KR20140034084A - A bottle without vaccum panel - Google Patents

Abstract

The present invention relates to a bottle without a vacuum panel which is stretch blow molded and can hold a capacity of 400-650 ml. Provided is a bottle including a reinforced bottom unit without a vacuum panel comprising: an inlet including a through-type opening part in which contents are filled and a support ring formed to be protruded in order for a thread and a container to be easily conveyed; a shoulder part integrally connected and molded to the inlet and in which the diameter is extended to the bottom; a body part integrally connected to the bottom of the shoulder part in which the diameter is extended and including a lateral wall and a plurality of ribs; and a bottom part for closing the bottom of the bottle without a vacuum panel to store contents with the inlet, the shoulder part, and the body part. Accordingly, sound pressure absorption function is demonstrated by the dent transformation of the bottom part while the contraction progression of the bottle caused by the sound pressure is prevented by the rib of the body part and the labeling can easily performed. A hill part is adjusted to a predetermined thickness and the bottle is not damaged during decompression by adjusting the surface area of the bottom part while being aesthetic.

Description

A panel without vaccum panel with reinforced bottom

The present invention relates to a container, specifically, having a torso having shape retention, and when the inside is decompressed, this decompression is absorbed by the deformation of the recessed shape of the bottom wall of the bottom and the A panelless container comprising a reinforced bottom of a volume of 400 ml to 650 ml that allows for significant absorption of vacuum pressure without unwanted deformation.

Conventionally, a biaxially stretched blow molded bottle made of polyethylene terephthalate (hereinafter referred to as PET) resin, a so-called PET bottle, has excellent transparency, mechanical strength, heat resistance, gas barrier properties, etc., and is widely used as a container for various beverages. It is becoming. In addition, manufacturers and fillers, as well as consumers, recognize that PET containers are light, inexpensive, renewable and can be manufactured in large quantities.

As a method of filling a PET bottle of a liquid solution such as a juice drink or a tea that requires sterilization, there is a method called so-called high temperature filling, and the liquid solution is filled into the bottle at a temperature of about 90 ° C. After sealing by sealing, it cools, and the inside of a bottle becomes a considerable pressure reduction vacuum state. Such liquid products, such as juices and isotonic, are often filled in containers while the liquid product is at elevated temperatures, typically 68 ° C. to 96 ° C. and usually about 85 ° C.

When packaged in this way, the high temperature of the liquid product is used to sterilize the container when filling the liquid. This process is known as hot filling. Containers designed to withstand the above process are known as hot filled or thermoset containers.

For this reason, for applications involving high temperature filling as described above, for example, a vacuum panel which is a region easily deformed in a recessed shape by intentional pressure reduction is formed on the body part, and the vacuum panel is recessed during pressure reduction. To maintain a good appearance and to ensure rigidity as a bottle at parts other than the vacuum panel, and to prevent troubles in the conveying line, loading and storage of the bottle, refrigeration of the product, and in the vending machine. It has an absorption function.

While such a vacuum panel allows the container to withstand the rigors of the high temperature filling process, a smooth glassy appearance cannot be achieved and a wrap or sleeve label that is rolled up during labeling is attached over the container's vacuum panel to label the sidewalls and the vacuum panel. It will not wrinkle or stick smoothly. For example, when holding a container, the label tends to fall off due to various cracking forms of the vacuum panel and the pushing of the label toward the center portion.

Therefore, if it is necessary to avoid the formation of the vacuum panel in the body part by the design request regarding the appearance of the bottle, or the vacuum panel itself is a part that is easily bent and deformed, the body wall rigidity is increased to increase the body body. In applications such as those sold in vending machines that need to provide high shape retention to the part, the vacuum panel is not formed in the body portion, and the depressive shape of the bottom wall of the bottom portion is deformed to exert a reduced pressure absorption function. It is necessary to use a synthetic resin bottle that has developed a container different from the existing bottle.

In particular, even if a vacuum panel is formed in the trunk portion, the area is limited. Therefore, it is difficult to sufficiently balance the rigidity, the buckling strength, and the vacuum absorption function of the trunk portion. It is necessary to exercise.

In addition, the circumferential groove ribs of the trunk portion increase the stiffness and the buckling strength of the trunk portion, and when the inside is decompressed, the shape of the trunk portion is maintained while deforming the larger recessed portion of the bottom portion while maintaining the shape of the trunk portion. R & D is being actively conducted to fully demonstrate this.

Patent Document 1: Publication No. 10-2011-0092209 Patent Document 2: Publication No. 10-2006-0031606

In patent document 1, in a container without a vacuum panel, the bottom part includes a ground part, a heel part, and a bottom part on which the container is supported so that the vacuum resistance in the residue of the container meets the demand. At this time, the heel portion is adjacent to the inversion ring and surrounds the circumference of the inversion ring as a whole, and the bottom portion receives the vacuum force generated by the inversion ring which surrounds the circumference and the circumference of the depression as a whole so that the bottom without unwanted deformation in the body portion. A technique has been described for a bottom portion structure that allows absorption of vacuum sound pressure by means of a portion.

However, when the container is molded by the above structure, desired characteristics are not satisfied in the heel portion of the bottom of the container. One of the characteristics of the heel portion is that the thickness is not formed thick enough to satisfy the problem that it is difficult to uniformly absorb the vacuum sound pressure, and thus it is difficult to overcome the deformation of the body portion.

In addition, studies on the weak cause of the drop impact revealed that the region called the heel portion of the container is formed with a relatively thin thickness, so that the heel portion deforms or ruptures due to the thin thickness when the drop impact test is performed. I may do it. Deformation of the heel adversely affects the ground portion and significantly impairs the independence of the heat resistant bottle. In addition, if the heel portion is a thin thickness, there is also a problem that the deformation is simply by pressing by hand.

In patent document 2, the recessed part formed by recessing the bottom wall in the bottle inner direction was arrange | positioned so that deformation | transformation may be made, and the recessed edge is made into the base of the inner part of the ground part formed in the periphery at the bottom of the bottom part. Inverted deformation is possible by connecting the recessed circumferential wall portion formed in an upright shape from the immediate vicinity of the inner circumference of the ground portion to the recess, the recessed recessed portion formed in the center of the recessed portion, the upper end of the recessed circumferential wall portion and the base end of the recessed recessed portion. It has a flat ring-shaped inverted wall portion formed so as to be arranged, and by further arranging a circumferential rib wall portion that functions as a circumferential rib at an upper end portion of the recessed circumferential wall portion and a connecting portion of the inverted wall portion, The pressure-reduction absorption function is fully exhibited by this, and the bent edge formed according to the deformed deformation There is a technique to suppress the progress made possible fully restored from the substrate at the same time, depressed deformation state is secured to the free-standing.

However, the above technology is designed to protrude outward from the bottom heel to form a container after PALLETIZE and packaging of the molded container. There is a disadvantage in that economic efficiency is lowered during production.

In addition, the above-described technology defines the wall and the inversion ring as a design element, and when the thickness of the heel and the bottom is not maintained at a constant ratio during the molding of the container, the heel deformation occurs, thereby achieving the purpose of absorbing the negative pressure of the bottom and the independence of the container. There are insufficient technical limitations.

The present invention has been invented to solve the above problems, the object is to form a thin thickness of the recess 440, the inversion ring 450 provided in the bottom portion to a predetermined thickness and the height of the protrusion of the recess 440 By adjusting the radius (R) of the (H) and the inversion ring 450 to sufficiently absorb the sound pressure by satisfying the optimized surface area, the heel portion 410 is secured in a predetermined ratio, the heel formed in a relatively thin thickness It is an object of the present invention to provide a panelless container including a reinforced bottom part capable of forming a container having negative pressure absorption and independence, and resistant to drop impact, compared to a conventional molded article having a part.

The present invention for achieving the above technical problem, as a stretch blow-shaped panelless container 10 that can hold a capacity of 400ml to 650ml, the through-shaped opening 110, the thread 120 and the filling the contents An inlet portion 100 having a support ring 130 protruding to facilitate transportation of the container; A shoulder portion 200 which is integrally formed with the inlet portion 100 and is formed to expand in diameter at a lower end thereof; A body part 300 which is integrally formed with the lower end of the shoulder portion 200 in which the diameter is extended and includes a side wall 310 and a plurality of ribs 350; A bottom portion 400 which serves to close the bottom of the panelless container 10 in order to store contents together with the inlet portion 100, the shoulder portion 200, and the body portion 300; , ≪ / RTI >

The bottom 400 is progressive in the shape of a truncated cone with a top surface 461 substantially parallel to the support surface and a recessed side surface 462 that is a plane inclined upwardly with respect to the longitudinal axis of the center of the container 10. Depression 460 having a smaller radius; A ground portion 420 formed at the lowermost end of the container 10 to support the container to stand upright in contact with a floor; The ground portion 420 and the body portion 300 is integrally formed and molded to form a gentle curve in a convex shape from the ground portion 420, the portion connected to the body portion 300 protrudes in the vertical direction Hill portion 410 is formed so as not to be straight; A ground wall portion 430 which is formed at an inner circumference of the ground portion 420 to form an inclined angle upward; A recessed portion 440 formed at an upper end of the ground wall portion 430 at a protruding height H toward the center of the container; A ring having a radius R, which is raised downward from the recess 440 toward the recess 460 and connected to the recess 460 in a semicircular shape, and completely surrounds the recess 460. An inversion ring 450 molded into; It provides a panelless container comprising a reinforced bottom portion, characterized in that formed.

In addition, the present invention provides a panelless container including a reinforced bottom portion, characterized in that the surface area combined with the concave portion 440 and the inversion ring 450 is formed between 2000 mm 2 and 2900 mm 2.

In addition, the present invention provides a panelless container including a reinforced bottom portion, characterized in that the ratio of the surface area of the concave portion 440 and the inversion ring 450 to the bottom cross-sectional area of the container is 15% to 60%. .

In addition, in the present invention, the thickness of the heel portion 410, the ground portion 420, the ground wall portion 430 is constant, the thickness of the concave portion 440 and the inversion ring 450 is the heel portion 410, Provided is a panelless container comprising a reinforced bottom portion characterized in that it is comprised between 55% and 85% of the thickness of the ground portion 420 and ground wall portion 430.

In addition, in the present invention, the rib 350 provided in the body portion 300, the labeling is easy, so that the interval (L) is characterized in that formed in a large number from 12.5mm to 18.7mm to withstand sound pressure It provides a panelless container comprising a reinforced bottom portion.

In addition, in the present invention, the radius (R) of the inversion ring 450 provides a panelless container including a reinforced bottom portion, characterized in that formed in 10mm to 13mm.

In addition, in the present invention, the protrusion height (H) of the recess 440 provides a panelless container including a reinforced bottom portion, characterized in that formed in 9mm to 12mm.

In addition, in the present invention, the ground portion 420 provides a panelless container including a reinforced bottom portion, characterized in that it is formed to support continuously or intermittently on the bottom.

In addition, in the present invention, the inversion ring 450 provides a panelless container including a reinforced bottom portion, characterized in that the radial rib is formed on the surface.

In addition, in the present invention, the inversion ring 450 is formed with the deflection height (IH) which is the shortest vertical distance from the bottom, the deflection height (IH), characterized in that formed from 5mm to 9mm Provided is a panelless container comprising a reinforced bottom.

In addition, in the present invention, the inversion ring 450 is formed to have a predetermined radius of curvature r2 at the point of deflection height (IH), the radius of curvature r2 is formed of 5mm to 25mm Provided is a panelless container comprising a reinforced bottom portion.

In addition, in the present invention, the concave portion 440 is formed to have a predetermined radius of curvature r1 at the point of the projection height (H), the radius of curvature r1 is formed of 1mm to 5mm Provided is a panelless container comprising a reinforced bottom portion.

Also in the present invention, the panelless container including the reinforced bottom portion, characterized in that the ratio of the radius of curvature r2 of the inversion ring 450 to the radius of curvature r1 of the recess 440 is within the range of 3 to 7. To provide.

In addition, in the present invention, the moving distance of the depression during the negative pressure provides a panelless container, characterized in that within the range of 2mm to 7mm.

In addition, in the present invention, the negative pressure of the container provides a panel-free container, characterized in that within the range of 21cc to 41cc.

In addition, the present invention provides a panelless container, characterized in that the ratio of the negative pressure to the total capacity of the container is within the range of 4 to 9%.

According to the panelless container including the reinforced bottom portion of the present invention, it is possible to exert a negative pressure absorbing function by the depression of the bottom portion, and to prevent the shrinkage progression of the container due to the negative pressure by the rib of the body and to facilitate the labeling. At the same time, it is possible to adjust the heel portion to a predetermined thickness and to adjust the surface area of the bottom portion so as not to impair the independence of the pathogen at the time of decompression and at the same time to give an aesthetic sense.

1 is a perspective view of a container according to the present invention
Figure 2 is a bottom cross-sectional view in a steady state of the container according to the present invention
Figure 3 is a bottom cross-sectional perspective view of the container in a steady state according to the present invention
Figure 4 is a bottom cross-sectional view in a negative pressure state of the container according to the present invention
5 is a bottom cross-sectional perspective view of a negative pressure state of the container according to the present invention

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Further, detailed descriptions of well-known functions and configurations that may be unnecessarily obscured by the gist of the present invention are omitted.

First, as shown in Figure 1, the panelless container 10 according to the present invention is a size that can hold a capacity of 400ml to 650ml inlet 100, shoulder 200, the body 300, the bottom It is configured to include a portion (400).

The panelless container 10 of the present invention is a container that is blow molded and directed from a single layer or multilayer material, such as polyethylene terephthalate resin, to a single biaxially having a single structure. The panelless container 10 may be formed by other methods, for example, from other conventional materials including polyethylene napthalate (PEN) and PET / PEN mixtures or copolymers.

Generally, a container containing a volume of 400 ml to 650 ml is a vacuum produced by filling a liquid product such as juice and isotonic at a temperature of about 85 ° C. and about a volume difference of about 22 cc generated during cooling. It must be able to absorb the town pressure sufficiently. More specifically, it should have a sound pressure amount within the range of 21cc to 41cc, and the ratio of the sound pressure amount to the total capacity of the container should be within the range of 4% to 9%, it is possible to smoothly perform the filling process such as beverage.

Therefore, in order to accommodate the vacuum negative pressure inside the container in place of the vacuum panel formed in the body portion of the conventional container ribs 350 in place of the vacuum panel to facilitate the labeling operation in the body portion 300 of the present invention. And the bottom 400 adopts an advanced structure.

The inlet portion 100 is a threaded portion 120 and the screw thread 120 formed to cover and cover the opening 110 by a screw (not shown) through a through-shaped opening 110, which is an inlet filled with contents. It includes a support ring 130 protruding convexly in a lower side of the).

The support ring 130 may be molded in a precursor forming step at the beginning of manufacture, and may be used to hold the support ring 130 to transport a plastic container. For example, the panelless vessel 10 may be moved by a support ring 130, which may be used to help position the precursor in a mold or end users move the vessel 10. It can be used to make.

The shoulder portion 200 is formed integrally connected with the inlet portion 100 is extended to extend the diameter to the body portion 300 formed at the bottom.

The body portion 300 is formed in parallel in the vertical direction at a predetermined interval between the plurality of ribs 350 and the plurality of ribs 350 roundly molded in the central axis direction around the body portion 300 is formed Consists of a labelable side wall 310, extending from the shoulder portion 200 to the bottom portion 400.

When the inside of the container is in a negative pressure state by the cooling after the high temperature filling process, the rib 350 is displaced to contract up and down while preventing the oval deformation of the body portion 300 due to the effect of the depression molding. Efficient sound pressure absorption function is exhibited.

Interval between the ribs 350 of the body portion (L) is preferably adjusted to 12.5mm to 18.7mm. In this case, when the interval (L) between the ribs 350 is less than 12.5 mm, the oval deformation of the body part 300 is prevented by the ribs formed with a plurality of negative pressures generated after the beverage is filled in the container. Although it may be efficient, when the label displaying the advertisement and the characteristics of the product on the body portion 300, the adhesion area is relatively reduced and the label is easily dropped.

If the body portion 300 is labeled using a PET shrinkage label, even if the gap L between the ribs 350 is less than 12.5 mm, the problem of falling the above label may be solved. There is a disadvantage that the position of the label may be changed by the up and down shrinkage of the rib 350.

In addition, when the interval (L) between the ribs 350 is more than 18.7mm, the container of the design having a high filling temperature or a large space of the head space does not completely absorb sound pressure and thus the body portion ( There is a disadvantage that can be deformed (oval) of 300).

In addition, more preferably, the interval between the ribs (L) is preferably adjusted to 12.5mm to 15.5mm.

2 and 3, the bottom portion 400 of the panelless container 10 to store the contents together with the inlet portion 100, the shoulder portion 200 and the body portion 300 It extends from the body part 300 and closes a floor, and is formed from the heel part 410, the ground part 420, the ground wall part 430, the recessed part 440, the inversion ring 450, and the recessed part 460. .

The ground portion 420 is formed at the bottom end of the panelless container 10 to be in contact with the bottom to support the container upright. In addition, the ground portion 420 may be formed to support the floor continuously or intermittently.

The heel portion 410 is formed outside the ground portion 420 and is formed to be connected to the body portion 300. In this case, the shape of the heel portion 410 is formed in a round curve formed from the ground portion 420 is connected to the body portion 300, and has a straight shape that does not protrude outward in the vertical direction. That is, in order to improve the aesthetics of the container 10, the heel portion 410 does not protrude outwards and becomes a straight shape in the vertical direction together with the sidewall 310 to flow flat and consistently. Such alternative embodiment vessels provide a more traditional visual impression and are also capable of carrying larger numbers in parallel loading of the vessels, making them suitable for containers that are sensitive to logistics fluidity.

The ground wall portion 430 is rounded at a predetermined angle upward from an inner circumference of the ground portion 420 to be connected to the recess 440.

The concave portion 440 is recessed to the center of the container at the upper end of the ground wall portion 430. In this case, it is rounded at a predetermined angle to be connected to the inversion ring 450.

The inversion ring 450 has a predetermined radius (R) and is raised downward from the concave portion 440 toward the recess 460 to be connected to the recess 460 in a semicircular shape. That is, it is molded into a ring shape completely surrounding the depression 460.

The depression 460 formed at the center of the bottom portion 400 has a top surface 461 substantially parallel to the support surface when viewed in cross section, and a depression side surface that is a plane inclined upward to have a gradual radius with respect to the vertical direction. 462 is provided with a truncated cone shape and is connected to the inversion ring 450. The exact shape of the depression 460 may be greatly changed according to various design criteria.

Therefore, as shown in FIGS. 4 and 5, the deformation angle of the recess 440 is increased to cap the container 10, seal it, cool it, and accommodate a change in volume when forming a negative pressure. In addition, the inversion ring 450 exhibits a conical shape having a curved surface shape, so that the recessed portion 460 can be flexibly ascended upwardly to absorb the sound pressure. The larger the deformation angle of the concave portion 440, the larger the amount of volume absorption that can be achieved.

In the panelless container including the reinforced bottom portion of the present invention, the heel portion 410 is formed to be straight in the vertical direction, and adjusted to a predetermined thickness to fully exhibit sound pressure absorbing function and to improve the independence and aesthetics of the pathogen. There is a purpose. Therefore, the thickness of the heel portion 410, the grounding portion 420, the ground wall portion 430 is formed to increase the durability and independence of the container, and the thickness of the recessed portion 440, the reverse ring 450 is relatively To form a thin as it is to increase the absorption function of the vacuum sound pressure by flexibly pushing the depression 460 to the upper side inside.

As one embodiment, in order to achieve the above invention, the thickness of the bottom portion 400 is defined as a ratio.

That is, the thickness of the concave portion 440 or the inversion ring 450 that absorbs the sound pressure to the thickness of the heel portion 410, the ground portion 420, the ground wall portion 430 that is responsible for the durability of the container 10 is 55. Preferably, the composition is at a level of% to 85%.

To improve the durability and independence of the container by controlling the thickness of the bottom part 400 to prevent deformation of the container due to the vacuum sound pressure generated after filling the beverage even in the member of the vacuum panel which is a design constraint element of the body part 300. do.

When the thickness of the concave portion 440 and the inversion ring 450 is less than 55% of the thickness of the heel portion 410, the ground portion 420, and the ground wall portion 430, the bottom portion 400 facilitates sound pressure. Absorption is possible, but there is a difficulty in securing the buoyancy due to the thin thickness during blow molding of the container.

On the other hand, when the thickness of the concave portion 440 and the inversion ring 450 exceeds 85% of the thickness of the heel portion 410, the grounding portion 420, and the ground wall portion 430, the bottom portion during blow molding of the container ( It is easy to secure the formation of the buoyancy (400), but due to the thick thickness of the fluid (flexible) is not secured because it does not play a role to absorb the negative pressure, after filling the beverage Oval (oval) deformation of the container 10 is generated, the label is It is impossible to commercialize because of its poor commerciality due to a drop in aesthetics such as falling easily.

Therefore, the bottom portion 400 is formed in a predetermined ratio so that its overall configuration is "M" shaped when viewed in sectional view so as to withstand sound pressure sufficiently.

Since the container has various designs, the height of the container and the diameter of the bottom may be different depending on the design formed in the container. That is, even if a container that can hold the same capacity, if the height of the container is low, the diameter of the bottom should be relatively high.

However, when the diameter of the bottom portion is small, the upward displacement of the recess 460 due to the increase in the deformation angle of the recess 440 is increased to absorb the negative pressure, so that when the lid is removed and opened, the recess 460 is upward. The problem is that the filling liquid leaks because the liquid level filled in the container is not lowered as a result of recovery from the displaced depression deformation state.

The concave portion 440 and the inversion ring 450 are deformed to substantially absorb sound pressure, and the protrusion height H of the concave portion 440, the radius of curvature of the concave portion r1, and the inversion ring deflection height. (IH), the radius of curvature r2 of the reversal ring, and the radius R of the reversal ring 450, the surface area of the recess 440, the reversal ring 450 and the recess 440 and the reversal ring ( The shape produced by 450 is determined. The protrusion height H is a value measured at the point where the vertical distance from the bottom to the recess 440 is the maximum, and the inversion ring deflection height IH is the vertical distance from the bottom to the inversion ring 450. Is the value measured at the point where is the minimum. The radius of curvature r1 of the concave portion is a value at the projected height H measurement point, and the radius of curvature r2 of the reversing ring is the height of the inversion ring deflection height IH. The value at the point.

In this case, the surface area of the concave portion 440 and the inversion ring 450 will depend largely on the volume of absorbable volume that the container 10 can absorb.

Therefore, the concave portion 440 and the inversion ring 450, which are deformed to substantially absorb sound pressure, preferably have a surface area of 2000 mm 2 to 2900 mm 2, which is a sum total of the curved portions in a steady state, and more preferably, the concave portion. The portion 440 and the inversion ring 450 may be formed to have a surface area of 2300 mm 2 to 2600 mm 2 combined in the entire curved state in a steady state.

If the surface area of the concave portion 440 and the reversal ring 450 is less than 2000 mm 2, the bottom portion may not be formed to be flexible. It is difficult to commercialize due to problems and loss of independence.

In order to maximize the surface area of the bottom part 400, radial ribs may be provided to the inversion ring 450, or the bottom part 400 may be radially embodied. The number of radioactive ribs on the bottom may be formed as many as necessary, but when the number of ribs is too large, there is a disadvantage in that the fluidity of the bottom is reduced.

In addition, it is preferable that the ratio of the surface area of the concave portion 440 and the inversion ring 450 in combination with the bottom cross-sectional area of the container is 15% to 60%, and more preferably 20% to 35% (wherein the bottom of the container The cross-sectional area refers to the area that the container occupies substantially the bottom when the container is placed on a flat surface, and is a radius of the shortest distance from the central longitudinal axis to the outermost part of the grounding part 420. Cross-sectional area).

If less than 15%, the sound pressure absorption degree of the bottom portion is insufficient, it may be difficult to achieve the target sound pressure, if more than 60%, the degree of bending of the concave portion 440 and the inversion ring 450 will be very severe, inversion There may be problems with ring restoration, problems with leakage of filler fluid, loss of independence, etc.

Further, the inversion ring deflection height IH is 5 mm to 9 mm, the radius of curvature r2 of the inversion ring is 5 mm to 25 mm, the protrusion height H of the concave portion is 9 mm to 12 mm, and the radius of curvature r1 of the concave portion 440. Silver is preferably formed from 1mm to 5mm.

Even when the surface area of the recess 440 and the inversion ring 450 is 2000 mm 2 to 2900 mm 2, the sound pressure absorption efficiency and the inversion ring 450 are changed depending on the curved shape of the recess 440 and the inversion ring 450. This is because commercialization factors, such as restoration and independence, can vary greatly.

For example, when the protrusion height H of the concave portion is too low outside the above range, there may be a problem in independence (as will be understood with reference to the embodiments to be described later), and the concave curvature radius r 1 If too small out of this range, when the container deformation due to the negative pressure is generated, excessive stress may be applied to the concave portion and the filling liquid may leak, and the radius of curvature r2 of the reversing ring is too low beyond the above range. Or high will cause problems in the degree of restoration of the reversal ring 450.

From this point of view, the recess 440 and the inversion ring 450 are preferably bent at an appropriate angle and shape, and the inversion ring deflection height IH, the radius of curvature r2 of the inversion ring, and the protrusion of the concave portion. The height H and the radius of curvature r1 of the recess 440 may be adjusted within the above range.

In particular, the radius of curvature r2 of the inversion ring relative to the radius of curvature r1 of the recess is preferably within the range of 3 to 7, more preferably within the range of 4 to 6. If it is less than 3, the refraction angle of the inversion ring becomes relatively severe, which may not only cause problems in the restoring force but also adversely affect the degree of sound pressure absorption. Excessive stress is applied to the recesses, which may result in leakage of the filling liquid.

In the present invention, it is preferable that the moving distance of the recessed portion at the time of the negative pressure is within the range of 2mm to 7mm (the movement distance of the recessed portion is measured by the movement distance of the top surface). If it is less than 2 mm, it may be difficult to achieve the target negative pressure amount, and if it is more than 7 mm, the level of change in the liquid level of the beverage is too large in the filling step of the beverage, and the beverage may flow out of the filling step of the beverage.

Example 1

In order to confirm the operation and effect of the container 10 of the present invention, the depression 460 has a diameter of about 11.84 mm, an inversion ring deflection height IH of about 7.28 mm, and a radius of curvature r2 of the inversion ring about 10.52. mm, the radius of curvature r1 at the height of the concave portion H is set to about 1.98 mm, and the radius of the inversion ring 450 is within a range where the surface area of the inversion ring and the concave portion satisfies 2000 mm 2 to 2900 mm 2 ( Four different pathogens, each having R) of 9 mm, 10 mm, 11.7 mm, and 12 mm, were prepared, and a reduced pressure absorption capacity measurement test was performed for the radius R of the inversion ring 450.

Table 1 below is an example of containers showing the principles and concepts described above.

Radius of reversing ring Volume Absorption 9 mm 19 cc 10 mm 22 cc 11.7 mm 23 cc 12 mm 22.5 cc

Table 1 shows the absorption capacities of the containers having different radii as the absorption capacities (cc) relative to the radius R of the inversion ring 450.

As described above, a container which can generally contain a volume of 400ml to 650ml sufficiently absorbs the vacuum pressure generated due to volume difference of at least about 22cc generated by cooling after filling the container with the contents at a temperature of about 85 ° C. You should be able to.

Therefore, the panelless container 10 according to the present invention preferably has a radius R of the inversion ring 450 of 10 mm to 13 mm.

If the radius R of the inversion ring 450 is too small, the inversion ring 450 protrudes further downward than the ground portion 420 and loses the independence of the container. Due to the surface area, it is difficult to commercialize because the floor is not easily formed during blow molding.

[Example 2]

The radius R of the reversing ring 450 is set to 11.7 mm, and the remaining conditions except for the protrusion height H of the recess 440 are formed in the same manner as in Example 1, but the protrusion height of the recess 440 ( According to H), other pathogens of 7.2 mm, 9.0 mm, 11.0 mm, 11.58 mm, and 13.0 mm were prepared, respectively, and a pressure-absorbing absorption capacity measurement test was performed on the protrusion height H of the recess 440.

Table 2 below is an example of containers showing the principles and concepts described above.

Height of recess Volume Absorption 7.2 mm Loss of independence 9.0 mm 18.5 cc 11.0 mm 18.3 cc 11.58mm 19.0 cc 13.0 mm Floor shaping

Table 2 shows absorption capacities of containers having different heights as absorption capacities (cc) relative to the protrusion height (H) of the concave portion 440.

As described above, a container that can hold a volume of 400ml to 650ml can sufficiently absorb the vacuum pressure generated by the volume difference of about 22cc generated after cooling after filling the container with liquid at the temperature around 85 ℃. However, in this case, as shown in Table 2, the difference in volume absorption amount according to the protrusion height (H) of the concave portion 440 is insufficient, and satisfies the volume absorption amount of 22cc.

However, if the protrusion height H of the concave portion 440 is made too low, the inversion ring 450 protrudes further downward than the ground portion 420, resulting in a loss of independence of the container.

In addition, if the protrusion height H of the concave portion 440 is too high, the container may not have a compact shape, and the portion due to the thin thickness of the heel portion 410 and the ground portion 420 during blow molding of the container may not be obtained. There will be difficulties in securing formation.

Therefore, in the panelless container 10 according to the present invention, it is preferable that the protrusion height H of the recess 440 is 9 mm to 12 mm.

In addition, more preferably, the protrusion height H of the concave portion 440 is formed to be 10mm to 11mm.

The embodiment of the panelless container including the reinforced bottom of the present invention described above is merely illustrative, and those skilled in the art to which the present invention pertains have various modifications and equivalent embodiments. You can see that it is possible. Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

10: panelless container 100: inlet
110: opening 120 thread
130: support ring 200: shoulder
300: body part 310: side wall
350: rib 400: bottom
410: heel portion 420: ground portion
430: ground wall portion 440: recessed portion
450: reverse ring 460: depression
461: top surface 462: depression side
L: Spacing between ribs H: Height of protrusion of recess
IH: deflection height of inversion ring r1: radius of curvature of recess
r2: radius of curvature of the inversion ring R: radius of the inversion ring

Claims (16)

A stretch blow molded panelless container 10 capable of containing a volume of 400 ml to 650 ml,
An inlet 100 having a through-shaped opening 110 filled with contents, a thread 120 and a support ring 130 protruding to facilitate transportation of the container;
A shoulder portion 200 which is integrally formed with the inlet portion 100 and is formed to expand in diameter at a lower end thereof;
A body part 300 which is integrally formed with the lower end of the shoulder portion 200 in which the diameter is extended and includes a side wall 310 and a plurality of ribs 350;
A bottom portion 400 which serves to close the bottom of the panelless container 10 in order to store contents together with the inlet portion 100, the shoulder portion 200, and the body portion 300;
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The bottom portion 400,
A depression having a progressively smaller radius in the shape of a truncated cone having a top surface 461 substantially parallel to the support surface and a recessed side surface 462 that is a plane inclined upwardly with respect to the longitudinal axis of the center of the vessel ( 460);
A ground portion 420 formed at the lowermost end of the container 10 to support the container to stand upright in contact with a floor;
The ground portion 420 and the body portion 300 is integrally formed and molded to form a gentle curve in a convex shape from the ground portion 420, the portion connected to the body portion 300 protrudes in the vertical direction Hill portion 410 is formed so as not to be straight;
A ground wall portion 430 which is formed at an inner circumference of the ground portion 420 to form an inclined angle upward;
A recessed portion 440 formed at an upper end of the ground wall portion 430 at a protruding height H toward the center of the container;
A ring having a radius R, which is raised downward from the recess 440 toward the recess 460 and connected to the recess 460 in a semicircular shape, and completely surrounds the recess 460. An inversion ring 450 molded into;
Panelless container comprising a reinforced bottom portion, characterized in that formed. The method of claim 1,
A panelless container comprising a reinforced bottom portion, characterized in that the concave portion 440 and the inversion ring 450 combined surface area is formed between 2000 mm 2 and 2900 mm 2. 2. The panelless container of claim 1, wherein the ratio of the surface area of the concave portion (440) and the inversion ring (450) to the bottom cross-sectional area of the vessel is between 15% and 60%. The method of claim 1,
The thickness of the heel portion 410, ground portion 420, ground wall portion 430 is constant,
The concave portion 440 and the thickness of the inversion ring 450 are reinforced bottom portion, characterized in that composed of 55% to 85% of the thickness of the heel portion 410, ground portion 420 and ground wall portion 430 Panelless container containing. The method of claim 1,
Rib 350 provided in the body portion 300,
A panelless container comprising a reinforced bottom portion, characterized in that the labeling is easy, and the spacing (L) therebetween is formed in a number from 12.5 mm to 18.7 mm so as to withstand sound pressure. The method of claim 1,
Radius (R) of the reversal ring 450 is a panelless container comprising a reinforced bottom portion, characterized in that formed in 10mm to 13mm. The method of claim 1,
The protrusion height (H) of the concave portion 440 is a panelless container comprising a reinforced bottom portion, characterized in that formed in 9mm to 12mm. The method of claim 1,
The ground portion 420,
A panelless container comprising a reinforced bottom portion formed to support the bottom continuously or intermittently. The method of claim 1,
The inversion ring 450,
A panelless container comprising a reinforced bottom portion, the radial ribs being formed on a surface thereof. The method of claim 1,
The inversion ring 450 is formed with a deflection height (IH) that is the shortest vertical distance from the bottom, the deflection height (IH), characterized in that the reinforced bottom portion is characterized in that formed from 5mm to 9mm Panelless container. The method of claim 10,
The inversion ring 450 is formed to have a predetermined radius of curvature r2 at the point of deflection height IH, wherein the radius of curvature r2 is formed to be 5 mm to 25 mm. A panelless container including a bottom part. 8. The method of claim 7,
The concave portion 440 is formed to have a predetermined radius of curvature r1 at the point of the height of the projection (H), the radius of curvature r1 is reinforced, characterized in that formed in 1mm to 5mm A panelless container including a bottom part. The panelless container of claim 1, wherein a ratio of the radius of curvature r2 of the inversion ring 450 to the radius of curvature r1 of the recess 440 is within a range of 3 to 7. . The panelless container according to claim 1, wherein the moving distance of the depression during the negative pressure is within a range of 2 mm to 7 mm. The panelless container according to claim 1, wherein the negative pressure of the container is within a range of 21 cc to 41 cc. The panelless container according to claim 1, wherein the ratio of the negative pressure to the total capacity of the container is within the range of 4% to 9%.

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