JP6972558B2 - Drug bottle - Google Patents

Description

The present invention relates to a drug bottle containing a drug such as a solid dialysis agent used for preparing a dialysate used for artificial dialysis.

There are two types of dialysis agents, a liquid type and a solid type. Most of the liquid type dialysis agent is occupied by water, and the weight and volume of the liquid type dialysis agent are large, so that the load of the transportation work to the dialysis medical staff is large and the storage space is also large. Therefore, in recent years, when a dialysate is used, a solid-type dialysis agent (hereinafter referred to as a solid dialysis agent) that is put into an automatic dissolution device and dissolved in water to prepare the dialysate has rapidly become widespread. ing.

Currently, there are two types of containers for storing solid dialysis agents: bag type and bottle type. A technique relating to a bag-type container for storing a solid dialysis agent is disclosed in, for example, Japanese Patent Application Laid-Open No. 2006-136615 (Patent Document 1).

Japanese Unexamined Patent Publication No. 2006-136615

Since the bottle-type container that stores the solid dialysis agent is made of a material with higher rigidity than the bag-type container, it is difficult to crush the container to reduce the volume of the container after use, and it is discarded. Sometimes there is the problem of being bulky.

An object of the present invention is to provide a drug bottle that can easily reduce the volume after use while ensuring rigidity.

The drug bottle of the present invention includes a bottle body, a first mouth portion formed at the upper end of the bottle body, and a second mouth portion formed at the lower end of the bottle body. The bottle body is formed with a groove that is recessed toward the inside of the bottle body and extends in the vertical direction. The groove has a bottom. In the cross section orthogonal to the vertical direction of the bottle body, the thickness of the cross section at the bottom is larger than the thickness of the cross section at the position farthest from the center of gravity of the cross section orthogonal to the vertical direction of the bottle body.

In the above-mentioned drug bottle, the bottom of the groove recessed toward the inside of the bottle body constitutes a pillar-like portion extending in the vertical direction. As a result, the rigidity of the drug bottle in the vertical direction is increased, so that deformation of the drug bottle during use can be suppressed. Since the drug bottle can be easily crushed starting from a portion having a small wall thickness away from the center of gravity, the volume of the drug bottle after use can be easily reduced.

The bottom extends vertically from the top of the groove to the bottom of the groove. By extending the bottom of the thick groove to the vicinity of the first mouth and the vicinity of the second mouth, the rigidity of the parts near the first mouth and the second mouth is increased, so that the deformation of the drug bottle is further suppressed. can do.

The shape of the groove in the cross section orthogonal to the vertical direction of the bottle body includes an arcuate portion. As a result, the drug bottle can be easily molded, and the productivity is improved.

The cross section of the bottle body orthogonal to the vertical direction is substantially rectangular. The groove is formed on the long side of a substantially rectangular cross section. This makes it possible to reliably and easily construct a thick bottom portion.

The above groove has a first groove and a second groove. The first groove and the second groove are formed so as to face each other with the center of gravity of the cross section orthogonal to the vertical direction of the bottle body. As a result, the rigidity of the drug bottle in the vertical direction becomes higher, so that the deformation of the drug bottle can be suppressed more reliably.

According to the present invention, it is possible to realize a drug bottle that can easily reduce the volume after use while ensuring rigidity.

It is a perspective view which shows the schematic structure of a drug bottle. It is a front view of the drug bottle shown in FIG. 1. It is a top view of the medicine bottle shown in FIG. 1 before the port portion is attached. It is a bottom view of the medicine bottle shown in FIG. 1 before the port portion is attached. It is an end view of the bottle body along the VV line shown in FIG. 1. It is an enlarged view of the region VI shown in FIG. It is an enlarged view with the region VII shown in FIG. It is a schematic diagram which shows the attachment state to the automatic dissolution apparatus of a medicine bottle.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following drawings, the same or corresponding parts are given the same reference numbers, and the description thereof will not be repeated.

<Overall configuration of drug bottle 1>
FIG. 1 is a perspective view showing a schematic configuration of the drug bottle 1. FIG. 2 is a front view of the drug bottle 1 shown in FIG. In the present specification, the direction indicated by the double-headed arrows in FIGS. 1 and 2 is referred to as the vertical DR1. As shown in FIGS. 1 and 2, the drug bottle 1 includes a bottle body 2, a first mouth portion 3, and a second mouth portion 4. The first mouth portion 3 is formed at the upper end of the bottle body 2. A flange portion is formed at the upper end of the first opening portion 3. The second mouth portion 4 is formed at the lower end of the bottle body 2. A flange portion is formed at the lower end of the second opening portion 4. The port portion 5 is fixed to the flange portion of the first opening portion 3 and the flange portion of the second opening portion 4.

The bottle body 2 includes a body portion 8, a first shoulder portion 9, and a second shoulder portion 10. The body portion 8 has a substantially rectangular box shape. The body portion 8 extends along the vertical DR1. The first shoulder portion 9 is connected to the upper end of the body portion 8. The first shoulder portion 9 extends from the body portion 8 to the first mouth portion 3. The first shoulder portion 9 is a part of the bottle body 2, and the cross section orthogonal to the vertical DR1 of the bottle body 2 decreases toward the upper side of the bottle body 2. The second shoulder portion 10 is connected to the lower end of the body portion 8. The second shoulder portion 10 extends from the body portion 8 to the second mouth portion 4. The second shoulder portion 10 is a part of the bottle body 2, and the cross section of the bottle body 2 orthogonal to the vertical DR1 decreases toward the lower side of the bottle body 2. The first mouth portion 3 is connected to the upper end of the first shoulder portion 9. The second mouth portion 4 is connected to the lower end of the second shoulder portion 10. The first mouth portion 3 and the second mouth portion 4 are formed to have a smaller diameter than the body portion 8 of the bottle body 2. The first opening portion 3 and the second opening portion 4 have a cylindrical outer peripheral surface.

A groove 14 is formed in the bottle body 2. The groove 14 has a shape in which the outer surface of the bottle body 2 is recessed toward the inside of the bottle body 2. The groove 14 extends in the vertical direction DR1 over the first shoulder portion 9, the body portion 8 and the second shoulder portion 10. The groove 14 has an upper end edge portion 15 and a lower end edge portion 16. The upper end edge portion 15 constitutes the upper end of the groove 14. The upper end edge portion 15 is formed on the first shoulder portion 9. The lower end edge portion 16 constitutes the lower end of the groove 14. The lower end edge portion 16 is formed on the second shoulder portion 10. The groove 14 extends in the vertical direction DR1 from the upper end edge portion 15 to the lower end edge portion 16.

FIG. 3 is a top view of the drug bottle 1 shown in FIG. 1 before the port portion 5 is attached. A liquid inlet 6 through which a liquid flows is formed at the upper end of the first opening 3. The liquid inlet 6 seen along the vertical DR1 has a circular shape. Let the radius of the liquid inlet 6 be r1. The port portion 5 is welded to the flange portion at the upper end of the first opening portion 3 and fixed to the first opening portion 3. The liquid inlet 6 is covered by the port portion 5.

FIG. 4 is a bottom view of the drug bottle 1 shown in FIG. 1 before the port portion 5 is attached. A liquid discharge port 7 from which a liquid is discharged is formed at the lower end of the second port portion 4. The liquid discharge port 7 seen along the vertical DR1 has a circular shape. The radius of the liquid discharge port 7 is r2. The port portion 5 is welded to the flange portion at the lower end of the second opening portion 4 and fixed to the second opening portion 4. The liquid discharge port 7 is covered with the port portion 5.

The direction indicated by the double-headed arrow in FIGS. 3 and 4 is referred to as the short side direction DR2. The short side direction DR2 is orthogonal to the vertical direction DR1.

After the port portion 5 is welded to one end of the bottle body 2 (the upper end of the first mouth portion 3 or the lower end of the second mouth portion 4), a solid-type drug (for example, a solid dialysis agent such as baking soda) is added to the drug bottle. Can be put in 1. After that, another port portion 5 is welded to the other end opposite to one end. The port portion 5 has a filter. The filter is configured to prevent leakage of the drug in the drug bottle 1 and to allow a solution (for example, RO water) described later and a dialysate in which the drug is dissolved in the solution to pass through the filter.

FIG. 5 is an end view of the body portion 8 along the VV line shown in FIG. The cross section of the body portion 8 orthogonal to the vertical direction is substantially rectangular. The body portion 8 has a pair of first wall surfaces 11 and a pair of second wall surfaces 12. The first wall surface 11 and the second wall surface 12 extend in the vertical direction DR1. The first wall surface 11 is a wall surface forming a long side of a substantially rectangular cross section orthogonal to the vertical DR1 of the body portion 8. Let G be the center of gravity in the cross section of the body portion 8 orthogonal to the vertical DR1. The pair of first wall surfaces 11 are formed so as to face each other with the center of gravity G interposed therebetween. The second wall surface 12 is a wall surface forming a short side of a substantially rectangular cross section orthogonal to the vertical DR1 of the body portion 8. The pair of second wall surfaces 12 are formed so as to face each other with the center of gravity G interposed therebetween.

The cross section of the groove 14 orthogonal to the vertical DR1 is arcuate. The groove 14 is formed on the first wall surface 11. The grooves 14 are formed in pairs facing each other with the center of gravity G interposed therebetween. The groove 14 has a bottom 17. The bottom portion 17 constitutes a portion of the bottle body 2 closest to the center of gravity G. As shown in FIG. 1, the bottom portion 17 extends in the vertical direction DR1 from the upper end edge portion 15 to the lower end edge portion 16. The distance a between the bottom portion 17 and the center of gravity G shown in FIG. 5 is larger than the radius r1 of the liquid inlet 6 shown in FIG. The distance a shown in FIG. 5 is larger than the radius r2 of the liquid discharge port 7 shown in FIG.

The depth of the groove 14 in the short side direction DR2 shown in FIGS. 3 and 4 is the outer peripheral surface 3a of the first wall surface 11 of the body portion 8 and the first mouth portion 3 or the outer peripheral surface of the second mouth portion 4 in the short side direction DR2. It is larger than the length obtained by halving the distance from 4a. Assuming that the depth of the groove 14 in the short side direction DR2 is b and the distance from the long side of the substantially rectangular cross section orthogonal to the vertical direction DR1 of the body portion 8 to the outer peripheral surface 3a of the first opening portion 3 is c1. × b> c1. If the distance from the long side of the cross section of the substantially rectangular cross section orthogonal to the vertical DR1 of the body portion 8 to the outer peripheral surface 4a of the second opening portion 4 is c2, then 2 × b> c2.

FIG. 6 is an enlarged view of the region VI shown in FIG. FIG. 7 is an enlarged view of the region VII shown in FIG. FIG. 6 shows a cross section of the bottom portion 17 orthogonal to the vertical DR1. FIG. 7 shows a cross section orthogonal to the vertical DR1 at a position farthest from the center of gravity G. As shown in FIGS. 6 and 7, the thickness of the cross section orthogonal to the vertical DR1 at the bottom 17 is larger than the thickness of the cross section orthogonal to the vertical direction at the position farthest from the center of gravity G. Assuming that the thickness of the cross section orthogonal to the vertical DR1 at the bottom 17 is t1 and the thickness of the cross section orthogonal to the vertical DR1 at the position farthest from the center of gravity is t2, t1> t2.

<Molding method for drug bottle 1>
The drug bottle 1 of the present invention is molded by blow molding. Blow molding is a method of molding a hollow resin product by sandwiching a parison (tube-shaped thermoplastic resin) with a mold, closing the top and bottom of the parison, blowing air, and pressing the parison against the inner surface of the mold. .. In blow molding, the parison expands like a balloon with the parison as the axis. The parison that comes into contact with the mold closer to the axis begins to cure sooner. Therefore, the wall thickness at a position closer to the axis of the bottle body 2 is larger than the wall thickness at a position away from the axis of the bottle body 2. As a result, in the drug bottle 1 of the present embodiment, the wall thickness of the bottom 17 located near the center of gravity G becomes large, and the wall thickness at the position away from the center of gravity G decreases.

As described above, the distance a shown in FIG. 5 is larger than the radius r1 of the liquid inlet 6 shown in FIG. The distance a shown in FIG. 5 is larger than the radius r2 of the liquid discharge port 7 shown in FIG. By determining the dimensions of the bottle body 2 in this way, it is possible to prevent the parison before expansion from coming into contact with the mold.

<How to use the drug bottle 1>
FIG. 8 is a schematic view showing a state in which the drug bottle 1 is attached to the automatic melting device 100. The automatic dissolution device 100 is attached to the dialysis machine. The automatic melting device 100 sandwiches the drug bottle 1 from above and below. The drug bottle 1 has a drug (for example, baking soda) inside. The automatic dissolution device 100 supplies a dissolution liquid (for example, RO water) into the drug bottle 1. The lysate passes through the filter, passes through the liquid inlet 6, and is supplied to the drug bottle 1. A saturated solution of the drug and the solution is prepared in the drug bottle 1. The saturated solution passes through the filter through the liquid discharge port 7 and is discharged to the dialysis machine.

The drug bottle 1 suppresses deformation during use of the automatic dissolution device 100 and prevents the drug bottle 1 from coming off the automatic dissolution device 100 during use. When the drug bottle 1 is discarded after use, the bottle body 2 is easily deformed and is not bulky. A small groove 13 is formed in the bottle body 2. The small groove 13 has a shape that is recessed toward the inside of the bottle body 2. The small groove 13 allows the bottle body 2 to be more easily deformed.

<Action effect>
The action and effect of the drug bottle 1 of the embodiment will be collectively described as follows. A reference number is attached to the configuration of the embodiment, which is an example.

As shown in FIGS. 1 and 2, the drug bottle 1 of the present embodiment includes a bottle body 2, a first mouth portion 3, and a second mouth portion 4. The bottle body 2 is formed with a groove 14 extending in the vertical direction DR1 that is recessed toward the inside of the bottle body 2. The groove 14 has a bottom 17. The thickness of the cross section orthogonal to the vertical DR1 at the bottom 17 is larger than the thickness of the cross section orthogonal to the vertical DR1 at the position farthest from the center of gravity G.

The drug bottle in which the groove 14 is not formed may be disengaged from the automatic melting device 100 due to deformation during use of the automatic melting device 100, particularly deformation immediately after use of the automatic melting device 100. In the drug bottle 1 in which the groove 14 of the present embodiment is formed, the bottom portion 17 of the groove 14 recessed inward constitutes a pillar-like portion extending in the vertical direction DR1. Since the thickness of the cross section of the bottom portion 17 orthogonal to the vertical DR1 is large, the pillar-like portion has high rigidity. As a result, the rigidity of the vertical DR1 of the drug bottle 1 is increased, so that the deformation of the drug bottle 1 during use of the automatic melting device 100 is suppressed, and the drug bottle 1 is suppressed from coming off the automatic melting device 100.

While the wall thickness of the bottom 17 located near the center of gravity G increases, the wall thickness of the bottle body 2 decreases and the rigidity decreases at a position away from the center of gravity G in the bottle body 2. Therefore, since the bottle body 2 can be easily deformed starting from the portion having a small wall thickness, the drug bottle 1 can be easily crushed when the drug bottle 1 is discarded after use, and the bottle body 1 is not bulky. ..

By providing a difference in the wall thickness of the bottle body 2 in this way, it is possible to realize the drug bottle 1 in which the volume after use can be easily reduced while ensuring the rigidity.

As shown in FIG. 1, the bottom portion 17 extends in the vertical direction DR1 from the upper end edge portion 15 to the lower end edge portion 16. Since the bottom portion 17 of the thick groove 14 extends to the vicinity of the first opening portion 3 and the vicinity of the second opening portion 4, the rigidity of the portions near the first opening portion 3 and the second opening portion 4 is increased. The deformation of the bottle 1 can be further suppressed.

As shown in FIG. 5, the groove 14 in the cross section orthogonal to the vertical DR1 of the bottle body 2 is arcuate. The shape of the groove 14 may be arbitrary, for example, V-shaped. However, by making the groove 14 into an arc shape, manufacturing becomes easy and productivity is improved.

The cross section of the bottle body 2 orthogonal to the vertical DR1 is substantially rectangular, and the groove 14 is formed on the long side of the substantially rectangular cross section. The center of gravity G in the cross section orthogonal to the vertical DR1 of the bottle body 2 and the bottom portion 17 are close to each other. In the blow molding described above, the wall thickness of the portion of the bottle body 2 near the axis becomes large. Therefore, since the thickness t1 of the cross section orthogonal to the vertical DR1 in the bottom portion 17 located near the center of gravity G can be increased, the thick bottom portion 17 can be reliably and easily configured.

The grooves 14 are formed in pairs facing each other with the center of gravity G interposed therebetween. When the groove 14 is formed in only one place, the portion facing the groove 14 with the center of gravity G in between is easily deformed. Since the grooves 14 are formed in pairs facing each other with the center of gravity G interposed therebetween, the rigidity of the vertical DR1 of the drug bottle 1 becomes higher, so that the deformation of the drug bottle 1 can be suppressed more reliably.

(Difference in wall thickness of bottle body 2)
The drug bottle 1 of the embodiment is produced, and in the bottle body 2, the wall thickness t1 (FIG. 6) at the bottom 17 located near the center of gravity G and the wall thickness t2 (FIG. 7) at the position farthest from the center of gravity G. And was measured. A dial gauge was used for the measurement. Table 1 shows the wall thickness measurement results of the two drug bottles 1 (No. 1 and No. 2) in the bottle body 2.

As a comparative example, a drug bottle having no groove formed in the bottle body was prepared, and the wall thickness of the portion of the bottle body near the center of gravity and the wall thickness of the portion away from the center of gravity were measured. A dial gauge was used for the measurement. Table 2 shows the wall thickness measurement results of the two drug bottles (No. 1 and No. 2) having no groove formed in the bottle body.

From Tables 1 and 2, it can be seen that in the bottle body 2 in which the groove 14 of the embodiment is formed, the difference between the wall thickness of the portion near the center of gravity and the wall thickness of the portion away from the center of gravity is larger. ..

(Change in drug bottle length)
The drug bottle 1 of the embodiment and the drug bottle in which the groove of the comparative example is not formed are attached to the automatic dissolution device 100, respectively, and the upper and lower treatments sandwiching the drug bottle before and immediately after the use of the automatic dissolution device 100 are performed. The distance between the tools was measured. Table 3 shows the change in the jig interval between before and immediately after the use of the automatic dissolution device 100 when the drug bottles 1 (No. 1 and No. 2) of the two embodiments are used for the automatic dissolution device 100. Indicates the amount. Table 4 shows the amount of change in the jig interval between before and immediately after the use of the automatic dissolution device 100 when the drug bottles (No. 1 and No. 2) of the two comparative examples are used for the automatic dissolution device 100. show.

As shown in Table 4, when the drug bottle of the comparative example in which the groove was not formed was used for the automatic melting device 100, the distance between the jigs became smaller immediately after use, that is, the comparative example in which the groove was not formed. The drug bottle was deflated immediately after use. This is because the drug bottle in which the groove is not formed has a small rigidity in the vertical DR1.

On the other hand, as shown in Table 3, when the drug bottle 1 of the embodiment in which the groove 14 was formed was used for the automatic dissolution device 100, it did not shrink immediately after the use of the automatic dissolution device 100.

By providing a difference in the wall thickness of the bottle body 2 in this way, the rigidity of the drug bottle 1 in the vertical DR1 can be increased and the deformation of the drug bottle 1 can be suppressed, and as a result, the drug bottle 1 becomes the automatic melting device 100. It was shown that the situation where the automatic melting device 100 can be removed during use can be avoided.

As a modification, the shape of the drug bottle 1 may be a cylinder, an elliptical cylinder, a polygonal column, or the like. The small groove 13 does not have to be formed in the bottle body 2. The bottom portion 17 of the groove 14 may not extend over the upper end edge portion 15 and the lower end edge portion 16. For example, the groove 14 may be formed only on the body portion 8 of the bottle body 2.

Although the embodiments of the present invention have been described above, it should be considered that the embodiments disclosed this time are exemplary in all respects and are not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and is intended to include the meaning equivalent to the scope of claims and all modifications within the scope.

1 Drug bottle, 2 Bottle body, 3 1st port, 3a Outer surface of 1st port, 4 2nd port, 4a Outer surface of 2nd port, 5 Port, 6 Liquid inlet, 7 Liquid drain Exit, 8 Body, 9 First Shoulder, 10 Second Shoulder, 11 First Wall, 12 Second Wall, 13 Small Groove, 14 Groove, 15 Top Edge, 16 Bottom Edge, 17 Bottom, DR1 Vertical , DR2 short side direction, G center of gravity, a distance between the bottom and the center of gravity, b groove depth, c1 distance from the long side of the substantially rectangular cross section to the outer peripheral surface of the first mouth, c2 the length of the substantially rectangular cross section. The distance from the side to the outer peripheral surface of the second port, the radius of the r1 liquid inlet, the radius of the r2 liquid outlet, the wall thickness of the t1 bottom, and the wall thickness at the position farthest from the t2 center of gravity.

Claims (4)

With the bottle body
The first mouth portion formed at the upper end of the bottle body and
A second neck portion formed at the lower end of the bottle body, Ru provided with, a drug bottle,
The bottle body is formed with a groove extending in the vertical direction, which is recessed toward the inside of the bottle body.
The groove has a bottom and
The cross section of the bottle body orthogonal to the vertical direction is substantially rectangular, the groove is formed on the long side of the cross section, and in the cross section, the thickness of the wall of the drug bottle at the bottom thereof is the cross section of the cross section. The depth of the groove in the short side direction of the cross section is larger than the thickness of the wall at the position farthest from the center of gravity, and the depth of the groove in the short side direction divides the distance between the edge portion of the groove and the first mouth portion in the short side direction. A drug bottle that is larger than one length. The drug bottle according to claim 1, wherein the bottom portion extends in the vertical direction from the upper end of the groove to the lower end of the groove. The drug bottle according to claim 1 or 2, wherein the shape of the groove in the cross section includes an arcuate portion. The groove has a first groove and a second groove.
The drug bottle according to any one of claims 1 to 3, wherein the first groove and the second groove are formed so as to face each other with the center of gravity of the cross section interposed therebetween.

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