KR100519088B1 - measuring and dispensing container - Google Patents

Abstract

The present invention relates to a container for transporting, metering, separating, and discharging a liquid substance using a dispensing device combined with a measuring container. The liquid material, for example, a liquid beverage, pharmaceuticals, chemicals, pesticides, seasonings, detergents, It is to prevent the loss or overuse of contents and protect the human body from harmful substances by using the device to safely quantify the substances handled in liquids such as additives and cocktails, and to quantify the contents and improve convenience of distribution. In the present invention, by operating the structural combination form of the fluid storage unit containing the liquid material and the metering unit that can be separated and accommodated differently, the structure of the object to be discharged out of the metering container after transporting, quantifying and separating the material from the storage unit to the metering unit. Present the function. According to the present invention, by transporting the material in a container formed integrally with the various liquid substances required to be quantified by a separate device or tool, the loss of constituents of the contents and protection of the human body from dangerous substances and prevention of loss of the contents and The convenience of dispensing and post-processing problems after dispensing are simplified.

Description

Metering and dispensing container

The present invention relates to a container for transporting, measuring, separating, and discharging a liquid substance using a dispensing device combined with a measuring container. In the related art, a separate measuring spoon or measuring cup is used to measure and distribute the contents contained in a storage unit. There is no separate measuring equipment or the use is cumbersome because of the cumbersome use of the raw material is not weighed in the rough use of resources, especially if the substance is a drug or chemicals can be exposed to environmental pollution as well as dangerous situations have. This is especially true for medication bottles containing small amounts of child syrup prepared in pharmacies that are frequently used as disposable products. In order to increase the therapeutic effect, the administration of conventional dosage bottle, even if the weighing scale is inaccurate or accurate, if you use a regular rice spoon, you have to use the method of subtracting the dosage from the scale engraved on the bottle. Could grow. In addition to the hassle of having to carry a measuring spoon or measuring cup at all times in order to administer the drug, there were inconveniences caused by various operations such as weighing a spoon or measuring cup and administering it to a child and washing the spoon or cup every time. Before weighing and administering a spoon, the drug was likely to spill or spill on the move, and there was a lot of trouble to wash the clothes as well as the drug. Even more severe cases of children's rejection of drugs were found. If the spoon has a scale, it is fortunate, but if there is no measuring spoon, it is still the practice to feed the spoon. In some cases, the drug is poured into a spoonful of rice, weighed, topped with powdered medicine, and stirred with a finger. This is a very serious problem due to the nature of the drug to ensure hygiene and safety in terms of ensuring the safety of the drug. As the preparatory procedure for administering the drug is complicated, the caregiver feeding the drug must maintain tension for a long time, and the child who takes the drug increases the objection to the drug, making it difficult to accurately and safely administer the drug. . In order to solve the problems described above, the container for storing the drug and the tool for weighing are not separated and are united, the metering is convenient, and the separation and loss of the drug when mixing the powdered medicine can be prevented. If the container can be administered as it is, all the above problems are eliminated. Another example is that in case of diluting chemicals used for cleaning, such as women's cleaners or bathroom cleaners, most of them are excessive because they do not have accurate weighing due to lack of measuring containers or cumbersome use. The tendency to use has led to waste of resources as well as accelerated environmental pollution. In addition to the container that needs to be used in real life in order to eliminate the inconvenience of using a separate mechanism, the following containers are separated from the storage unit and the separate water metering unit in the same container.

end. Container containing engine oil additive

I. A container containing a chemical to prevent microbial propagation or a mouthwash container in a water tank that is a component of a humidifier

  However, the above two cases were used when a certain amount was to be weighed and then dispensed. The lower storage container was pressurized from the outside to increase the air pressure of the storage unit placed at the bottom to transfer the material to the separate storage meter located at the upper side. The pressure of the metering part increased the air density and the pressure increased as the content entered, so it was necessary to pressurize more and more to transfer the content to the separate capacity meter. At this time, the air must be balanced through the circulation of the lower storage part or the air out of the separate water metering unit, and it can be moved continuously.The separate water metering unit of the upper part is sealed by a stopper, and the lower part of the pipeline through which air can be circulated. Since the liquid is blocked by the flowable material in the reservoir, the upper air is not exchanged with the lower reservoir in the normal state, and therefore, a stronger force is required to transfer the fluid to the separated water metering unit. Therefore, the material moves as much as the pressing force when pressurized once, there was a disadvantage that it is difficult to accurately weigh and has to pressurize several times. In this case, even when weighing in this way, when a considerable force is applied when pressurized, it is difficult to transfer the material transferred to the separated water metering unit to the storage unit in reverse when it is weighed excessively than the target amount. Also me. In the case of the above-mentioned disadvantages, such as to make a separate compartment in the neck of the container to block the movement of the material between the separate water metering unit and the storage unit, and the pipe for transporting the lower material to the upper side must be perforated from the side. There was a point that the manufacturing cost of the container increased.

Also, in a container containing a carbonated gas, when the contents in the container are distributed to the outside, the carbon dioxide dissolved in the beverage is discharged to the outside as the container moves, or when the cap is closed and then opened again. As soon as it was opened, the concentration of carbon dioxide remaining in the contents of the container was gradually reduced, resulting in a significant decrease in the refreshing feeling, which resulted in a tasteless taste.

The present invention has the object of removing the conventional closed end as described above to conveniently weigh and ensure safety. In order to achieve the above object, the separate water metering unit and the fluid storage unit may be detachable and a device functioning as a valve is required between the two compartments. Therefore, in the present invention, the separately manufactured fluid storage unit and the separate water metering unit are connected to each other, and when dispensing, the integrated container is turned upside down, and the storage unit is located at the lower part of the water storage unit at the bottom, between the two compartments. Match the outlet of the fluid storage unit and the inlet of the separate water metering unit so that the fluid flows from the upper storage unit to the separate storage unit of the lower part. This is accomplished by making them inconsistent with each other. If the amount is more than the target amount, it is easily corrected by transferring from the storage unit to the storage unit in the same way that the storage unit divides the storage unit from the storage unit, so that the accuracy of the quantitative distribution can be improved. Even if it is necessary to mix two or more substances in an enclosed space, it becomes a container with multiple compartments, so that mixing and dispensing are possible without using a separate dispenser.

In addition, in order to prevent or reduce the carbon dioxide concentration of the carbonated beverage, closing the cap at the same time as dispensing the beverage to prevent or maintain the carbon dioxide concentration of the carbonated beverage. To this end, the container containing the contents is inverted so that the liquid layer is on the bottom and the gas layer is on the top. At this time, if the beverage is dispensed from the lower part of the liquid layer below, the carbon dioxide gas that has been discharged to the outside moves to the closed upper space, and if the inlet through which the liquid flows is blocked, the carbon dioxide gas can no longer go out and the container is returned to normal. When the container is closed even after returning to the position, the carbon dioxide which has flowed out of the beverage is in equilibrium between the liquid layer and the gas layer in the container. Therefore, the structure of the container that can minimize the loss of carbon dioxide gas should be possible by dispensing the container upside down, if the container to create a closed space at the same time blocking the distribution port flows.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that the above objects can be specifically implemented.

Weighing container (A) made of synthetic resin as a raw material for dispensing the flowable substances contained in the storage container by a certain amount, the body of the storage part is cylindrical and engraved, and the inner peripheral surface of the lower part prevents separation and It forms and maintains the circumferential insertion portion 11 that can be inserted into the upper jaw of the storage container or the connector so that it can be fastened to the storage container and constitute a packing member 101 to prevent leakage to the outer bottom The annular shape of the measuring container which is in close contact with the opening end surface of the storage container or connector and has an annular projection 12 having an O-ring shape corresponding to the annular guide groove 24 on the outer circumferential surface of the neck of the storage container and is in close contact with the annular guide groove 24. The inner diameter of the protrusion is preferably smaller than the outer diameter of the annular guide groove 24 of the neck of the storage container in order to increase the airtight effect. One or more inlets for receiving contents from the storage container are formed at the bottom of the separate container 14, and the inlet is configured to penetrate the bottom or side of the separate container according to the shape of the container or connector. . The inlet and lower portion of the annular projection of the insertion portion 11 of the metering vessel, which is formed on the lower bottom of the separating accommodation portion, may have a structure of a female screw so that the linear movement can be changed into a rotational movement. The upper part is composed of a discharge port 15 and a stopper 16 capable of discharging the measured contents to the outside, and has a double stopper structure to enable a small amount of dispensing. The storage container must have a specific coupling part structure in which the coupling part coincides with the lower end of the weighing container in order to be integrally formed with the weighing container.

According to the first embodiment of the present invention, the operation of the combined surface of the two vessels acting as the valve is in close contact with the neck of the storage vessel when the bottom surface of the annular protrusion is brought into close contact with the lower jaw 26 of the storage vessel by standing the container integrally upside down. Clogged inlet 13 is pushed into the body portion of the storage container larger than the inner diameter of the neck, the inlet is opened while the contents in the storage container is introduced through the open inlet (Fig. 12). When the target amount is accommodated in the measuring container so that the annular projection 12 is in close contact with the upper jaw 22, the inlet is again in close contact with the inner surface of the neck of the storage container. To achieve this, the reservoir should have a width greater than the diameter of the inlet opening of the guide groove 24 in the neck.

According to the second embodiment of the present invention, the neck of the storage container has a cylindrical and constant inner diameter, and the groove 221 of the neck is provided on the outer circumferential surface of the neck as much as the stoppers 217 extending downward from the outer circumferential surface of the measuring container. In the outer circumferential surface of the lower jaw 226, the storage container is coupled to the measuring container so as to convexly emerge from the upper end 225 of the body part to transfer the contents of the storage container, and the tunnel-shaped discharge guide part perpendicular to the outer peripheral surface of the measuring container. 223 (Fig. 2). This makes it possible to move the contents only when the inlet port 213 of the measuring container matches the discharge induction part of the storage container when dispensing the contents of the storage container (FIG. 12). After inserting the measuring container (A) into the storage container (B) containing the flowable material, the upright container is placed upside down, and the storage container is turned upside down, and then the discharge induction part of the storage container and the inlet port of the measuring container (213). ), The inlet is opened and the contents of the storage container are introduced into the receiving part of the measuring container (FIG. 12). When the process of weighing is finished, when the measuring container and the storage container are rotated in different directions, the inlet 213 is in close contact with the inner circumferential surface of the neck of the storage container to block the inflow of the contents (Fig. 12). The contents can be discharged to the outside through the upper cap of the container.

According to the third embodiment of the present invention, the lower jaw of the storage container has an outer diameter larger than the upper jaw, and the inner jaw of the annular protrusion lower portion 344 in the insertion portion 311 of the measuring container has a male screw shape in the lower jaw, and the inner diameter thereof is a female screw method. It is formed so as to have a structure corresponding to the lower jaw of the storage container, and by rotating the annular projection 312 vertically reciprocating the annular guide groove 324 by opening and closing the inlet 313 to the vertical as in the first embodiment It will be reciprocating (Fig. 3). This has the advantage of giving too much force between the weighing container and the storage container to prevent the container from falling off and smooth the operation.

Fourth Embodiment of the Present Invention The following tenth embodiment provides a configuration in which an operation mode can be applied to a bottle shape in which a metering container of the present invention is generally screwed. In order to achieve this, the connector is configured to provide a connector to be combined with the storage container. The connector is mainly composed of an upper portion 761 and a lower portion 762. 762) and the lower jaw part is called the middle part 763, and the cylindrical part having a value smaller than the outer diameter of the lower part is called the upper part 761, and the lower inner circumferential surface can be screwed to match the general bottle shape. Shaped and the upper structure of the connector is the annular guide groove 786 of the storage container neck is inserted into the insertion portion 711 of the measuring container. The upper surface of the connector has an outlet 784 through which the contents can be discharged from the storage container, and the upper portion 761 of the connector is formed in a cylindrical shape, but corresponds to the annular protrusion 712 having a constant internal diameter inside the insertion portion 711 of the measuring container. A circular guide groove 786 having a constant outer diameter is formed to form a packing member that prevents leakage on the upper bottom surface of the connector that matches the upper opening surface of the storage container so as to be in close contact with the opening end surface of the storage container or the connector. .

In the fourth embodiment of the present invention, a tunnel-shaped discharge guide portion 467 is formed in the connector middle portion 461 having a cylindrical inner diameter of the upper portion from the upper end of the screwing portion, convexly convex than the periphery and perpendicularly contacting the inner surface of the neck. The upper structure of the connector is inserted into the annular guide groove 465 of the upper portion of the connector to be coincident with the annular projection 412 of the meter container inserting portion 411, as described in the first embodiment, to prevent airtightness and separation. Play a role.

In the fifth embodiment of the present invention, the lower inner circumferential surface forms a screwable shape so as to match a general bottle shape, and the upper part of the connector 561 is formed in a cylindrical shape, but the inner diameter is constant, and the measuring vessel is inserted into the outer circumferential surface of the neck. Inside the part 511, there is an annular guide groove 576 corresponding to the annular projection 512, and the groove 577 is provided with the groove 577 as long as the stop projection 517 extending downward from the outer peripheral surface of the measuring container. It is formed on the lower jaw (573) to stabilize the operation when operating and to determine the opening and closing and to form a structure in which the inlet blocking plate (579) formed in the inlet 513 of the eccentric in the weighing container is in close contact with the upper connector The inlet 513 and the outlet 575 can be made to coincide with each other, and the valve can be opened and closed.

The sixth embodiment of the present invention is similar to the fifth embodiment, but the connector forms a lower jaw without a recess, the upper surface of the connector is in close contact with the lower end surface of the separate storage reservoir, and the stopper 677 of the metering container is The inlet blocking plate is formed at a position adjacent to the inlet 613 so as to operate only in the outlet 673 of the connector.

In the seventh embodiment of the present invention, the inlet blocking plate 782 of the connector is configured to have a constant thickness and match the inner diameter of the inlet of the metering vessel so as to block the inlet 781 of the metering vessel. When configured to have two or more ribs 783 extending from the lower surface to the inner surface of the upper portion of the connector, the outlet is made between the ribs due to the difference between the outer diameter of the inlet blocking plate and the inner diameter of the connector neck. The operation method is that when the connector coupled to the weighing container and the storage container is pulled in the direction passing through the center line of the container, the inlet blocking plate 782 of the connector opens the inlet 781 to start the material movement and when the weighing is finished, the weighing container and the storage container are stored. The inlet is blocked when the connector coupled to the container is pushed in the direction crossing the center line of the container.

The eighth embodiment of the present invention has a structure similar to that of the seventh embodiment, wherein an annular protrusion lower portion 891 having a female thread structure is formed under the annular protrusion 812 of the measuring container and a male screw is provided at the bottom of the connector neck. The lower jaw screw portion 890 is formed and the annular guide groove 886 is formed thereon, so that the vertical operation of the seventh embodiment is changed to the rotation direction operation.

The ninth embodiment of the present invention has a structure similar to the seventh embodiment, wherein the inlet plate 941 of the metering container has an internal thread inlet constituting the female screw portion 913 at the inner circumference thereof coupled with the male screw inlet closure plate 942. Forming a spherical plate (941) and the corresponding connector comprises a male thread inlet orifice plate (942) formed with a male thread on the outer periphery of the inlet blocking plate to change the vertical operation of the seventh embodiment to a rotational operation. do.

In the tenth embodiment of the present invention, the inlet blocking projection 1031 of the metering container is formed on the bottom of the rib connecting plate 1039 perpendicular to the bottom and at least two or more ribs 1032 radially from the lower outer periphery of the rib connecting plate 1039. ) Is connected to the separate storage reservoir bottom plate 1033 and the inlet 1040 is formed between the ribs and the annular projection 1034 of the insert moves the guide groove 1037 of the connector and the female thread portion 1035 of the annular projection 1034 ) Has a structure having a larger inner diameter than the upper portion and the female screw portion 1035 has a female screw formed to coincide with the lower jaw screw portion 1038 formed on the lower jaw of the connector. The upper end of the connector is formed in a conical shape, but has an outlet 1036 at the end, and the operation is made by rotating the connector and the measuring container coupled to the storage container in different directions. When the container is made upside down and turned counterclockwise, the outlet 1036 of the connector leaves the inlet block protrusion 1031 from the storage container while the contents are introduced into the metering container through the inlet 1040 between the ribs. When the target amount is rotated in the clockwise direction when the coupling surface of the two vessels outlet 1036 is blocked by the inlet block projection 1031, the metering is completed.

The present invention made as described above in the metered distribution of the flowable material,

First, since a series of processes of storing, weighing, and distributing are made in an integrated container, a simple structure is possible, and thus, a separate device is not required. Therefore, the manufacturing cost is reduced, and it is widely applied to disposable products requiring weighing. You can make the effect

Secondly, by making a series of processes of storing, weighing, and dispensing in an integrated container, it is not necessary to use a separate device for weighing, storing, transporting, and cleaning, thereby improving convenience.

Third, the effect of reducing the waste of resources due to the loss of the contents by being made in an integrated container when measuring and distributing the contents,

Fourth, by measuring and distributing the contents in an integrated container, if the contents come into contact with the human body, it is effective to protect the human body from dangerous substances.

Fifth, even when the fluid contents contained in the storage container or the measuring container are mixed with the powder or soluble solid substance of the medicine, the compartment is separated and blocked, thus preventing the mixing of the material even when the container is shaken.

Sixth, even if multiple compartments are used to mix different liquid materials or even when they are the same, even if they need to be mixed at different capacities, the continuous process can be carried out in an enclosed space by opening only the adjacent vessels with each vessel separated. It has the effect of causing it to happen.

Seventh, when using a container containing a carbonated beverage is provided with a container that can reduce the concentration of carbon dioxide during distribution has the effect of maintaining a long refreshing feel of the carbonated beverage.

Figure 1 is an exploded perspective view of the fracture of the dispensing container according to the present invention.

Figure 2 is an exploded perspective view of the fracture of the dispensing container of another embodiment according to the present invention.

Figure 3 is an exploded perspective view of the fracture of another embodiment of the dispensing container according to the present invention.

Figure 4 is an exploded perspective view of the fracture of the dispensing container coupled to the connector according to the present invention.

Figure 5 is an exploded perspective view of the fracture of the dispensing container of another embodiment coupled to the connector according to the present invention.

Figure 6 is an exploded perspective view of the fracture of another embodiment of the dispensing container coupled to the connector according to the present invention.

Figure 7 is an exploded perspective view of the fracture of the dispensing container of another embodiment coupled to the connector according to the present invention.

Figure 8 is an exploded perspective view of the fracture of another embodiment of the dispensing container coupled to the connector according to the present invention.

Figure 9 is an exploded perspective view of the fracture of the dispensing container of another embodiment coupled to the connector according to the present invention.

Figure 10 is an exploded perspective view of the fracture of the dispensing container of another embodiment coupled to the connector according to the present invention.

12 is an operational cutaway view of the metering container of FIG. 1 in accordance with the present invention.

11 is an operational cutaway view of the metering container of FIG. 2 in accordance with the present invention.

Claims (11)

 The dispensing container made of a synthetic resin as a raw material for dispensing a certain amount of the flowable material is composed of a measuring container at the upper part and a storage container at the lower part, while the upper measuring container is a separate accommodating storage part 14 for receiving the contents of the storage container. And the graduation is engraved, and the bottom surface constitutes the packing member 101 to enhance the airtightness effect, and the inner circumferential surface of the lower part prevents the release and maintains the airtightness and the storage container or the connector neck to be fastened to the storage container. At least one inlet 13 is formed to form an insert portion 11 that can be inserted into and to receive the contents from the storage container, and a discharge port 15 and a double plug at the top to discharge the metered contents to the outside. In the upper measuring container and the lower portion, characterized in that consisting of 16, the neck has a cylindrical inner diameter, the upper jaw top surface shovel Synthetic resin as a raw material characterized in that the storage container formed in contact with the packing of the negative portion and formed between the upper jaw and the lower jaw to form an annular guide groove (24) having a constant outer diameter for guiding the annular projection (12) of the measuring vessel as a raw material Weighing container made (Fig. 1) The method of claim 1,  The inlet 213 is configured to penetrate the lower side of the separate storage reservoir 214 and extends with the outer circumferential surface of the metering container to facilitate the operation of the valve and to include a stopper protrusion 217 for determining the opening and closing of the valve. In the upper measuring container A2 and the lower part, the groove 221 is provided on the outer circumferential surface lower jaw 226 of the neck as much as the stopper 217 extending downward from the outer circumferential surface of the measuring container on the outer circumferential surface of the neck. Weighing container made from synthetic resin as a raw material characterized in that the storage container having a tunnel-shaped discharge induction part 223 vertically convex from the top of the periphery from the top of the periphery (Fig. 2) . The method of claim 1,  The inlet 313 is configured to penetrate the lower side of the separate storage compartment 314 and extends downwardly and has a lower portion 344 of the annular protrusion 312 having a larger inner diameter than the upper portion 343 of the annular protrusion 312. An annular guide groove 324 having a width larger than the diameter of the inlet of the metering container and the metering container is formed, and the lower jaw having a male thread having an outer diameter larger than the upper jaw is formed below the annular guide groove 324 of the neck of the storage container. Weighing distribution container made of a synthetic resin as a raw material consisting of a synthetic container characterized in that the inlet is opened and closed by rotating the annular projection groove 324 up and down by rotating the storage container is formed (Fig. 3). The metering container, which is integrated with the lower end of the metering container and the connector inserted in order to be applied to a metering container made of a synthetic resin as a raw material for distributing a certain amount of a flowable material and a screw-type general container commonly used, Consists of a measuring container at the upper part and a storage container at the lower part, but the upper measuring container has a separate accommodating storage part 414 for accommodating the contents of the storage container, and is engraved with a scale, and a packing member 101 for enhancing the airtight effect at the bottom. And the inner circumferential surface of the lower part serves to prevent separation and to maintain confidentiality, and to form an inserting portion 411 that can be inserted into a storage container or connector neck so as to be fastened with the storage container, and to receive contents from the storage container. One or more inlets 413 are formed thereon and the upper part can discharge the metered contents to the outside. 415 and a double stopper 416, the upper part of the metering container, characterized in that it is combined with the screw-type container commonly used in the female threaded portion and the inner bottom to the airtight to the portion corresponding to the storage container opening end surface In order to increase the holding effect, the lower part 462 consisting of the packing member and the inlet blocking surface and the inlet blocking surface blocking the inlet of the metering container and the inlet of the metering container are formed. On the outer circumferential surface of the formed neck, an upper guide 469 formed on the annular guide groove 465 having an outer diameter corresponding to the annular projection 412 in the insertion portion 411 of the measuring container and the annular guide groove corresponding to the insertion groove of the measuring container. ) And the lower jaw 463 is made of synthetic resin as a raw material, characterized in that the connector consisting of an upper portion that is combined with the measuring vessel formed on the intermediate outer peripheral surface Metered dispensing vessel The method of claim 4, wherein  Inlet 413 is configured to penetrate the lower side of the separate storage reservoir 414 and extends with the outer circumferential surface of the metering container to facilitate the operation of the valve, characterized in that consisting of a stopper 417 to determine the opening and closing of the valve. A groove 466 is formed in the lower jaw 463 of the connector, and the groove 466 as large as that the upper stopper 417 extending downward from the outer circumferential surface of the upper weighing container A and the measuring container A is operated. Weighing distribution made from synthetic resin as a raw material, characterized in that the connector is formed integrally with a tunnel-shaped discharge guide portion 467 which rises convexly to the lower end of the connector neck with a cylindrical inner diameter and is in direct contact with the inner surface of the neck. Vessel (FIG. 4).  The method of claim 4, wherein An outlet 575 for outflow of contents from a metering container and a storage container formed of a stopper protrusion 517 extending downwardly of the outer circumferential surface and an outlet blocking plate 579 having an eccentric inlet 513 at the bottom of the separate accommodating storage part is provided. The upper end surface 574 of the excitation connector forms a structure in close contact with the inlet blocking plate 579 in which the inlet 513 of the metering container is formed to stabilize the operation when operating with the structure that can open and close the valve by rotation. Weighing made of synthetic resin as a raw material characterized in that the connector made of synthetic resin as a raw material is characterized in that the groove is guided to the stopper 517 of the outer circumferential surface of the measuring container on the outer circumferential surface of the connector Dispensing vessel (Figure 5).  The method of claim 4, wherein A metering container and a stopper protrusion composed of a stopper 677 adjacent to the inlet 613 and an outlet blocking plate 679 having an eccentric inlet 613 formed on the bottom of the separate accommodating storage part are accommodated, and the contents are discharged from the storage container. A metering distribution container made of synthetic resin as a raw material, characterized in that it consists of a connector formed on the uppermost surface of the possible outlet 667 (Fig. 6). The method of claim 4, wherein The inlet 713 is formed at the center of the annular outlet blocking plate at the bottom of the separate metering unit, and the metering vessel having the inner diameter of the annular protrusion 711 larger than the annular protrusion 712 and the inlet blocking plate 782 are formed in the metering container. Two or more ribs 783 may be configured to have a predetermined thickness and have a predetermined thickness so as to block the inlet 781 and extend from the lower surface of the inlet blocking plate to the inner surface of the connector 761. The dispensing container made of synthetic resin as a raw material, characterized in that composed of a connector formed on the top surface of the outlet 784 between the ribs due to the difference in the outer diameter of the inlet blocking plate and the inner diameter of the connector neck (Fig. 7).  The method of claim 7, wherein  A measuring container having an annular protrusion lower portion 891 having a female screw structure extending below the annular protrusion 812 and a male screw portion 890 having a male screw formed on the lower jaw 863 are formed thereon, and an annular guide groove 886 is formed thereon. Is made of a synthetic resin, characterized in that Entered dispensing container (Figure 8). The method of claim 7, wherein   It is characterized by consisting of a connector having a female thread inlet plate (941) with a female thread inlet periphery (941) formed in the inner inlet port and a male thread inlet blocking plate (942) formed a male thread on the outer periphery of the inlet blocker plate. Weighing and dispensing container made of synthetic resin as a raw material (Fig. 9). The method of claim 7, wherein  An inlet blocking protrusion 1031 is formed on the bottom of the rib connecting plate 1039 perpendicular to the bottom, and at least two ribs 1032 are separated from the lower outer periphery of the rib connecting plate 1039, and the storage compartment bottom plate 1033. Inlet 1040 is formed between the ribs and the annular projection 1034 of the insertion portion is formed in the lower portion of the annular projection 1034, the female threaded portion 1035 has a structure having a larger inner diameter than the upper end and Weighing container made of a synthetic resin as a raw material, characterized in that formed in a conical shape consisting of a connector having an outlet 1036 at the end and a male screw portion 1038 on the lower jaw (Fig. 10).