeline 21 is located container 1 and communicates with each other with container 1 inner chamber, the export of second pipeline 22 is located the container 1 outside. Therefore the utility model discloses when the vessel is overturned, because the drain pipe includes first pipeline and the second pipeline that communicates with each other and the circuitous of relative first pipeline buckle with first pipeline, can prevent the unrestrained outside of liquid of vessel inner chamber, it is succinct to have a structure, safety and sanitation, low in manufacturing cost's characteristics, and simultaneously, when liquid is got to needs, only need squeeze the liquid that the vessel can extrude vessel inner chamber according to the user demand, make liquid get into first pipeline, second pipeline from first pipeline entry, flow from the export of second pipeline at last, when loosening the vessel, outside gas gets into vessel inner chamber and tonifying qi from the drain pipe, can repeat squeeze the vessel and carry out repeated squeeze and hold between the fingers and get liquid, have the characteristics of taking convenience and ration.

As shown in fig. 1 and 2, the first pipe 21 is connected with the second pipe 22 in a U-shape or a V-shape according to design requirements.

As shown in fig. 1 and 2, according to design requirements, the inlet of the first pipe 21 is located at the inner top end position of the container body 1, and the connection point of the first pipe 21 and the second pipe 22 is located at the inner bottom end position of the container body 1.

As shown in fig. 1, the outlet of the second duct 22 is disposed vertically upward for convenience of use. When the container body is vertically placed for use, the container body is squeezed to squeeze liquid in the inner cavity of the container body, so that the liquid enters the liquid outlet pipe 2 from the inlet of the first pipeline 21 and finally flows out from the outlet of the second pipeline 22.

Example 2:

example 2 differs from example 1 in that:

as shown in fig. 3 and 4, in order to facilitate taking and improve taking efficiency, the liquid outlet pipe 2 is provided with a liquid outlet control structure 3 which can control the liquid in the inner cavity of the container body 1 to directly flow out from the second pipeline 22 when the container body 1 is erected.

As shown in fig. 3 and 4, the liquid outlet control structure 3 includes a valve tube 31, a liquid outlet hole 311 that connects the inner cavity of the valve tube 31 with both the first pipeline 21 and the second pipeline 22 is disposed on the valve tube 31, a liquid inlet hole 312 that connects the inner cavity of the valve tube 31 with the inner cavity of the container body 1 is disposed on the valve tube 31, and a valve block 32 that can open the liquid inlet hole 312 and the liquid outlet hole 311 when the container body 1 is erected and can close the liquid inlet hole 312 and the liquid outlet hole 311 when the container body 1 is tilted is movably disposed on the valve tube 31. When the container body is erected, the liquid inlet hole 312 and the liquid outlet hole 311 are opened by the valve block 32 at the moment, namely, the inner cavity of the container body is communicated with the first pipeline 21 and the second pipeline 22 through the valve pipe, when liquid is required to be taken, the container body is squeezed to extrude the liquid in the inner cavity of the container body, so that the liquid directly enters the inner cavity of the valve pipe 31 from the liquid inlet hole 312, and then the liquid flows out of the outer side through the liquid outlet hole 311 and the second pipeline 22, because the first pipeline 21 is communicated with the inner cavity of the container body, the air pressure in the first pipeline 21 is the same as the air pressure in the inner cavity of the container body 1, and the liquid cannot flow to the first pipeline 21 and only flows to the second pipeline 22. When the container body is inverted, the valve block 32 seals the liquid inlet hole 312 and the liquid outlet hole 311, and when liquid needs to be taken, the container body is squeezed to squeeze liquid in the inner cavity of the container body, so that the liquid enters from the inlet of the first pipeline 21 and then flows out of the outer side from the outlet of the second pipeline 22.

As shown in fig. 3 and 4, in order to prevent the liquid in the liquid outlet pipe from flowing back to the inner cavity of the container body, a one-way liquid outlet valve 23 is arranged on the liquid outlet pipe 2, which can make the liquid in the inner cavity of the container body 1 flow out of the outer side in a one-way manner.

Example 4:

example 4 differs from example 1 in that:

as shown in fig. 5, in order to facilitate taking and improve taking efficiency, the liquid outlet pipe 2 is provided with a liquid outlet control structure 3 capable of controlling the liquid in the inner cavity of the container body 1 to directly flow out from the second pipeline 22 when the container body 1 is erected.

As shown in fig. 5, the liquid outlet control structure 3 includes a valve tube 31, a liquid outlet hole 311 is disposed on the valve tube 31, the liquid outlet hole 311 connects the inner cavity of the valve tube 31 with the first pipeline 21 and the second pipeline 22, a liquid inlet hole 312 connects the inner cavity of the valve tube 31 with the inner cavity of the container body 1 is disposed on the valve tube 31, and a valve block 32 is movably disposed on the valve tube 31, and can open the liquid inlet hole 312 and the liquid outlet hole 311 when the container body 1 is erected and can close the liquid inlet hole 312 and the liquid outlet hole 311 when the container body 1 is tilted. When the container body is erected, the liquid inlet hole 312 and the liquid outlet hole 311 are opened by the valve block 32 at the moment, namely, the inner cavity of the container body is communicated with the first pipeline 21 and the second pipeline 22 through the valve pipe, when liquid is required to be taken, the container body is squeezed to extrude the liquid in the inner cavity of the container body, so that the liquid directly enters the inner cavity of the valve pipe 31 from the liquid inlet hole 312, and then the liquid flows out of the outer side through the liquid outlet hole 311 and the second pipeline 22, because the first pipeline 21 is communicated with the inner cavity of the container body, the air pressure in the first pipeline 21 is the same as the air pressure in the inner cavity of the container body 1, and the liquid cannot flow to the first pipeline 21 and only flows to the second pipeline 22. When the container body is inverted, the valve block 32 seals the liquid inlet hole 312 and the liquid outlet hole 311, and when liquid needs to be taken, the container body is squeezed to squeeze liquid in the inner cavity of the container body, so that the liquid enters from the inlet of the first pipeline 21 and then flows out of the outer side from the outlet of the second pipeline 22.

As shown in fig. 5, a liquid outlet control chamber 24 is provided on the liquid outlet pipe 2, the liquid outlet control chamber 24 is provided with a third valve port 241 for communicating the first pipeline 21 with the liquid outlet control chamber 24, the liquid outlet control chamber 24 is further provided with a fourth valve port 242 for communicating the liquid outlet control chamber 24 with the second pipeline 22, and a ball 243 is movably provided in the liquid outlet control chamber 24, wherein the ball 243 can seal the fourth valve port 242 when the container body 1 is erected and can seal the third valve port 241 when the container body 1 is tilted. When the container body is erected and needs to take liquid, the container body is squeezed to squeeze the liquid in the inner cavity of the container body, so that the liquid directly enters the inner cavity of the valve tube 31 from the liquid inlet hole 312 and then flows out of the outer side through the liquid outlet hole 311 and the second pipeline 22, and at the moment, the ball 243 blocks the fourth valve port 242 to prevent the liquid from flowing to the first pipeline 21; when the container body is inverted and liquid taking is needed, the container body is squeezed to squeeze liquid in the inner cavity of the container body, so that the liquid flows out of the outer side through the inlet of the first pipeline 21, the liquid outlet pipe 2 and the outlet of the second pipeline 22, the ball 243 blocks the third valve opening 241 to prevent the liquid in the liquid outlet pipe 2 from flowing back to the inner cavity of the container body, and the liquid pushes against the ball 243 to open the third valve opening 241 during liquid taking.

Examples 5, 6:

examples 5 and 6 differ from example 1 in that:

as shown in fig. 6 and 7, the liquid outlet control structure 3 includes a valve pipe 31 communicated with the second pipeline 22, the valve pipe 31 is provided with a first valve port 313 capable of communicating an inner cavity of the valve pipe 31 with the first pipeline 21, the valve pipe 31 is further provided with a second valve port 314 communicating the inner cavity of the valve pipe 31 with an inner cavity of the container body 1, the valve pipe 31 is provided with a valve block 32 capable of plugging the first valve port 313 and opening the second valve port 314 when the container body 1 is erected, and when the container body 1 is inclined, the valve block 32 can open the first valve port 313 and plug the second valve port 314. When the container body is erected and needs to take liquid, the valve block 32 seals the first valve port 313 and opens the second valve port 314 at the moment, the container body is squeezed to squeeze liquid in the inner cavity of the container body, and the liquid enters the inner cavity of the valve pipe 31 from the valve port 314 and then flows out of the outlet of the second pipeline 22; when the container body is inverted and needs to take liquid, the valve block 32 opens the first valve port 313 and closes the second valve port 314, the container body is squeezed to squeeze the liquid in the inner cavity of the container body, so that the liquid enters the liquid outlet pipe from the inlet of the first pipeline 21 and then flows out of the outlet of the second pipeline 22.

Claims

1. The squeezing and pinching container is characterized by comprising a container body (1) which can be squeezed and pinched to be deformed, wherein a liquid outlet pipe (2) is connected to the container body (1), the liquid outlet pipe (2) comprises a first pipeline (21) and a second pipeline (22) which is communicated with the first pipeline (21) and bends and roundly relative to the first pipeline (21), an inlet of the first pipeline (21) is positioned in the container body (1) and is communicated with an inner cavity of the container body (1), and an outlet of the second pipeline (22) is positioned outside the container body (1).

2. A kneading vessel according to claim 1, characterised in that the first duct (21) is connected to the second duct (22) in a U-or V-shape.

3. A kneading vessel according to claim 1, characterized in that the inlet of the first duct (21) is located at the inner top end of the vessel body (1) and the junction of the first duct (21) and the second duct (22) is located at the inner bottom end of the vessel body (1).

4. A kneading vessel according to claim 1, characterised in that the outlet of the second duct (22) is arranged vertically upwards.

5. A kneading container as claimed in claim 1, characterized in that the outlet pipe (2) is provided with an outlet control structure (3) for controlling the liquid in the inner cavity of the container body (1) to flow directly from the second conduit (22) when the container body (1) is erected.

6. The squeeze container according to claim 5, wherein the liquid outlet control structure (3) comprises a valve tube (31), the valve tube (31) is provided with a liquid outlet (311) communicating both the inner cavity of the valve tube (31) with the first pipeline (21) and the second pipeline (22), the valve tube (31) is provided with a liquid inlet (312) communicating the inner cavity of the valve tube (31) with the inner cavity of the container body (1), and the valve tube (31) is movably provided with a valve block (32) capable of opening the liquid inlet (312) and the liquid outlet (311) when the container body (1) is erected and blocking the liquid inlet (312) and the liquid outlet (311) when the container body (1) is tilted.

7. The squeeze container according to claim 5, wherein the liquid outlet control structure (3) comprises a valve pipe (31) communicated with the second pipeline (22), a first valve port (313) capable of communicating the inner cavity of the valve pipe (31) with the first pipeline (21) is arranged on the valve pipe (31), a second valve port (314) capable of communicating the inner cavity of the valve pipe (31) with the inner cavity of the container body (1) is further arranged on the valve pipe (31), a valve block (32) capable of closing the first valve port (313) and opening the second valve port (314) when the container body (1) is erected is arranged on the valve pipe (31), and when the container body (1) is inclined, the valve block (32) is capable of opening the first valve port (313) and closing the second valve port (314).

8. A kneading container as claimed in claim 6 or 7, characterized in that the tapping pipe (2) is provided with a one-way tapping valve (23) which enables the liquid in the interior of the container body (1) to flow out of the outside in a one-way manner.

9. A squeeze container according to claim 6 or 7, characterized in that the outlet pipe (2) is provided with a liquid outlet control chamber (24), the liquid outlet control chamber (24) is formed with a third valve port (241) for communicating the first pipe (21) with the liquid outlet control chamber (24), the liquid outlet control chamber (24) is further formed with a fourth valve port (242) for communicating the liquid outlet control chamber (24) with the second pipe (22), and the liquid outlet control chamber (24) is movably provided with a ball (243) for sealing the fourth valve port (242) when the container body (1) is erected and for sealing the third valve port (241) when the container body (1) is tilted.