JP7365210B2 - discharge pump - Google Patents

Description

The present invention relates to a discharge pump that is attached to the mouth of a container body and is used to discharge contents contained within the container body.

Discharge pumps are known that are attached to the mouth of a container body and discharge the contents. For example, Patent Document 1 discloses that the device has a mounting cap attached to the mouth of a container body that accommodates contents, and a discharge port for discharging the contents to the outside, and that the mounting cap is located on the side of the container body. A discharge pump is disclosed that includes a discharge head that can be pushed down, a cylinder that is held by a mounting cap, and a suction mechanism that is connected to the cylinder and sucks the contents inside the container body.

According to this type of discharge pump, by pressing down the discharge head, a predetermined amount of the contents sucked by the suction mechanism can be discharged from the discharge port. In this way, a predetermined amount of contents can be discharged with a simple operation, so it can store contents such as shampoo, conditioner, liquid soap, alcohol disinfectant, lotion, etc. whose amount is generally constant each time. Discharge pumps are widely used in containers.

JP2019-26324A

Incidentally, in recent years, efforts to reduce environmental impact have become more important than ever, and waste separation is extremely important for promoting recycling or properly disposing of waste. The above-mentioned conventional discharge pump includes a metal member such as a coil spring within the cylinder that biases the discharge head upward. Therefore, conventionally, the discharge pump was removed from the container body and separated as non-combustible material. However, most of the discharge pump is made of resin, and it is preferable that the discharge pump also be able to be separated into resin parts and metal members.

Therefore, an object of the present invention is to provide a discharge pump that can separate metal members from resin parts.

The present invention has a mounting cap that is attached to the mouth of a container body that accommodates contents, and a discharge port for discharging the contents to the outside, and is pressed down toward the container body with respect to the mounting cap. A discharging head that can be provided, a biasing member that biases the dispensing head upward, and a suction mechanism that suctions the contents within the container body in accordance with the operation of the dispensing head are disposed, and the mounting a cylinder screwed onto and held by the cap, the cylinder being provided with an operating section on its outer circumferential surface for performing a rotation operation to release the screwing between the cylinder and the installed cap; An overcap that covers the ejection head is attached to the mounting cap, and the overcap has a fitting part into which the operating part is fitted, and the operating part is fitted into the fitting part. The urging member, the suction mechanism, or both may include a metal member, and the metal member may be connected to the mounting cap and the cylinder. The discharge pump can be removed from the cylinder by unscrewing the cylinder .

The mounting cap includes a mounting tube that is mounted on the outer peripheral surface of the mouth of the container body, and a cylinder groove that is provided in the mounting tube and into which the tip of the cylinder is press-fitted, and the cylinder groove and the tip of the cylinder are connected to each other. Of the contact surfaces where the two parts contact each other, one of the contact surfaces is provided with a thread in advance, and the other contact surface is provided with a thread in the vertical direction at an angle larger than the lead angle of the thread. Preferably, a plurality of extending vertical ribs are provided, and the cylinder groove and the cylinder are screwed together by plugging the tip of the cylinder into the cylinder groove.

Preferably, the outer peripheral surface of the mounting cap is provided with a fitting convex portion into which the fitting portion is fitted.

According to the discharge pump according to the present invention, the mounting cap that is attached to the mouth of the container body that accommodates the contents is screwed together with the cylinder. Therefore, when discarding the container, after removing the mounting cap from the container body, the screwing between the mounting cap and the cylinder can be released by, for example, rotating the cylinder with respect to the mounting cap. If the biasing member or suction mechanism installed in the cylinder includes metal parts, these metal parts can be removed from the cylinder and separated into metal parts and resin parts, and they can be disposed of appropriately. It becomes possible to dispose (including recycling), etc.

FIG. 2 is a diagram for explaining a discharge pump according to an embodiment of the present invention, in which (a) is a partial side sectional view showing the discharge pump, and (b) is an overcap that covers the discharge head of the discharge pump. It is a partial side sectional view showing a state in which the overcap shown in FIG. 1(b) is attached to the discharge pump shown in FIG. 1(a). 2 is a diagram for explaining each part of the discharge pump in FIG. 1, (a) is a part of a cross section taken along the line XX in FIG. FIG. 3B is a side sectional view showing a fitted state; FIG. It is a cross-sectional view taken in the direction of arrows, showing the cross-sectional shape of the operating section. It is a perspective view which shows the lower part of a cylinder for demonstrating the procedure which makes an operating part fit inside the fitting part provided in the overcap, and removes a cylinder from a mounting cap.

A discharge pump 100 according to an embodiment of the present invention will be described below with reference to FIGS. 1 to 4.
First, a schematic configuration of a discharge pump 100 according to the present embodiment will be described with reference to FIG. A discharge pump 100 shown in FIG. 1(a) includes a mounting cap 10 that is attached to the mouth of a container body (not shown), a discharge head 20 having a discharge port 21a for discharging contents to the outside, and a mounting cap 10. A cylinder 30 is held on the inside of the mounting cap 10 so that a lower portion 32 thereof extends toward the container body. The discharge pump 100 is configured such that the mounting cap 10 and the cylinder 30 are screwed together, and the cylinder 30 can be removed from the mounting cap 10 by rotating the cylinder 30 with respect to the mounting cap 10.

Further, the discharge pump 100 can be equipped with an overcap 40 shown in FIG. 1(b). The overcap 40 has a cylindrical shape with a top wall 41, and a notch 43 (fitting portion) is formed in the lower part of the peripheral wall 42. The notch portion 43 includes an engaging portion 43a having a predetermined shape, and a guide portion 43b provided in series with the lower portion of the engaging portion 43a. In this embodiment, the engaging portion 43a has a substantially hexagonal shape (hexagonal shape with rounded corners) when viewed from the front. More specifically, the engaging portion 43a is arranged such that its uppermost vertex _o0 overlaps the central axis O in front view, and the two opposing sides _s1 and _s2 are at the center. It has a substantially hexagonal shape oriented substantially parallel to the axis O. The guide portion 43b has a substantially trapezoidal shape when viewed from the front. The lower end of the guide portion 43b coincides with the lower end of the overcap 40 and is open. The notch portion 43 is formed such that the lower end of the guide portion 43b is larger than the maximum width of the engaging portion 43a (the shortest distance between sides _s1 and _s2 ). On the other hand, on the outer circumferential surface 11a of the mounting cap 10 (mounting tube 11) of the discharge pump 100, a fitting convex portion 11b has a predetermined shape substantially the same as the engaging portion 43a when viewed from the front, and protrudes radially outward from the outer circumferential surface 11a. is provided. When the overcap 40 is attached to the discharge pump 100, the fitting protrusion 11b of the attachment cap 10 is fitted into the notch 43 of the overcap 40, forming a mechanism for preventing the overcap 40 from coming off (see FIGS. 2 and 2). (See Figure 3(a)). Further, the overcap 40 can be used as a jig for rotating the cylinder 30 with respect to the mounting cap 10 when removing the cylinder 30 from the mounting cap 10 (FIG. 4). Note that this point will be discussed later.

Note that "upper" and "lower" in this specification indicate a relative positional relationship, and when the discharge pump 100 is attached to the mouth of the container body with the container body placed in an upright position. In this case, the side where the container body is located will be referred to as "lower" and the side where the discharge head 20 will be located will be referred to as "upper". Further, the circumferential direction refers to a direction in which the cylinder 30 revolves around the central axis (indicated by the symbol O in FIG. 1), and the radial direction refers to a direction perpendicular to the central axis. Furthermore, the central axes of the cylinder 30, overcap 40, and container body are assumed to coincide with the central axis O of the cylinder 30. Each component will be explained below.

The configuration of the mounting cap 10 of the discharge pump 100 will be described with reference to FIGS. 1 and 2. As shown in FIG. 1, the mounting cap 10 includes a mounting tube 11 that is mounted on the outer peripheral surface of the mouth of a container body (not shown), and a ring cap 12 that is provided on the top of the mounting tube 11.

The mounting cylinder 11 has a female threaded portion 11c on its inner circumferential surface that is screwed into a male threaded portion formed on the outer circumferential surface of the mouth of the container body (see FIG. 2).

As shown in FIG. 2, the ring cap 12 includes a ring-shaped bottom wall 13 that covers the upper end of the mounting tube 11 and the upper end of the mouth of the container body, and is erected from the upper surface of the bottom wall on the outer peripheral side of the bottom wall 13. an outer circumferential cylinder 14, an inner circumferential cylinder 15 erected from the inner circumferential end of the bottom wall 13, a ring-shaped ceiling wall 16 connected to the upper end of the inner circumferential cylinder 15 and protruding radially inward; The guide tube 17 is provided vertically from the inner peripheral end of the wall 16. The outer cylinder 14, the bottom wall 13, and the inner cylinder 15 form a head groove A that is open at the top (see FIG. 3(b)). Furthermore, the inner cylinder 15, the top wall 16, and the guide cylinder 17 constitute a cylinder groove B that is open at the bottom. The guide tube 17 has a smaller diameter than the mouth of the container body, and a stem 22 included in a discharge head 20, which will be described next, is inserted therethrough.

The ejection head 20 includes a pressing portion 21 and the stem 22 described above. The push-down part 21 includes the above-mentioned discharge port 21a, and includes a top wall 21b, a hanging wall 21c hanging downward from the outer peripheral end of the top wall 21b, and a hanging wall 21c provided on the back surface of the top wall 21b and fitted into the upper end of the stem 22. It includes a vertical tube 21d to be attached, a discharge port 21a provided in a hanging wall 21c, and a discharge passage 21e communicating with the stem 22. The lower end of the hanging wall 21c is inserted into the head groove A formed by the outer cylinder 14 provided on the ring cap 12, the bottom wall 13, and the inner cylinder 15.

The stem 22 includes an upper tube 22a and a lower tube 22b inserted into the upper tube 22a, and the upper tube 22a and the lower tube 22b are fitted. The lower cylinder 22b is urged upward by a biasing member 50 disposed within the cylinder 30.

The cylinder 30 is formed into a substantially cylindrical shape with open upper and lower ends, and inside thereof is provided the biasing member 50 and a suction mechanism for suctioning the contents. A storage space is provided inside the cylinder 30 to store a predetermined amount of contents sucked from the inside of the container body by the suction mechanism. Furthermore, a portion of the lower tube 22b and the upper tube 22a of the stem 22 are inserted into the cylinder 30.

As shown in an enlarged view in FIG. 3(b), the upper end portion 31 (tip portion) of the cylinder 30 is composed of an inner circumferential tube 15 provided on the ring cap 12, a top wall 16, and a guide tube 17. The cylinder groove B is inserted into the cylinder groove B, and is screwed into the cylinder groove B. Specifically, a plurality of vertical ribs 15a parallel to the central axis direction of the cylinder 30 are provided on the inner circumferential surface of the inner circumferential tube 15, which is the inner wall surface of the cylinder groove B. Further, the vertical rib 15a is provided with a thread groove 15b (female thread) that corresponds to a thread 31a (male thread) provided on the outer peripheral surface of the upper end portion 31 of the cylinder 30. The thread groove 15b is formed, for example, by press-fitting a cylinder 30 having a thread 31a formed on the outer circumferential surface of the upper end portion 31 into a cylinder groove B in which a plurality of vertical ribs 15a are provided, that is, by so-called hammering. By plugging, a thread groove 15b corresponding to the thread 31a provided on the upper end 31 of the cylinder 30 is formed (transferred) by deforming the vertical rib 15a. Further, the upper end portion 31 of the cylinder 30 is held between the inner circumferential tube 15 and the guide tube 17.

Next, the configuration of the lower portion 32 of the cylinder 30 will be described with reference to FIG. 1 again. The cylinder 30 has a vertically elongated cylindrical shape, and includes a portion disposed inside the mounting cap 10 and a portion disposed below the mounting cap 10. Here, the lower (exposed) portion of the mounting cap 10 is referred to as the lower portion 32 of the cylinder 30. The lower portion 32 of the cylinder 30 is provided with an operating portion 33 having a substantially hexagonal cross section as shown in FIG. 3(c). The outer shape of the operating portion 33 is substantially the same as the outer shape of the fitting convex portion 11b (see FIG. 1) provided on the outer circumferential surface 11a of the mounting cap 10.

As shown in FIG. 1, a step portion 34 is provided below the operating portion 33 and projects outward in the radial direction. A tapered portion 35 whose diameter is reduced is provided, and a cylindrical pipe fitting portion 36 into which a suction pipe 70 introduced into the container body is fitted is provided below the tapered portion 35.

Next, referring to FIG. 2, the biasing member 50 and the suction mechanism will be described. In this embodiment, the biasing member 50 is a metal coil spring, and is in contact with the lower tube 22b of the stem 22 and the inner peripheral surface of the cylinder 30. When the push-down part 21 is pressed down and a downward force is applied to the push-down part 21, a downward force is applied to the biasing member 50 via the lower cylinder 22b, and the coil spring is compressed. When the downward force on the pressing part 21 is released, the coil spring returns to its original shape, and at this time pushes the lower cylinder 22b back upward.

The suction mechanism includes a piston 61, a suction valve provided at the lower part 32 of the cylinder 30, and the like. The piston 61 is disposed below the guide tube 17 of the ring cap 12, and is provided in the cylinder 30 so as to be slidable on the inner circumferential surface of the cylinder 30 and the outer circumferential surface of the lower tube 22b of the stem 22. The suction valve opens and closes a flow path for contents connecting the suction pipe 70 and the accommodation space in the cylinder 30.

Next, the operation of the discharge pump 100 will be briefly explained. When the pressing part 21 of the ejection head 20 is pressed down and a downward force is applied to the pressing part 21, the stem 22 moves downward together with the pressing part 21. At this time, the stem 22 (lower cylinder 22b) moves downward with respect to the piston 61, and the communication hole 22c provided in the lower cylinder 22b is opened. Note that the communication hole 22c is a hole that communicates between the inside and outside of the lower cylinder 22b in the radial direction. After this communication hole 22c is opened, the piston 61 is pushed down by the upper cylinder 22a and moves downward together with the stem 22 while sliding against the inner peripheral surface of the cylinder 30, and the biasing member 50 is compressed downward. . At this time, the inside of the housing space of the cylinder 30 is pressurized, the suction valve is closed, and the communication hole 22c is opened. As a result, the contents stored in the accommodation space of the cylinder 30 are discharged to the outside from the discharge port 21a via the discharge passage 21e provided in the stem 22 and the discharge head 20.

When the downward force on the pressing part 21 is released, the stem 22 moves upward because it is urged upward by the urging member 50 and returns to its original position. With this operation, the inside of the accommodation space of the cylinder 30 becomes negative pressure, the communication hole 22c becomes closed, and the suction valve becomes open. As a result, the contents are sucked from the container body into the housing space of the cylinder 30 via the suction pipe 70, and a predetermined amount of the contents is stored in the housing space of the cylinder 30 again.

Next, a method for unscrewing the mounting cap 10 and the cylinder 30 will be explained. As described above, in the discharge pump 100 of this embodiment, the cylinder groove B provided in the mounting cap 10 and the upper end portion 31 of the cylinder 30 are screwed together (see FIGS. 2 and 3(b)). Therefore, by rotating the cylinder 30 with respect to the mounting cap 10, the threaded engagement between the mounting cap 10 and the cylinder 30 can be released.

In the discharge pump 100 of the present embodiment, the outer shape of the operating portion 33 provided at the lower part of the cylinder 30 and the inner circumferential shape of the engaging portion 43a of the notch portion 43 are approximately the same shape. Therefore, as shown in FIG. 4, for example, the discharge head 20 is held so that the cylinder 30 is disposed upward, and the operating section 33 is inserted through the guide section 43b of the notch section 43 provided in the overcap 40. Then, the operating portion 33 is fitted into the engaging portion 43a, and the overcap 40 can be used like a wrench (jig). At this time, the engaging portion 43a is prevented from coming off by the stepped portion 34. Then, by rotating the operating portion 33 using the overcap 40, the threaded state between the mounting cap 10 and the cylinder 30 can be released, and the cylinder 30 can be easily separated from the mounting cap 10.

For example, if the content is liquid soap, etc., the surface of the cylinder 30 etc. will have liquid soap etc. attached to it, and even if the operating section 33 is provided at the lower part 32 of the cylinder 30, the cylinder 30 will not be attached to the mounting cap 10. It may be difficult to rotate the When the cylinder 30 is rotated using the overcap 40, the notch part 43 and the operating part 33 are fitted, so the contents will not slip and the contents will not stick to your hands. The cylinder 30 can be easily separated from the mounting cap 10.

From the above, according to the discharge pump 100 of the present embodiment, when the biasing member 50 and the suction mechanism provided in the cylinder 30 include metal members (coil springs, ball valves, etc.), the mounting cap 10 The cylinder 30 can be separated, these metal members placed inside the cylinder 30 can be taken out, the metal parts and the resin parts can be separated, and each can be disposed of appropriately (including recycling), etc. It becomes possible to do this. In this embodiment, it is assumed that everything other than the biasing member 50 is made of resin, and the container body is also made of resin.

In the conventional discharge pump 100, the upper end of the cylinder 30 has an undercut shape, and the cylinder 30 is assembled to the mounting cap 10 by press-fitting (plugging) the upper end of the cylinder 30 into a cylinder groove provided in the mounting cap 10. Therefore, it was difficult to separate the cylinder 30 from the mounting cap 10. On the other hand, although it is relatively easy to provide a thread 31a on the upper end 31 of the cylinder 30, it is difficult to provide a thread groove on the inner wall surface of the cylinder groove B, which complicates the manufacturing process and increases costs. becomes. However, in the discharge pump 100 of the present embodiment, the upper end 31 of the cylinder 30 is provided with a thread 31a, and the inner wall surface of the cylinder groove B is provided with a plurality of vertical ribs 15a parallel to the central axis direction. By plugging the portion 31 into the cylinder groove B, the cylinder 30 can be assembled to the mounting cap 10 in the same manner as before while forming the thread groove 15b on the inner wall surface of the cylinder groove B, and the manufacturing process can be simplified. A configuration in which the cylinder 30 and the cap can be easily separated can be realized without major changes.

The present embodiment described above is only one aspect of the discharge pump 100 according to the present invention, and can be modified as appropriate without departing from the spirit of the present invention. For example, in the embodiment described above, the biasing member 50 is a metal coil spring, but the present invention is not limited to this embodiment. A metal ball valve may be used as the suction mechanism. Further, the configurations of the ejection head 20 and the suction mechanism are not limited to the examples shown in the above embodiments, and can of course be modified as appropriate.

Further, in the embodiment described above, the overcap 40 is provided with the notch 43, and the operating portion 33 is inserted from the lower end side of the overcap 40 so that the operating portion 33 is fitted into the notch 43. However, the present invention is not limited to this embodiment. For example, the overcap 40 may be provided with a through hole into which the operating portion 33 can be fitted, and this may be used as the fitting portion according to the present invention.

Furthermore, in the above embodiment, the fitting protrusion 11b is provided on the outer peripheral surface 11a of the mounting cap 10, and the fitting protrusion 11b is fitted into the notch 43 of the overcap 40. It is not necessarily necessary to provide such a fitting convex portion 11b on the outer peripheral surface 11a of 10. Further, the cross-sectional shape of the operating portion 33, the inner circumferential shape of the engaging portion 43a of the notch portion 43, and the outer shape of the fitting convex portion 11b are not limited to the approximately hexagonal shape shown in this embodiment. Of course, the shape may be various polygonal shapes such as a triangular shape or a quadrangular shape, or it may be a shape in which a part of a circular arc is cut by a straight line. Moreover, these shapes do not have to be the same. Furthermore, the operating portion 33 may have a configuration in which a plurality of vertical ribs are provided on the outer peripheral surface. In short, it is sufficient that the operating section 33 has a shape that functions as a non-slip when the operating section 33 is rotated. Further, the notch portion 43 only needs to have a side or a surface that engages with the operating portion 33 when the operating portion 33 is rotated.

Further, in the above embodiment, the thread 31a is provided on the outer circumferential surface of the upper end 31 of the cylinder 30, and the plurality of vertical ribs 15a are provided on the inner wall surface of the cylinder groove B, but the threads and the vertical ribs are Of the contact surfaces where the cylinder groove and the upper end (tip) of the cylinder 30 come into contact with each other, one of the contact surfaces is provided with a thread in advance, and the other contact surface has a plurality of longitudinal threads. It is sufficient that ribs are provided, and the embodiment is not limited to the above embodiment. However, as described above, it is often difficult to provide a thread on the inner wall surface of the cylinder groove B. Therefore, as in the above embodiment, it is preferable to provide a vertical rib on the abutment surface on the side of the cylinder groove B, and provide a thread on the abutment surface (outer peripheral surface) on the side of the upper end 31 of the cylinder 30.

Further, in the above embodiment, a plurality of vertical ribs 15a are provided on the inner wall surface of the cylinder groove B parallel to the central axis direction, but one contact surface is provided with a thread in advance, and the other contact surface is provided with a thread. When providing a plurality of vertical ribs, it is sufficient that these vertical ribs are arranged in parallel at an angle larger than the lead angle of the thread, and the direction in which the vertical ribs extend does not need to be parallel to the central axis direction. . However, by making the extending direction of the vertical ribs 15a parallel or substantially parallel to the central axis direction, mold release after molding becomes easier.

10: Mounting cap 11: Mounting tube 11a: Outer circumferential surface 11b: Fitting convex portion 11c: Female threaded portion 12: Ring cap 13: Bottom wall 14: Outer circumferential tube 15: Inner circumferential tube 15a: Vertical rib 15b: Thread groove 16: Top Wall 17 : Guide cylinder 20 : Discharge head 21 : Push part 21a : Discharge port 21b : Top wall 21c : Hanging wall 21d : Vertical cylinder 21e : Discharge path 22 : Stem 22a : Upper cylinder 22b : Lower cylinder 22c : Communication hole 30 : Cylinder 31 : Upper end 31a : Thread 32 : Lower part 33 : Operation part 34 : Step part 35 : Taper part 36 : Pipe fitting part 40 : Overcap 41 : Top wall 42 : Peripheral wall 43 : Notch part 50 : Biasing Member 61: Piston 70: Suction pipe 100: Discharge pump A: Head groove B: Cylinder groove O: Center shaft

Claims (3)

an attachment cap that is attached to the mouth of the container body that accommodates the contents;
a discharge head that has a discharge port for discharging the contents to the outside and is provided so as to be able to be pushed down toward the container body with respect to the mounting cap;
A biasing member that biases the ejection head upward and a suction mechanism that suctions the contents in the container body according to the operation of the ejection head are disposed, and are screwed and held by the mounting cap. a cylinder,
Equipped with
The cylinder is provided with an operation part on its outer circumferential surface for performing a rotation operation to release the threaded engagement between the cylinder and the mounting cap,
An overcap that covers the ejection head is attached to the attachment cap,
The overcap has a fitting part into which the operating part is fitted, and can be used as a jig for rotating the operating part by fitting the operating part into the fitting part. ,
The biasing member, the suction mechanism, or both include a metal member, and the metal member is removable from the cylinder by unscrewing the mounting cap from the cylinder. The mounting cap includes a mounting tube that is mounted on the outer peripheral surface of the mouth of the container body, and a cylinder groove that is provided on the mounting tube and into which the tip of the cylinder is press-fitted,
Among the contact surfaces where the cylinder groove and the tip end of the cylinder contact each other, one of the contact surfaces is provided with a thread in advance, and the other contact surface is provided with a lead of the thread. A plurality of vertical ribs extending in the longitudinal direction at an angle larger than the angle are provided, and the cylinder groove and the cylinder are screwed together by plugging the tip of the cylinder into the cylinder groove. The discharge pump according to item 1. The discharge pump according to claim 1 or 2 , wherein the outer peripheral surface of the mounting cap is provided with a fitting convex portion into which the fitting portion is fitted.

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