KR20210125746A - Pumping type fluid container with non-metal elastic part - Google Patents

Abstract

The present invention relates to a pumping type fluid container with a non-metal elastic part to reduce manufacturing costs. According to an embodiment of the present invention, the pumping type fluid container comprises: a container part opened upward and accommodating a fluid; a pumping part including a cylinder (210) having a suction port through which the fluid flows formed in the lower part, having a fluid passage through which the fluid moves formed therein, and supported by the container coming in contact with the upper end part of the container on the outer circumferential surface, a piston (220) moving inside the cylinder (210) and having a pressing part formed on one side to pressing the fluid, and a pressing shaft (230) moving the piston (220) as the piston (220) is pressed and having a discharge port formed on one side to discharge the fluid; and a cap coupled to an inlet of the container part to fix the pumping part to the container part. The pumping part (200) includes a housing cover (250) having a non-metallic elastic part (260) formed therein to be elastically deformed according to a pressure applied to a button or nozzle of the fluid container.

Description

Pumping type fluid container with non-metal elastic part

The present invention relates to a pumping-type fluid container, and more particularly, to a pumping-type fluid container having a housing cover including a non-metal elastic part elastically deformed by pressure, and a joint for coupling a pressure shaft and a cylinder.

Among cosmetics, in the case of liquid or gel cosmetics with a low viscosity of 0.01*poise, such as lotions, creams, gels, shampoos, rinses, etc., the pump type It is accommodated in cosmetic containers and used.

In the prior art, as shown in FIG. 1 , a pumping-type fluid container for accommodating cosmetics having a coefficient of viscosity generally pumps the container part 10 for accommodating the content, and the content of the container part 10 . It may be configured to include a pumping unit 20 for discharging to the outside by operation, and a cap 30 for fixing the pumping unit 20 to the container unit 10 .

The pumping unit 20 moves inside the cylinder 21 and the cylinder 21 in which the fluid passage is formed so that the fluid can move, and the piston 22 and the piston 22 in which a pressurizing unit for pressing the fluid is formed on one side. ) and may be configured to include a pressure shaft 23 in which a discharge port for discharging the fluid to one side is formed.

Further, the pumping unit 20 is provided between the coupling member 27 for coupling the cylinder 21 and the pressing shaft 23 and the cylinder 21 and the pressing shaft 23, and the pumping unit 20 is pressurized. It elastically deforms accordingly and when the pressure applied to the pumping unit 20 is removed, the pressure shaft 23 may include an elastic member 25 that provides a restoring force for returning to the original position.

However, in the conventional pumping type fluid container, a spring such as a metal spring has been mainly adopted as a means for providing a restoring force for returning the pumping unit 20, which moves up and down as the pumping unit 20 is pressed, to its original position. As a result, the conventional pumping-type fluid container inevitably consists of a combination of a metal material such as a metal spring and various dissimilar material parts such as a plastic material such as the container part 10. rom has been pointed out.

Furthermore, in view of the current situation in which most pumping-type fluid containers are incinerated or buried because it is difficult to separate and collect when disposing of pumping-type fluid containers made of different materials, environmental pollution problems caused by waste plastics have been pointed out.

In order to solve the above-mentioned problems of the prior art, some domestic and foreign related companies have conducted research to replace the metal spring with plastic, but it is difficult to commercialize the product, such as elastic restoring force, durability, pressure tightness, and pumping functionality. The quality was inferior to that of the conventional pumping type fluid container, so there was no case of commercialization in earnest.

In addition, the coupling member 27 and the pumping part 20 for coupling the cylinder 21 and the pressure shaft 23 formed in the pumping part 20 between the production process and the assembly process of the conventional pumping type fluid container are returned to their original positions. As a means for providing a restoring force for returning, an additional process for providing an elastic member such as a metal spring is required, and as a result, an increase in assembly time as well as an increase in production cost has been pointed out.

Furthermore, the conventional pumping type fluid container provides a restoring force for returning the coupling member 27 and the pumping unit 20 to the original position and the coupling member 27 for coupling the cylinder 21 and the pressure shaft 23 formed in the pumping unit 20 to the original position. As a means, a spring such as a metal spring has been required as an essential component. As a result, as the number of parts required for manufacturing a conventional pumping type fluid container increases, a problem has been pointed out that market competitiveness deteriorates as the production cost rises.

The present invention has been devised to solve the problems of the prior art, and the objects of the present invention are as follows.

First, according to the present invention, the housing cover is elastically deformed according to the pressure applied to the piston to replace the role of the existing metal spring, thereby providing a separate metal An object of the present invention is to provide a pumping type fluid container that does not contain a spring or metal.

Second, to provide a pumping type fluid container that not only replaces the spring material with synthetic resin, but also has an elastic body structure design to enable quantitative discharge while maintaining the elastic restoring force, durability, pressure tightness, and pumping function of the conventional metal spring. do.

Third, in order to improve circulation by maximizing recycling and recycling when disposing of a product, it is intended to provide a pumping type fluid container in which all parts are made of plastic.

Fourth, the present invention further minimizes the number of parts required for manufacturing a pumping-type fluid container by providing a housing cover, which is a multifunctional part having a function of a non-metallic elastic part and a coupling member, which can be included in a conventional pumping-type fluid container, and the assembly process and An object of the present invention is to provide a pumping type fluid container that can simplify the production process.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

According to the present invention, the container part that is opened to the upper part and accommodates the fluid therein, the suction port through which the fluid is introduced is formed in the lower part, the fluid passage through which the fluid moves is formed therein, and the container part is in contact with the upper part of the container part on the outer circumferential surface. A cylinder supported by the , moving inside the cylinder, a piston having a pressurizing part for pressurizing the fluid on one side, and a pressure shaft that moves the piston as the piston is pressurized, and a discharge port for discharging the fluid is formed on one side A pumping type fluid container is provided that includes a cap coupled to the inlet of the pumping part and the container part to fix the pumping part to the container part.

According to another feature of the present invention, there is provided a pumping-type fluid container, characterized in that the pumping unit includes a housing cover formed with a non-metallic elastic unit that elastically deforms according to the pressure applied to the piston.

In addition, the housing cover may include a joint for binding the cylinder and the pressure shaft.

Furthermore, the non-metallic elastic part is formed to extend and extend on one side of the extension part and the extension part on one side of the extension part as the pressing shaft moves linearly, and the other side of the extension part is extended and fixed to the cylinder to extend the extension part. It may be characterized in that it comprises a second coupling portion for supporting the.

In addition, the non-metallic elastic portion may be characterized in that it is made of elastomer, silicone or rubber.

On the other hand, the joint portion may include a guide member for limiting the range of the transverse elastic deformation of the non-metallic elastic portion elastically deformed according to the pressure applied to the piston, a connecting portion coupled to the non-metallic elastic portion, and an inner mounting portion coupled to the cylinder. have.

In addition, the joint may be characterized in that it is made of polypropylene or polyethylene.

In addition, the housing cover 250 may be characterized in that the non-metallic elastic part and the joint part are manufactured by double injection.

The effects of the present invention configured as described above will be described as follows.

First, in the pumping type fluid container in which the housing cover is formed according to an embodiment of the present invention, the housing cover elastically deforms according to the pressure applied to the piston, so that a separate metal spring or a metal-free pumping unit can perform a pumping function. .

Second, when the non-metallic elastic part formed on the housing cover is elastically deformed according to the pressure applied to the piston), the guide member formed in the joint part limits the transverse elastic range of the non-metallic elastic part, so that the durability of the pumping-type fluid container can be improved.

Third, the number of parts can be reduced by elastically deforming the housing cover formed in the pumping part according to the pressure applied to the piston. Therefore, it is possible to simplify the production process, and furthermore, it is possible to reduce the manufacturing cost of the pumping type fluid container.

Fourth, when disposing of the pumping-type fluid container, since metal parts are not used, the pumping-type fluid container can be disposed of without having to separate it into metal and plastic.

Effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a view showing a conventional pumping type fluid container.
2 is a cross-sectional view of a pumping type fluid container according to the present invention.
3 is an enlarged view of A, and is a cross-sectional view of a pumping type fluid container including a housing cover according to the present invention.
4 is a view showing a state in which the non-metallic elastic part starts to partially relax as the pumping starts by pressing the pressure shaft of the pumping type fluid container according to the present invention.
5 is a view showing a state in which the non-metallic elastic part is maximally relaxed by pumping of the pumping type fluid container according to the present invention.
6 is a view showing a state in which the non-metallic elastic part contracts as no pressure is applied to the pressure shaft of the pumping type fluid container according to the present invention.
7 is a view showing a state in which the pumping type fluid container according to the present invention is restored to its original state.

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

Unless otherwise defined, all technical and scientific terms used herein will have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, but have the meanings commonly understood from those defined separately in the specification In case of conflict, the description of the present specification will take precedence.

For a clearer understanding of the invention proposed in the drawings, parts irrelevant to the description are omitted. In addition, when "includes" a component of the invention, it means that other components may be further included in addition to the included component, rather than excluding other components unless there is a special circumstance. Furthermore, "part" described in the specification means one unit that performs a specific function of the present invention.

Identification numbers (first, second, etc.) in each component or step are used for convenience of description. Therefore, the identification code does not mean the order of each component or step, and may be implemented differently regardless of the order of the identification code unless a specific order is described in the specification. That is, each step may be performed in the same order as the described order or may be performed in the reverse order.

2 is a cross-sectional view of a pumping type fluid container according to the present invention.

3 is a view showing a state in which the non-metallic elastic part 260 starts to partially relax as the pumping starts by pressing the pressure shaft 230 of the pumping type fluid container according to the present invention.

Hereinafter, a structure of a non-metal pumping type fluid container according to a preferred embodiment of the present invention will be described with reference to FIGS. 2 and 3 .

A pumping-type fluid container according to an embodiment of the present invention has an upper opening and a container part for accommodating a fluid therein, a suction port for introducing a fluid in the lower part, a fluid passage through which the fluid moves is formed therein, and a container on the outer circumferential surface. As the cylinder 210, which is supported by the container unit in contact with the upper end of the unit, moves inside the cylinder 210 and pressurizes the piston 220 and the piston 220 in which a pressurizing unit for pressurizing the fluid is formed on one side, the piston It moves 220 and may include a pumping unit including a pressure shaft 230 having a discharge port for discharging the fluid on one side and a cap coupled to the inlet of the vessel unit to fix the pumping unit to the vessel unit.

The pumping unit 200 may include a housing cover 250 having a non-metallic elastic unit 260 that elastically deforms according to the pressure applied to the button or nozzle of the fluid container.

The non-metal elastic part 260 is a first coupling part (262) which is stretched and stretched as the pressing shaft 230 moves in a straight line, and is formed to extend on one side of the extension part (262) and fixed to the pressing shaft (230). 261 ) and a second coupling part 263 extending from the other side of the extension part 262 and being fixed to the cylinder 210 to support the extension extension of the extension part 262 .

The first coupling portion 261 may be formed in a shape to be in contact with the lower end of the pressure shaft 230 to wrap the lower end of the pressure shaft 230 , and as shown in FIG. 2 , the pressure shaft 230 and The first coupling portion 261 may be formed in a shape that can be inserted into the receiving space formed by a predetermined interval between the pistons 220 .

The first coupling part 261 may be formed at the lower end of the extended part 262 , and as shown in FIG. 2 , the first coupling part 261 is pressed into the receiving space formed between the extended part 262 and the first coupling part 261 . The upper end of the first coupling part 261 may be formed to extend to such a degree that the shaft 230 can be press-fitted.

The method of coupling the first coupling part 261 and the pressure shaft 230 is exemplified by a press fit, but it is not necessarily limited thereto, and any known coupling method may be used. For example, a coupling method by friction, a coupling method using an adhesive, etc. may be adopted for coupling the first coupling part 261 and the pressure shaft 230 .

Furthermore, the coupling method of the first coupling part and the pressure shaft 230 may be parallel to each other in order to prevent the deterioration of the internal solution and realize the airless technology in which the air injection is blocked. By way of example, the first coupling part 261 and the pressure shaft 230 are coupled by force fitting in a kitchen type, and an adhesive is applied to one surface where the first coupling part 261 and the pressure shaft 230 are pressed together. By adopting this method as an auxiliary means, it is possible to block the injection of air into the container.

The first coupling part 261 may receive the pressure applied to the piston 220 according to the user's use and transmit the force transmitted from the piston 220 to the extension part 262, and the extension part 262 may undergo elastic deformation. It can be a fixed axis of up and down movement when moving up and down.

As described above, the extension portion 262 may be elastically deformed according to a force applied to the piston 220 received from the first coupling portion 261 formed at the lower end of the extension portion 262 .

The extension part 262 may be formed with a cylindrical shape larger than the diameter of the pressure shaft 230 to surround the outer circumferential surface of the pressure shaft 230 as shown in FIG. It may be designed in a structure such as a spiral, circular, pyramidal, or rhombus shape to have it.

In the pumping-type fluid container in which the housing cover 250 including the non-metal elastic part 260 is formed according to an embodiment of the present invention, the extension part 262 elastically deforms according to the pressure applied to the piston 220, so that a separate metal Pumping part can perform pumping function without spring

The second coupling part 263 is formed at the upper end of the extension part 262 and may extend in a direction toward the inner surface of the cap. The second coupling portions 263 and 263 are preferably configured to have the same shape and size as the connection portion 282 formed in the joint portion 280 as shown in FIG. 2 .

The lower end surface of the second coupling portion 263 may have a shape of a predetermined concavo-convex corresponding to the unevenness formed in the connection portion 282 for fitting with the connection portion 282 formed in the joint portion 280 .

The second coupling part 263 may be a supporting point for fixing and supporting the expansion and contraction extension of the extension part from one side according to the vertical movement of the piston 220 .

As shown in FIG. 2, it is preferable that there is one unevenness formed on the lower surface of the second coupling part 263, but there may be more than one unevenness in order to prevent deterioration of the internal solution and realize the airless technology in which air injection is blocked. have.

The method in which the second coupling portion 263 and the connecting portion 282 are coupled is exemplified by fitting coupling, but it is not necessarily limited thereto, and any known coupling method may be used. For example, a coupling method by friction, a screw coupling, a coupling method using an adhesive, etc. may be adopted for coupling the second coupling portion 263 and the connecting portion 282 .

Furthermore, the coupling method of the second coupling part 263 and the coupling part 282 may be parallel to each other in order to prevent deterioration of the internal solution and to realize an airless technology in which air injection is blocked. By way of example, the second coupling part 263 and the connecting part 282 are coupled by a force fit, but the second coupling part 263 and the connecting part 282 are applied with an adhesive on one side of the force fit. By adopting this method as an auxiliary means, it is possible to block the injection of air into the container.

The material of the non-metal elastic part 260 may be made of elastomer, silicone, or rubber. According to the present invention, the non-metal elastic part 260 elastically deforms according to the pressure applied to the piston 220 to replace the role of the existing metal spring, thereby providing a separate metal A springless pumping type fluid container can be provided.

Furthermore, not only simply replacing the spring material with synthetic resin, but also maintaining the elastic restoring force, durability, pressure tightness, and pumping function of the conventional metal spring through the structure as described above.

The housing cover 250 binds the cylinder 210 and the pressure shaft 230 and may include a joint 280 formed at the upper end of the cylinder 210 .

The joint 280 is a guide member 281 that limits the range of elastic deformation of the transverse axis of the non-metallic elastic part 260 elastically deformed according to the pressure applied to the piston 220, and the non-metallic elastic part 260. It may include a portion 282 and an inner mounting portion 283 coupled to the cylinder 210 .

The guide member 281 may be formed adjacent to the outer peripheral surface of the non-metallic elastic part.

The guide member 281, as shown in FIG. 2, may be formed with a cylindrical shape larger than the diameter of the extension part 262 in order to surround the outer peripheral surface of the extension part 262, but the extension part 262. It may be formed in a structure such as a spiral, circular, pyramidal, or rhombus shape to protect the extension portion 262 corresponding to the shape of .

As shown in FIG. 2, the guide member 281 is preferably configured to have a height lower than the length of the extension portion 262 so that the connection portion 282 can be formed, and when the extension portion 262 is elastically deformed. , the durability of the pumping type fluid container can be improved by limiting the range of the transverse axis that can be elastically deformed.

The connecting portion 282 is formed at the upper end of the guide member 281 and may extend in a direction toward the cap 30 . In order to couple with the lower surface of the second coupling part 263 formed at the upper end of the non-metallic elastic part 260 , it may have a predetermined concave-convex shape corresponding to the unevenness formed in the second coupling part 263 .

As shown in FIG. 2 , it is preferable that there is one unevenness formed on the top surface of the joint 282 , but in order to prevent the deterioration of the internal solution and realize the airless technology in which air injection is blocked, the upper end of the joint 282 is The unevenness formed on the surface may be two or more.

The inner mounting portion 283 is formed on the outer periphery of the lower end surface of the connecting portion 282, is formed at a predetermined interval from the guide member 281, and is formed in a direction facing the guide member 281 formed on one side of the connecting portion 282. can be

The upper end of the cylinder 210 may be inserted into the accommodating space formed between the guide member 281 and the inner mounting portion 283 . A coupling groove 284 may be formed on the inner circumferential surface of the inner mounting portion 283 so that the coupling protrusion formed at the upper end of the cylinder 210 inserted into the receiving space can be press-fitted.

A coupling protrusion may be formed on the outer circumferential surface of the inner mounting portion 283 for binding to the engaging portion formed inside the cap.

The material of the joint 280 may be made of polypropylene or polyethylene.

The housing cover 250 in which the non-metal elastic part 260 and the joint part 280 are formed may be characterized in that it is manufactured by double injection of the non-metal elastic part 260 and the joint part 280 . Therefore, according to the present invention, as the number of parts required for manufacturing the pumping-type fluid container is reduced, the production process can be simplified, and further, the manufacturing cost of the pumping-type fluid container can be reduced.

3 is a view showing a state in which the non-metallic elastic part 260 starts to partially relax as the pumping starts by pressing the pressure shaft 230 of the pumping type fluid container according to the present invention.

4 is a view showing a state in which the non-metallic elastic part 260 is maximally relaxed by pumping of the pumping type fluid container according to the present invention.

5 is a view showing a state in which the non-metallic elastic part 260 is contracted because no pressure is applied to the pressure shaft 230 of the pumping type fluid container according to the present invention.

6 is a view showing a state in which the pumping type fluid container according to the present invention is restored to its original state.

When pressure is applied to the piston 220 , the pressure shaft 230 may start a linear motion. As shown in FIG. 4 , as the pressing shaft 230 linearly moves downward in the longitudinal direction of the pressing shaft 230 , the force applied to the pressing shaft 230 may be transmitted to the first coupling part 261 . According to the direction and magnitude of the force transmitted to the first coupling part 261 , the extension part 262 may elastically extend downward in the longitudinal direction of the pressing shaft 230 . At this time, the second coupling portion 263 may fix and support the elastic extension movement of the extension portion 262 .

When the pressure applied to the piston 220 reaches the maximum, as shown in FIG. 5, the linear motion of the pressure shaft 230 is momentarily stopped and the expansion and contraction movement of the extension part 262 reaches the maximum point. can

When the pressure applied to the piston 220 is removed, as shown in FIG. 6 , the force applied to the pressure shaft 230 as it linearly moves upward in the longitudinal direction of the pressure shaft 230 is applied to the first coupling part 261. can be delivered. According to the direction and magnitude of the force transmitted to the first coupling part 261 , the extension part 262 may elastically contract upward in the longitudinal direction of the pressing shaft 230 . At this time, the second coupling part 263 may fix and support the elastic contraction movement of the extension part 262 .

When the pressure applied to the piston 220 is removed and a predetermined time has elapsed, the linear motion of the pressure shaft 230 completely stops and the expansion/contraction motion of the extension part 262 can be stopped as shown in FIG. 7 . have.

Furthermore, when disposing of the pumping-type fluid container, since metal parts are not used, the pumping-type fluid container can be disposed of without having to separate it into metal and plastic.

This embodiment is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains may make various modifications and variations of this embodiment within the scope not departing from the essential characteristics of the present invention. It will be possible.

This embodiment is intended to explain, not to limit the technical spirit of the present invention, and therefore, the scope of the present invention is not limited by the present embodiment.

The protection scope of the present invention should be construed by the claims, and all technical ideas equivalent to or recognized as equivalent should be construed as being included in the scope of the present invention.

10 - container
20 - pumping part
30 - cap
21 - cylinder
22 - piston
23 - pressure shaft
25 - elastic member
27 - coupling member
100 - container
200 - pumping unit
300 - cap
210 - cylinder
220 - piston
230 - pressure shaft
250 - housing cover
260 - non-metallic elastic part
261 - first coupling part
262 - kidney
263 - second coupling part
280 - joint
281 - Guide member
282 - Junction
283 - inner part
284 - mating groove

Claims (7)

In the pumping type fluid container in which the stored fluid is discharged by pumping,
a container part that is opened upward, and the fluid is accommodated therein;
A suction port through which the fluid is introduced is formed in the lower part, a fluid passage through which the fluid moves is formed therein, and a cylinder supported by the container part in contact with the upper end of the container part on the outer circumferential surface, moving inside the cylinder, a pumping unit including a piston having a pressurizing unit pressurizing the fluid on one side and a pressure shaft moving the piston as the piston is pressurized, and a pressurizing shaft having a discharge port for discharging the fluid at one side; and
a cap coupled to the inlet of the container part and fixing the pumping part to the container part; includes,

The pumping unit,
Housing cover including a non-metallic elastic part elastically deformed according to the pressure applied to the button or nozzle of the fluid container
A pumping type fluid container comprising a
The method of claim 1,
The non-metallic elastic part,
an extension part which is stretched and contracted as the pressure shaft moves in a straight line;
a first coupling part extending from one side of the extension part and fixed to the pressure shaft; and
a second coupling part extending from the other side of the extension part and fixed to the cylinder to support the extension extension of the extension part
A pumping type fluid container comprising a
The method of claim 1,
The non-metallic elastic part is a pumping type fluid container, characterized in that any one of elastomer, silicone, and rubber can be selected.
The method of claim 1,
The housing cover is
A joint formed at an upper end of the cylinder and binding the cylinder and the pressure shaft
Non-metal pumping type fluid container further comprising a
5. The method of claim 4,
The joint is
An inner mounting portion having a coupling groove formed on an inner surface so that the cylinder can be inserted
A pumping type fluid container further comprising a
5. The method of claim 4,
The joint is
a guide member that limits a range of elastic deformation of the horizontal axis of the non-metallic elastic part elastically deformed according to the pressure applied to the piston and is formed adjacent to an outer peripheral surface of the non-metallic elastic part; and
a connecting portion formed at an upper end of the joint to be coupled to the non-metallic elastic portion;
A pumping type fluid container further comprising a
5. The method of claim 4
Pumping type fluid container, characterized in that the joint is made of polypropylene or polyethylene

Images