JPH0427761Y2 - - Google Patents

Description

[Detailed explanation of the idea] [Industrial application field] The present invention relates to a filling nozzle.

[Conventional technology]

Conventionally, filling nozzles that fill containers with highly viscous, stringy liquid or semi-solid cosmetics, drugs, etc., spray compressed air from the nozzle opening at the end of filling to prevent stringing. However, this method has the disadvantage that some of the contents may be scattered by the compressed air ejected from the nozzle opening and adhere to the mouth of the container and its surroundings, causing stains. Moreover, it is necessary to adjust the extrusion operation of the contents and the operation of blowing out compressed air each time depending on the physical properties of the contents, such as viscosity and stringiness.

Therefore, Shoji Fukushima, one of the inventors of this invention, and his colleagues developed the special public service in 1983-22402 as a means to solve these drawbacks.
As disclosed in the above publication, an extremely effective filling nozzle was devised that prevents the removal of string from the opening of the injection tube by the contents at the end of filling and prevents the string from staining the opening of the container.

However, with the filling nozzle of this invention, if it is desired to enlarge the opening of the injection tube 13, each part of the whole, including the nozzle body, must be made larger. This has the disadvantage that it is expensive in terms of cost.

[The problem that the idea aims to solve]

The present invention has been developed in view of the above-mentioned matters, and allows the diameter of the opening of the injection pipe to be changed easily and inexpensively, and allows the diameter of one filling nozzle to be formed into various diameters. The technical challenge is to do so.

[Means to solve the problem]

In the present invention, an annular protrusion 3 is protruded from the upper surface of a nozzle body 2 in which a content introduction passage 1 is curved downward from the side surface, and a cylinder 4 fitted on the annular protrusion 3 is used as a nozzle. A piston shaft 9 is provided vertically to a piston portion 8 which is detachably attached to the main body 2 and slides up and down within the cylinder 4, and compressed air inlets and outlets 10 and 11 are provided at the top and bottom of the piston portion 8 of the cylinder 4, respectively. death,
An injection tube 13 having a small diameter portion 12 at its tip is removably installed on the lower surface of the nozzle body 2, and slides up and down inside the nozzle body 2, and when descending, the small diameter injection tube 13 has an opening 14 at its lower end. This is a filling nozzle formed by removably engaging and engaging the upper end of a spindle 16 having a recess 15 on its lower end surface and the lower end of a piston shaft 9.

The upper end of the spindle 16 and the lower end of the piston shaft 9 have end faces facing each other with an S-shaped cross section, and the end faces are detachably attached to each other to form a meshing locking portion 17. The part 17 is located within the annular protrusion 3 at the top dead center of the piston part 8, and is located in the nozzle body 2 at the bottom dead center and is always held around the nozzle body 2, and is a sliding member that allows the spindle 16 to be inserted into the nozzle body 2. An atmosphere opening port 20 connecting the hole 18 with the outside is bored, and with this atmosphere opening port 20 as a reference, the sliding holes 1 on the cylinder 4 side and the injection pipe 13 side are drilled.
Gaskets 19a and 19b are provided on the inner circumferential surfaces of the cylinders 8, respectively.

[Effect]

In the present invention, when the cylinder 4 is removed from the nozzle body 2, the spindle 16 and piston shaft 9 are removed.
is pulled up to the outside of the annular protrusion 3 of the nozzle body 2, so that the engagement between the spindle 16 and the engagement portion 17 of the piston shaft 9 can be disengaged.

Then, the injection tube 13 is removed from the lower surface of the nozzle body 2, and the spindle 16 is extracted downward from the nozzle body 2.

Next, an injection tube 13 with an opening 14 of a desired diameter and a spindle 1 matching this injection tube 13 are prepared.
6, insert this spindle 16 into the nozzle body 2, and insert the engaging locking portion 1 of the spindle 16.
7 with the engaging locking portion 17 of the piston shaft 9,
The cylinder 4 is externally fitted onto the piston portion 8, and the cylinder 4 is attached to the nozzle body 2.

When a new injection tube 13 is attached to the lower surface of the nozzle main body 2, an injection tube 13 having a different diameter of the opening 14 can be attached to the filling nozzle.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

Figure 1 is a cross-sectional view, in which the contents, liquid, semi-solid, especially viscous, are curved downward from the side.
An annular protrusion 3 is protruded from the upper surface of a nozzle body 2 having an introduction path 1 for introducing stringable cosmetics, foods, medicines, etc.

The cylinder 4 is fitted closely to the annular protrusion 3.
The cylinder 4 is connected to the nozzle body 2 airtightly and removably by sandwiching the flange 5 at the lower end and the flange 6 at the upper end of the nozzle body 2 with a clamp fitting 7.
A piston portion 8 that slides vertically within the cylinder 4 is fitted into the cylinder 4. A piston shaft 9 is vertically disposed in the piston portion 8, and compressed air inlets and outlets 10 are provided above and below the piston portion 8 of the cylinder 4. , 11 are bored respectively.

On the lower surface of the nozzle body 2, there is a small diameter portion 12 at the tip.
The upper end of the injection tube 13 is connected to the upper end of the injection tube 13 by a screw cap 22 or other suitable means so as to be detachable so as to prevent the contents from leaking.

The nozzle body 2 has a spindle 1 which slides up and down within the nozzle body 2 and which, when descending, tightly fits into a small diameter part 12 having an opening 14 at the lower end and has a recess 15 on the lower end surface. It has been inserted.
The upper end of the spindle 16 and the lower end of the piston shaft 9 are removably interlocked by a meshing locking portion 17 formed to face the upper end of the spindle 16 and the lower end of the piston shaft 9. .

The upper end of the spindle 16 and the lower end of the piston shaft 9 have S-shaped cross-sectional end faces facing each other, and the end faces are detachably attached to each other to form an interlocking locking portion 17. This meshing locking part 1
7 is located within the annular protrusion 3 at the top dead center of the piston portion 8, and is located within the nozzle body 2 at the bottom dead center, so that the periphery thereof is always held by the annular protrusion 3 or the nozzle body 2.

When the spindle 16 is lowered, the lower edge of the spindle 16 is brought into alignment with the lower edge of the opening 12, or the lower edge of the spindle 16 is made to slightly protrude from the lower edge of the opening 12. 18 is a sliding hole of the spindle 16, 19a is a packing, and 20 is an air opening for smoothing the sliding of the spindle 16 and preventing compressed air from entering the contents due to wear of the packing 19a.

The atmosphere opening port 20 connects the outside with a sliding hole 18 through which the spindle 16 is inserted into the nozzle body 2, and the inner circumferential surface of the sliding hole 18 on the cylinder 4 side with this atmospheric opening 20 as a reference. The packing 19a is provided in the sliding hole 1 on the side of the injection pipe 13.
A gasket 19a is provided on the inner circumferential surface of 8. Also,
21 is a content injection port.

Note that instead of the clamp fitting 7, the flanges 5 and 6 may be connected using screws, bolts, or nuts, or the upper end of the nozzle body 2 and the lower end of the cylinder 4 may be connected by screwing. be.

In the embodiment of the present invention constructed as described above, the compressed air inlet/outlet 10 opened at the upper part of the cylinder 4 is opened to the atmosphere, compressed air is introduced through the compressed air inlet/outlet 11 opened at the lower part, and the piston part 8 and the spindle 1 are connected to each other.
6 and rise.

Then, with the tip of the spindle 16 retracted from the small diameter portion 12 to open the opening 14 of the small diameter portion 12, the lower end of the injection tube 13 is inserted into the container, the contents pressing device is activated, and the contents are pushed out. The contents are forced into the introduction path 1 through the contents pressure inlet 21 and discharged into the container through the opening 14 of the small diameter section 12.

At the same time, the container is pulled down to prevent contact between the contents filled in the container and the tip of the injection tube 13, and after filling a predetermined amount of contents, the compressed air inlet/outlet 11 at the bottom of the cylinder 4 is opened to the atmosphere. Compressed air is introduced from the upper compressed air inlet/outlet 10, the piston part 8 and the spindle 16 are lowered, and the spindle 1
6 is tightly fitted into the small diameter portion 12 to stop the contents from being discharged from the opening 14.

FIG. 2 shows an embodiment in which the injection tube 13 and spindle 16 of the embodiment shown in FIG. 1 are replaced with larger-diameter ones, so that the apparatus can be applied to a container having a large diameter container opening. This injection tube 13 has a small diameter portion 12 larger in diameter than the small diameter portion 12 of the previous embodiment at its lower end.

The spindle 16 has a large-diameter tip portion 23 formed at the lower end of the spindle 16 to tightly fit into the small-diameter portion 12 having a large diameter. moreover,
The same reference numerals as in the above embodiment indicate parts having the same structure, and the filling and stopping operations for filling the container with contents are the same as in the above embodiment.

In the embodiment shown in FIG. 1, the screw cap 22 is removed, the injection tube 13 is removed from the nozzle body 2, and the flange 6 of the nozzle body 2 and the flange 5 of the cylinder 4 are removed.
The cylinder 4 is removed from the nozzle body 2 by removing the clamp fitting 7 that connects the cylinder 4 to the nozzle body 2, and the piston part 8 is pulled up and the engagement locking part between the piston shaft 9 and the spindle 16 is attached to the upper surface of the annular protrusion 3 of the nozzle body 2. When it protrudes further, the piston shaft 9 is moved laterally to release the meshing lock.

Next, the spindle 16 is pulled out from the sliding hole 18 downward, and the spindle 16, which has a large-diameter tip 23 at the lower end shown in FIG. to lock.

Then, the cylinder 4 is attached to the piston part 8,
The upper and lower flanges 5 and 6 are connected by a clamp fitting 7, and an injection tube 13 having a small diameter portion 12 with a large diameter at the lower end is screwed onto the lower surface of the nozzle body 2 to form a cap 2.
2, and the only parts to be replaced are the spindle 16 and the injection tube 13.

After filling a predetermined amount of contents into containers such as small-diameter tube containers and large-diameter containers,
Due to the rapid descent of the piston part 8, the spindle 16
The lower end or the lower end of the large diameter tip 23 is connected to the small diameter part 1.
2, and when the lower end of the spindle 16 or the lower end surface of the large diameter tip 23 coincides with the opening surface of the lower end of the small diameter section 12 or protrudes and stops, the small diameter section 12 is filled. The air in the recess 15 formed on the spindle 16 or the lower end surface of the large diameter tip 23 is compressed by the contents, and the air in the recess 15 expands rapidly.
The contents at the lower part of the tip of the container 2 are blown downward, the threads around the opening 14 are removed, and the openings of the containers are prevented from being soiled by the threads when the containers are removed.

[Effect of idea]

In the present invention, the cylinder 4 is detachably connected to the nozzle body 2, and the injection pipe 13 is attached to the lower surface of the nozzle body 2.
The upper end of the spindle 16, which slides up and down within the nozzle body 2, and the lower end of the piston shaft 9 are removably engaged and engaged with each other.

Therefore, from the nozzle body 2, the cylinder 4
By removing the injection tube 13 and disengaging the upper end of the spindle 16 from the lower end of the piston shaft 9, the injection tube 13 and the spindle 16 can be replaced without replacing the nozzle body 2.

Therefore, the present invention works in the same way as preparing several types of filling nozzles by preparing one filling nozzle and a replacement injection tube 13 and spindle 16. It can be provided at low cost.

Then, remove the spindle 16 from the piston shaft 9, pull it out below the sliding hole 18, and remove it.
Since the lower end of the spindle 16 can be removed without passing through the slide hole 18, the spindle 16 can be removed without passing through the slide hole 18.
The tip of the slide hole 18 can be formed to have a larger diameter than the diameter of the sliding hole 18.

Further, the upper end of the spindle 16 and the lower end of the piston shaft 9 have S-shaped cross sections facing each other, and the cross sections are removably attached to each other to form a meshing locking portion 17. Reference numeral 17 is located within the annular protrusion 3 at the top dead center of the piston portion 8, and located within the nozzle body 2 at the bottom dead center, so that the circumference is always held.

Therefore, the engagement locking portion 17 between the upper end of the spindle 16 and the lower end of the piston shaft 9 is connected to the sliding hole 18.
Since there is absolutely no risk of it coming off inside, there is no need to form the interlocking locking part 17 into a locking part with a complicated structure.

Therefore, when the cylinder 4 is removed and the engagement locking part 17 is pulled out of the sliding hole 18,
Engagement locking part 1 with an S-shaped cross section that can be easily disengaged
7, and the spindle 16 can be easily removed.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of one embodiment of the present invention, and FIG. 2 is a sectional view showing the embodiment of FIG. 1 in which the injection tube and spindle are replaced with larger diameter ones. DESCRIPTION OF SYMBOLS 1... Introduction path, 2... Nozzle body, 3... Annular protrusion, 4... Cylinder, 8... Piston part, 9...
... Piston shaft, 10, 11 ... Compressed air inlet/outlet,
12... Small diameter portion, 13... Injection tube, 14... Opening, 15... Recess, 16... Spindle, 17...
...Meshing locking part, 18...Sliding hole, 19a, 19b
...Patsukin, 20...Air release port.

Claims (1)

[Claims for Utility Model Registration] An annular protrusion 3 is protruded from the upper surface of the nozzle body 2 in which a content introduction passage 1 is bored in a curved manner downward from the side surface, and the annular protrusion 3 is fitted into the annular protrusion 3. A cylinder 4 is detachably connected to the nozzle body 2, a piston shaft 9 is vertically disposed on a piston part 8 that slides up and down inside the cylinder 4, and compressed air inlets and outlets 10 are provided above and below the piston part 8 of the cylinder 4. . The upper end of the spindle 16, which has a recess 15 on the lower end surface and the lower end of the piston shaft 9, is removably engaged and engaged with the small diameter part 12 having an opening 14 at the lower end, and the upper end of the spindle 16 has a recess 15 on the lower end surface. and the lower end of the piston shaft 9 have end faces facing each other with an S-shaped cross section, and these end faces can be freely attached to and detached from each other to constitute a meshing and locking portion 17 . It is located within the annular protrusion 3 at the top dead center, is located in the nozzle body 2 at the bottom dead center, and its surroundings are always maintained, and the atmosphere connects the outside with the sliding hole 18 through which the spindle 16 is inserted into the nozzle body 2. An opening port 2 is bored, and on the inner peripheral surface of the sliding hole 18 on the cylinder 4 side and the injection pipe 13 side, based on the atmospheric opening port 20,
A filling nozzle characterized in that gaskets 19a and 19b are provided, respectively.