CN111674687A - Quantitative container and quantitative fetching method - Google Patents

Abstract

The invention discloses a quantitative container and a quantitative fetching method, the quantitative cavity is provided with a cavity, the top or the side part of the cavity or the connection part of the top and the side part is provided with an inlet and an outlet, at least a separating part which is connected with the inner wall of the cavity except the tail end extends from the inner wall of the cavity or the inner wall at the inlet and the outlet to the interior of the cavity, at least one part of the separating part is bent or curved to form a bending part by a broken line towards the upper part of the cavity, the bending part forms a quantitative cavity alone or together with the cavity wall of the cavity, or the separating part is at least provided with a groove facing the top of the containing cavity, the groove forms a quantitative containing cavity, an upright containing cavity communicated with the quantitative containing cavity is arranged below or at the lower part of the separating part, a canyon between the tail end of the separating part and the side wall of the containing cavity forms a passage opening of the upright containing cavity and the quantitative containing cavity, and the central axis of the inlet and the central axis of the passage opening are not overlapped. This application makes the quantitative thing of pouring volume get in the container and pours out for liquid does not receive external pollution.

Description

Quantitative container and quantitative fetching method

Technical Field

The invention relates to a quantitative container and a method for quantitatively acquiring a carrier.

Background

In the fields of medicine, chemical industry, daily chemical products, kitchen supplies and the like, liquid products, granular products and powder products have great demands on quantitative pouring of containers, such as liquid of medical medicaments, chemical medicaments, edible oil and the like. At present, the conventional method is to pour by using auxiliary tools such as beakers and measuring cups, but the pouring mode needs additional auxiliary tools, the cost is high, the auxiliary tools are not suitable for cleaning, a quantitative container with a built-in device is also provided, the general structure is complex, the cost is high, the popularization and the use cannot be realized, and if particles are involved, the quantity is large, the time is wasted, and the sanitation is not realized.

Disclosure of Invention

Based on the defects of the prior art, the invention provides a quantitative container and a quantitative fetching method for the quantitative container, solves the problem that the container can independently and quantitatively obtain a loading object, avoids the pollution outside the container when the quantitative loading object is obtained, and solves the problems that the loading object in the container cannot be salvaged and reused when the quantity of the loading object is obtained, and the manufacturing cost is high due to the complex structure of a quantitative container product.

The technical scheme of the invention is as follows:

a quantitative container is characterized by comprising: the container comprises a container, an inlet and an outlet which can allow loading and unloading are arranged at the top or the side of the container or the connection part of the top and the side, a container cover is arranged at the inlet and the outlet, a separating part which is connected with the inner wall of the container except the tail end and at the rest part extends from the inner wall of the container or the inner wall at the inlet and the outlet to the interior of the container, at least one part of the separating part is bent or curved towards the upper part of the containing cavity in a fold line to form a bent part, the bent part alone or together with the cavity wall of the containing cavity forms a certain amount of containing cavity, or the separating part is at least provided with a groove facing the top of the containing cavity, the groove forms a quantitative containing cavity, an upright containing cavity communicated with the quantitative containing cavity is arranged below or at the lower part of the separating part, the strait between the tail end of the partition part and the side wall of the cavity forms a passage opening of the upright cavity and the quantitative cavity, and in addition, the central axis of the inlet and the central axis of the outlet are not overlapped with the central axis of the passage opening.

Further, the passage opening is not smaller than the diameter of a single or unit load.

Further, the separating part is formed by bending or curve bending a single-layer separating plate, or formed by pressing or assembling at intervals, bending or bending more than two layers of separating plates, or formed by blocks.

Further, the inlet and the outlet are located on a side edge of the top of the cavity, which is opposite to the side far away from the channel port, or on a side wall of the cavity, which is above the partition part and far away from the channel port.

Further, the container cover is mounted on the access in a state of surrounding the access, and the loading object can be prevented from entering and exiting the cavity after the container cover is covered.

Further, the volume of the upright cavity is not less than the volume of the quantitative cavity.

Further, when the loaded object in the quantitative accommodating cavity tilts and is poured out from the inlet and the outlet, the partition part and the peripheral walls of the bottom and the side parts of the accommodating cavity form a blocking and accommodating cavity, the partition part extends from the initial position to the inside of the accommodating cavity, or the partition part is arranged at the initial position of the accommodating cavity, or the shape of the partition part at least can ensure that the loaded object in the blocking and accommodating cavity can be completely blocked to transit from the passage port to the quantitative accommodating cavity when the loaded object is completely poured out from the quantitative accommodating cavity.

Furthermore, the partition portion includes a resistance portion which is arranged below or at the lower portion of the partition portion and extends towards the bottom of the upright cavity in a protruding manner, the resistance portion separates the upright cavity into a resistance cavity and a loading channel 100 which are communicated with each other, the resistance cavity is used for blocking loading of the resistance cavity when the upright cavity tilts and transferring the loading from the loading channel 100 to the quantitative cavity, and the resistance cavity blocks loading of the loading channel and transferring the loading to the quantitative cavity when the quantitative cavity is completely poured with the loading.

Further, the volume of the blocking volume is not less than the volume of the dosing volume.

Furthermore, the cavity and the partition part inside the cavity are partially or completely made of hard transparent materials.

Furthermore, the cavity and the partition part inside the cavity are partially or completely made of glass or hard plastics.

The method for taking the quantitative material from the quantitative container is characterized by comprising the following steps of,

step 1: when the quantitative loading device is in an initial state, wherein the initial state is a vertical state of the containing cavity, the quantitative containing cavity does not contain the loading object, the loading object is stored in the vertical containing cavity, the containing cavity in the vertical position is tilted, or shaken or whipped, so that the loading object in the vertical containing cavity partially or completely enters the quantitative containing cavity through the channel port, if the residual part exists, the residual part falls back to the vertical containing cavity, and the quantitative loading object is reserved in the quantitative containing cavity;

and 2, after the object is loaded into the quantitative cavity, tilting the cavity, and only pouring the object loaded in the quantitative cavity out from the inlet and outlet.

And 3, returning the cavity to the initial state.

Furthermore, in step 2, after the object loading enters the quantitative accommodating cavity, the accommodating cavity is tilted, the object loading in the quantitative accommodating cavity is poured out from the inlet and the outlet, and the object loading in the quantitative accommodating cavity is kept blocked by the blocking cavity formed by the partition part, the bottom of the accommodating cavity and the peripheral wall of the side part of the accommodating cavity when the object loading in the quantitative accommodating cavity is poured out from the inlet and the outlet and enters the quantitative accommodating cavity.

The invention has the beneficial effects that: the quantitative container and the quantitative fetching method enable the process of pouring or obtaining the quantitative object to be carried out in the container, so that the object is not polluted by the outside, and then the quantitative object is poured out or taken out of the container without an external measuring cup or vessel;

the problem that too much or too little quantitative loading occurs in pouring or obtaining the quantitative loading can be adjusted in the container, and waste caused by external pollution is avoided;

moreover, when the quantitative object is poured or obtained, the manual operation is convenient, the action is natural, and other devices are not needed to intervene;

finally, the device is simple in structure, extremely low in production cost, capable of being used on a large scale, and capable of improving efficiency and saving resources.

Drawings

FIG. 1-1 is a front cross-sectional view of the embodiment 1;

FIGS. 1-2 are perspective cross-sectional views of embodiment 1;

FIGS. 1-3 are exploded perspective views of embodiment 1;

FIGS. 1-4 are sectional views of the upright position of embodiment 1 after being turned 90 degrees;

FIGS. 1-5 are sectional views of the upright position of embodiment 1 after being turned 180 degrees;

FIGS. 1-6 are cross-sectional views of embodiment 1 after being inverted 360 degrees from the upright position;

FIGS. 1 to 7 are sectional views of the upright position of the first embodiment shown in FIG. 1, after being turned on its side at a predetermined angle;

FIGS. 1 to 8 are sectional views showing the state where the carrier of embodiment 1 is poured out;

FIGS. 1 to 9 are sectional views showing the state where the carrier of embodiment 1 is poured out;

FIG. 2-1 is a front cross-sectional view of the embodiment of FIG. 2;

FIG. 2-2 is a perspective cross-sectional view of the embodiment of FIG. 2;

FIGS. 2-3 are exploded perspective views of the embodiment of FIG. 2;

FIGS. 2-4 are cross-sectional views of embodiment 2 after being turned 90 degrees from the upright position;

FIGS. 2-5 are cross-sectional views of the upright position of embodiment 2 after being turned 180 degrees;

FIGS. 2-6 are cross-sectional views of the upright position of embodiment 2 after being inverted 360 degrees;

FIGS. 2 to 7 are sectional views of the upright position of the first embodiment shown in FIG. 2, after being turned on its side at a predetermined angle;

FIGS. 2 to 8 are sectional views showing the state where the carrier of embodiment 2 is poured out;

FIGS. 2 to 9 are sectional views showing the configuration of the carrier of the embodiment 2 after pouring out;

FIG. 3-1 is a sectional view of the exploded state of the embodiment 3;

FIG. 3-2 is a front cross-sectional view of the embodiment of FIG. 3;

FIGS. 3 to 3 are sectional views showing the state where the carrier of embodiment 3 is poured out;

FIG. 4-1 is a schematic perspective view of the fourth embodiment of FIG. 4;

FIG. 4-2 is a front cross-sectional view of the embodiment of FIG. 4;

FIGS. 4 to 3 are sectional views showing the state where the carrier of the embodiment 4 is poured out;

FIG. 5-1 is a front cross-sectional view of the embodiment of FIG. 5;

FIG. 5-2 is a perspective cross-sectional view of the embodiment of FIG. 5;

FIGS. 5-3 are exploded perspective views of the embodiment of FIG. 5;

FIGS. 5-4 are sectional views of the upright position of the embodiment of FIG. 5 after being turned 90 degrees;

FIGS. 5-5 are sectional views of the upright position of the embodiment of FIG. 5 after being turned 180 degrees;

FIGS. 5-6 are cross-sectional views of the upright position of the embodiment of FIG. 5 after being inverted 360 degrees;

FIGS. 5-7 are sectional views of the upright position of the embodiment 5 after being turned on its side at a certain angle;

FIGS. 5 to 8 are sectional views showing the state where the carrier of the embodiment 5 is poured out;

FIGS. 5 to 9 are sectional views showing the state where the carrier of the embodiment 5 is poured out;

FIG. 6-1 is a front cross-sectional view of the embodiment of FIG. 6;

FIG. 6-2 is a sectional view showing the state where the carrier of the embodiment 6 is poured out;

FIG. 7-1 is a schematic perspective view of the embodiment of FIG. 7;

FIG. 7-2 is a front cross-sectional view of the embodiment of FIG. 7;

fig. 7-3 are sectional views showing the state where the load of embodiment 7 is poured out.

Detailed Description

The upper part of the container is the opposite direction of gravity, the lower part of the container is the gravity, the upright part of the container is the upright part along the gravity, and when the container is upright or overturned, the loading objects in the container are distributed or distributed according to the gravity direction.

The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments. It should be noted that the features of the following embodiments and examples may be combined with each other without conflict.

Preferred embodiments of the present invention will be described with reference to the accompanying drawings. In all the drawings, the same components are denoted by the same reference numerals, and overlapping description thereof will be omitted as appropriate.

In the following examples, cough water, alcohol, honey and syrup are exemplified as the liquid agents, but the liquid agents are not limited thereto, and examples thereof include skin cosmetics such as facial cleanser, detergent, dish detergent, hair styling gel, liquid foundation and beauty lotion, hair dye, disinfectant, soy sauce applied to foods such as bread, liquid laundry detergent such as edible oil, household detergent, disinfectant, and topical detergent, and flowable jelly, and the viscosity is not particularly limited. The particles include drug particles, and the powder includes food powder and pharmaceutical powder.

[ embodiment 1 ]

As shown in fig. 1-1 to 1-9, the overall structure of the quantitative container of the present embodiment is a cube, wherein fig. 1-1 is a front view of the present embodiment, and as can be seen from the figure, the volumetric flask of the present embodiment includes a cavity 10, an inlet and outlet 20 for allowing liquid, colloid, granule or powder to enter and exit is arranged at the top of the cavity 10, the width of the inlet and outlet 20 can be determined according to the size of the loaded object, and the inlet and outlet 20 is located on the side of the top of the cavity 10 relatively far from the passage port 70 or on the side wall of the cavity 10 above the partition 40 and far from the passage port 70. The access 20 is provided with a container cover 30, external threads are arranged outside the access 20, internal threads are arranged inside the container cover 30, the container cover 30 is movably mounted on the access 20 in a state of surrounding the access 20, and when the container cover 30 is covered, the loaded objects can be prevented from entering and exiting the cavity 10.

The partition board extending into the cavity 10 and connected to the inner wall of the entrance 20 or the inner wall of the exit 10 and bending toward the top of the cavity 10 integrally, the partition 40 of this embodiment is a partition board, and of course, a partition block with a certain thickness or any shape may be used, but the partition board of this embodiment only needs to be provided with a bent portion bending toward the top of the cavity along a folding line to satisfy the quantitative requirement, and in addition, the quantitative function of the partition board of this embodiment can be realized by the function, and other components do not make specific limitations, the partition board of this embodiment divides the cavity 10 into an upright cavity 50 and a quantitative cavity 60 located above the upright cavity 50, and the partition board can be connected to the inner wall of the cavity 10 by bonding or welding, and according to the condition of carrying objects, the functions of sealing air and water or preventing particles or powder from being missed can be achieved, the plates forming the receiving chamber 10 may also be fused by bonding or welding, or may be integrally formed, in addition, the shape of the detail part on the partition plate is not limited, that is, the shape in the quantitative receiving chamber is not limited, and may be wavy or linear, but the tail end of the partition plate needs to be bent upward, that is, bent toward the top of the receiving chamber 10, if a partition block with a certain thickness or any shape is adopted, the tail end of the partition block is bent upward or curved, and is higher than the rest of the partition block to form a groove, or a groove is directly dug on the partition block to realize the function of storing the object, in this embodiment, the straight plate is bent, so that the partition plate and the sidewall of the receiving chamber 10 can enclose a certain amount of receiving chamber 60, wherein a channel port 70 for exchanging or circulating the object is provided between the quantitative receiving chambers 60 of the upright receiving chamber 50, and the channel port 70 of the quantitative receiving chamber 60 are formed by the bending part of the partition plate toward the top of the receiving 10, and if a granular or other carrier or a powdered carrier is to be quantitatively poured, the opening 70 is not smaller than the diameter of the granular or powdered carrier or the maximum diameter of the unit carrier. Furthermore, the central axis of the inlet and outlet 20 and the central axis of the passage port 70 are not overlapped, and the non-overlapping is to ensure that the inlet and outlet 20 and the passage port 70 are not at the same height when the loaded substance in the quantitative cavity 60 is poured out from the inlet and outlet 20, and it should be further described that if the inlet and outlet 20 is disposed on the side wall of the cavity 10, the side wall is also far away from the passage port 70, and the inlet and outlet can also be disposed on the front wall or the rear wall far away from the passage port 70. In addition, the access opening 20 is arranged to ensure that the loaded item can enter and exit the dosing chamber 60 from the access opening 20, and the position of the access opening can influence the tilting angle of the dosing chamber 60 required for pouring the loaded item.

For the sake of beauty and simple manufacturing process, the divider plate of this embodiment is in the L-shaped right-angle plate of the horizontal lying shape when the cavity 10 is erected, wherein, the L-shaped right-angle plate, except the edge of the tail of the L-shaped right-angle plate, has the other peripheries all seamlessly joined with the inner wall of the cavity 10, and encloses a quantitative cavity 60 with the inner wall of the cavity 10, and for better sealing, two folded plates of the L-shaped straight plate are integrally formed.

As a further optimization of the technique, the volume of the upright volume 50 is not less than the volume of the dosing volume 60. If the volume of the upright cavity 50 is smaller than the volume of the quantitative cavity 60, the object in the upright cavity 50 can be poured out at one time, and the meaning of quantitative pouring is lost.

In addition, when the above-mentioned loaded object in the quantitative cavity 60 is turned over or poured out from the entrance, at least a part of the partition portion 40 and the peripheral walls of the bottom and the side of the cavity form a blocking cavity, and the length of at least a part of the partition portion 40 extending from the initial position to the inside of the cavity, or the arrangement of the partition portion 40 at the initial position of the cavity, or the shape of the partition portion 40 can at least ensure that the loaded object in the blocking cavity 80 can be completely blocked from being transited from the passage opening 70 to the quantitative cavity 60 when the loaded object is completely poured out from the quantitative cavity.

The resistance-capacitance chamber of this embodiment directly comprises the bottom surface of partition portion and the side wall that just stands the chamber, when carrying thing and verting and pouring out from the access & exit, the bottom surface of partition portion and the side wall that just stands the chamber play in effect and block that the thing of carrying passes through from passway mouth 70 to ration appearance chamber, have formed the resistance-capacitance chamber. For example, in the present embodiment, when the above-mentioned loaded object in the quantitative cavity 60 is poured out from the inlet 20, the partition plate and the peripheral wall of the bottom and the side of the cavity 10 form a blocking cavity 80, the length of the partition plate extending from the initial position to the inside of the cavity 10, or the arrangement of the partition plate at the initial position of the cavity 10, or the shape of the partition plate at least can ensure that when the loaded object is completely poured out from the quantitative cavity 60, the loaded object in the blocking cavity 80 can be completely blocked from flowing out from the passage opening 70 to the quantitative cavity 60. If the partition is a block, the bottom surface and the side wall of the block form a blocking cavity. The shape of the bottom surfaces of the divider and the blocks is not limited, but the flat surfaces may be curved or sloped.

The resistance containing cavity 80 has the function that the resistance containing cavity 80 can enable the loaded object in the upright containing cavity 50 to be loaded in the resistance containing cavity 80 and not to flow out after tilting for a certain angle, so that the loaded object in the upright containing cavity 50 can be loaded in the resistance containing cavity 80 and not to flow out after tilting for a certain angle, that is, the loaded object in the upright containing cavity 50 can be prevented from flowing out of the resistance containing cavity 80 by the cavity wall of the resistance containing cavity 80 when the quantitative containing cavity 60 tilts, that is, the loaded object does not flow into the quantitative containing cavity 60, and the loaded object in the upright containing cavity 50 can not flow out of the containing cavity 10 through the inlet and outlet 20 in the state that the container cover 30 is opened.

In addition, the volume of the blocking volume 80 is not smaller than the volume of the dosing volume 60. The operation principle is the same as the arrangement principle of the upright cavity 50, and the description is omitted here.

In addition, the volume of the upright cavity 50 is also not less than the volume of the baffle cavity 80.

[ 2 nd embodiment ]

As shown in fig. 2-1 to 2-9, in the embodiment 2, compared with the first embodiment, the functions of the container cover 30, the inlet and outlet 20, the quantitative cavity 60, the blocking cavity 80, the cavity 10 and the upright cavity 50 are the same, but the blocking cavity is different in arrangement, the blocking cavity may be composed of a blocking part and a cavity peripheral wall, the blocking part is arranged below or below the partition part and protrudes from the bottom of the upright cavity, the blocking part divides the upright cavity into the blocking cavity 80 and a loading channel 100 which are communicated with each other, the blocking cavity 80 is used for blocking the loading of the blocking cavity from being transited from the loading channel 100 to the quantitative cavity when the upright cavity is turned over, and the blocking cavity 80 blocks the loading from being transited from the loading channel 100 to the quantitative cavity when the quantitative cavity 60 is completely filled with the loading. In addition, the shape of the blocking portion is not limited as long as the blocking effect can be achieved, and the blocking portion may have a structure such as a straight plate, a curved plate, an irregularly-shaped plate body, or a block body.

Specifically, a baffle 90 extends below the partition plate and toward the upright cavity 50, the baffle has a blocking portion as described above, the baffle 90 and the sidewall of the cavity 10 located closer to the channel opening 70 form a loading channel 100, when an object enters and exits the upright cavity 50, the object can enter and exit through the loading channel 100, in addition, the caliber of the loading channel 100 is not smaller than the diameter of the particle or powder loading object or the unit loading object, for example, the unit loading object formed by bonding several separate particles, the baffle and the partition plate are integrally formed, and the partition plate extends downward toward the bending portion at the top of the cavity 10.

[ embodiment 3 ]

As shown in fig. 3-1 to 3-3, in the embodiment 3, compared with the embodiment 1, the functions of the container cover 30, the inlet and outlet 20, the dosing cavity 60, the blocking cavity 80, the cavity 10 and the erected cavity 50 are the same, except that the shape of the cavity of the first embodiment is a square shape, the shape of the embodiment is a cylindrical shape, and the shape structure of the cylindrical shape requires that the shape of the structural components inside the cavity is matched with the cylindrical shape, so that there is no difference in function.

[ 4 th embodiment ]

As shown in fig. 4-1 to 4-4, the container lid 30, the dosing chamber 60, the blocking chamber 80, the chamber 10, and the erection chamber 50 of embodiment 4 are the same as those of embodiment 1, with the difference that: the position of the inlet and outlet 20 is arranged on the side wall of the cavity; secondly, the method comprises the following steps: the partition part is a curve plate, the end part of the curve plate is bent towards the top of the cavity, and a concave quantitative cavity is formed by the end part of the curve plate and the side wall of the cavity. The overall shape of the chamber is the same as that of embodiment 1.

[ 5 th embodiment ]

As shown in fig. 5-1 to 5-9, compared to embodiment 1, the functions of the container cover 30, the inlet/outlet 20, the quantitative cavity 60, the blocking cavity 80, the passage port 70, and the upright cavity 50 are the same, and the principle of quantitative reverse loading is the same as that of embodiment 1, except that: the shape of the cavity is flat when viewed from the side, and the shape of the cavity is a curve transition shape with a narrow upper part and a wide middle part and then a narrow lower part when viewed from the front; secondly, the method comprises the following steps: the division part starts from the inlet and the outlet; thirdly, the method comprises the following steps: the partition part is an arc-shaped bent plate, the tail end of the arc-shaped bent plate is bent towards the top of the accommodating cavity 10 in a curved hook shape, the tail end of the arc-shaped bent plate is removed, and the rest parts of the arc-shaped bent plate are connected with the inner wall of the accommodating cavity 10 to form a quantitative accommodating cavity 60 together with the inner wall of the accommodating cavity 10.

[ 6 th embodiment ]

As shown in fig. 6-1 to 6-2, compared to embodiment 2, the functions of the container cover 30, the inlet/outlet 20, the quantitative cavity 60, the blocking cavity 80, the passage port 70, and the upright cavity 50 are the same, and the principle of quantitative reverse loading is the same as that of embodiment 1, except that: the shape of the cavity 10 may be a flat shape or a cylindrical shape or other shapes; secondly, the method comprises the following steps: the holding chamber 60 is formed by an inverted L-shaped plate-shaped holding portion 41 provided below the quantitative holding chamber 60. Of course, this is just the shape of the stopper 41 of the present embodiment, and the shape of the stopper 41 may not be limited, and may be a curved panel or a block plate of an arbitrary shape.

[ 7 th embodiment ]

As shown in fig. 7-1 to 7-3, this embodiment is an oil can structure, and compared with embodiment 1, the container cover 30, the inlet/outlet 20, the dosing cavity 60, the blocking cavity 80, the passage port 70, and the upright cavity 50 have the same functions, and the principle of quantitative loading and unloading is the same as that of embodiment 1, except that the first: the shape of the cavity 10 can be irregular flat column shape, and can be other structures according to actual conditions; secondly, the inlet and outlet 20 is arranged at the connecting part of the top and the side wall of the cavity; thirdly, the partition 40 is formed by upper and lower curved plates connected with each other and having the same curvature, and the ends of the upper and lower curved plates are connected in a smooth transition manner, or may be integrally formed.

In addition, the connection in the above embodiments may be a seamless sealing connection or a breakpoint connection, specifically, depending on the form of the object to be loaded in the container, if the container is a liquid, a gel or a powder, a seamless connection is suggested, if the container is a granular object, a seamless sealing connection or a breakpoint connection may be selected, and when the breakpoint connection is performed, the distance between the breakpoints is smaller than the diameter of the object.

It should be added that the quantitative cavity 60 in the present application is not limited to the quantitative loading when the quantitative cavity is fully loaded, and a separation scale may be set on the structure of the quantitative cavity 60 according to actual needs, and different quantitative cavities are represented by different separation scales.

In addition, it should be noted that besides the above embodiments, there are many other embodiments, which are not exhaustive, in the above embodiments, all the external configurations may be interchanged or adjusted, all the internal configurations may be interchanged or adjusted according to actual needs, and the partition portion 40 constituting the baffle cavity 80 may be selected and adjusted, or a part of the configurations in some embodiments may be selected for re-integration and adjustment, so long as the quantitative inverted structural design of the present application is satisfied, which is within the protection scope of the present application.

It should be further noted that, the material of any one or any combination of the above embodiments is not limited, and may be made of a suitable material according to the object to be placed, or may be made of a material that is completely or partially transparent according to the whole container, for example, the front panel of the container may be made of a transparent material, and the rest may be made of an opaque material, or may be made of a transparent material, so as to facilitate external observation of whether the container is quantitative, the transparent material may be made of a rigid plastic or glass, the rigid plastic may be made of a plastic bottle, such as plastic bottle, or a rigid disposable plastic tableware, such as high density polyethylene, PET plastic, PP plastic, or PETG plastic, and the opaque material may be made of metal, wood, or opaque rigid plastic.

The following general procedure for analyzing a quantitative extract includes the steps of:

step 1: when the quantitative loading device is in an initial state, the loading object is stored in the upright cavity (the initial state is a cavity upright state, and the quantitative cavity does not contain the loading object), the cavity in the upright position is tilted, or shaken or whipped, so that the loading object in the upright cavity partially or completely enters the quantitative cavity through the channel port, if the residual part exists, the residual part falls back to the upright cavity, and the quantitative loading object is stored in the quantitative cavity;

step 2, after the object loading enters the quantitative cavity, tilting the cavity, only pouring the object loading in the quantitative cavity out of the inlet and outlet, if the quantitative cavity contains the quantitative object loading in the initial state, directly starting from the step 2, and implementing the step 2;

and 3, returning the cavity to the initial state.

In step 2 of the method, when the receiving chamber 10 is tilted, the inlet/outlet 20 is tilted downward by an angle slowly until all the loaded objects in the quantitative receiving chamber 60 can be poured out, where the tilting angle can be understood as tilting in a tilting plane perpendicular to the horizontal plane, the tilting plane is not limited to one plane, and is a series of rotating planes taking the gravity line as the axis, the maximum rotating angle is determined according to the structure and position of the quantitative receiving chamber, when the loading object is to be poured out, the tilting plane can be switched between more than two rotating planes, and finally, when the loaded objects are to be kept to be poured out, only the quantitative loaded objects in the quantitative receiving chamber 60 can be poured out, and the loaded objects in the resistance receiving chamber 80 can not pass through the passage opening 70.

It should be added that the volume of the dosing chamber 60 can be set to a certain volume according to the actual requirements. In the present embodiment, the volume of the measurement volume chamber 60 is set to 10ml, that is, 10ml in a state where the measurement volume chamber 60 is supported by the bottom of the measurement volume container and is self-supporting. 1, the volume of the object in the quantitative cavity 60 does not reach the rated value of 10ml, the quantitative cavity can reach the standard by turning, swinging or swinging, the direction of the central axis of the turning of the cavity 10 is not absolutely vertical to the gravity direction, and the angle deviation of a certain degree is allowed, in addition, the moving track of the cavity 10 in the turning process can be a standard circumferential regular curve or an irregular curve, and the action when the quantitative cavity 60 is poured out is carried out. 2, to make the ration hold the interior carrier liquid of chamber 60 and be less than current year thing volume, reduce liquid promptly, but the chamber 10 that verts of small-angle, pour the action of carrying the thing as above, make ration hold the interior carrier flow of chamber 60 wherein, for example pour the bowl normal water in the life, only need to pour the bowl side water just, the angle is bigger water is poured more.

The volume of the upright receptacle 50 can also be set in advance according to the actual situation.

The above embodiments are merely representative of the centralized embodiments of the present invention, and the description thereof is specific and detailed, but it should not be understood as the limitation of the scope of the present invention, and it should be noted that those skilled in the art can make various changes and modifications without departing from the spirit of the present invention, and these changes and modifications all fall into the protection scope of the present invention. Therefore, the protection scope of the present patent should be subject to the appended claims.

Claims (13)

1. A quantitative container is characterized by comprising: the container comprises a container, an inlet and an outlet which can allow loading and unloading are arranged at the top or the side of the container or the connection part of the top and the side, a container cover is arranged at the inlet and the outlet, a separating part which is connected with the inner wall of the container except the tail end and at the rest part extends from the inner wall of the container or the inner wall at the inlet and the outlet to the interior of the container, at least one part of the separating part is bent or curved towards the upper part of the containing cavity in a fold line to form a bent part, the bent part alone or together with the cavity wall of the containing cavity forms a certain amount of containing cavity, or the separating part is at least provided with a groove facing the top of the containing cavity, the groove forms a quantitative containing cavity, an upright containing cavity communicated with the quantitative containing cavity is arranged below or at the lower part of the separating part, the strait between the tail end of the partition part and the side wall of the cavity forms a passage opening of the upright cavity and the quantitative cavity, and in addition, the central axis of the inlet and the central axis of the outlet are not overlapped with the central axis of the passage opening.

2. A dosing container as claimed in claim 1, characterized in that: the passage opening is not smaller than the diameter of the individual or unit load.

3. A dosing container as claimed in claim 1, characterized in that: the partition part is formed by bending or curve bending a single-layer partition plate, or formed by pressing or assembling, bending or bending more than two layers of partition plates at intervals, or formed by blocks.

4. A dosing container as claimed in claim 1, characterized in that: the inlet and the outlet are positioned on the side edge of the top of the cavity, which is relatively far away from one side of the channel port, or positioned above the partition part and far away from the side wall of the cavity of the channel port.

5. A dosing container as claimed in claim 1, characterized in that: the container cover is arranged at the access in a state of surrounding the access, and the loading object can be prevented from entering and exiting the cavity after the container cover is covered.

6. A dosing container as claimed in claim 1, characterized in that: the volume of the upright cavity is not less than that of the quantitative cavity.

7. A dosing container as claimed in claim 1, characterized in that: when the loaded object in the quantitative accommodating cavity is tilted and poured out from the inlet and the outlet, the separating part and the peripheral wall of the bottom and the side part of the accommodating cavity form a blocking accommodating cavity, the separating part extends from the initial position to the inside of the accommodating cavity, or the separating part is arranged at the initial position of the accommodating cavity, or the shape of the separating part at least can ensure that the object in the blocking accommodating cavity can be completely blocked to be transited from the passage port to the quantitative accommodating cavity when the quantitative accommodating cavity is completely poured with the object.

8. The dosing chamber according to claim 7, wherein: the partition part comprises a resistance part which is arranged below or on the lower part of the partition part and extends towards the bottom of the upright containing cavity in a protruding mode, the upright containing cavity is divided into a resistance containing cavity and a loading channel 100 which are communicated with each other by the resistance part, the resistance containing cavity is used for blocking loading of the resistance containing cavity when the upright containing cavity tilts and transferring the loading from the loading channel 100 to the quantitative containing cavity, and the resistance containing cavity blocks loading of the loading channel and transferring the loading to the quantitative containing cavity when the quantitative containing cavity is completely poured.

9. A dosing container as claimed in claim 7 or 8, characterized in that: the volume of the blocking cavity is not less than that of the quantitative cavity.

10. A dosing container as claimed in claim 1, characterized in that: the cavity and the partition part inside the cavity are partially or completely made of hard transparent materials.

11. The dosing chamber according to claim 10, wherein: the cavity and the partition part inside the cavity are partially or completely made of glass or hard plastics.

12. A method for quantitatively taking an object in a quantitative container, which is characterized by comprising the steps of, in accordance with any one of the above 1 to 11,

step 1: in the initial state, the object is stored in the upright cavity, the cavity in the upright position is tilted, shaken or thrown, so that the object in the upright cavity partially or completely enters the quantitative cavity through the channel port, if the rest part exists, the rest part falls back to the upright cavity, and the quantitative object is reserved in the quantitative cavity;

and 2, after the object is loaded into the quantitative cavity, tilting the cavity, and only pouring the object loaded in the quantitative cavity out from the inlet and outlet.

And 3, returning the cavity to the initial state.

13. The method for quantitatively taking an object out of a quantitative container according to claim 12, wherein the quantitative container is tilted to the quantitative cavity after the object is introduced into the quantitative cavity in step 2, and the pouring of the object from the quantitative cavity through the inlet and outlet further comprises keeping a resistance cavity formed by the partition and the peripheral walls of the bottom and side portions of the quantitative cavity to block the object from entering the quantitative cavity when the object is poured from the inlet and outlet.

Images