KR100593246B1 - Bottle - Google Patents

Abstract

The present invention relates to a container in which two different kinds of materials are isolated and accommodated in one body, and the two spaces are mixed and usable by mutually communicating the isolated spaces as needed. The container body 100 having the 110 formed therein, the insertion portion 220 coupled to the inside of the injection hole 110, and the exposed portion 230 exposed to the outside, both sides are open to the additive receiving space 202 inside The additive storage member 200 and the injection port 110 to form a screw threaded to the male screw 112 and the additive receiving space 202 is selectively isolated or communicated with the contents receiving space 102 of the container body 100 By providing a container including a cap 300 and the additive storage member separating means for separating the additive storage member 200 from the injection port 110, the material to be mixed should be stored in different independent storage containers Hey Eliminate the hassle of waste, further reduce the waste of resources, it is possible to accurately measure and mix a certain amount at all times, thereby stabilizing the chemical and physical properties after mixing.

Container, inlet, cap, additive storage member, valve member

Description

Courage {BOTTLE}             

1 is an exploded perspective view showing a configuration of a first embodiment of a container according to the present invention.

2a to 2d are sectional views showing the operating state of the first embodiment of the container according to the present invention;

Figure 3 is a partially enlarged cross-sectional view showing an example of forming the inlet of the container body.

4 is a cross-sectional view showing a configuration of the second embodiment of the container according to the present invention.

Fig. 5 is a cross sectional view showing a configuration of the third embodiment of the container according to the present invention.

6 is a cross-sectional view of a bonded state showing the constitution of a fourth embodiment of a container according to the present invention.

7A and 7B are cross-sectional views in combination showing the construction and operation of a fifth embodiment of a container according to the present invention.

8A and 8B are cross-sectional views in combination showing the construction and operation of a fifth embodiment of a container according to the present invention;

* Description of the symbols for the main parts of the drawings *

100: container body 102: contents receiving space

110: inlet 112: male thread

114: jamming jaw 116: jamming projection

200: additive storage member 202: additive receiving space

210: lifting jaw 222: locking groove

232: communication hole 234: step

236: first seal groove 300: cap

310: outer wall 312: female thread

314: external injection hole 320: sealing

322: second seal groove 330: inner wall

332: internal injection hole

The present invention relates to a container, and more particularly, to a container in which two different materials are sequestered in one body and, if necessary, the two spaces are mixed and usable by communicating with each other in an isolated space. .

Currently, most containers in the market are distributed and sold, with only one substance stored in one container. However, there is a need to use a mixture of two different materials throughout the industry. For example, in the case of coffee beverages, it is possible to mix sugar or cream powder in the coffee beverage, and in the case of medicines or chemicals, such an example may be given.

However, in the past, when a mixture of two different materials is used, it is cumbersome to separately purchase a container containing each material, and in particular, a metering device is additionally required for accurate weighing when mixing. Without the mechanism, it was difficult to maintain the correct mix ratio.

Therefore, the present invention is proposed to solve the above problems of the prior art, the purpose of which is to separate and distribute the two materials to be mixed in one container, the container that can prevent the waste of resources by making two containers In providing.

Another object of the present invention is to provide a container capable of mixing any two materials in an accurate mixing ratio with simple operation in use.

Still another object of the present invention is to provide a container that can maintain a good airtight inside the receiving space for accommodating the additives to protect the additives from oxidation and decay, and to be compatible with the inlet of a common bottle. have.

The purpose of the present invention is to store the additives formed on the outer periphery of the container body is formed with an injection hole is formed in the outer periphery, the insertion portion coupled to the inside of the injection hole, the exposed portion exposed to the outside to open the both sides to form an additive receiving space inside By a container including a member, a cap screwed to a male screw in the inlet, and selectively separating or communicating the additive receiving space with the contents receiving space of the container body, and an additive storage member separating means for separating the additive storage member from the inlet. Can be achieved.

The additive storage member separating means forms a lifting jaw protruding radially outward at the center of the outer circumference of the additive storage member, and is configured to interfere with the female screw formed on the inner circumference of the cap in the axial direction.

The additive storage member separating means is composed of a connecting shaft extending from the support shaft and a lifting plate integrally formed at the end of the connecting shaft to interfere with the end of the insertion portion in the axial direction.

A valve seat protruding radially inwardly is formed at the end of the insert of the additive storage member, and a support shaft protruding in the axial direction at the center of the cap, and coupled to the end of the support shaft to contact the valve seat to provide an additive receiving space. It is configured to be isolated from the contents receiving space of the main body.

The inner side of the cap is formed a cylindrical inner wall projecting in the axial direction spaced apart from the outer wall in a predetermined distance, the outer peripheral surface of the inner wall and the inner peripheral surface of the exposed portion is configured to be in surface contact.
The inner side of the cap is formed a cylindrical inner wall projecting in the axial direction spaced apart from the outer wall in a predetermined distance, the outer peripheral surface of the inner wall and the inner peripheral surface of the exposed portion is configured to be in surface contact.
The outer and inner injection holes are formed on the outer wall and the inner wall of the cap, respectively, on the coaxial shaft, and the exposed part of the additive storage member has a communication hole for communicating the outer injection hole and the inner injection hole at a predetermined position when the cap rotates. do.

delete

The communication hole is configured in the form of a long hole to maintain the communication state of the outer injection hole and the inner injection hole more than a predetermined angle during the rotation of the cap.

A step is formed in the inner circumference of the exposed portion of the additive storage member, and the first seal groove is formed in the step so that the inner wall end of the cap can be inserted in a predetermined depth in the axial direction.

The outer side of the inner wall is further formed with a second seal groove so that the end portion of the exposed portion can be inserted in a predetermined depth in the axial direction.

The injection port is composed of a double injection molding the injection port member separately and molded integrally with the inlet of the container body.

The present invention also has a container body having an injection hole in which an annular stopper protrudes on the outer circumference, an insertion portion coupled to the inside of the injection hole, and an exposed portion exposed to the outside, both sides of which are open to form an additive receiving space therein. An additive storage member, and a hook is formed at the front end coupled to the stopper of the inlet, it can be achieved by a container consisting of a cap for selectively separating or communicating the additive receiving space with the contents receiving space of the container body. Such a configuration can be effectively applied to a flask and a container which is not threaded into an inlet such as a test tube or a wine bottle.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2a to 2d show a view of a first embodiment of a container according to the invention. FIG. 1 is an exploded perspective view, and FIGS. 2A to 2D show an operating state. According to the present invention, the container body 100 having the injection hole 110 and the additive storage member 200 and the injection hole 110 are coupled to the inside of the injection hole 110 and provide the additive receiving space 102. The screw 300 is coupled to the additive storage member 200 and is composed of a cap 300 for sealing the additive receiving space 202.

A male screw 112 is formed at an outer circumference of the injection hole 110, and a locking jaw 114 protrudes radially outward from a lower end thereof. In addition, the inner periphery of the injection hole 110 is formed with a spiral locking projection 116 protruding radially outward.

The additive storage member 200 is configured as an open cylindrical shape on both sides, the ring-shaped lifting jaw 210 is protruded integrally in the radially outer side in the axial center portion of the outer circumference. The lifting jaw 210 is preferably configured to be inclined to have an inclination corresponding to the inclination of the male screw 112. In addition, the additive storage member 200 is composed of the insertion portion 220 is inserted into the inlet 110 of the container body 100, one side of the lifting jaw 210, the opposite side is the outer side of the inlet 110 The exposed portion 230 is configured to. The lifting jaw 210 corresponds to the exposed part. The outer periphery of the insertion portion 220 is coupled to the spiral locking projection 116 is formed a spiral locking groove 222 to limit the axial movement of the additive storage member 200, the exposed portion 230 is in communication A ball 232 is formed. In addition, the valve seat 224 is formed integrally with the end portion of the insertion portion 220 protruding radially inward to form the discharge hole 234 in the center portion.

The cap 300 is configured to have a cylindrical shape in which one side is opened and the other side is hermetically sealed. The cap 300 includes a cylindrical outer wall 310 and a sealing part 320 for sealing one side of the outer wall. A female thread 312 screwed to the male screw 112 of the injection hole 110 is formed at the inner circumference of the open end, and is selectively detachable to the container body. A support shaft 340 protruding in the axial direction is integrally formed at the center of the sealing part 320, and the discharge hole 234 is selectively opened by contacting the valve seat 224 at the end of the support shaft 340. The valve member 342 is fixed. The valve member 342 is composed of a soft material and is compressed when pressure is applied even in contact with the valve seat 224 and is configured to be in close contact with the valve seat. This is effective to have a good sealing effect. In addition, a cylindrical inner wall 330 protruding axially at a position spaced inwardly from the outer wall 310 by the sealing portion 320 side of the cap 300 is configured integrally. The inner wall 330 is configured to fit the inner diameter of the exposed portion 230 of the additive storage member 200. As for the outer diameter of the inner wall 330, it is preferable to make the fitting tolerance with respect to the inner diameter of the exposure part 230 to maintain good sealing performance. In addition, an outer injection hole 314 and an inner injection hole 332 are formed in the outer wall 310 and the inner wall 330 so as to be coaxially disposed with each other. Each of the external injection hole 314 and the internal injection hole 332 is formed to be in communication with the communication hole 232 at a predetermined position when the additive storage member 200 is released from the injection port 110. Preferably, the injection holes 314 and 332 and the communication holes 232 are arranged in a straight line with the cap 300 uncoiled a predetermined distance from the injection hole. The communication hole 232 of the additive storage member 200 is configured in the form of a long hole along the direction of the screw thread is preferably configured to maintain a state of continuous communication over a certain angle during the rotation of the cap 300.

According to the present invention, the spiral locking projection 116 and the locking groove 222 has a function for limiting the axial movement of the additive storage member 200 and the function of the seal but as an additional component that is not an essential component. It must be understood. That is, when the content is a material that creates a predetermined pressure in the receiving space, it is limitedly selected when the stopping force against the axial movement of the additive storage member 200 is required.

The operating state of the container according to the present invention will be described. (Herein, 'contents' refers to a material contained in the container body 100, and 'additives' refers to a material contained in the additive storage member 200.) First, a closed state in FIG. The initial state of the product is shown. According to this, the contents are accommodated in the hermetic contents receiving space 102, and the additive receiving space 202 is stored in a state where the additives are also isolated from the contents containing space. The additive storage space 202 is sealed by the inner wall 330, the additive storage member 200, the valve member 342, and the valve seat 224. At this time, the outer injection hole 314 and the inner injection hole 332 are shifted from each other in the state entering the container body 100 side more than the communication hole 232, so that the space in the additive storage member 200 to maintain a closed state do. In addition, it is fitted to the inner wall of the exposed end 230 of the additive storage member 200 of the inner wall 330 of the cap 300, the lifting jaw 210 is in close contact with the inner surface of the outer wall 310 of the cap 300. Since the additive receiving space 202 maintains a good sealing state.

In this state, when the cap 300 is rotated in the opening direction (counterclockwise direction), as shown in FIG. 2B, the valve member 342 rises and a gap is generated between the valve seat 224 and the additive. It is introduced into the container body 100 and mixed with the contents. At this time, as the cap 300 rotates, the outer injection hole 314 and the inner injection hole 332 rotate in a spiral and coincide with the communication hole 232 of the additive storage member 200 at a predetermined position so that the atmospheric pressure is increased. It acts as the additive receiving space 202 and the addition of the additives is made smoothly. In the state shown in Figure 2b, the outer injection hole 314 and the inner injection hole 332 and the communication hole 232 is shown in a state in which the discharge hole 234 is opened slightly in the coaxial state, the actual discharge The hole 234 is the angle at which the outer injection hole 314 and the inner injection hole 332 and the communication hole 232 is located coaxially maintains a predetermined angle range. At this time, in the initial phase that starts to match, the discharge hole 234 is kept in a closed state, and the opening of the discharge hole 234 is started as a ratio after a predetermined angle. The necessity follows from the description of FIG. 2C.

Subsequently, when the cap 300 is rotated counterclockwise, the female screw 312 is caught by the lifting jaw 210 of the additive storage member 200, as shown in FIG. 2C, and the cap 300 rotates from this time. The silver additive storage member 200 exerts a force that rotates in the axial direction, and the additive storage member 200 is separated from the injection hole 110 in which the spiral locking groove 222 is separated from the spiral locking protrusion 116.

On the other hand, the present invention has been described in the above description about the state in which the additive is accommodated at the time of shipment of the product. However, the present invention can be used by injecting the additive in the receiving space required by the user in the product is shipped in the empty state of the additive receiving space.

That is, the present invention rotates the cap 300 in the counterclockwise direction, the outer injection hole 314 and the position immediately before the position of Figure 2b, that is, the position before the valve member 342 is formed between the valve seat 224 The inner injection hole 332 starts to coincide with the communication hole 232. This is possible because the communication hole 232 is formed in the long hole shape is configured to maintain the state of communicating the external injection hole 314 and the internal injection hole 332 for a certain angle during the rotation of the cap 300. . Therefore, when the user injects the desired amount of additives in the above state, the additives are kept in the storage space 202 in the additive storage member 200 without being introduced into the container body 100. In this state, when the cap 300 is tightened in the clockwise direction, the valve member 342 is more tightly adhered to the valve seat 224 to be in the initial state of shipment of the product. In the same manner as the operation is introduced into the container body (100).

Figure 3 shows a molding example for the inlet of the container body according to the present invention. The injection port of the container body 100 is formed of a double injection structure for separately forming the injection hole member 120 and assembling it to the inlet of the container body 100 in order to effectively configure the spiral locking projection 116 of the injection hole 110. It is preferable to be.

In figure 4 a second embodiment of a container according to the invention is shown. It discloses a means that can be replaced with the lifting jaw for the interaction of the cap 300 and the additive storage member 200. According to this, one side is coupled to the support shaft 340 and the connecting shaft 350 extending in the axial direction from the support shaft 340 and the disk-shaped lifting plate 352 is integrally formed at the end of the connecting shaft 350. . The upper surface of the elevating plate 352 is in close contact with the bottom of the additive storage member 200, the opening hole 354 is formed so as not to restrict the addition of the additive in the receiving space 202 into the container body 100. .

In the operation of the second embodiment, when the cap 300 is rotated counterclockwise, the lifting plate 252 touches the bottom surface of the additive storage member 200 at a predetermined position, and the cap 300 continues from this point. When rotated counterclockwise, the rotational force of the cap moves the additive storage member 200 in the axial direction, and the locking groove 222 is separated from the locking protrusion 116 so that the additive storage member 200 is removed from the injection hole 110. Are separated. In this second embodiment, the lifting jaw is not required on the outside of the additive storage member 200 as in the first embodiment. In other words, the lifting jaw can be present in a softer ring shape to serve as a sealing function.

5 shows the construction of a third embodiment of a container according to the invention. This discloses a structure for maintaining the seal structure of the cap 300 and the additive storage member 200 more closely. To this end, a step 234 is formed on the inner circumference of the exposed portion of the additive storage member 200. A first seal groove 236 is formed in the step 234 so that the end of the inner wall 330 of the cap 300 can be inserted at a predetermined depth in the axial direction. In addition, a second seal groove 322 is formed at an outer side of the inner wall 330 so that the end portion of the exposed portion 230 can be inserted at a predetermined depth in the axial direction.

The additive storage member 200 is coated with a soft material such as elastic and elastic silicone, non-toxic rubber, non-toxic PVC, it is possible to implement an effective sealing by coupling to the inner wall 330. This can effectively limit the leakage of gas when the additive inside the receiving space 202 is a gas-containing material such as a carbonated beverage.

6 shows a configuration of a fourth embodiment of the present invention. This discloses an embodiment in which the container of the present invention is applied to a container in which a screw is not formed outside the injection port such as a flask, a test tube, a wine bottle, or cans. According to this, a ring-shaped stopper 412 protruding radially outward is formed at the outer circumference of the injection hole 410.

Since the additive storage member 200 is the same configuration as the first embodiment of the present invention, the detailed description thereof will be omitted and the same reference numerals are used. A step 234 is formed at an inner circumference of the exposed portion 230 of the storage member 200. A first seal groove 236 is formed in the step 234 so that the end of the inner wall 530 of the cap 500 can be inserted at a predetermined depth in the axial direction.

The cap 500 is configured to have a cylindrical shape in which one side is opened and the other side is hermetically sealed. The cap 500 includes a cylindrical outer wall 510 and a sealing part 520 for sealing one side of the outer wall. The hook 512 which is caught by the stopper 412 of the injection hole 410 is formed at the inner circumference of the open end. The sealing portion 520 side of the cap 500 is integrally formed with a cylindrical inner wall 530 protruding in the axial direction at a position spaced inward from the outer wall 510 by a predetermined distance. The inner wall 530 is configured to fit the inner diameter of the exposed portion 230 of the additive storage member 200. The second sealing groove 322 is formed in the sealing part 520 of the outer side of the inner wall 530 so that the end portion of the exposed portion 230 can be inserted at a predetermined depth in the axial direction. In addition, an outer injection hole 514 and an inner injection hole 532 are formed in the outer wall 510 and the inner wall 530, respectively. Each of the outer injection hole 514 and the inner injection hole 532 is formed to be in communication with the communication hole 232 of the additive storage member 200 in a predetermined position. Preferably, the cap 500 is configured such that the respective injection holes lie in a straight line with the cap 500 moved outward from the injection hole by a predetermined distance. In addition, the grip portion 524 is formed on the closed end side to extend radially outward to facilitate separation in the axial direction.

In this fourth embodiment, when the gripping portion 524 is pulled in the axial direction, the hook 512 is separated from the stopper 412, and when the predetermined distance moves, the hook 512 is caught by the stopper 412. Is separated from the inlet 410. In the process, the additive W2 in the additive accommodating space 202 is introduced into the contents accommodating space 402 of the container body 400 by the same operation as in the first embodiment. Thus, this fourth embodiment can be effectively applied to containers which are not provided with screws at the periphery of the above-mentioned inlet.

7a and 7b disclose a diagram of a fifth embodiment of a container according to the present invention. Here, the example which comprised this invention on the bottom face of a container is disclosed.

According to this, the communication hole 622 is formed in the lower wall 620 of the container body 600, extending from the lower wall 620 to the bottom and the extension wall 610 is formed with a locking groove 612 on the outer periphery This is composed integrally. In addition, the one side is formed of a cylindrical opening includes an additive storage member 700 is slidably inserted into the extension wall 610. A support shaft 716 protruding in the axial direction is formed in the center of the additive storage member 700, and a valve member 718 for selectively opening and closing the communication hole 622 is fixed to the support shaft 716 end. . A male screw 712 is formed outside the cylindrical portion 710 of the additive storage member 700. On the outside of the additive storage member 700 is a cylindrical operating member 800 is open one side. The operation member 800 is formed at the open end with a locking step 812 is caught in the locking groove 612 of the extension wall 610. In addition, a female screw 814 is formed on the inner surface of the operating member 800 to screw the male screw 712 of the additive storage member 700. A sealing member 830 is interposed between the locking groove 612 and the locking jaw 812 to prevent leakage of the contents. In addition, the lower end of the extension wall 610 and the inside of the cylindrical portion 810, it is preferable to provide a long bending path by placing the bent contact portion 714 to be mutually fitted in the axial direction.

In the fifth embodiment of the present invention, the valve member 718 blocks the communication hole 622 because the additive storage member 700 is in a raised position with reference to the drawings as shown in FIG. Therefore, the additive receiving space 702 and the contents receiving space 602 are kept insulated from each other, and when the operating member 800 rotates, the female screw 814 and the male screw 712 interact. That is, the additive storage member 700 is lowered by the rotation of the female screw 814. Accordingly, since the communication hole 622 is opened, the contents accommodation space 602 and the additive accommodation space 702 are able to communicate with each other. In this state, the user can mix the contents and the additives in both spaces by inverting or shaking the container body 600 up and down. In this embodiment, by placing the additive storage member in the lower portion of the container, it can be easily applied when a larger amount of additives is required.

8A and 8B show the configuration of the sixth embodiment of the present invention. In this embodiment, the additive receiving space is provided so that two kinds of additives can be used. The same configuration as that of the first embodiment of the present invention is omitted in the description and the same reference numerals. According to this, the container body 100 having an injection hole 110, the male thread 112 is formed on the outer periphery, the additive storage member 900 is pressed into the injection hole 110 and forms an additive receiving space, The cap 940 is screwed to the inlet 110 and interlocked with the additive storage member 200 to seal the additive receiving space and partition the interior into two separate additive receiving spaces 902 and 904. Consists of.

The additive storage member 900 is configured to have an open cylindrical side, and the ring-shaped lifting jaw 910 protruding radially outward is integrally formed at the outer circumference of the central portion. A communication hole 912 is formed at the open end of the additive storage member 900, and a plurality of discharge holes 914 are formed around the lower end of the additive storage member 900. In addition, the bottom surface 916 of the additive storage member 900 is configured such that the central portion is convex so that the additive can be smoothly introduced into the contents receiving space (102). In addition, the bottom surface 916 is configured to effectively seal the additive receiving space by installing the seal member 918 at a portion where the lower end of the inner wall 970 and the separation wall 980 to be described later, respectively.

The cap 940 includes a cylindrical outer wall 960 whose one side is open and the other side is closed by the sealing part 950. The seal 950 has a seal groove 952 into which the upper end of the additive storage member 900 is inserted. A female screw 964 screwed to the male screw 112 of the injection hole 110 is formed at an inner circumference of the open end of the outer wall 960, and a separation wall protruding axially in the center of the sealing part 950 ( 970 is integrally formed, and a cylindrical inner wall 970 is integrally formed on the sealing part 950 side of the cap 940 at a position spaced inwardly from the outer wall 960 by an axial direction. The inner wall 970 fits axially movable in the additive storage member 200. In addition, an outer injection hole 962 and an inner injection hole 972 are formed in the outer wall 960 and the inner wall 970, respectively. The configuration and operation of the outer injection hole 962 and the inner injection hole 972 and the communication hole 912 is the same as the first embodiment of the present invention.

In the sixth embodiment of the present invention having such a configuration, as shown in FIG. 7A, different types of materials, such as sugar and cream powder, may be separated and stored by the separating wall 980, and may be stored. Rotating the cap 940 raises the inner wall 970 and opens the discharge hole 914 as shown in FIG. 7B, so that the additives in each of the receiving spaces 902 and 904 enter the contents receiving space 102. do. At this time, since the bottom surface is curved and protruded, the addition proceeds smoothly by its own weight. In addition, when the cap is further rotated, as in the first embodiment of the present invention, the female screw 112 interferes with the lifting jaw 910 and separates the additive storage member 900 from the injection hole 110.

In this sixth embodiment, two different types of additives can be effectively stored and mixed when needed. Furthermore, the part accommodating space can be modified by appropriately designing the discharge hole 914 and the dividing wall 980. The compartments can be divided into three or more spaces, so they can be effectively used even when several kinds of mixtures are required.

The present invention is not limited thereto but includes all the ranges expected by the change and addition within the scope without departing from the technical spirit of the present invention. For example, it can be expected to configure the additive receiving space in the center of the container body, and furthermore, it can also be expected to connect two or more of the above configuration in succession.

As described above, the present invention is capable of storing and distributing two different materials in one container to be distributed and easily mixing the two materials by communicating a space separated by a predetermined operation during use. It becomes usable. Therefore, the two materials that need to be mixed with each other should be stored in separate storage containers to reduce the hassle and waste of resources, and improve the reliability of the product by increasing the freshness in actual use (when tasting in the case of beverage). It also provides benefits. In other words, it prevents a change in physical properties due to long-term elapsed in the pre-mixed state.                     

In addition, since it is possible to accurately measure and mix a certain amount at all times, it is possible to stably provide the conventional chemical and physical properties due to poor mixing ratio, and to maintain good product properties.

Claims (19)

The container body 100 is formed with an injection hole 110 is formed on the outer periphery, An additive storage member 200 having an insertion part 220 coupled to the inside of the injection hole 110, an exposure part 230 exposed to the outside, and both sides of which are open to form an additive receiving space 202 therein; A cap 300 screwed to the male screw 112 of the inlet 110 to selectively isolate or communicate the additive receiving space 202 with the contents receiving space 102 of the container body 100; Container containing an additive storage member separating means for separating the additive storage member 200 from the injection port (110). The method of claim 1, wherein the additive storage member separating means, The lifting jaw 210 is formed to protrude radially outward at the center of the outer periphery of the additive storage member 200, and is configured to interfere with the female screw 312 formed at the inner periphery of the cap 300 in the axial direction. Courage to do. The method of claim 1, wherein the additive storage member separating means, The lifting shaft 340 is integrally formed at the end of the connecting shaft 350 and the connecting shaft 350 extending from the support shaft 340 and interfering in the axial direction with the end of the insertion portion 220 is characterized in that Courage to do. The valve seat 224 according to any one of claims 1 to 3, wherein an end portion of the insertion portion 220 of the additive storage member 200 protrudes radially inward and a discharge hole 234 is formed at the center thereof. And a support shaft 340 protruding in the axial direction in the center of the cap 300 and the end of the support shaft 340 to close the discharge hole 234 to open the additive receiving space 202. Container, characterized in that the valve member (342) is isolated from the contents receiving space (102) of the container body (100) is fixed. The inner side of the cap 300 is formed with a cylindrical inner wall 330 protruding in the axial direction spaced in a predetermined distance from the outer wall 310, the outer peripheral surface of the inner wall 330 and the exposed portion ( A container, the inner circumferential surface of which is configured to be movable in surface contact. According to claim 5, The outer wall 310 and the inner wall 330 of the cap 300 is formed with an outer injection hole 314 and the inner injection hole 332 coaxially, respectively, of the additive storage member 200 The exposed portion 230 is a container, characterized in that the communication hole (232) for communicating the outer injection hole (314) and the inner injection hole (332) is formed at a predetermined position when the cap 300 is rotated. The container according to claim 6, wherein the communication hole (232) is configured in a long hole shape so as to maintain a communication state between the external injection hole (314) and the internal injection hole (332) by a predetermined angle or more when the cap is rotated. According to claim 5, wherein the step 234 is formed on the inner circumference of the exposed portion of the additive storage member 200, the end of the inner wall 330 of the cap 300 is inserted into the step 234 to a predetermined depth in the axial direction The container characterized in that the first seal groove (236) is formed to be. The container according to claim 8, wherein a second seal groove (322) is further formed on an outer side of the inner wall (330) so that an end portion of the exposed portion (230) can be inserted at a predetermined depth in the axial direction. The container according to claim 1, wherein the injection hole (110) is formed by double injection molding the injection hole member (120) separately and integrally molding the injection hole member (120) at the inlet of the container body (100). A container body 400 having an injection hole 410 in which a ring stopper 412 of the outer periphery is protruded; An additive storage member 200 having an insertion part 220 coupled to the inside of the injection hole 410, an exposure part 230 exposed to the outside, and both sides of which are open to form an additive receiving space 202 therein; A hook 512 coupled to the stopper 412 of the injection hole 410 is formed at the tip, and a cap for selectively separating or communicating the additive receiving space 202 with the contents receiving space 402 of the container body 400. A container consisting of 500. 12. The container as claimed in claim 11, wherein the closed end (520) of the cap (500) is formed with a gripping portion (524) extending radially outward. An injection hole is formed in the upper portion, and a communication hole 622 is formed in the sealed lower wall 620, and extends downward from the lower wall 620, and an extension wall 610 in which a locking groove 612 is formed at an outer circumference thereof. The container body 600 is formed integrally with this, An additive storage member including a male screw 710 formed on an outer circumference of the cylindrical body having one side open, a slidably inserted into the extension wall 610, and a valve member 718 opening and closing the communication hole 622. 700), Wrapping the outer side of the additive storage member 700 and rotatably coupled to the container body 600, the container consisting of an operating member 800 for moving the additive storage member 700 in the axial direction during rotation. The method of claim 13, wherein the operation member 800 is formed in the open end locking jaw 812 rotatably coupled to the locking groove 612 of the extension wall 610, the additive storage member on the inner side Containers, characterized in that configured to move the additive storage member 700 in the axial direction by screwing with the male screw (712) of (700). An injection hole 110 having a male thread 112 formed on an outer circumference thereof, and having a container body 100 having a contents receiving space 102 therein; An additive storage member having a plurality of additive receiving spaces 902 and 904 fitted into the injection hole 110 and having a lifting jaw 910 formed at an outer circumference thereof and selectively communicating with the contents receiving space 102 therein ( 900), Two isolations of the outer wall 960 screwed to the female screw 112 of the injection hole 110, the inner wall 970 fitted to the additive storage member 200, and the additive receiving spaces 902 and 904. A container consisting of a cap 940 integrally formed with a partition wall 980 partitioning into spaces. The method of claim 15, A plurality of discharge holes 914 is formed around the lower end of the additive storage member 900, the bottom surface 916 of the additive storage member 900, characterized in that configured to protrude gradually toward the center. The method of claim 16, The bottom surface (916), characterized in that the sealing member (918) is installed in the portion where the lower end of the inner wall (970) and the separation wall (980), respectively. The method of claim 17, The seal portion 950 is a container, characterized in that the seal groove (952) is formed is inserted into the top of the additive storage member (900). The method of claim 18, The outer injection hole 962 and the inner injection hole 972 are respectively formed in the outer wall 960 and the inner wall 970 so as to correspond to the respective additive receiving spaces 902 and 904, respectively. The outer injection hole 962 and the inner injection hole 972 of the container which is disposed coaxially with each other at a predetermined position to communicate the additive receiving space (902) (904) with the outside air.

Images