KR100973645B1 - PLUG DEVICE OF VESSEL USING THE CHARACTERISTIC Of VISCOSITY - Google Patents

Abstract

The present invention relates to a closure device for a container using viscosity, which is a physical property of a liquid, and does not leak contents even when the container is inverted due to a user's mistake. In order to develop a stopper that can be used, the basic principle applied here is to take advantage of the physical properties that control the flow of the liquid due to the adhesion generated by the viscosity when the liquid passes through narrow gaps or flow paths. will be.

In the configuration of the present invention, the plug body 30 is inserted into and bound to the neck portion 71 of the container, and the plug body 30 provided with the solution discharge port 32 at the center thereof is combined with the inside of the plug body, and adhesive force is generated by the viscosity of the liquid. The gap plate 40 having the gap and the flow path formed therebetween, and the gap plate to be in close contact with the inner bottom surface of the stopper body, the fixing plate 50 having a through hole through which the solution contained in the container can be introduced To develop a container closure device 60 using viscosity, which is a physical property of a liquid.

Therefore, the closure device having the function of preventing leakage and controlling the discharge amount by the above method can solve the anxiety about the conduction of the container to the user, and prevent the waste due to the excessive discharge.

Stopper, Container, Viscous, Leak, Prevent, Adjust

Description

PLUG DEVICE OF VESSEL USING THE CHARACTERISTIC OF VISCOSITY}

The present invention relates to a container closure device, in particular, even when the container is inverted due to the user's mistake in daily life, the liquid in the container does not leak, while if you want to use the liquid in the container as much as you want It relates to a container closure device using the physical viscosity of the liquid to discharge the amount.

The cap of the container currently being used is a sealing function for simple leakage prevention, or like the container of food products, the shape of the discharge port is changed into a circle or a rhombus to adjust the shape and amount of the contents to be discharged.

More advanced types of stoppers such as spray type, pump type, and dropper type are mainly applied to medicines and cosmetic containers, and the main material used for manufacturing such stoppers is mainly plastics, and is mass-produced by injection molding. This is done.
The cap of a general container having a simple discharge port has a problem in that the contents of the container are leaked due to the impact that the contents of the container fall when falling. I have a burden.
The sealing function has a more obvious form than the above simple shape cap, and spray type and pump type stoppers which are widely applied are composed of a large number of parts (7 to 11) in order to be suitable for the sealing and quantity adjusting functions desired. Due to the high manufacturing cost, the contents of the working components are dried and may cause a breakdown, and the remaining amount in the container may not be completely discharged, or the remaining amount between components may be a waste of resources.
In addition, there is also the inconvenience that the user is not easy to discharge as much as desired.

Therefore, the present invention is to solve the above-mentioned conventional problems, the number of parts is simple, the structure is simple, even when the container is inverted, no leakage, easy to control the discharge amount, the remaining amount in the container almost no waste An object of the present invention is to provide a container closure device using a new concept of viscosity.

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In order to achieve the above object, the present invention uses viscosity, which is a physical property of a liquid. More specifically, when a liquid passes through a narrow flow path or gap, the liquid is formed due to the adhesive force generated by the viscosity of the liquid. The principle of controlling the flow of is to apply to the closure device.
The configuration of the closure device 60 is inserted into the neck portion 71 of the container, the closure and the stopper body 30 is provided with a solution discharge port 32 in the position penetrating the center portion of the upper and lower surfaces of the main body, and It is coupled to the inside of the stopper body, the gap plate 40 and the gap that generates the adhesive force and the gap plate 40 is in close contact with the bottom surface of the gap plate, and serves as a bottom on the gap plate bottom flow path 42 having a cross section and a length By completing the flow path, the through-hole 51 through which the solution in the container is introduced is combined with the fixing plate 50 formed in the center to generate adhesive force in the closure device.
The gap plate is a disc-shaped member, and a central groove 44 having a predetermined depth is formed on the bottom surface of the disc-shaped member, and a plurality of gap plate bottom flow passages 42 extending from the central groove to the end portion of the circumference are formed. A flow path end hole 43 is formed at the end of each of the gap plate bottom flow paths, and a protruding jaw 41 is formed at a predetermined interval on an upper surface of the gap plate.
The protruding jaw is in contact with the bottom surface of the plug body to form the upper plate 46 of the gap plate, and the upper plate of the gap plate is connected to the bottom of the solution discharge port 32 of the plug body.
The degree of adhesive force generated at this time is proportional to the cross section and the length of the upper gap of the gap plate and the bottom plate of the gap plate 42 formed in combination with the inner bottom surface of the plug body 30, and the viscosity of the contents contained in the container. Is also affected.
In addition, in order to discharge the amount desired by the user, the number of gaps and flow paths leading to the solution discharge port 32 should be appropriately set.
In order to simplify the above structure, the plug plate may be omitted and a stopper may be formed on the upper surface of the fixing plate 50 to generate an adhesive force for controlling the flow of the solution. This will be explained in detail later.
Compared with the general closure device, the closure device of the present invention is differentiated by using the viscosity of the contents itself contained in the container without moving parts.

The container closure device using the viscosity characteristics according to the present invention uses the principle that the flow of the liquid is stopped due to the adhesive force generated when the solution contained in the container passes through the narrow gap flow path, on the other hand The external force applied by gravity or the hand acts larger than the adhesive force to control the discharge amount. Therefore, the structural sealing device utilizes the adhesive force of the liquid as a physical property without a separate working part.
The closure device according to the present invention has the following effects.
First, even if the container is inverted due to the user's mistake, the contents are not leaked, and psychological anxiety is solved.
Second, the leak prevention function of the container can prevent safety accidents,
Third, because only the user can discharge as much as possible, the waste caused by excessive discharge is reduced,
Fourth, there is almost no remaining content in the container, so less waste of resources,
Fifth, since there is no use of the operation parts having a separate opening and closing function, the cause of failure is reduced, the reliability of the function is increased,
Sixth, the manufacturing cost is low by minimizing and simplifying the quantity of parts,
Seventh, it has a function to prevent customer's mistakes, thereby improving the reliability and sales promotion of the product.

Hereinafter, a closure device of a container using viscosity, which is a physical property of a liquid, according to the present invention will be described in detail with reference to the accompanying drawings.
1 is a perspective view of the lid and the closure device of the present invention from the container disassembled;
Figure 2a to 2c is a view showing the structure of the closure device according to the invention, Figure 2a is a plan view, Figure 2b is a bottom view, Figure 2c is a sectional view.
3A to 3C show the structure of the gap plate according to the present invention. FIG. 3A is a plan view, FIG. 3B is a bottom view, and FIG. 3C is a sectional view.
4a and 4b are a cross-sectional view and a plan view showing a structure of a fixing plate according to the present invention.
Referring to FIG. 1, the closure device 60 of the container of the present invention is inserted into and bound to the neck portion 71 of the container 70, and the lid 10 is attached to the top of the closure device 60. .
In the stopper body 30 shown in FIG. 2C, a solution discharge port 32 is formed at a position penetrating the center portion of the upper surface and the bottom surface, and a packing portion 31 is formed on the upper portion of the plug body. At the bottom of the fixing plate 50 there is a locking jaw portion 33 for binding.
The configuration of the closure device of the present invention, as shown in Figure 2c, the gap plate 40 is formed in the plug body 30, the gap and the flow path for generating adhesive force, and the gap plate inner bottom surface of the plug body It is combined with the fixed plate 50 of the disc-shaped member having a through-hole 51 in the center so as to be in close contact with the solution contained in the container.
In the above configuration, the gap plate 40 may be omitted, and this case will be described in the embodiment.

In the following description of each component to be combined in the stopper body, the gap plate 40 shown in Figs. 3a to 3c is a disc-shaped member is formed with a central groove 44 of a predetermined depth on the bottom surface, A plurality of gap plate bottom flow passages 42 are formed to generate an adhesive force from the central groove 44 to the end portion of the circumference. The end of each of the gap plate bottom flow passages 42 has a predetermined length into the disc member. The gap plate flow path end hole 43 is formed.

In addition, the projection jaw 41 is disposed on the upper surface of the gap plate 40 at regular intervals, the gap between the gap plate and the bottom surface of the plug body 30 by the projection jaw 41 flows through the solution (2c and 46 in FIG. 3c) are formed and also serve as a flow path.
The gap plate upper flow path 46 is connected to the bottom of the solution discharge port 32 of the plug body 30 at the center of the gap plate 40, so that the solution flowing through the gap plate upper flow path 46 is the solution discharge port 32. It is discharged to the outside through.
When the container is to be conductive or to be used, the solution introduced through the gap plate bottom center groove 44 passes through the gap plate bottom flow path 42 and through the gap plate flow path end hole 43. Go to (46).
At this time, in the solution in the gap and the flow path, the flow of the solution is controlled if the adhesive force in the plug device is greater than the internal pressure, the solution is discharged through the solution discharge port 32 of the plug body when the internal pressure is greater than the adhesive force.
The fixing plate 50 shown in FIGS. 4A and 4B is assembled to the bottom of the gap plate 40 so that the gap plate is brought into close contact with the inner bottom surface of the plug body, and on the gap plate bottom flow path 42 having a cross section and a length. It serves as a bottom surface to complete the flow path, the through hole 51 is formed in the central portion of the fixed plate 50 so that the solution in the container flows into the central groove 44 of the bottom of the gap plate through the through hole of the fixed plate.

In this case, when the lower shape of the fixing plate 50 is concave, it is possible to reduce the remaining amount in the container.
In the structure of the closure device 60 as described above, the degree of adhesive force that controls the flow of liquid varies depending on the shape of the gap plate upper flow path 46 and the gap plate bottom flow path 42, and the solution accommodated in the container. Viscosity also acts as a variable.

In addition, in order to discharge the amount desired by the user, it is necessary to appropriately set the number of gaps and flow paths leading to the solution discharge port.

FIG. 5 illustrates that when a user intends to use the contents in the container 70, when the container 70 is shaken up or down or pressed by hand, the external force applied from the outside is greater than the adhesive force of the solution formed in the stopper device 60. In the case where the container 70 is inverted due to a mistake of the user, the adhesive force is generated along the gap plate bottom flow path 42 formed on the bottom surface of the gap plate 40. The flow of is stopped and the adhesive force acts by the secondary passage upper flow passage 46 to supplement the leak prevention function to double the reliability of the leak can be increased.

In the simple structure of eliminating the gap plate in Figure 2c, it consists of a stopper body 30 and the fixing plate 50 in close contact with the inner bottom surface of the stopper body, the through-hole 51 in the center portion on the fixing plate of Figure 6a and 6b The gap plate 40 is moved eccentrically from the center of the fixing plate, starting from the through hole 55 of the upper surface of the eccentric fixing plate to the position of the solution discharge port 32 on the bottom surface of the stopper body 30. In the same way as the bottom flow channel 42, the fixing plate flow path (56, 57) is generated on the upper surface of the fixing plate 50 in a straight line or curve, the adhesive force is generated by the viscosity of the solution, and the plug body in the same way It can also be formed in the bottom surface of 30.
The closure device according to the above has a leak prevention function and a discharge amount control function while reducing the number of parts, and is suitable for a small capacity container because the adhesive force for controlling the flow of liquid is relatively smaller than that of a gap plate.

The new type of container closure device creates new markets for manufacturers of container closures and plastic injection mold manufacturers.

1 is a perspective view of the lid and the closure device of the present invention disassembled from the container.

Figures 2a to 2c is a plan view, bottom view, cross-sectional view of the closure device according to the present invention.

3A to 3C are plan, bottom and sectional views of the gap plate according to the present invention.

4a and 4b is a cross-sectional view and a plan view showing a structure of a fixing plate according to the present invention.

5 is a view showing a state in which the solution is discharged from the container equipped with the closure device of the present invention.
6a and 6b are views showing an embodiment of the fixed plate flow path.
<Description of the code | symbol about the principal part of drawing>
10: cap 30: stopper body
31 packing part 32 solution outlet
33: engaging jaw 40: gap plate
41: protrusion jaw 42: bottom plate of the gap plate
43: euro end hole 44: the center groove
46: upper flow path of the gap plate
50: fixing plate 51, 55: through hole
56, 57: fixed plate flow path
60: stopper
70: container 71: container neck portion

Claims (6)

The plug body 30 is inserted into and bound to the neck of the container, and has a solution discharge port 32 provided at a position penetrating through the center of the top and bottom surfaces of the main body, and a gap plate mounted inside the plug body 30. 40 and a fixed plate 50 mounted to the bottom of the gap plate 40 and having a through hole 51 formed in the center thereof. The gap plate 40 is a disc-shaped member, which is a bottom of the disc-shaped member. A central depth groove 44 having a predetermined depth is formed on the surface, and a plurality of gap plate bottom flow passages 42 extending from the center groove 44 to the end portion of the circumference are formed, and ends of each of the gap plate bottom flow passages 42 are formed. A flow path end hole (43) is formed in the container closure device using the viscous characteristics formed on the upper surface of the gap plate 40, the projection jaw (41) at a predetermined interval. The method according to claim 1, The stopper body 30 has a discharge port 32 is formed in the upper central portion, the lower end of the discharge port 32 is a container using a viscous characteristic configured to be connected to the through hole 51 formed in the central portion on the fixed plate 50 Stopper. delete The method according to claim 1, In the simple structure to omit the gap plate 40, it consists of a stopper body 30 and the fixing plate 50 in close contact with the inner bottom surface of the stopper body, the through hole 51 in the center portion on the fixing plate 50 Eccentrically moves from the center of the fixed plate to a certain point, the adhesive force is generated by the viscosity of the solution starting from the through hole 55 of the upper surface of the eccentric fixing plate to the position of the solution outlet 32 of the bottom surface of the plug body 30 The container closure device using the viscosity characteristics formed in the contact surface between the upper surface of the fixing plate 50 and the bottom surface of the closure body 30. delete The method according to claim 1, The protruding jaw 41 is in contact with the bottom surface of the plug body 30 to form the upper plate 46 of the gap plate, the central portion of the upper plate 46 of the gap plate discharge port formed in the center of the plug body 30 (32) Container closures using viscous properties adapted to be connected to the bottom.

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