JP4055185B2 - Squeeze bottle - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a squeeze bottle that can be squeezed elastically so as to greatly reduce its internal volume.
[0002]
[Prior art]
Conventionally, for example, in eye drop bottles, various resin squeeze bottles that increase the internal pressure by pressing the bottle body and drop the content liquid filled inside are used. The amount of squeeze is extremely limited compared to the internal volume, and only a limited amount of about a few drops can be discharged in one squeeze. If the body part was forcibly pressed to take out a large amount with one squeeze, part of the bottle wall part was bent and damaged, and could not be restored to its original shape.
[0003]
As such a conventional squeeze bottle, the thing currently disclosed by Unexamined-Japanese-Patent No. 2001-120638 can be mentioned, for example. This bottle can hold a hollow portion formed of a flat gripping surface formed in a hollow portion of a flexible hollow cylinder in two circumferential directions with two fingertips. The wall thickness of the bottle body is substantially uniform throughout. The squeeze deformation of the conventional squeeze bottle is performed by slightly curving the gripping surface inwardly as shown in FIG. 4 or FIG. Thus, the eye drop can be taken out only by a few drops with one squeeze.
[0004]
Japanese Utility Model Laid-Open No. 5-44134 discloses an eye drop container made of a relatively hard synthetic resin material and having a flat structure container body provided with a droplet discharge port on one side. An ophthalmic bottle in which a pressing deformation part having an automatic return behavior surrounded by a bellows structure part is formed is disclosed. In this eye drop bottle, since the pressing deformation portion is surrounded by the bellows structure portion, it is considered that the deformation amount of the pressing deformation portion can be secured relatively large, but the entire container is made of a relatively hard synthetic resin material. Therefore, the deformation part is only the pressure deformation part on one side of the body part, and even if it is surrounded by the bellows structure part, the amount of deformation is limited to a small amount and cannot be squeezed to the extent that the internal volume is halved. .
[0005]
On the other hand, the applicants of the present application have a squeeze bottle with an inner and outer two-layer structure, and a bag-like inner layer that can shrink as the inner volume decreases is provided inside the outer layer constituting the bottle body, and the content liquid is contained in the inner layer. Developed a container configured to pressurize the air between the outer layer and the inner layer by squeezing the bottle and compress the inner layer with this pressurized air to discharge the content liquid. This is disclosed in Japanese Patent Laid-Open No. 2001-114328. Since the bottle of the embodiment disclosed in the publication is a hair styling bottle and is a relatively large bottle having a large content, it has a relatively large squeeze while having a generally uniform wall thickness by blow molding. It can be deformed. However, when the same structure is adopted in an eye drop bottle with an internal volume of less than 20 ml, the squeeze amount is extremely limited as described above if the required wall thickness is ensured, and the air between the outer layer and the inner layer is sufficient. It becomes impossible to pressurize and the content liquid cannot be taken out.
[0006]
[Problems to be solved by the invention]
In view of the above circumstances, an object of the present invention is to make it possible to squeeze and deform even a relatively small squeeze bottle such as an eye drop bottle (for example, to an extent that reduces the internal volume by half).
[0007]
[Means for Solving the Problems]
In order to achieve the above object, the present invention takes the following technical means.
[0008]
That is, the present invention relates to a squeeze bottle in which a mouth portion is provided through a shoulder portion at the upper end of a bottomed cylindrical body portion that can be elastically contracted and deformed, and the peripheral wall of the body portion has a predetermined interval. A flat cylinder having a small front-rear width compared to the left-right width of the body portion from a pair of front-rear rigid wall portions and left and right flexible connection wall portions connecting the left and right edges of the rigid wall portions. Each flexible connection wall portion has an arc shape in which the front and rear central portions protrude outward in the left and right directions, and the upper end of each rigid wall portion is a shoulder via the flexible upper connection portion. And a lower end thereof is connected to a bottom portion of the trunk portion via a flexible lower connection portion.
[0009]
According to the squeeze bottle of the present invention, the left and right edges of the pair of front and rear rigid wall portions are connected by the flexible connection wall portion, and the upper and lower sides of the rigid wall portion are also connected to the shoulder portion via the flexible connection portion. Since it is connected to the bottom portion, when both wall portions are pressed with two fingertips so that the front and rear rigid wall portions are brought close to each other, the whole body portion is squeezed and deformed so that it is relatively small. Even if it is a bottle, it can be squeezed and deformed to the extent that the internal volume is reduced by half or more. The connecting portion is not damaged by elastic deformation. Therefore, a large amount of content liquid can be taken out with one squeeze, and in the so-called Delami container in which the content liquid storage bag is provided inside the bottle, the content liquid can be reliably discharged to the end.
[0010]
The squeeze bottle of the present invention can be integrally formed by a conventionally known blow molding method so that the rigid wall portion is relatively thick, while the left and right connection walls and the upper and lower connection portions are relatively thin. By setting the shaping shape and changing the blow ratio for each part, the rigid wall part is given rigidity that hardly bends by the pressing force of the finger, and the connection wall part and the connection part have It is possible to provide flexibility enough to elastically deform following the large parallel movement of the front and rear rigid walls. The outer surface of the rigid wall portion is preferably flat, but may be a curved surface that is slightly curved outward or inward in the radial direction. The wall thickness of the rigid wall varies depending on the physical properties of the molded resin material and the overall size and structure of the bottle, but is preferably in the range of 0.3 mm to 1.2 mm, and the average wall thickness is 0.5 mm. About -0.8 mm is preferable. On the other hand, the thickness of the connecting wall and the connecting portion is preferably in the range of 0.1 mm to 0.8 mm, and the average thickness is preferably about 0.2 mm to 0.5 mm.
[0011]
In order to obtain a squeeze bottle having the above structure from a parison having a substantially uniform wall thickness by blow molding, it is preferable to improve the shaping surface structure of the blow molding die. For example, in the case of a conventional so-called oval bottle blow molding die, the short-diameter side shaping surface of the body portion is a flat or convex curved surface having a larger diameter than the short-diameter wall surface, and the short-diameter side is formed on the short-diameter side. By reducing the blow ratio, the short side wall of the bottle body is made thick and rigid, and the blow ratio on the long diameter side is made larger to make the long side wall of the bottle body thin and flexible. It becomes possible to make it a connection wall part. Furthermore, forming the shaping surface of the blow molding die so as to form convex portions protruding outward in the front-rear direction above and below the rigid wall portion, and partially increasing the blow ratio at the top and bottom of the rigid wall portion Thus, thin flexible connection portions can be formed above and below the rigid wall portion.
[0012]
When the squeeze bottle of the present invention is made of a blow-molded plastic bottle, the flexible upper connecting part and the flexible lower connecting part are located on the front and rear sides of the rigid wall part, and these connecting parts The average wall thickness is smaller than the average wall thickness of the rigid wall portion, the left and right width of the body portion is larger than the front and rear width, and the average wall thickness of the left and right flexible connection wall portions is the average wall thickness of the rigid wall portion. The thickness is preferably smaller than the thickness. According to this, the squeeze bottle of the present invention can be easily and low-cost only by improving the shaping surface structure of the blow molding die as described above, without changing the structure and blow process of other blow molding devices. It can be manufactured.
[0013]
Further, in the squeeze bottle of the present invention, the cross section of the body portion may be a long oval shape in the left-right direction, and the rigid wall portion may be a long rectangular shape in the vertical direction when viewed from the front. The vertical dimension of the outer surface of the rigid wall can be greater than 20 mm, more preferably greater than 25 mm. Usually, when the bottle body is gripped and pressed by two fingertips, the thumb and forefinger, the range in which the fingertip contacts the outer surface of the bottle body and exerts a pressing force is less than 1 cm in the vertical direction. . Therefore, when trying to squeeze a conventional squeeze bottle with two fingertips, only a range of about 1 cm in contact with the fingertips is curved and deformed, and only a very small amount of content liquid can be taken out. On the other hand, in the squeeze bottle of the present invention, when the upper and lower central portions of the pair of front and rear rigid walls are pressed with two fingertips, the rigidity causes the rigid walls to move inward of the bottle over 20 mm above and below, increasing the internal volume. Can be reduced. Furthermore, by making the left and right dimensions of the outer surface of the rigid wall portion larger than ½ of the left and right width of the entire trunk portion (distance between the top portions of the outer surfaces of the left and right arc-shaped connecting wall portions) and larger than 10 mm, The squeeze operability of the rigid wall portion can be improved, and the squeeze property of the entire body portion can be further structured. In addition, by making the distance between the outer surfaces of the front and rear rigid wall portions smaller than the left and right dimensions of the outer surface of the rigid wall portion, the curvature of the left and right connection wall portions is increased and smooth elastic deformation of the wall portions is achieved. Can be performed.
[0014]
More preferably, when the front and rear rigid walls are made to approach until the distance between the central portions is reduced by pressing the upper and lower central portions of the front and rear rigid walls, the upper and lower ends of the rigid walls are the center. The left and right connection wall portions and the upper and lower connection portions can be configured to deform within the elastic region so as to move following the portion. Furthermore, even when the front and rear rigid wall portions are squeezed until they come into contact with each other, the left and right connection wall portions and the upper and lower connection portions can be configured to be deformed within the elastic region.
[0015]
The squeeze bottle of the present invention can be suitably used for a pump container having a content liquid storage bag therein. The pump container may include the squeeze bottle and a fluid storage bag having a discharge opening. The bag may be provided inside the bottle body, and the discharge opening may be connected to the bottle mouth. The bottle can be provided with a vent hole for introducing outside air between the bottle and the bag. Moreover, a stopper can be provided in the bottle mouth part. The plug has a discharge path for discharging the fluid contained in the bag to the outside. A dispensing valve can be attached to the discharge path to open and close the discharge path of the plug. The dispensing valve can include a valve flange and a valve head, and preferably the valve flange and the valve head can be connected via a valve sleeve having a flexible structure. The valve flange seals the inner peripheral edge of the discharge passage. The valve head is connected to the inner peripheral edge of the valve flange directly or indirectly via a valve sleeve or the like, and allows a flow of the fluid when a predetermined dispensing pressure acts on the inner side of the bag. And an orifice that opens to close the fluid flow when the predetermined dispensing pressure is removed. Further, the stopper may be provided with a support portion for abutting and supporting the valve head so as to prevent the orifice of the valve head from opening when a negative pressure is generated inside the bag. In such a container, in order to open the dispensing valve, it is necessary to increase the inside of the bag to a predetermined dispensing pressure or higher. However, the squeeze bottle of the present invention is elastically configured so that the entire body is crushed. Since the squeeze can be greatly deformed, it is possible to generate a dispensing pressure without causing breakage.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
The eye drop container 10 is shown in FIG.1 and FIG.2 as a dispensing container provided with the squeeze bottle which concerns on one Example of this invention. This eye drop container 10 includes a laminated peeling bottle 11 having an inner / outer two-layer structure formed by blow molding from a bottomed cylindrical laminated parison, a spout 12 attached to a mouth portion 11a of the bottle 11, and a cap 13. I have. When the user removes the cap 13, inverts the laminated bottle 11, and squeezes the body 11 b by pressing, the eye drop (fluid) inside the bottle 11 passes through the discharge channel in the spout 12 as shown in FIG. 5. It is dripped from the front-end | tip nozzle part 15 through. In the figure, the actual height of the bottle 11 is about 56.2 mm, the left and right width of the body portion 11 b is about 25 mm, the front and rear width of the body portion 11 b is about 17.5 mm, and the inner capacity is 10. It is about 9 ml.
[0017]
The laminated bottle 11 has a laminated structure of a squeeze bottle 1 constituting an outer layer and a fluid containing bag 16 constituting an inner layer. The squeeze bottle 1 and the bag 16 both have a cylindrical mouth portion and a body portion having a flat cross section. The outer layer bottle 1 can be formed of a synthetic resin material such as PET or EVOH, for example, and the inner layer bag 16 is formed of a synthetic resin (for example, polyolefin such as polyethylene) having a property of easily peeling from the outer layer bottle 1. Can be molded. Note that the mouth portion 16a of the bag 16 constitutes a discharge opening of the liquid storage bag.
[0018]
As shown in FIGS. 3 and 4, the squeeze bottle 1 has a shoulder 3 that gradually decreases in diameter as it moves upward at the upper end of a bottomed cylindrical body 2 that can be elastically contracted and deformed. A cylindrical mouth portion 4 is provided. As shown in FIG. 2, the peripheral wall of the body portion 2 has a pair of front and rear rigid wall portions 5 facing each other with a predetermined interval, and left and right flexible portions connecting the left and right edge portions of the rigid wall portions 5. The connecting wall portion 6 is formed in a flat oval shape having a small front-rear width compared to the left-right width of the body portion 2. Each rigid wall 5 has a rectangular shape that is long in the vertical direction when viewed from the front, and is flat in the horizontal and vertical cross sections, but may not be completely flat or may be slightly curved. Each flexible connection wall portion 6 has an arc shape in which the front and rear center portions protrude outward in the left and right directions, and the radius of curvature is smaller than the short diameter of the body portion 2. Each rigid wall portion 5 has an upper end edge connected to the shoulder portion 3 via the flexible upper connection portion 7 and a lower end edge thereof connected to the shoulder portion 2 via the flexible lower connection portion 8. It is connected to the bottom 2a. Thus, each rigid wall portion 5 is surrounded by only the flexible portions 6, 7, and 8, and the front and rear rigid wall portions 5, the bottom portion 2a, and the shoulder portion 3 are flexible. They are integrally connected only by the sex parts 6, 7, and 8.
[0019]
The flexible upper connecting portion 7 and the flexible lower connecting portion 8 are located on the front and rear outer sides than the rigid wall portion 5. Therefore, when the bottle 1 is blow-molded from the plastic parison, the elongation ratio of the resin material at the portion where the connection portions 7 and 8 are formed is increased, and the connection portions 7 and 8 are formed relatively thin. The connecting portions 7 and 8 are provided with flexibility that can be easily deformed. On the other hand, the rigid wall portion 5 is formed thick, and the wall portion 5 can be provided with rigidity that is difficult to be deformed. The average thickness of the connecting portions 7 and 8 is preferably less than half the average thickness of the rigid wall portion 5.
[0020]
Further, the left and right width of the body portion 2 of the squeeze bottle 1 is larger than 1.5 times the front and rear width (that is, the distance between the outer surfaces of the front and rear rigid wall portions 5), and the left and right connection wall portions are formed during blow molding. As a result of the increase in the elongation ratio of the resin material at the portion forming 6, the average thickness of the left and right flexible connecting wall portions 6 is made smaller than the average thickness of the rigid wall portion 5.
[0021]
In more detail, the cross section of the trunk | drum 2 exhibits the ellipse shape long in the left-right direction, and the rigid wall part 5 is long rectangular shape up and down in front view, Comprising: The outer surface of the rigid wall part 5 is The vertical dimension h is about 25 mm to 28 mm, and the lateral dimension w of the outer surface is larger than ½ of the lateral width W of the entire body 2 and larger than 10 mm. Furthermore, the distance D between the outer surfaces of the front and rear rigid wall portions 5 is smaller than the left-right dimension w of the outer surface of the rigid wall portion 5.
[0022]
With the above-described configuration of the squeeze bottle 1, the front and rear rigid wall portions 5 are made to approach until the distance between the central portions is halved by pressing the upper and lower central portions of the front and rear rigid wall portions 5 with two fingertips. When this occurs, the left and right connecting wall portions 6 and the upper and lower connecting portions 7 and 8 are deformed within the elastic region so that the upper and lower ends of the rigid wall portion 5 move following the center portion.
[0023]
Further, the mouth portion 4 of the squeeze bottle 1 of the present embodiment is provided with a vent hole 17 for introducing outside air between the bottle body portion 2 and the body portion 16b of the bag 16. Two vent holes 17 are formed at positions opposed to each other in the diameter direction. The vent hole 17 is formed so as to penetrate from the inner surface side of the outer layer bottle 1 to the outer surface side, and is not formed in the inner layer bag 16.
[0024]
The body portion 16b of the inner layer bag 16 has a film shape, and can be easily contracted and deformed as the content liquid decreases. On the other hand, the mouth portion 16a of the inner layer bag 16 is formed to be relatively thick as compared with the body portion 16b, and exhibits a recoverability to a cylindrical shape.
[0025]
The air holes 17 formed in the mouth portion 4 of the outer layer bottle 1 are normally closed from the inside by the mouth portion 16a of the inner layer bag 16. Thus, the mouth portion 16a of the inner layer bag 16 functions as a check valve for the vent hole 17, and this inner layer mouth portion 16a is formed when a negative pressure is generated between the outer layer body portion 2 and the inner layer body portion 16b. The vent hole 17 is opened by being deformed inward by the atmospheric pressure. On the other hand, when the negative pressure is eliminated, the vent hole 17 is closed by the recoverability of the inner layer mouth portion 16a itself. Note that the center of the bottom of the bag 16 is locked to the center of the bottom of the outer bottle 1, thereby preventing the bottom side of the bag 16 from rolling up.
[0026]
The stopper 12 is a first stopper member 21 fitted in the bottle opening 4, and a second stopper attached to the outer periphery of the bottle opening 4 while being connected to the first stopper member 21 in the axial direction. The plug member 22 is mainly constituted.
[0027]
The first plug member 21 includes a cylindrical first tube portion 21a whose base end portion is in contact with the distal end surface of the bottle mouth portion 4, and a second tube portion 21b provided inside the first tube portion 21a. However, it is integrally formed through a flange 21c projecting radially outward from the tip of the second cylindrical portion 21b. The base end portion of the second cylinder portion 21b protrudes to the base end side (lower side in FIG. 1) from the base end portion of the first cylinder portion 21a, and the base end portion of the second cylinder portion 21b is the bottle mouth. The part 4 is fitted in an airtight and liquidtight manner. A horizontal plate-like support wall portion 21d is provided on the inner surface of the second cylindrical portion 21b in the axially intermediate portion. The support wall portion 21d is provided with through holes 23 penetrating in the axial direction at four locations around the center portion so as to avoid the center portion. Moreover, the recessed part by which the connector leave 24a and the valve head 24b of the dispensing valve 24 mentioned later are engage | inserted is formed in the upper part side of the support wall part 21d.
[0028]
The second plug member 22 is a substantially cylindrical member, and a top plate having a nozzle portion 15 formed at the tip in the axial direction is integrally formed. The first tube portion 21 a of the first plug member 21 is fitted on the inner periphery of the second plug member 32. The outer periphery of the distal end portion of the second plug member 22 is formed in a small diameter cylindrical shape through a step, and the cap 13 is screwed onto the outer periphery of the small diameter cylindrical portion.
[0029]
A thin plate-like filter 25 is disposed at the center of the lower surface of the top plate of the second plug member 22. Examples of the filter 25 include a membrane filter, a sintered body filter, a hydrophilic porous flat membrane, and a hydrophobic porous flat membrane from the discharge downstream side (outside the container) to the discharge upstream side (inside the container). Those capable of preventing permeation of pathogenic microorganisms can be appropriately used. The filter 25 is disposed on the discharge downstream side of the dispensing valve 24, and is disposed adjacent to the nozzle portion 15 in the illustrated example, and is fitted into the second plug member 22 above the first plug member 21. The holding member 26 is held. The holding member 26 is formed with a through hole 26 a for allowing the content liquid to flow through the filter 25. Thus, the discharge passage of the spout 12 that allows the inside of the bag 16 and the outside of the container to communicate with each other is constituted by the above-described through-hole 23, cavity portion, through-hole 26a, and flow passage in the nozzle portion 15.
[0030]
In the dispensing valve 24, a valve flange 24c, a valve head 24b, and a connector sleeve 24a are integrally formed of an elastic material such as silicon rubber.
[0031]
The valve flange 24c has a substantially ring shape, and the cross-sectional shape is a triangular shape that increases in thickness toward the outer side in the radial direction. The valve flange 24c is sandwiched from above and below in an airtight and liquid-tight manner by the first plug member 21 and the second plug member 22, and seals the inner peripheral edge of the discharge passage in an airtight and liquid-tight manner. .
[0032]
The valve head 24b has a circular shape in plan view and is formed on a spherical surface that curves in a convex shape toward the inside of the bottle, and an orifice 24d made of a cross-shaped cut is provided at the center. . The orifice 24d opens to allow the flow of fluid (content liquid) inside the inner bag 16 when a predetermined dispensing pressure is applied to the inner surface of the head 24b, and the predetermined dispensing pressure is removed. Then, it closes so that the flow of fluid may be interrupted. The central lower surface of the valve head 24b is formed to be substantially flat, and the orifice 24d is provided within the range where the flat surface is formed. The flat surface of the valve head 24d is in contact with the upper surface of the support wall portion 21d in a normal state.
[0033]
The connector sleeve 24a is substantially cylindrical, and one end in the axial direction is integrally connected to the inner peripheral edge of the valve flange 24c, and the other end in the axial direction is integrally connected to the outer peripheral edge of the valve head 24b. . The connector sleeve 24a has a relatively thin and flexible structure so that it can be easily deformed. Thereby, when a predetermined pressure smaller than the predetermined dispensing pressure acts on the inner surface of the valve head 24b, the valve head 24b is displaced to the downstream side (tip side) while the orifice 24d is kept closed. As a result, the connector sleeve 24a is elastically deformed so as to bend. Further, when the small predetermined pressure is removed, the connector sleeve 24a is restored and deformed, and the valve head 24b is displaced upstream (base end side) with the orifice 24d closed. The fluid remaining in is sucked back to the upstream side of the filter. The fluid suction force may be obtained by the restoring force of the connector sleeve 24a, or may be obtained by the negative pressure on the inner surface of the head 24b.
[0034]
The structure of the connector sleeve 24a is not limited to the illustrated example, and for example, a bellows structure that can be elastically deformed so as to contract in the axial direction may be used.
[0035]
In the eye drop container 10 according to the present embodiment, when the internal pressure rises in a small range less than a predetermined dispensing pressure due to its carrying and temperature fluctuation, the valve head 24b is kept at the tip while the orifice 24d of the dispensing valve 24 remains closed. The internal pressure is reduced according to the amount of displacement, and the pressure rise is mitigated. In order to discharge the content liquid from the nozzle portion 15, the user inverts the bottle 11 and presses the body portion 11b radially inward from the short diameter direction, and the inner pressure of the head 24b is equal to or higher than a predetermined dispensing pressure. As a result, the content liquid in the inner layer bag 16 is opened from the nozzle portion 15 by opening the orifice 24d of the dispensing valve 24. When the pressing of the delami bottle 11 is stopped, first, the valve head 24b is restored and deformed so that the orifice 24d is closed, and then the connector sleeve 24a is restored and deformed. When the sleeve 24a is restored, the content liquid remaining in the nozzle flow path (that is, the opening of the discharge path tip) is sucked back into the cavity on the upstream side of the filter 25, and the content liquid is blocked from the outside air by the filter 25. It stays in the formed cavity.
[0036]
When the delamination bottle 11 is stopped from being pressed, the outer layer bottle 1 is restored to its original shape. However, when the orifice 24d is closed, the backflow of the content liquid and the inflow of outside air into the inner layer bag 16 do not occur. Does not return to its original shape, but shrinks as the liquid content decreases. On the other hand, when the outer layer bottle 1 returns to its original shape, a negative pressure is generated in the space between the outer layer body 2 and the inner layer body 16b, so that the inner layer port 16a is deformed radially inward by atmospheric pressure. The air hole 17 of the outer layer bottle 1 is opened, and air enters between the inner layer bag 16 and the outer layer bottle 1 through the air hole 17. At this time, the inner layer 16 also has a negative pressure, and the valve head 24b of the dispensing valve 24 is subjected to a force to be deformed toward the inside of the container. However, the head 24b is abutted and supported by the support wall 21d. Therefore, while having the structure of the flexible head 24b as described above, the head 24b is deformed inward to open the orifice, so that outside air or the like is prevented from flowing into the inner layer bag 16. When sufficient outside air is introduced from the vent hole 17 and the outer layer body portion 2 returns to its original shape, the deformation of the inner layer mouth portion 16a is canceled by the restoring property of the inner layer mouth portion 16a itself, and the cylindrical shape is restored. The vent hole 17 is closed by the inner layer opening 16a.
[0037]
When the user presses the bottle 11 again, the air between the outer layer body 2 and the inner layer body 16b leaks out of the bottle because the inner layer port 16a presses and closes the vent hole 17. The air is compressed by volume reduction due to deformation of the outer layer body 2, and the inner layer body 16b is pressurized from the outside by the pressurized air.
[0038]
The present invention is not limited to the structures shown in the above embodiments, and appropriate modifications can be made within the scope of the technical idea described in the claims.
[0039]
【The invention's effect】
According to the present invention, even a relatively small squeeze bottle such as an eye drop bottle having an internal volume of less than 30 ml can be greatly squeezed without causing breakage.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view of an eye drop container including a squeeze bottle according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of the dispensing container taken along line AA.
FIG. 3 is a four-side view of the squeeze bottle.
FIG. 4 is a longitudinal sectional view of the squeeze bottle.
FIG. 5 is a longitudinal sectional view of the same eye drop container in use.
FIG. 6 is a front view showing a state of the bottle body portion in the same use state.
[Explanation of symbols]
1 squeeze bottle
2 trunk
3 shoulder
4 mouths
5 Rigid wall
6 Flexible connection wall
7 Flexible upper connection
8 Flexible lower connection

Claims (4)

In a squeeze bottle in which a mouth is provided via a shoulder at the upper end of a bottomed cylindrical body that can be elastically contracted and deformed, the peripheral wall of the body is a pair of front and rear facing each other with a predetermined interval Each of the rigid wall portions and the left and right flexible connecting wall portions connecting the left and right edges of the rigid wall portions are configured in a flat cylindrical shape having a small front-rear width compared to the left-right width of the trunk portion. The flexible connecting wall portion has an arc shape with the front and rear central portions protruding outward in the left and right directions, and each rigid wall portion has an upper end connected to the shoulder portion via the flexible upper connecting portion. The squeeze bottle is characterized in that the lower end thereof is connected to the bottom of the body part via a flexible lower connection part. 2. The squeeze bottle according to claim 1, wherein the flexible upper connection portion and the flexible lower connection portion are located on the front and rear sides of the rigid wall portion, and an average of these connection portions. The wall thickness is smaller than the average wall thickness of the rigid wall, the left and right width of the body is larger than the front and back width, and the average wall thickness of the left and right flexible connection walls is larger than the average wall thickness of the rigid wall. Is a small squeeze bottle. 3. The squeeze bottle according to claim 1, wherein a cross section of the trunk portion has a long oval shape in the left-right direction, and the rigid wall portion has a rectangular shape that is long in the vertical direction in a front view. The vertical dimension of the outer surface of the part is larger than 20 mm, the lateral dimension is larger than 1/2 of the lateral width of the entire body part and larger than 10 mm, and the distance between the outer surfaces of the front and rear rigid walls is A squeeze bottle characterized by being smaller than the left and right dimensions of the outer surface. In the squeeze bottle according to claim 1, 2 or 3, when the front and rear rigid wall portions are made to approach until the distance between the central portions is halved by pressing the upper and lower central portions of the front and rear rigid wall portions. The squeeze bottle is characterized in that the left and right connecting wall portions and the upper and lower connecting portions are deformed in an elastic region so that the upper and lower ends of the rigid wall portion move following the central portion.

Images