KR200281525Y1 - Pumping plant of cosmetic case - Google Patents

Abstract

The present invention relates to a pumping device of a cosmetic container is installed in the opening of the cosmetic container to discharge the contents by a predetermined amount by the pumping operation by the pressing operation, and more specifically to the sealing structure of the piston valve reciprocating in the cylinder It improves the discharge efficiency by placing the discharge passage of the contents on the outer periphery of the piston rod while increasing the suction power of the contents, and also prevents the epocket phenomenon that the pressure generated inside the cylinder flows into the container when the pump is operated. This is to improve the pumping efficiency of the vacuum pump.

It is installed in the nozzle cap screwed to the inlet of the cosmetic container is pumping device of the container to discharge the contents of the container by a predetermined amount to the outside by the pressing operation, provided in the upper portion of the nozzle cap (20) Actuated, the fluid passage tube 31 is integrally formed at the center of the lower and at the same time having one side of the nozzle 33 is in communication with the fluid passage tube 31 while being supported by the return spring (40) 30); The suction port 51 which is fastened to the lower portion of the nozzle cap 20 and has a compression chamber 52 and an operating chamber 53 having different diameters therein and is in communication with a container at the lower portion of the operating chamber 53 is formed. And the upper part of the operating chamber 53 and the cylinder 50, the locking projection 54 is formed to protrude; The upper guide tube 73 is fastened to the fluid passage tube 31 of the operation button 30 in a force-fitting manner, and the gap maintaining protrusion 74 is radially formed on the outer circumference of the guide tube 73 to form a cylinder ( A piston 70 which is operated up and down within 50; A piston valve 80 for inserting and fastening a center hole 82 into the piston 70 to compress the compression chamber 52 in the cylinder 50 by the lifting operation thereof; The rod 63 of the upper portion is coupled to the guide tube 73 of the piston 70 while the intake port 51 is coupled to the operating chamber 53 in the cylinder 50 and the stroke distance is limited by the locking jaw 62. Shaft valve 60 to open and close the; will be configured.

Description

Pumping plant of cosmetic case

The present invention relates to a pumping device of a cosmetic container is installed in the opening of the cosmetic container to discharge the contents by a predetermined amount by the pumping operation by the pressing operation, and more specifically to the sealing structure of the piston valve reciprocating in the cylinder It improves the discharge efficiency by placing the discharge passage of the contents on the outer periphery of the piston rod while increasing the suction power of the contents, and also prevents the epocket phenomenon that the pressure generated inside the cylinder flows into the container when the pump is operated. This is to improve the pumping efficiency of the vacuum pump.

Generally, a cosmetic container for storing various cosmetics in a liquid or gel state is equipped with a pressure pumping means for smoothly discharging the contents to the outside during use.

The pressurized pumping means have been proposed and widely used in various structures up to now, and their alternative principle is that when the user presses the operation button with a finger, the pressure inside the container is pumped by the pressing force generated by its operation, and the external volume is discharged by a certain amount through the nozzle. To be discharged.

Looking at the pumping apparatus of the conventionally proposed cosmetic container as an example, it may be a utility model registration No. 187929 as shown in Figure 1 of the accompanying drawings.

The nozzle cap 2 is mounted on the inlet side of the container 1, and at the same time, an operation button 4 having a nozzle 3 is installed at the nozzle cap 2, and the operation is lifted by a pressing operation. Plunger 8 is coupled to the lower portion of the fluid passage pipe 5 is connected to the elastic spring is elastically supported by the return spring (6) to discharge the contents to the nozzle (3) through the orifice (7), The outer diameter of (8) is fitted with a valve 10 which is tightly coupled to the inner diameter of the cylinder (9) and is operated up and down, and a ball valve (11) for opening and closing it is provided at the inlet (9a) of the cylinder (9). .

In addition, the flange 12 is formed in the lower portion of the return spring 6 to facilitate the opening and closing operation of the ball valve 11 and the flange 12 is a ball valve 11 by another spring (13) It is configured to be combined with).

Accordingly, the plunger 8 connected by the fluid passage pipe 5 moves downward while compressing the return spring 6 in response to the pressing of the operation button 4, and the contents in the cylinder 9 are closed by the pressing force thereof. It is discharged to the nozzle 3 side through the orifice 7 between the 10 and the plunger 8.

At this time, the ball valve 11 is in a state in which the inlet port 9a is closed by the pressure in the cylinder 9 and the spring 13.

On the contrary, when the operation button 4 is released, the plunger 8, the fluid passage tube 5, the operation button 4, etc. are raised by the return force of the return spring 6, and the cylinder ( As the vacuum pressure is generated in 9), the ball valve 11 opens the suction port 9a, so that the contents in the container 1 flow into the empty space in the cylinder 9 to await discharge.

However, in such a conventional structure, there are various problems as follows.

First, when the ball valve 11 opens and closes the suction port 9a connected to the container 1, or in a gel state in which the viscosity of the content is relatively high, the content is distributed around the suction port 9a. There is a problem that 11 does not open and close the suction port 9a smoothly.

That is, the ball valve 11 does not immediately block the inlet port 9a due to the high viscosity content at the time of compression due to the lowering of the plunger 8, and internally generated pressure flows into the container 1 through the inlet port 9a. By doing so, there is a problem in which air pockets, in which air flows, are generated inside the container 1.

This air pocket phenomenon has become a major factor that hinders the pumping function of the contents.

In addition, in addition to the above problems, the sealing structure of the valve 10 for elevating operation in the cylinder 9 to generate a vacuum pressure is not good, that is, the valve 10 is simply in close contact with the inner diameter of the cylinder 9, and elevating operation. Since the sealing structure is a strong vacuum pressure is not applied to the cylinder 9, there is a problem that the pumping efficiency is lowered.

In particular, when the elasticity of the valve 10 is slightly lost due to the simple structure, there is a disadvantage in that the pumping efficiency is significantly reduced due to poor airtightness due to sealing.

Furthermore, the discharged contents pass between the valve 10 and the plunger 8, enter the inside of the plunger 8 through the orifice 7 perforated on the side of the plunger 8, and then through the nozzle 3. As it is discharged to the outside, that is, discharged through the labyrinth fluid passage, a large load is applied, and there is a disadvantage that smooth discharge is not achieved.

Therefore, the present invention has been made in consideration of the conventional problems as described above, and its purpose is to improve the sealing of the valve operated in the cylinder to prevent the leakage of pressure during the pumping operation, as well as to generate a strong vacuum pressure in the cylinder. To improve the suction power of the contents, and to improve the discharge efficiency by forming the discharge path of the contents between the outer circumference of the piston and the fluid passage pipe to achieve a flexible discharge, and to provide the inlet of the cylinder connected to the container to the shaft valve. The present invention provides a pumping device for a cosmetic container that is formed to be opened and closed precisely so as to prevent deterioration of a pumping function due to an air pocket.

The present invention to achieve this object is achieved by providing an atomizer pumping means of an improved structure. This is to prevent the pressure leakage phenomenon by forming the sealing structure of the piston valve which is operated in the cylinder in a multi-stage block structure. Of course, a strong vacuum pressure is generated in the cylinder to improve pumping efficiency, and a fluid passage is formed between the fluid passage tube and the piston formed in the lower part of the operation button so that the contents can be discharged flexibly without any load. It is characterized in that the inlet of the cylinder is configured to be opened and closed correctly through the shaft valve to prevent the phenomenon of the air pocket that the internally generated pressure is introduced into the container during the pumping operation to improve the pumping efficiency of the vacuum pump.

1 is a cross-sectional view showing a pumping device of a conventional cosmetic container

2 is an enlarged view illustrating main parts of FIG. 1;

Figure 3 is a cross-sectional view showing a pumping device of the cosmetic container of the present invention

4 is an operating state diagram of FIG.

5 is an exploded perspective view showing the main portion of the present invention in detail

6 is a main configuration showing the present invention operation state

7 is a state in which the lowering operation by a predetermined interval in Figure 6

Figure 8 is a state of fully lowered operation in Figure 7

9 is a state in which the rising operation by a predetermined interval in FIG.

FIG. 10 is a state diagram fully raised and returned to FIG. 9. FIG.

11 is a state in which the piston and the piston valve of the present invention is opened

12 is a state in which the piston rises to close the passage in FIG.

FIG. 13 is a state diagram completely closed in FIG. 12 (description of reference numerals for main parts of the drawing)

20: nozzle cap 21: screw 22: guide

23: operator 30: operation button 31: fluid passage pipe

32: locking jaw 40: return spring 50: cylinder

51: inlet 52: compression chamber 53: operating chamber

54: locking projection 60: shaft valve 61: space

62: jam jaw 63: road 70: piston

71: projection 72: sealing groove 72a: tapered surface

73: guide 74: interval maintenance projection 80: piston valve

81: groove 82: center hole 83: operating groove

84: sealing protrusion 90: ball valve

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

3 and 4 of the accompanying drawings shows in detail the pumping means of the cosmetic container according to the present invention.

It is composed of a nozzle cap 20 that is screwed to the upper end of the container as shown in the figure, the operation button 30 for the user to press the hand by pressing the top of the nozzle cap 20 is return spring ( 40) is mounted in a state of being elastically supported.

The nozzle cap 20 is screwed into and separated from the inlet of the cosmetic container, the contents are accommodated as usual, the lower inner diameter of the screw 21 is formed and the upper guide tube 22 is projected upwards It is integrally formed, the center is formed with an operating hole 21 penetrating up and down. In addition, the operation button 30 is mounted on the top of the nozzle cap 20.

The operation button 30 is formed in a cylindrical shape, the fluid passage tube 31 is integrally formed at the lower portion and inserted into the operation hole 23 of the nozzle cap 20, and at the end of the fluid passage tube 31. The outwardly engaging projection 32 is formed to be prevented from being caught by the lower end of the operating hole 23 of the nozzle cap 20 to be separated from the outside, and to communicate with the inside on one side of the outer circumferential surface to discharge the contents to the outside. The nozzle 33 is formed.

In addition, a return spring 40 is mounted on the outer circumference of the fluid passage tube 31 between the operation button 30 and the nozzle cap 20.

The return spring 40 is always a coil spring to operate the operation button 30 upward by the elastic force itself.

In addition, a cylinder 50 communicating with the container is fastened to the lower portion of the nozzle cap 20.

The cylinder 50 is formed in a cylindrical shape with a narrow suction port 51 formed at a lower portion thereof, and a compression chamber 52 having different inner diameters therein and an operating chamber 53 for elevating operation by installing a shaft valve to be described later. The operating chamber 53 has a narrower inner diameter than the compression chamber 52 and is located directly above the suction port 51, and a locking protrusion 54 is formed at the upper inner diameter of the operating chamber 53. It limits the stroke distance according to the lifting operation of the shaft valve.

The shaft valve 60 is operated to elevate in the operating chamber 52 to open and close the inlet 51, and has a shape in which the cup is inverted upside down, and a predetermined space 61 is formed therein. A plurality of engaging jaw 62 is formed radially, the rod-shaped rod 63 is formed integrally thereon.

The axial valve 60 is formed in the form of a cup that is downwardly opened, thereby blocking the inlet 51 so as to cover the upper part, thereby improving the blocking efficiency, and the locking jaw 62 of the outer periphery is operated in the operating chamber 52. It is caught by the engaging projection 54 in the) limiting the operating distance of the shaft valve 60. In addition, the rod 63 of the upper portion is formed in a rod-shaped to fit the inner diameter of the piston 70 to be described later Coupled to lift and operate the shaft valve 60 by the piston (70).

On the other hand, in another embodiment of the above-described configuration by installing a separate ball valve 90 in the space 61 of the shaft valve 60 to configure the inlet 51 to open and close twice to improve the opening and closing efficiency. Can be.

In addition, the piston 70 is a lifting operation in the cylinder 50, the outer periphery is formed a plurality of projections 71 which are radially supported in close contact with the inner diameter of the cylinder 50, the upper surface will be described later in the circumferential direction The sealing groove 72 is formed to be coupled to the piston valve, the upper center portion is formed with a guide tube 73 is integrally formed at the same time, and at the same time, the gap maintaining protrusion 74 is radially formed at the lower outer periphery of the guide tube 73. As the protrusions 71 are protruded on the outer periphery, the protrusions 71 provide a space for the fluid to pass therebetween in close contact with the inner diameter of the cylinder 50, and the sealing groove 72 will be described later, but the bottom of the inner portion. The surface is formed as a tapered surface (72a) to increase the sealing efficiency when combined with the piston valve. The guide tube (73) is formed so as to penetrate up and down so that the rod 63 of the shaft valve (60) described above is forcibly fitted. Coupled to the piston, when the piston 70 The rod 63 of the axial valve 60 coupled to the inner tube 73 is lifted and operated by the frictional force. In addition, the piston valve 80 coupled to the piston 70 has flexibility and restoring force. It is molded of such excellent rubber, synthetic resin, etc., and is formed in a cylindrical shape so as to be able to move up and down while being in close contact with the inner diameter of the cylinder 50, and a concave groove 81 is formed in the center of the outer periphery to maintain excellent elastic force. A central hole 82 is formed at the center of the valve to penetrate up and down, and is inserted into the guide tube 73 of the piston 70. At this time, the gap maintaining protrusion 74 formed at the outer diameter of the guide tube 73 is formed. The space is provided between them through the space provided therein. In addition, the upper surface is formed with an inwardly concave operation groove 83 is formed so that the operation button 30 is inserted into the lower end of the fluid passage pipe 31 when the operation is lowered. Protrude downward The sealing protrusion 84 is formed along the circumferential direction to be coupled to and separated from the sealing groove 72 of the piston 70 to open or close the fluid passage. That is, the piston valve (according to the lifting operation of the piston 70) The sealing protrusion 84 of the 80 and the sealing groove 72 of the piston 70 are separated and coupled to allow and block the passage of fluid therebetween.

Therefore, the present invention, which is configured as described above, is assembled as shown in FIGS. 3 and 4 of the accompanying drawings, and in this state, the nozzle cap 20 is used by screwing into the inlets of various cosmetic containers.

3 shows the standby state without using the cosmetic container. In this case, the operation button 30 is maintained upward by the elastic force of the return spring 40. Accordingly, the piston ( 70), the piston valve 80 and the like is raised at the same time the inlet port 51 of the cylinder 50 is connected to the container to maintain the closed state of the shaft valve 60 and the ball barb 90 is lowered.

Here, the ball valve 90 will be described as working with the axial valve 60 for convenience or convenience according to another embodiment.

In addition, FIG. 4 of the drawings shows a state in which the operation button 30 is fully pressed in order to use the contents in the cosmetic container, which means that the piston 70 and the piston valve 80 are pressed by the pressing force of the operation button 30. The state in which the contents were discharged to the outside through the nozzle 33 by lowering and compressing the contents in the compression chamber 52 is shown.

Referring to the operation state as described above in more detail with reference to Figure 6 below.

3 and 6 are in the standby operation state, when the operation button 30 is pressed in this state, the operation button 30 is lowered while compressing the return spring 40, the operation button 30 is lowered As a result, the fluid passage tube 31 and the piston 70 are first lowered by the interval L of the preliminary section as shown in FIGS. 7 and 11.

Accordingly, the end surface of the fluid passage tube 31 is in contact with the upper surface operating groove 83 of the piston valve 80 and at the same time, the sealing groove 72 of the piston 70 is a sealing projection ( A fluid passage through which fluid flows is formed by releasing from 84 and opening between them. At this time, as the piston 70 descends, the axial valve 60 which is forcibly fitted to its guide tube 73 is also formed. By lowering by the friction force, the inlet port 51 in the cylinder 50 is blocked, and at the same time, the ball valve 90 is also lowered to block the inlet port 51 twice.

Subsequently, the fluid passage pipe 31 lowers the piston valve 80 as shown in FIG. 8 by the operation button 30 which continues to descend so that the piston valve 80 compresses the compression chamber 52.

Accordingly, the contents in the compression chamber 52 flows into the center hole 82 of the piston valve 80 through the fluid passage opened between the piston 70 and the piston valve 80, and then the Ascending through the passage between the inner diameter and the guide tube 73 of the piston 70 is discharged to the outside through the nozzle 73. On the contrary, when the operation button 30 held down is released, the operation button 30 is The return spring 40 is operated by the elastic force of the return spring to the original position, and as shown in FIG. 9, the lowered piston 70 and the fluid passage tube 31 first block the fluid passage in the state of being raised by the distance L. do.

That is, when the piston 70 and the fluid passage pipe 31 is raised by the distance (L), the sealing groove 72 of the piston 70 and the sealing protrusion 84 of the piston valve 80 are mutually coupled and therebetween Shut off the fluid passage.

When explaining this operation in more detail as shown in Figures 11 to 13 of the accompanying drawings, the sealing projection 84 formed in the lower portion of the piston valve 80 is inserted between the sealing groove 72 of the piston 70 first It is firstly sealed with the inner surface A of the sealing groove 72, and is secondarily sealed while being bent by the tapered surface 72a of the sealing groove 72 as it is continuously inserted, and then deformation of the sealing protrusion 84. It is sealed to the outer surface (B) of the sealing groove (72) by a third shape.

This sealing operation prevents pressure leakage in the compression chamber 52, thereby improving suction efficiency during the suction operation in which the contents stored in the container are sucked into the compression chamber 52.

Subsequently, the piston valve 80 is moved upward by the upward operation, so that a vacuum pressure is generated in the compression chamber 52. As a result, the shaft valve 60 and the ball valve 90 are raised as shown in FIG. By opening the suction port 51, the contents in the container flow into the compression chamber 52 through the suction port 51.

At this time, the shaft valve 60 is raised by the interval that the engaging jaw 62 of the outer periphery is caught by the engaging projection 54 in the operating chamber 53 to open the suction port 51, the piston continuously operated 70 is accommodated by the slip operation by being coupled to the rod 63 of the axial valve 60 by the slip operation.

Therefore, the lifting operation as described above is repeated by the pressing operation of the operation button 30 to discharge the contents in the container quantitatively through the nozzle.

As described in detail above, the present invention consists of a multi-stage sealing structure of the piston valve reciprocating in the cylinder to prevent pressure leakage, thereby greatly improving the suction efficiency of the contents of the container sucked into the compression chamber of the cylinder. Will have

In addition, during the pumping operation, the contents in the compression chamber are discharged through the fluid passage between the piston and the fluid passage pipe through the inner diameter of the piston valve, so that a smooth discharge operation is performed without any load.

In addition, the inlet port of the vacuum pump connected to the container is configured to open and close the shaft valve made of a tubular type to prevent the so-called air pocket phenomenon that the pressure generated internally during the operation of the pump into the container to improve the pumping efficiency of the vacuum pump It will have the effect of letting.

Claims (4)

In the pumping device of the container installed in the nozzle cap screwed to the inlet of the cosmetic container to discharge the contents inside the container by a predetermined amount to the outside by pressing operation, It is provided at the top of the nozzle cap 20, the lifting operation, and the fluid passage tube 31 is integrally formed at the center of the lower and at the same time having a nozzle 33 in communication with the fluid passage tube 31 on one side An operation button 30 supported by the return spring 40; The suction port 51 which is fastened to the lower portion of the nozzle cap 20 and has a compression chamber 52 and an operating chamber 53 having different diameters therein and is in communication with a container at the lower portion of the operating chamber 53 is formed. And the upper part of the operating chamber 53 and the cylinder 50, the locking projection 54 is formed to protrude; The upper guide tube 73 is fastened to the fluid passage tube 31 of the operation button 30 in a force-fitting manner, and the gap maintaining protrusion 74 is radially formed on the outer circumference of the guide tube 73 to form a cylinder ( A piston 70 which is operated up and down within 50; A piston valve 80 for inserting and fastening a center hole 82 into the piston 70 to compress the compression chamber 52 in the cylinder 50 by the lifting operation thereof; The rod 63 of the upper portion is coupled to the guide tube 73 of the piston 70 while the intake port 51 is coupled to the operating chamber 53 in the cylinder 50 and the stroke distance is limited by the locking jaw 62. A shaft valve for opening and closing the 60; Pumping device of the cosmetic container, characterized in that consisting of. The method of claim 1, The piston valve 80 is formed in a cylindrical shape in close contact with the inner diameter of the cylinder 50, the lifting operation is formed, the outer periphery is formed in the groove 81 is concave toward the center from the upper, lower portion, the upper groove in the concave operating groove At the same time as the 83 is formed in the lower surface of the pumping device of the cosmetic container, characterized in that the downwardly projecting sealing projections 84 are formed along the circumferential direction. The method of claim 1, Pumping device of the cosmetic container, characterized in that the inlet port 51 in the cylinder 50 is configured to block the double by installing a ball valve 90 together with the axial valve 60. The method of claim 1, The piston 70 forms a sealing groove 72 which is concave inwardly on the upper surface thereof, while the piston valve 80 is formed by both side surfaces A and B in the sealing groove 72 and a tapered surface 72a formed on the bottom surface. When combined with a sealing projection pump 84 and pumping device of the cosmetic container, characterized in that configured to be sealed in multiple stages.