KR102477141B1 - Nozzle lever type pump vessel having lever structure - Google Patents

Abstract

The present invention relates to a nozzle lever type pump container with a lever structure. Firstly, a user can alternatively use any one of a push button method or a nozzle lever method, and in case of using a nozzle lever, the user can use only one hand to press the nozzle lever and simultaneously receive liquid from a discharge port of the nozzle lever to generate a large force with a small amount of force by applying the lever principle, thereby enabling one-handed use and also being very easily used by the elderly and infirm. Secondly, the pump container of the present invention is eco-friendly by using plastic springs, and is released in a state that is locked by a locking lever and not locked by pressing a push button (discharge cap) when released, without compressing a plastic spring to have elastic deformation, so that no deformation of the plastic spring occurs during a product distribution process, and after releasing the locking lever, the user (consumer) selects the nozzle lever or the push button to discharge the liquid, thereby solving a conventional problem of low pumping force. The pump container comprises a container, a cap shoulder, a cap body, a cylinder, a suction hose, a check valve, an elastic member, an adaptor, a stem, a piston ring member, a nozzle lever, and a push button.

Description

Lever structure nozzle lever type pump container {NOZZLE LEVER TYPE PUMP VESSEL HAVING LEVER STRUCTURE}

The present invention relates to a nozzle lever-type pump container having a leverage structure, and more particularly, to a method using a push button or a method using a nozzle lever, as well as using a nozzle lever. In the case of the method, since the user can use only one hand to press the nozzle lever and receive the liquid from the discharge port of the nozzle lever at the same time, it is possible to generate a large force with a small amount of force by applying the lever principle, enabling one-handed use. is, of course, related to a nozzle lever-type pump container with a lever structure that can be used very easily by the elderly.

In general, since a container containing liquid contents widely used in daily life is equipped with a small manual pump, the contents of the liquid are discharged out in a certain amount by simply pressing the small manual pump, so the user can use it easily. . Such a pump is called a 'dispenser', and when the user presses the pump, the contents contained in the chamber inside the pump are discharged out through the nozzle (discharge hole) of the nozzle head of the pump due to the pressure difference. . On the other hand, when the force pressing the pump is removed, the pump returns to its original state upward by the elastic restoring force of the spring installed between the container and the pump, and the contents in the container are sucked back into the chamber in the pump.

Such a dispenser is also widely used in shampoo containers, and is used to conveniently discharge a certain amount of shampoo solution contained in the shampoo container.

Conventionally, a cap in which a general lid is covered at the inlet of the shampoo container and a cap formed with a discharge port through which the shampoo solution is discharged has been used. Due to the convenience of discharge and the structural advantage of preventing waste of the shampoo solution by suppressing excessive discharge, most shampoo containers are equipped with a pump (dispenser).

Looking at the configuration of the conventional dispenser (No. 20-0428943 for registered model room) manufactured for the above purpose is as follows.

A conventional dispenser includes a container in which liquid is accommodated; a housing fixed to the opening side of the container and formed downward and having a negative pressure hole; A hollow shaft that moves up and down by a user's push in the housing; A piston connected to the lower part of the shaft to pressurize or depressurize the inside of the housing; A nozzle head fixed to an upper portion of the shaft while communicating with the shaft; and a chaplet fixed to an upper end of the housing and located between the housing and the shaft. to provide

A spring having an upper end in contact with a lower end of the piston is installed inside the housing, and a discharge hole is formed between the shaft and the chaplet to secure the inflow and outflow of air.

Since the conventional dispenser has to lift the contents from the end of the tube, that is, the bottom of the container, when pumping, the pumping force is small and the probability of pumping failure is high. In particular, when the viscosity of the contents is high, it is more difficult to pump the contents. There is a problem in that the discharge power is lowered and it is difficult to press the nozzle head. Since the steel spring is built into the housing and is always in contact with the liquid inside the container, there is a risk of deterioration of the liquid due to corrosion of the spring. There is a problem that the manufacturing cost is high due to the excessive number of parts, and since the steel spring and the remaining components made of plastic are assembled together, it is not easy to separate the collection for recycling when disposing of the dispenser.

Domestic Registration No. 20-0428943 (registration date: October 10, 2006)

The present invention was invented to improve the above problems, and the problem to be solved by the present invention is that in the case of pumping by a nozzle lever method employing a lever structure, the user presses the nozzle lever using only one hand and simultaneously presses the nozzle lever Since liquid can be received and used from the discharge port of the lever, a large force can be generated with a small force by applying the lever principle, enabling one-handed use and providing a nozzle lever-type pump container with a lever structure that the elderly can use very easily. is to do

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

In order to achieve the above object, the nozzle lever-type pump container of the lever structure according to a preferred embodiment of the present invention accommodates the liquid therein, the upper part is open on the inlet side and the neck portion having a first coupling part on the outer circumferential surface A vessel in which is formed; a cap shoulder having a second coupling portion formed on an inner circumferential surface to be detachably coupled to the first coupling portion, a spring receiving portion bent into the neck portion, and a stem through-hole formed in the center; a cap body coupled to an upper portion of the cap shoulder, having a stem through-hole formed in a lower portion of the center, a nozzle lever support guide jaw formed on one inner surface, and a nozzle lever guide slot formed on the other inner surface; a cylinder connected to a lower portion of the cap shoulder and inserted into the container, and having a liquid accommodating space formed therein to suck the liquid in the container and discharge the sucked liquid when the liquid is pumped; a suction hose installed in a lower opening formed at a lower side of the cylinder to suck the liquid in the container; a check valve installed at a lower opening of the cylinder to selectively open and close the passage of the suction hose to suck the liquid into the liquid accommodating space and to discharge the sucked liquid when liquid is pumped; an elastic member (plastic spring) installed in the spring accommodating part and having a stem through-hole formed in the center; It is installed on top of the elastic member so that it can be installed up and down in the vertical direction while being elastically supported by the elastic member, a stem connection part having a flow path is formed in the lower part of the center, and a nozzle lever connection part is formed on the upper part of the stem connection part. An adapter having a nozzle lever hinge formed on both sides thereof; A stem body having a flow path therein and installed through the stem through-hole so as to be installed up-down together with the adapter when liquid is pumped, a liquid suction hole is formed on a side surface of a lower end of the stem body, and the stem body a stem in which a first stopper is formed in the middle of an outer circumferential surface of the stem and a second stopper is formed at a lower end of the stem body; It is installed in the cylinder so as to be up-down, and when the stem is up-down, the liquid suction hole is opened and closed by the first stopper and the second stopper to pump liquid, so that the lower end of the stem body can slide vertically. A piston ring member (piston ring) that is installed so as to; The adapter is rotatably coupled to the nozzle lever hinge part so that the liquid can be pumped by pressing the adapter downward, and is inserted into the guide slot of the nozzle lever to protrude out of the cap body. A flow path is formed along the direction, a discharge hole is formed at one end of the flow path, an inlet portion having an inlet hole connected to the nozzle lever communication hole is formed at the other end of the flow path, and the nozzle lever support guide jaw is supported at the end portion. A nozzle lever on which a support portion is formed to become; and a push button coupled to an upper portion of the adapter to pressurize the adapter downward to pump liquid, and is installed on the upper portion of the cap body to be slidable in an upward and downward direction. There are features composed of, including.

In addition, it is characterized by a structure in which the liquid is discharged by selecting a method of pressing the nozzle lever downward or a method of pressing the push button downward.

When pumping is performed by pressing the nozzle lever downward (when the lever principle is applied), the support portion of the nozzle lever remains caught on the upper end of the nozzle lever supporting guide jaw, but presses the push button downward. In the case of pumping in such a way, the support of the nozzle lever is characterized in that it is configured to be guided along the nozzle lever support guide jaw.

Hinge protrusions may be formed at both sides of the nozzle lever, and hinge holes may be formed at both upper ends of the exposure prevention cover to be coupled to the hinge protrusions.

In addition, the nozzle lever-type pump container having a leverage structure according to a preferred embodiment of the present invention further includes an exposure prevention cover installed on the nozzle lever to prevent exposure of the nozzle lever guide slot during liquid pumping.

In addition, when the exposure prevention cover is moved downward by pressing the nozzle lever downward, the cap shoulder may have an insertion space for the exposure cover so that the exposure cover can be inserted.

In addition, the nozzle lever hinge portion includes a guide block for guiding up-down movement of the nozzle lever when the nozzle lever rotates, a hinge groove formed on an inner wall surface of the guide block, and the It has a guide slant surface for guiding into the hinge groove.

Hinge protrusions may be formed on both sides of the nozzle lever so as to slide along the guide slope and engage into the hinge groove.

In addition, a first guide rail and a second guide rail may be formed on an inside of the cap body and an outer circumference of the adapter, respectively, to guide up-down movement (up-down movement) of the adapter.

In addition, in order to prevent mis-discharge of the liquid, a locking lever for limiting rotation of the nozzle lever may be installed on the nozzle lever.

In addition, the lock lever may be rotatably installed at a lower end of the nozzle lever by a hinge, and a lock lever accommodating groove may be formed at a lower end of the nozzle lever so that the lock lever is accommodated in the nozzle lever.

In addition, when it is desired to limit the position of the nozzle lever using the lock lever, the lock lever is rotated around the hinge to be drawn out of the lock lever receiving groove and positioned vertically so that the lower end of the lock lever is It may be configured to be caught at the bottom of the nozzle lever guide slot.

When the lower end of the lock lever is caught on the lower end of the nozzle lever guide slot, the position of the nozzle lever is limited so that the liquid is not arbitrarily discharged due to the user's negligence.

In addition, the nozzle lever connecting portion has a concave groove, and the inlet portion of the nozzle lever is formed in a hemispherical shape, so that when the nozzle lever is rotated and pressed around the nozzle lever hinge portion during liquid pumping, the inlet portion is in the concave groove. It is characterized in that it is configured to be in close contact to prevent leakage of liquid.

As described above, the present invention has the following effects.

First, in the case of a method using a nozzle lever, as well as being able to alternatively use either a method using a push button or a method using a nozzle lever, the user presses the nozzle lever using only one hand and the nozzle at the same time Since liquid can be received and used from the discharge port of the lever, a large force can be generated with a small force by applying the lever principle, which enables one-handed use and has the advantage that the elderly can use it very easily.

Second, it is eco-friendly because it uses a plastic spring, and the pump container of the present invention is not locked by pressing a push button (discharge cap) when released, but by locking the locking lever so that the plastic spring is not compressed and is not elastically deformed. Since it is released, there is no deformation of the plastic spring during the product distribution process, and after releasing the lock lever, the user (consumer) discharges (discharges) the liquid by selecting the nozzle lever or the push button, so the pumping power is reduced. The conventional problems can be solved.

The 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 perspective view showing a nozzle lever-type pump container having a leverage structure according to the present invention;
Figure 2 is a longitudinal cross-sectional view showing a nozzle lever-type pump container of a leverage structure according to the present invention
Figure 3 is a longitudinal cross-sectional view showing a lever structure nozzle lever type pump according to the present invention
Figure 4 is a vertical cross-sectional view explaining that liquid is discharged by pressing a push button downward in a nozzle lever-type pump having a leverage structure according to the present invention.
Figure 5 is a longitudinal cross-sectional view explaining that the liquid is discharged by pressing the nozzle lever downward in the nozzle lever type pump of the leverage structure according to the present invention.
Figure 6 is an exploded perspective view showing a nozzle lever type pump container of leverage structure according to the present invention
7 to 9 are exploded perspective views showing a nozzle lever type pump having a lever structure according to the present invention
Figure 10 is a separated longitudinal cross-sectional view showing components in the nozzle lever type pump of the leverage structure according to the present invention
11 is a view explaining the principle of leverage of the present invention

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings to the extent that those skilled in the art to which the present invention pertains can easily practice the present invention.

In describing the present embodiment, description of technical contents that are well known in the technical field to which the present invention belongs and are not directly related to the present invention will be omitted. This is to more clearly convey the gist of the present invention without obscuring it by omitting unnecessary description.

For the same reason, in the accompanying drawings, some components are exaggerated, omitted, or schematically illustrated.

Also, the size of each component does not entirely reflect the actual size. In each figure, the same reference number is given to the same or corresponding component.

Also, device or element orientation (e.g. “front”, “back”, “up”, “down”, “top”, “bottom”) ", "left", "right", "lateral"), etc., the expressions and predicates used in the present invention are only used to simplify the description of the present invention, and related It will be appreciated that it does not indicate or imply that a device or element simply must have a particular orientation.

Hereinafter, with reference to the accompanying drawings, a lever structure nozzle lever type pump container according to a preferred embodiment of the present invention will be described in detail.

1 is a perspective view showing a nozzle lever type pump container of a lever structure according to the present invention, and FIG. 2 is a longitudinal sectional view showing a nozzle lever type pump container of a lever structure according to the present invention.

As shown in Figures 1 and 2, the nozzle lever-type pump container 1 of the lever structure according to a preferred embodiment of the present invention accommodates the liquid (liquid content) therein, and the upper part is open at the inlet side and the outer circumferential surface A container 10 having a neck portion 11 having a first coupling portion 12 thereon; and a nozzle lever-type pump 100 detachably installed on the neck part 11 of the container 10 to pump liquid.

Corresponding to the first coupling portion 12, the cap shoulder 110 of the pump 100 may have a second coupling portion 112.

Here, the first coupling portion 12 and the second coupling portion 112 are coupling means for detachably coupling the pump 100 to the container 10, and are not limited to screw coupling methods, and other coupling structures may be used. All inclusive.

Hereinafter, a nozzle lever type pump 100 having a lever structure according to a preferred embodiment of the present invention will be described in detail.

3 is a longitudinal cross-sectional view showing a nozzle lever-type pump having a leverage structure according to the present invention, and FIG. 4 is a description of discharging liquid by pressing a push button downward in the nozzle lever-type pump having a leverage structure according to the present invention. FIG. 5 is a longitudinal cross-sectional view illustrating ejection of liquid by pressing the nozzle lever downward in the nozzle lever-type pump having a leverage structure according to the present invention.

6 is an exploded perspective view showing a nozzle lever-type pump container of a leverage structure according to the present invention, and FIGS. 7 to 9 are exploded perspective views showing a nozzle lever-type pump having a leverage structure according to the present invention. And Figure 10 is a separated longitudinal cross-sectional view showing the components in the nozzle lever type pump of the lever structure according to the present invention

As shown in the above figure, the nozzle lever-type pump 100 of the lever structure according to a preferred embodiment of the present invention has a hollow cap shoulder in which a stem through hole (H: shown in FIGS. 8 and 10) is formed in the center. (110); a cap body 120 coupled to an upper portion of the cap shoulder 110; a cylinder (housing) 130 having a liquid accommodating space 131; Suction hose 40 connected to the lower side of the cylinder 130; When liquid is pumped, a check valve 50 that selectively opens and closes a flow path (P: shown in FIGS. 4 and 5) of the suction hose 40; An elastic member 60 generating an elastic restoring force when liquid is pumped; An adapter (up-down member) 140 installed to be up-down and up-down while being elastically supported by the elastic member 60; When liquid is pumped, the stem 150 is installed to be up-down together with the adapter 140; When the stem 150 is up and down, the piston ring member 160 opens and closes the liquid suction hole 151a (shown in FIG. 6) of the stem 150 to pump liquid; A nozzle lever 170 having a lever structure that allows a user to pump liquid by pressing downward with one hand; and a push button 70 coupled to an upper portion of the adapter 140 to pump liquid by pressing the adapter 140 downward. There are features composed of, including. Here, the passage P refers to a passage through which the liquid passes during pumping in order to discharge (discharge) the liquid, which is the content of the container 10 .

In the nozzle lever type pump 100 having a leverage structure according to a preferred embodiment of the present invention, the push button 70 is pressed downward (shown in FIG. 4) or the nozzle lever 170 is pressed downward (lever). method) (shown in FIG. 5) to discharge the liquid.

First, in the case of the method using the push button 70 as shown in FIGS. 4 and 10, one hand presses the push button 70 and the other hand discharges liquid from the outlet 171 of the nozzle lever 170. On the other hand, as shown in FIGS. 5 and 10, in the case of the method using the nozzle lever 170, the user presses the nozzle lever 170 using only one hand and at the same time the nozzle lever 170 ) Can receive liquid from the discharge port 171 and use it, which generates a large force with a small force by applying the lever principle, which enables one-handed use and has the advantage that the elderly can use it very easily.

The configuration of the nozzle lever-type pump 100 having a lever structure according to a preferred embodiment of the present invention will be further described.

First, a second coupling part 112 (shown in FIG. 2) is formed on the inner circumferential surface of the cap shoulder 110 so as to be detachably coupled to the first coupling part 12 (shown in FIG. 6).

As shown in FIGS. 6 to 8 and 10 , the cap shoulder 110 has a spring receiving portion 113 bent toward the inside of the neck portion 11 and has a stem through hole H in the center. is formed The stem through hole H refers to a hole (hole) into which the upper end of the stem 150 is inserted and coupled.

The cap body 120 is coupled to an upper portion of the cap shoulder 110, a nozzle lever support guide jaw 121 is formed on one inner surface, and a nozzle lever guide slot 122 is formed on the other inner surface. The nozzle lever guide slot 122 refers to a groove formed in the cap body 120 to prevent interference between the nozzle levers 170 during liquid pumping.

The nozzle lever support guide jaw 121 and the nozzle lever guide slot 122 may be formed at positions facing each other.

The cap shoulder 110 is integrally assembled to the lower part of the cap body 120, which is defined as a cap.

The user is configured to couple or separate the nozzle lever-type pump 100 to the neck part 11 of the container 10 while rotating the cap in a forward or reverse direction (in the case of a screw coupling method).

In addition, as shown in FIG. 6 , the cylinder 130 is connected to the lower portion of the cap shoulder 110 and inserted into the container 10 . The cylinder 130 is integrally assembled to the lower portion of the cap shoulder 110.

When liquid is pumped, the cylinder 130 may have a liquid accommodating space 131 for sucking the liquid in the container 10 and discharging the sucked liquid, and may have a lower opening 132 formed at the lower side. have. The bottom of the flange 133 of the cylinder 130 is mounted on the upper end of the neck portion 11 through an O-ring O, and the O-ring O serves to prevent leakage of liquid.

In addition, as shown in FIGS. 3 and 6, the suction hose 40 is formed in a hollow structure having a flow path P and is formed on the lower side of the cylinder 130 to suck the liquid in the container 10. It may be installed in the lower opening 132 .

In addition, when liquid is pumped, the check valve 50 selectively opens and closes the flow path P of the suction hose 40 to suck the liquid in the container 10 into the liquid accommodating space 131 and transfer the sucked liquid to the outside. It may be mounted on the lower opening 132 of the cylinder 130 to discharge. The check valve 50 is opened when the liquid in the container 10 is sucked into the liquid accommodating space 131 and closed when the sucked liquid is discharged to the outside.

In addition, as shown in FIG. 9 , the elastic member 60 may be installed in the spring accommodating part 113 and a stem through hole H may be formed in the center. The stem 150 is installed through the stem through hole H.

The elastic member 60 of the present invention is eco-friendly because it is made of a cylindrical corrugated pipe spring made of a plastic material.

The elastic member 60 is corrugated and may be manufactured in various ways, such as a spring bellows made of plastic or a ring-type spring in which a ring is wound.

In a conventional pump container using a metal spring, when disposing of the pump container, it is very difficult to disassemble the metal spring in the pump due to the assembly structure, so the entire pump container has been discarded without being able to separate and collect the metal spring from the plastic pump. In the present invention, by using the plastic spring 60, the pump container can be recycled without separate collection.

The conventional pump container is used after releasing the compression state of the spring when the user (consumer) purchases and uses it after release, and since the plastic spring remains compressed for a long time during the product distribution process, the plastic spring There is still a problem that the pumping force is lowered because the elastic restoring force is significantly lowered.

However, unlike the conventional configuration, the pump container 1 of the present invention is not locked by pressing the push button (discharge cap) 70, but by applying a locking structure by rotation of the lock lever 190, Since the spring 60 is not compressed and released in a state where it is not elastically deformed, deformation of the plastic spring 60 does not occur at all during the product distribution process, and after unlocking the lock lever 190, the user (consumer) Since) discharges (discharges) the liquid by selecting the nozzle lever 170 or the push button 70, there is an advantage in that the pumping force does not drop at all even when a plastic spring is used unlike the prior art.

In addition, as shown in FIGS. 6 to 8 and FIG. 10 , the adapter 140 is elastically supported by the elastic member 60 and installed on top of the elastic member 60 so that it can be installed up and down. installed

The adapter 140 has a stem connection part 141 having a flow path P at the lower center, a nozzle lever connection part 142 is formed on the top of the stem connection part 141, and a nozzle lever hinge part 143 on both sides ) can be formed.

In addition, as shown in FIGS. 6 to 8 and 10, the stem 150 has a flow path P therein so that it can be installed up and down together with the adapter 140 when liquid is pumped, and has a stem through hole ( H) is provided with a stem body 151 installed through.

A liquid suction hole 151a is formed at the side of the lower end of the stem body 151, a first stopper 152 is formed in the middle of the outer circumferential surface of the stem body 151, and an inclined surface 153a is formed at the lower end of the stem body 151. ) A second stopper 153 having a may be formed.

In addition, as shown in FIG. 10, the piston ring member 160 is made of soft synthetic resin and can be installed up and down in the cylinder 130, and when the stem 150 is up and down, the first stopper ( 152) and the second stopper 153, the liquid suction hole 151a can be opened and closed to pump the liquid, so that the lower part of the stem body 151 can slide vertically.

The piston ring member 160 is mounted on the contact portion 161 that is in close contact with the inner circumferential surface of the housing 130, the stem body 151 and the holder portion 162 having a contact protrusion 162a for contacting the inclined surface 153a , And may be composed of a connection rib 163 connecting the contact portion 161 and the holder portion 162.

Here, the piston ring member 160 is inserted into the stem body 151 between the first stopper 152 and the second stopper 153 and is installed to be movable to some extent up and down, and the nozzle lever 170 is moved downward. , or when the push button 70 is pressed downward, the adapter 140 and the stem 150 move downward to expose the liquid suction hole 151a (the contact protrusion adheres to the inclined surface of the second stopper). state), and successively, the first stopper 152 presses the piston ring member 160 downward to increase the pressure in the liquid accommodation space 131 so that the liquid in the liquid accommodation space 131 moves through the liquid suction hole ( 151a), it is discharged (discharged) through the discharge hole 171 of the nozzle lever 170 through the passage P.

Prior to discharge, the check valve 50 already blocks the flow path P of the suction hose 40 by the high pressure in the liquid accommodating space 131 .

On the other hand, when the nozzle lever 170 is pressed downward or the push button 70 is removed, the adapter 140 and the stem 150 are moved by the elastic restoring force of the elastic member 60. Moving upward, successively, as the second stopper 153 pushes the piston ring member 160 upward, the liquid suction hole 151a is blocked by the piston ring member 160 (the contact protrusion is the second close contact with the inclined surface of the stopper), the liquid in the container 10 is charged into the liquid accommodation space 131 through the suction hose 40 by the pressure drop in the liquid accommodation space 131.

Prior to charging, the check valve 50 is in a state in which the flow path P of the suction hose 40 is already opened by the negative pressure (low pressure) of the liquid accommodating space 131 .

In addition, as shown in FIGS. 6 to 8 and 10, the nozzle lever 170 presses the adapter 140 downward to pump the liquid so as to be able to rotate to the nozzle lever hinge part 143 It is coupled and inserted into the nozzle lever guide slot 122 so as to protrude out of the cap body 120. It is preferable that the proportion of the nozzle lever 170 protruding out of the cap body 120 is 1/2 or more.

A support 174 to be supported on the nozzle lever support guide jaw 121 may be formed at an end of the nozzle lever 170 .

In the present invention, the liquid is discharged by selecting either pumping by pressing the nozzle lever 170 downward or pumping by pressing the push button 70 downward.

First, when pumping is performed by pressing the nozzle lever 170 downward (when the lever principle is applied), the support part 174 of the nozzle lever 170 is at the upper end of the nozzle lever support guide jaw 121. stay stuck

Also, when pumping is performed by pressing the push button 70 downward, the support part 174 of the nozzle lever 170 is configured to be guided up and down along the nozzle lever support guide jaw 121 .

Meanwhile, FIG. 11 is a diagram illustrating the principle of leverage of the present invention.

Referring to FIG. 11, the leverage principle applied to the present invention will be described.

Lever refers to a rod that transmits force, and the fulcrum supports the rod, and the supporting point is called "support point", and the point where force is applied is called "power point", and the object (corresponding to the adapter of the present invention) The point at which the force acts is called the "point of action".

There are three types of leverage. Class 1 lever, class 2 lever. There are 3 types of levers. Lever is classified according to the location of the fulcrum point, power point, and action point. Class 1 and 2 levers are used to produce a large amount of power with little force or when a large amount of force is required but a wide range of work is required. And the third-class lever is used when an object is moved quickly or sophisticated manipulation is required.

The technology of the present invention applies the principle of two types of levers, and is a lever in which the point of action is located between the point of force and the point of fulcrum.

The lever corresponds to the nozzle lever 170, the fulcrum corresponds to the support 174, and the force point corresponds to the force that the user presses the nozzle lever 170 towards the outlet 171. In the present invention, the adapter 140 is installed below the point of action.

In this lever structure, when the user lowers the discharge port of the nozzle head down, the force point is located farther from the fulcrum than the action point, so the user applies the principle of applying a greater force to the action point with less force.

By applying the lever principle in this way, when liquid is pumped, a large force can be generated with a small force, so that the elderly can use it easily and can conveniently use it with only one hand.

In addition, the push button 70 is coupled to and fixed to the upper end of the adapter 140 so that liquid can be pumped by pressing the adapter 140 downward, and is installed on the upper portion of the cap body 120 to be slidable in an up and down direction. can

A coupling protrusion 71 may be formed at the bottom of the push button 70 to be fixed to the upper end of the adapter 140 . A blocking portion 72 for blocking a portion of the nozzle lever guide slot 122 may be formed on one side of the push button 70 to extend.

In addition, the nozzle lever type pump 100 of the leverage structure of the present invention prevents exposure of the nozzle lever guide slot 122 during liquid pumping to protect the appearance, and the exposure prevention cover 180 installed on the nozzle lever 170 : shown in FIGS. 3 and 6).

When the nozzle lever 170 is pressed downward to move the exposure cover 180 downward, the cap shoulder 110 is formed into an exposure cover insertion space 115 so that the exposure cover 180 can be inserted. 10) is further provided.

Hinge protrusions 170a are formed on both sides of the nozzle lever 170, and hinge holes 180a are formed at both upper ends of the exposure prevention cover 180 to be coupled to the hinge protrusions 170a, thereby forming the hinge holes 180a ) Due to the hinge structure and its own weight, the exposure prevention cover 180 is always vertically disposed regardless of the rotation angle of the nozzle lever 170.

The adapter 140 connects the nozzle lever 170 and the stem 150, enables rotation of the nozzle lever 170, and prevents liquid from leaking even during rotation of the nozzle lever 170 during pumping. play a role

5 and 10, the nozzle lever hinge part 143 includes a guide block 143a for guiding up-down movement of the nozzle lever 170 when the nozzle lever 170 rotates, and a guide block It has a hinge groove (143b) formed on the inner wall surface of (143a) and a guide inclined surface (143c) for guiding the hinge groove (143b) to the inside. Hinge protrusions 170b are formed on both sides of the nozzle lever 170 to be inserted into the hinge groove 143b.

The guide block 143a serves to guide the nozzle lever 170 to stably operate when the nozzle lever 170 rotates, and the guide inclined surface 143c has a hinge protrusion 170b when assembled to guide the inclined surface 143c. It slides along and is formed on both sides of the nozzle lever 170 so as to stably engage into the hinge groove 143b.

In addition, in order to guide the up-down movement of the adapter 140 during liquid pumping, a first guide rail R1 and a second guide rail R2 are formed on the inside of the cap body 120 and the outer circumference of the adapter 140, respectively. It can be (shown in Figures 6 to 8). The second guide rail R2 is slidably installed relative to the first guide rail R1. Since the second guide rail R2 is slidably installed relative to the first guide rail R1, the up-down movement of the adapter 140 can be stably operated.

In addition, a locking lever (190: shown in FIGS. 3 and 6) is installed on the nozzle lever 170 to limit the rotation of the nozzle lever 170 in order to prevent erroneous discharge of the liquid (accidental discharge due to carelessness). It can be.

A locking lever 190 is rotatably installed at the lower end of the nozzle lever 170 by a hinge 191 (FIGS. 6 to 8).

As shown in FIG. 10 , a lock lever accommodating groove 176 is formed at the lower end of the nozzle lever 170 so that the lock lever 190 is received into the nozzle lever 170 . A hinge groove 176a is formed in the lock lever accommodating groove 176, and the hinge 191 is coupled to the hinge groove 176a.

When trying to limit the position of the nozzle lever 170 using the locking lever 190 (when limiting the downward movement of the nozzle lever), locking by rotating the locking lever 190 around the hinge 191 By withdrawing from the lever accommodating groove 176 and positioning it vertically, the lower end of the locking lever 190 may be configured to be caught on the lower end of the nozzle lever guide slot 122 .

When the lower end of the lock lever 190 is caught on the lower end of the nozzle lever guide slot 122, the position of the nozzle lever 170 is limited so that the liquid is not arbitrarily discharged due to the user's negligence.

Referring to the operation of the pump 100 according to a preferred embodiment of the present invention configured as described above is as follows.

First, referring to FIGS. 4 and 10, in the case of the method using the push button 70, one hand presses the push button 70 and the other hand receives liquid from the outlet 171 of the nozzle lever 170. Both hands can be used.

5 and 10, in the case of the method using the nozzle lever 170, the user presses the nozzle lever 170 using only one hand and at the same time liquid flows from the outlet 171 of the nozzle lever 170. can be received and used.

As shown in FIG. 11, the method of using the nozzle lever 170 can generate a large force with a small force by applying the lever principle, enabling one-handed use as well as being very easy for the elderly to use. There are advantages.

The pump 100 according to a preferred embodiment of the present invention uses a method of pressing the nozzle lever 170 downward or a method of pressing the push button 70 downward, depending on the elastic force of the elastic member 60. While the adapter 140 is elastically pressed downward by the stem 150, the stem 150 also moves downward and the liquid suction hole 151a is exposed (a state in which the contact protrusion is not in close contact with the inclined surface of the second stopper). 1 The stopper 152 presses the piston ring member 160 downward, and the liquid in the liquid accommodating space 131 is introduced into the liquid suction hole 151a by the pressure increase in the liquid accommodating space 131, and then the flow path P After passing through, it is discharged (discharged) through the discharge hole 171 of the nozzle lever 170. At this time, the check valve 50 blocks the flow path P of the suction hose 40.

On the other hand, when the nozzle lever 170 is pressed downward or the force pressing the push button 70 downward is removed, the adapter 140 elastically rises upward due to the elastic restoring force of the elastic member 60. While the stem 150 also moves upward, the liquid suction hole 151a is blocked by the piston ring member 160 as the second stopper 153 pushes the piston ring member 160 upward in succession. (The contact protrusion is in close contact with the inclined surface of the second stopper), the liquid in the container 10 is charged into the liquid accommodation space 131 through the suction hose 40 due to the pressure drop in the liquid accommodation space 131 . At this time, the check valve 50 is in a state in which the flow path P of the suction hose 40 is opened.

In this way, when liquid is discharged by using a method of pressing the nozzle lever 170 downward or by using a method of pressing the push button 70 downward, a pressure difference occurs in the pump and the pressure difference causes the flow path P The pumping process in which the liquid is discharged through is repeatedly performed.

As described above, the present invention has the following effects.

First, in the case of a method using a nozzle lever, as well as being able to alternatively use either a method using a push button or a method using a nozzle lever, the user presses the nozzle lever using only one hand and the nozzle at the same time Since liquid can be received and used from the discharge port of the lever, a large force can be generated with a small force by applying the lever principle, which enables one-handed use and has the advantage that the elderly can use it very easily.

Second, it is eco-friendly because it uses a plastic spring, and the pump container of the present invention is not locked by pressing a push button (discharge cap) when released, but by locking the locking lever so that the plastic spring is not compressed and is not elastically deformed. Since it is released, there is no deformation of the plastic spring during the product distribution process, and after releasing the lock lever, the user (consumer) discharges (discharges) the liquid by selecting the nozzle lever or the push button, so the pumping power is reduced. The conventional problems can be solved.

On the other hand, preferred embodiments of the present invention have been disclosed in the present specification and drawings, and although specific terms have been used, they are only used in a general sense to easily explain the technical content of the present invention and help understanding of the present invention. It is not intended to limit the scope of the invention. It is obvious to those skilled in the art that other modified examples based on the technical idea of the present invention can be implemented in addition to the embodiments disclosed herein.

The present invention may be modified in many ways and may take many forms. However, it should be understood that the present invention is not limited to the particular forms mentioned in the above detailed description, but rather all modifications, equivalents and substitutes within the spirit and scope of the present invention as defined by the appended claims. should be understood as including

10: Courage
11: neck portion
12: first coupling part
40: suction hose
50: check valve
60: elastic member
70: push button
100: Lever structure nozzle lever type pump container
110: cap shoulder
113: spring receiving part
115: exposure prevention cover insertion space
120: cap body
121: nozzle lever support guide jaw
122: nozzle lever guide slot
130: cylinder
131: liquid accommodation space
132: lower opening
140: adapter
141; stem connection
142: nozzle lever connection
142a: concave groove
143: nozzle lever hinge
143a: guide block
143b: hinge groove
143c: guide slope
150: stem
151: stem body
151a: liquid suction hole
152: first stopper
153: second stopper
153a: slope
160: piston ring member
161: close contact
162: holder part
162a: contact protrusion
163: connecting rib
170: nozzle lever
170a: hinge projection
170b: hinge protrusion
171: discharge hole
172: inflow hole
173: inlet
174: support
176: lock lever storage groove
176a: hinge groove
180: exposure protection cover
180a: hinge hole
190: lock lever
191: hinge
H: stem through hole
P: Euro
R1: first guide rail
R2: second guide rail

Claims (13)

A container 10 having a neck portion 11 having a first coupling portion 12 on an outer circumferential surface thereof and having an upper portion open on an inlet side for accommodating a liquid therein;
A second coupling portion 112 is formed on the inner circumferential surface so as to be detachably coupled to the first coupling portion 12, and a spring receiving portion 113 is bent to the inside of the neck portion 11, and the stem penetrates the center. a cap shoulder 110 in which a hole H is formed;
a cap body 120 coupled to an upper portion of the cap shoulder 110, having a nozzle lever support guide jaw 121 formed on one inner surface and a nozzle lever guide slot 122 formed on the other inner surface;
It is connected to the lower part of the cap shoulder 110 and is inserted into the container 10. Inside, there is a liquid accommodation space 131 for sucking the liquid in the container 10 and discharging the sucked liquid when liquid is pumped. Cylinder 130 formed;
A suction hose 40 connected to the lower opening 132 formed on the lower side of the cylinder 130 to suck the liquid in the container 10;
When liquid is pumped, the cylinder 130 selectively opens and closes the flow path P of the suction hose 40 to suck the liquid in the container 10 into the liquid accommodating space 131 and to discharge the sucked liquid. ) Check valve 50 installed in the lower opening 132 of;
an elastic member 60 installed in the spring accommodating part 113 and having a stem through hole H formed in the center;
It is installed on the upper part of the elastic member 60 so that it can be installed up and down while being elastically supported by the elastic member 60, and a stem connection part 141 having a flow path P is formed at the lower center of the center, , an adapter (up-down member) 140 having a nozzle lever connecting portion 142 formed on an upper portion of the stem connecting portion 141 and a nozzle lever hinge portion 143 formed on both sides;
A stem body 151 having a flow path P therein and installed through the stem through-hole H so as to be installed up and down together with the adapter 140 when pumping liquid is provided, and the stem body 151 A liquid suction hole 151a is formed on the lower side of the stem body 151, a first stopper 152 is formed in the middle of the outer circumferential surface of the stem body 151, and a second stopper 153 is formed on the lower end of the stem body 151 stem 150 formed;
It is installed in the cylinder 130 to be up-down, and when the stem 150 is up-down, the liquid suction hole 151a is opened and closed by the first stopper 152 and the second stopper 153 to supply liquid. a piston ring member 160 slidably installed at the lower end of the stem body 151 so as to pump;
The adapter 140 is rotatably coupled to the nozzle lever hinge 143 so as to pump liquid by pressing the adapter 140 downward, and is inserted into the nozzle lever guide slot 122 to protrude out of the cap body 120 Inside, a flow path P is formed along the longitudinal direction, a discharge hole 171 is formed at one end of the flow path P, and the other end of the flow path P is connected to the nozzle lever communication hole 142. a nozzle lever 170 having an inlet portion 173 having an inlet hole 172 and a support portion 174 formed at an end thereof to be supported by the nozzle lever support guide jaw 121; and
a push button 70 coupled to an upper portion of the adapter 140 so as to pressurize the adapter 140 downward to pump liquid, and is slidably installed on the upper portion of the cap body 120 in an up and down direction; Nozzle lever-type pump container of a lever structure comprising a. According to claim 1,
A nozzle lever-type pump container having a leverage structure further comprising an exposure prevention cover 180 installed on the nozzle lever 170 to prevent exposure of the nozzle lever guide slot 122 during liquid pumping. According to claim 2,
When the nozzle lever 170 is pressed downward to move the exposure cover 180 downward, the cap shoulder 110 is formed into the exposure cover insertion space so that the exposure cover 180 can be inserted. A nozzle lever-type pump container having a lever structure, characterized in that it further comprises (115). According to claim 2,
Hinge protrusions 170a are formed on both sides of the nozzle lever 170, and hinge holes 180a are formed at both upper ends of the exposure prevention cover 180 to be coupled to the hinge protrusions 170a. Nozzle lever type pump container with lever structure. According to claim 1,
The nozzle lever hinge part 143 is formed on a guide block 143a for guiding up-down movement of the nozzle lever 170 when the nozzle lever 170 rotates, and an inner wall surface of the guide block 143a It has a hinge groove (143b) and a guide inclined surface (143c) for guiding to the inside of the hinge groove (143b),
Lever structure, characterized in that hinge protrusions 170b are formed on both sides of the nozzle lever 170 so as to slide along the guide inclined surface 143c and engage into the hinge groove 143b Pump container. According to claim 1,
In order to guide the up-down movement of the adapter 140, a first guide rail R1 and a second guide rail R2 are formed on the inside of the cap body 120 and the outer circumference of the adapter 140, respectively. A nozzle lever-type pump container with a leverage structure. According to claim 1,
The nozzle of the lever structure, characterized in that the structure that discharges the liquid by selecting either pumping by pressing the nozzle lever 170 downward or pumping by pressing the push button 70 downward Lever type pump vessel. According to claim 1,
When pumping is performed by pressing the nozzle lever 170 downward, the support 174 of the nozzle lever 170 maintains a hooked state on the upper end of the nozzle lever support guide jaw 121,
When the push button 70 is pumped in a downward pressing manner, the support 174 of the nozzle lever 170 is configured to be guided along the nozzle lever supporting guide jaw 121. Lever structure, characterized in that Nozzle lever-type pump vessel. According to claim 1,
A nozzle lever-type pump container having a leverage structure, characterized in that a locking lever 190 for limiting rotation of the nozzle lever 170 is installed on the nozzle lever 170 to prevent mis-discharge of the liquid. According to claim 9,
The locking lever 190 is rotatably installed at the lower end of the nozzle lever 170 by a hinge 191, and the nozzle lever 170 so that the locking lever 190 is accommodated in the nozzle lever 170. The nozzle lever-type pump container of the leverage structure, characterized in that the locking lever receiving groove 176 is formed at the bottom of the. According to claim 10,
When the position of the nozzle lever 170 is limited using the lock lever 190, the lock lever 190 is rotated around the hinge 191 to withdraw it from the lock lever receiving groove 176 The nozzle lever-type pump container of the lever structure, characterized in that the lower end of the lock lever 190 is configured to be caught on the lower end of the nozzle lever guide slot 122 by positioning it vertically. According to claim 1,
When the nozzle lever 170 is pressed downward or the push button 70 is pressed downward, the adapter 140 is elastically pressed downward by the elastic force of the elastic member 60 and the stem 150 is also moved downward to expose the liquid suction hole 151a, the first stopper 152 presses the piston ring member 160 downward to increase the pressure in the liquid accommodating space 131 After the liquid in the liquid accommodating space 131 is introduced into the liquid suction hole 151a, it is discharged (discharged) through the discharge hole 171 of the nozzle lever 170 through the flow path P,
When the nozzle lever 170 is pressed downward or the force pressing the push button 70 downward is removed, the adapter 140 elastically rises upward by the elastic restoring force of the elastic member 60. The stem 150 also moves upward, and as the second stopper 153 pushes the piston ring member 160 upward, the liquid suction hole 151a is opened by the piston ring member 160. In the blocked state, a pumping process in which the liquid in the container 10 is charged into the liquid accommodation space 131 through the suction hose 40 by the pressure drop in the liquid accommodation space 131 is configured to be repeatedly performed. A nozzle lever-type pump container of a lever structure, characterized in that. In the pump container having a pump 100 detachably installed in the neck portion 11 of the container 10 for accommodating the liquid therein and having a pump 100 for pumping the liquid,
a cap shoulder 110 coupled to the neck portion;
a cap body 120 coupled to an upper portion of the cap shoulder 110;
a cylinder 130 connected to the lower portion of the cap shoulder 110 and having a liquid accommodating space 131;
A suction hose 40 connected to the lower side of the cylinder 130;
When liquid is pumped, a check valve 50 selectively opening and closing the flow path P of the suction hose 40;
an elastic member 60 installed in the cap shoulder 110;
An adapter 140 installed to be able to go up and down while being elastically supported by the elastic member 60;
A stem 150 having a hollow stem body 151 installed to be up-down together with the adapter 140 when liquid is pumped;
a piston ring member 160 installed in the cylinder 130 to be up-down and slidable up and down on the lower end of the stem body 151;
a nozzle lever 170 for pumping liquid by pressing the adapter 140 downward; and
a push button 70 coupled to an upper portion of the adapter 140 so as to pump liquid by pressing the adapter 140 downward, and installed slidably in an upward and downward direction on the upper portion of the cap body 120; Including,
A nozzle lever-type pump having a lever structure, characterized in that the structure is configured to discharge the liquid by pressing the nozzle lever 170 downward or pressing the push button 70 downward.

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