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JP6209465B2 - Impact resistant structure at the bottom of plastic packaging containers - Google Patents
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JP6209465B2 - Impact resistant structure at the bottom of plastic packaging containers - Google Patents

Impact resistant structure at the bottom of plastic packaging containers Download PDF

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JP6209465B2
JP6209465B2 JP2014040526A JP2014040526A JP6209465B2 JP 6209465 B2 JP6209465 B2 JP 6209465B2 JP 2014040526 A JP2014040526 A JP 2014040526A JP 2014040526 A JP2014040526 A JP 2014040526A JP 6209465 B2 JP6209465 B2 JP 6209465B2
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container
resin
diameter
bottom step
container body
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博行 水谷
博行 水谷
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Ishizuka Glass Co Ltd
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本発明は、樹脂製包装容器底部の耐衝撃構造に関し、特に、樹脂製の自立型の包装容器における底部の衝撃に対する耐性を高めるべく改良した構造に関する。   The present invention relates to an impact resistant structure at the bottom of a resin packaging container, and more particularly, to an improved structure for increasing the resistance to impact at the bottom of a self-supporting packaging container made of resin.

一般に、ミネラルウォーター、お茶、スポーツドリンク、ジュース等の清涼飲料水等のための容器では、いわゆるペットボトルと称されるポリエチレンテレフタレート等のポリエステル系樹脂からなる樹脂製容器が多用される。この種の樹脂製容器は、熱可塑性ポリエステル系樹脂組成物を延伸ブロー成形により容器底部と容器胴部とを一体に形成して構成される。   Generally, in containers for soft drinks such as mineral water, tea, sports drinks, juices, etc., resin containers made of polyester resins such as polyethylene terephthalate, so-called PET bottles, are frequently used. This type of resin container is formed by integrally forming a container bottom and a container body by stretch blow molding a thermoplastic polyester resin composition.

上記樹脂性容器では、衝突や落下等の衝撃によりその外形、特に容器底部が変形したり破損して液漏れが生じたりすることがあることから、底面に内部側への凹部とともに、複数の補強溝を形成して、容器底部の強度が高められている(例えば、特許文献1参照。)。   Since the outer shape of the above-mentioned resinous container, particularly the bottom of the container may be deformed or damaged due to impact such as collision or dropping, liquid leakage may occur. Grooves are formed to increase the strength of the container bottom (see, for example, Patent Document 1).

近年、樹脂製容器においては、製造コストの低減や、軽量化、環境への悪影響等を考慮し、材料(熱可塑性ポリエステル系樹脂組成物)の使用量を減らして形成する傾向にある。しかしながら、材料の使用量を減らすと容器が肉薄になるため、容器底部の強度が低下することが避けられない。そこで、容器の更なる肉薄化にも対応し得る強度を備えた樹脂製包装容器底部の耐衝撃構造が切望されている。   In recent years, resin containers tend to be formed by reducing the amount used of a material (thermoplastic polyester resin composition) in consideration of reduction in production cost, weight reduction, adverse effects on the environment, and the like. However, if the amount of the material used is reduced, the container becomes thinner, so that the strength of the bottom of the container is unavoidable. Therefore, an impact resistant structure at the bottom of the resin packaging container having strength that can cope with further thinning of the container is desired.

特開2009−227308号公報JP 2009-227308 A

本発明は、前記の点に鑑みなされたものであり、自立型樹脂製包装容器の肉薄化に対応して底部の衝撃に対する耐性を向上させた樹脂製包装容器底部の耐衝撃構造を提供するものである。   The present invention has been made in view of the above points, and provides an impact-resistant structure for the bottom of a plastic packaging container that has improved resistance to impact at the bottom in response to the thinning of the self-standing resin packaging container. It is.

すなわち、請求項1の発明は、熱可塑性ポリエステル系樹脂組成物を延伸ブロー成形により容器底部(20)と容器胴部(11)とを一体に形成した樹脂製容器において、前記容器底部(20)が、前記容器胴部(11)の下端から前記樹脂製容器の底面(15)に向けて湾曲しながら縮径する湾曲壁部(21)と、前記湾曲壁部(21)の下端に形成され前記樹脂製容器の自立時に接地する接地部(22)と、前記接地部(22)の内側に形成され該接地部(22)から前記樹脂製容器の内部側に傾斜しながら陥入する円錐状の陥凹部(23)と、前記陥凹部(23)の中心に形成され前記陥凹部(23)よりもさらに前記樹脂製容器の内部側に円錐台状に陥没する底段部(24)と、前記底段部(24)を中心として放射状に前記湾曲壁部(21)、前記接地部(22)、及び前記陥凹部(23)を経由して前記底段部(24)の端縁部(24a)に到達する底溝部(25)を備え前記底溝部(25)の溝深さは前記陥凹部(23)において前記接地部(22)から前記底段部(24)の端縁部(24a)にかけて連続して漸次浅く形成されているとともに、前記陥凹部(23)と前記底段部(24)との連接部分において、前記底段部(24)の端縁部(24a)が前記底段部(24)の中央部(24b)から前記陥凹部(23)にかけて前記樹脂製容器の外側に向けて湾曲状に膨出しており、前記陥凹部(23)の直径(D1)は前記容器胴部(11)の最大直径(D)に対して0.59ないし0.67倍であり、前記底段部(24)の中央部直径(D2)は前記容器胴部(11)の最大直径(D)に対して0.14ないし0.22倍であり、前記底段部(24)の端縁部直径(D3)は前記容器胴部(11)の最大直径(D)に対して0.17ないし0.26倍であり、前記接地部(22)から前記底段部(24)の端縁部(24a)までの深さ(H1)は前記容器胴部(11)の最大直径(D)に対して0.04ないし0.10倍であり、前記接地部(22)から前記底段部(24)の中央部(24b)までの深さ(H2)は前記容器胴部(11)の最大直径(D)に対して0.07ないし0.15倍を満たすことを特徴とする樹脂製包装容器底部の耐衝撃構造に係るThat is, the invention of claim 1 is the resin container in which the container bottom part (20) and the container body part (11) are integrally formed of the thermoplastic polyester resin composition by stretch blow molding, and the container bottom part (20). but the container body (11) the lower end from the curved wall portion whose diameter is reduced while being curved toward the bottom surface (15) of the resin vessel (21), formed at the lower end of the curved wall portion (21) a ground portion (22) for grounding when independence of the resin vessel, the ground portion (22) inside the formed grounding portion (22) conical be recessed while inclined toward the inside of the resin vessel from concavities (23), Sokodan unit for recessed inside side frustoconical further the resin vessel than the recessed portion formed in the center (23) of the recess (23) and (24), the curved wall radially around the Sokodan portion (24) (21), said ground portion (22), and provided with edge bottom groove reaching the (24a) (25) of the said Sokodan part via a recess (23) (24), said bottom groove (25) with being gradually shallow groove depth continuously the over the edge of the Sokodan portion from the ground portion (22) in recesses (23) (24) (24a) of said recessed At the connecting portion between the recess (23) and the bottom step (24), the edge (24a) of the bottom step (24) extends from the central portion (24b) of the bottom step (24). (23) bulges toward the outside of the resin container, and the diameter (D1) of the recess (23 ) is 0 with respect to the maximum diameter (D) of the container body (11). .59 to 0.67 times, and the center diameter (D2) of the bottom step (24 ) is the container body 0.14 to 0.22 times the maximum diameter (D ) of the portion (11) , and the edge diameter (D3) of the bottom step (24 ) is the maximum diameter of the container body (11) (D) is 0.17 to 0.26 times the depth (H1) from the grounding portion (22) to the edge (24a) of the bottom step portion (24). 0.04 to 0.10 times the maximum diameter (D ) of (11) , and the depth (H2) from the grounding portion (22) to the central portion (24b) of the bottom step portion (24 ) Relates to the impact resistant structure of the bottom of the plastic packaging container, which satisfies 0.07 to 0.15 times the maximum diameter (D ) of the container body (11) .

請求項の発明は、前記底溝部(25)が6ないし10本形成されている請求項1に記載の樹脂製包装容器底部の耐衝撃構造に係るThe invention according to claim 2 relates to the impact resistant structure of the bottom part of the resin packaging container according to claim 1, wherein 6 to 10 bottom groove parts (25) are formed.

請求項の発明は、前記底段部(24)の中央部(24b)の直径が10ないし15mmである請求項1または2に記載の樹脂製包装容器底部の耐衝撃構造に係るAccording to a third aspect of the present invention, there is provided the impact resistant structure for the bottom of the plastic packaging container according to the first or second aspect, wherein the diameter of the central portion (24b) of the bottom step portion (24) is 10 to 15 mm.

請求項の発明は、前記樹脂製容器が300〜900mLの内容量用の容器である請求項1ないしのいずれか1項に記載の樹脂製包装容器底部の耐衝撃構造に係るThe invention of claim 4 relates to the impact resistance structure of the bottom of the resin packaging container according to any one of claims 1 to 3 , wherein the resin container is a container for an internal volume of 300 to 900 mL.

請求項1の発明に係る樹脂製包装容器底部の耐衝撃構造は、熱可塑性ポリエステル系樹脂組成物を延伸ブロー成形により容器底部と容器胴部とを一体に形成した樹脂製容器において、前記容器底部が、前記容器胴部の下端から前記樹脂製容器の底面に向けて湾曲しながら縮径する湾曲壁部と、前記湾曲壁部の下端に形成され前記樹脂製容器の自立時に接地する接地部と、前記接地部の内側に形成され該接地部から前記樹脂製容器の内部側に傾斜しながら陥入する円錐状の陥凹部と、前記陥凹部の中心に形成され前記陥凹部よりもさらに前記樹脂製容器の内部側に円錐台状に陥没する底段部と、前記底段部を中心として放射状に前記湾曲壁部、前記接地部、及び前記陥凹部を経由して前記底段部の端縁部に到達する底溝部を備え前記底溝部の溝深さは前記陥凹部において前記接地部から前記底段部の端縁部にかけて連続して漸次浅く形成されているとともに、前記陥凹部と前記底段部の連接部分において、前記底段部の端縁部が前記底段部の中央部から前記陥凹部にかけて前記樹脂製容器の外側に向けて湾曲状に膨出しており、前記陥凹部の直径は前記容器胴部の最大直径に対して0.59ないし0.67倍であり、前記底段部の中央部直径は前記容器胴部の最大直径に対して0.14ないし0.22倍であり、前記底段部の端縁部直径は前記容器胴部の最大直径に対して0.17ないし0.26倍であり、前記接地部から前記底段部の端縁部までの深さは前記容器胴部の最大直径に対して0.04ないし0.10倍であり、前記接地部から前記底段部の中央部までの深さは前記容器胴部の最大直径に対して0.07ないし0.15倍を満たすため、容器内部の圧力を効果的に分散させて圧力変化により容器が膨張しても破裂等を抑制するとともに、容器底部の衝突時に生じる衝撃の応力を効果的に分散させて、当該容器の肉薄化に対応して底部の衝撃に対する耐性を効果的に向上させることができる。 The impact resistance structure of the bottom of the resin packaging container according to the invention of claim 1 is a resin container in which a container bottom and a container body are integrally formed by stretching blow molding of a thermoplastic polyester resin composition. Is a curved wall portion that is reduced in diameter while curving from the lower end of the container body toward the bottom surface of the resin container, and a grounding portion that is formed at the lower end of the curved wall portion and is grounded when the resin container is self-standing. A conical recess that is formed inside the grounding portion and inclines while inclining from the grounding portion toward the inside of the resin container, and the resin is further formed at the center of the recessed portion than the recess. A bottom step portion recessed in a truncated cone shape on the inner side of the container, and an edge of the bottom step portion radially passing through the curved wall portion, the grounding portion, and the recess portion around the bottom step portion comprising a bottom groove reaching the part, of the bottom groove Together are gradually shallower formed continuously toward the edge portion of the bottom step part of the ground portion in depth the recess in the connecting portion of the bottom step part and the recess, the edge of the bottom step part An edge portion bulges in a curved shape from the central portion of the bottom step portion to the recessed portion toward the outside of the resin container, and the diameter of the recessed portion is 0. 0 relative to the maximum diameter of the container body portion. 59 to 0.67 times, the center diameter of the bottom step is 0.14 to 0.22 times the maximum diameter of the container body, and the edge diameter of the bottom step is 0.17 to 0.26 times the maximum diameter of the container body, and the depth from the grounding portion to the edge of the bottom step is 0.04 relative to the maximum diameter of the container body. Or a depth from the grounding portion to the center of the bottom step portion is the above-mentioned capacity. In order to satisfy 0.07 to 0.15 times the maximum diameter of the trunk, the inner pressure of the container is effectively dispersed, and even if the container expands due to a pressure change, the bursting and the like are suppressed. It is possible to effectively disperse the stress of the impact generated at the time of the collision, and to effectively improve the resistance to the impact at the bottom corresponding to the thinning of the container.

請求項の発明は、請求項において、前記底溝部が6ないし10本形成されているため、底部の構造を複雑にすることなく、底溝部による優れた補強効果を得ることができる。 According to a second aspect of the invention, in the first aspect , since six to ten bottom groove portions are formed, an excellent reinforcing effect by the bottom groove portion can be obtained without complicating the structure of the bottom portion.

請求項の発明は、請求項1または2において、前記底段部の中央部直径が10ないし15mmであるため、底段部の補強効果をより良好に発揮させるとともに、容器内部の圧力を効果的に分散させることが可能となる。 The invention of claim 3 is the invention according to claim 1 or 2 , wherein the bottom step portion has a central portion diameter of 10 to 15 mm, so that the reinforcing effect of the bottom step portion can be more satisfactorily achieved and the pressure inside the container is effective. Can be dispersed.

請求項の発明は、請求項1ないしにおいて、前記樹脂製容器が300〜900mLの内容量用の容器であるため、市場規格の代替となり得る。 The invention of claim 4 can replace market standards in claims 1 to 3 because the resin container is a container for an internal volume of 300 to 900 mL.

本発明の一実施例に係るの樹脂製包装容器底部の耐衝撃構造を表した側面図である。It is a side view showing the impact-resistant structure of the resin packaging container bottom part concerning one Example of this invention. 図1の樹脂製包装容器底部の耐衝撃構造を表した斜視図である。It is the perspective view showing the impact-resistant structure of the resin packaging container bottom part of FIG. 図1の樹脂製包装容器底部の耐衝撃構造を表した平面図である。It is a top view showing the impact-resistant structure of the resin packaging container bottom part of FIG. 図3のA−A断面図である。It is AA sectional drawing of FIG. 図3のB−B断面図である。It is BB sectional drawing of FIG. 試作例1〜4の容器底部の概略図である。It is the schematic of the container bottom part of prototype examples 1-4.

図1〜3は、本発明の一実施例に係る樹脂製包装容器10の底部20の耐衝撃構造の側面図及び斜視図である。樹脂製包装容器10は、自立型樹脂製包装容器であって、いわゆるペットボトルと称され、ポリエチレンテレフタレート等の熱可塑性ポリエステル系樹脂組成物を延伸ブロー成形により容器胴部11と容器底部20とを一体に形成して構成される。   1 to 3 are a side view and a perspective view of an impact resistant structure of a bottom portion 20 of a resin packaging container 10 according to an embodiment of the present invention. The resin packaging container 10 is a self-supporting resin packaging container, and is called a so-called PET bottle. It is formed integrally.

樹脂製包装容器10の好適なサイズは、ミネラルウォーター、お茶、スポーツドリンク、ジュース等の清涼飲料水等が内容物として充填されて市場に流通される一般的なものであり、具体的には300〜900mLの内容量である。この容量は市場で広く普及している容器であり、市場規格の代替となり得る。また、この包装容器10では、近年の低コスト化、軽量化、環境への配慮等の要望から、材料(熱可塑性ポリエステル系樹脂組成物)の使用量を12〜16g程度に低減させて、壁部の肉薄化が計られている。   A suitable size of the resin packaging container 10 is a general one that is filled with soft drinks such as mineral water, tea, sports drinks, juices and the like and distributed to the market, specifically 300. The content is ~ 900 mL. This capacity is a widely used container in the market and can be an alternative to market standards. Further, in this packaging container 10, the amount of material (thermoplastic polyester resin composition) used is reduced to about 12 to 16 g due to recent demands for cost reduction, weight reduction, environmental consideration, etc. Thinning of parts is planned.

容器胴部11は、図1,2に示すように、略円筒形状を含む適宜形状に形成された部位であり、上部に図示しない容器口部を有する。容器胴部11には、強度向上や持ち易さ、装飾性向上等のために、必要に応じて適宜の凹凸部や括れ部等が形成される。   The container trunk | drum 11 is a site | part formed in the appropriate | suitable shape containing a substantially cylindrical shape, as shown to FIG. In the container body portion 11, appropriate uneven portions, constricted portions, and the like are formed as necessary in order to improve strength, ease of holding, decorativeness, and the like.

容器底部20は、当該樹脂製包装容器10を自立可能とするとともに、衝撃に対する耐性を向上させる構造を有するものであって、図4,5に示すように、湾曲壁部21と、接地部22と、陥凹部23と、底段部24と、底溝部25とを備える。   The container bottom portion 20 has a structure that enables the resin packaging container 10 to be self-supporting and improves resistance to impact, and as shown in FIGS. 4 and 5, the curved wall portion 21 and the grounding portion 22. And a recessed portion 23, a bottom step portion 24, and a bottom groove portion 25.

湾曲壁部21は、容器胴部11の下端から樹脂製容器10の底面15に向けて湾曲しながら縮径する部位である。湾曲壁部21は、容器底部20の角部を面取りした部位に相当し、衝突時や落下時等の変形や破損等の発生を抑制するとともに、容器内部の圧力を分散させる効果を有する。   The curved wall portion 21 is a portion that is reduced in diameter while being curved from the lower end of the container body portion 11 toward the bottom surface 15 of the resin container 10. The curved wall portion 21 corresponds to a portion where the corner portion of the container bottom portion 20 is chamfered, and has an effect of suppressing the occurrence of deformation or breakage at the time of a collision or dropping, and also distributing the pressure inside the container.

接地部22は、湾曲壁部21の下端に形成され樹脂製容器10の自立時に接地する部位である。接地部22は、当該容器10の自立性確保のために設けられた平面部分であり、底面15に所定幅で円周状に全周に亘って形成される。   The grounding portion 22 is a portion that is formed at the lower end of the curved wall portion 21 and is grounded when the resin container 10 is self-supporting. The grounding portion 22 is a flat portion provided to ensure the self-supporting property of the container 10, and is formed on the bottom surface 15 with a predetermined width over the entire circumference.

陥凹部23は、接地部22の内側に形成され該接地部22から樹脂製容器10の内部側に傾斜しながら陥入する円錐状の部位である。陥凹部23は、容器内部の圧力を分散させ、特に圧力変化が生じて当該容器10が膨張した場合の破裂等を抑制する。   The recessed portion 23 is a conical portion that is formed inside the grounding portion 22 and invades while tilting from the grounding portion 22 toward the inside of the resin container 10. The recessed portion 23 disperses the pressure inside the container, and suppresses rupture or the like when the container 10 expands due to a change in pressure.

底段部24は、陥凹部23の中心に形成され陥凹部23よりもさらに樹脂製容器10の内部側に円錐台状に陥没する部位である。底段部24は、容器底部20の衝突時の陥凹部23に対する衝撃の応力を分散させて陥凹部23を補強するとともに、容器内部の圧力を分散させる。特に、底段部24では、端縁部24aが、底段部24の中央部24bから陥凹部23にかけて樹脂製容器10の外側に向けて湾曲状に膨出している。これは、陥凹部23と底段部24との連接部分を面取りした部位に相当し、より効果的に容器内部の圧力を分散させる。また、底段部24の中央部24b直径D2は、容器10の大きさ(容量)に関わらず10ないし15mmである。直径D2が10mmより小さい場合、十分な補強効果が発揮されないおそれがある。直径D2が15mmより大きい場合、平坦部分が広くなりすぎて容器内部の圧力を十分に分散させることができなくなるおそれがある。   The bottom step portion 24 is a portion that is formed at the center of the recessed portion 23 and that is further recessed into a truncated cone shape on the inner side of the resin container 10 than the recessed portion 23. The bottom step portion 24 reinforces the recessed portion 23 by dispersing the stress of impact on the recessed portion 23 at the time of the collision of the container bottom portion 20 and also distributes the pressure inside the container. In particular, in the bottom step portion 24, the end edge portion 24 a bulges in a curved shape from the central portion 24 b of the bottom step portion 24 to the recessed portion 23 toward the outside of the resin container 10. This corresponds to a portion where the connecting portion between the recessed portion 23 and the bottom step portion 24 is chamfered, and disperses the pressure inside the container more effectively. Further, the diameter D2 of the central portion 24b of the bottom step portion 24 is 10 to 15 mm regardless of the size (capacity) of the container 10. When the diameter D2 is smaller than 10 mm, a sufficient reinforcing effect may not be exhibited. When the diameter D2 is larger than 15 mm, the flat portion becomes too wide and the pressure inside the container may not be sufficiently dispersed.

底溝部25は、容器内部側へ筋状にくぼんだ複数の溝部であり、底段部24を中心として放射状に湾曲壁部21、接地部22、及び陥凹部23を経由して底段部24の端縁部24aに到達するように形成される。底溝部25の溝深さは陥凹部23において接地部22から底段部24の端縁部24aにかけて漸次浅く形成される。この底溝部25は、容器底部20の衝突時に生じる衝撃の応力を分散させるための補強溝として作用する。底溝部25の数は、強度や成形容易性等の観点から6ないし10本形成される。底溝部25が6本より少ない場合、応力の分散が十分ではなく、所望の強度が得られないおそれがある。底溝部25が10本より多い場合、容器底部20の構造が複雑になりすぎるとともに、底溝部25の増加に伴う補強効果の向上が見込まれない。   The bottom groove portion 25 is a plurality of grooves recessed in a streak-like manner toward the inside of the container, and the bottom step portion 24 passes through the curved wall portion 21, the grounding portion 22, and the recessed portion 23 radially from the bottom step portion 24. It is formed so as to reach the end edge 24a. The groove depth of the bottom groove portion 25 is gradually shallower from the grounding portion 22 to the edge 24 a of the bottom step portion 24 in the recessed portion 23. The bottom groove portion 25 acts as a reinforcing groove for dispersing the stress of impact generated when the container bottom portion 20 collides. Six to ten bottom groove portions 25 are formed from the viewpoints of strength and ease of molding. When the number of the bottom groove portions 25 is less than 6, the stress is not sufficiently distributed, and a desired strength may not be obtained. When the number of the bottom groove portions 25 is more than ten, the structure of the container bottom portion 20 becomes too complicated, and the improvement of the reinforcing effect accompanying the increase in the bottom groove portions 25 is not expected.

これより、図4及び図5を用い、容器底部20における各部位同士の大小関係(割合)について説明する。図4は、図3のA−A線に対応し、底溝部25の中間位置における部分断面図である。図5は、図3のB−B線に対応し、底溝部25同士の中間位置における部分断面図である。   From this, the magnitude | size relationship (ratio) of each site | part in the container bottom part 20 is demonstrated using FIG.4 and FIG.5. FIG. 4 is a partial cross-sectional view corresponding to the line AA in FIG. 5 corresponds to the line BB in FIG. 3 and is a partial cross-sectional view at an intermediate position between the bottom groove portions 25.

当該容器底部20の耐衝撃構造にあっては、図4に示すように、陥凹部23の直径D1は容器胴部11の最大直径Dに対して0.59ないし0.67倍(D1/D=0.59〜0.67)であり、底段部24の中央部24b直径D2は容器胴部11の最大直径Dに対して0.14ないし0.22倍(D2/D=0.14〜0.22)であり、底段部24の端縁部24a直径D3は容器胴部11の最大直径Dに対して0.17ないし0.26倍(D3/D=0.17〜0.26)であり、接地部22から底段部24の端縁部24aまでの深さH1は容器胴部11の最大直径Dに対して0.04ないし0.10倍(H1/D=0.04〜0.10)であり、接地部22から底段部24の中央部24bまでの深さH2は容器胴部11の最大直径Dに対して0.07ないし0.15倍(H2/D=0.07〜0.15)を満たしている。 In the impact resistant structure of the container bottom 20, as shown in FIG. 4, the diameter D 1 of the recess 23 is 0.59 to 0.67 times the maximum diameter D of the container body 11 (D1 / D = 0.59-0.67), and the diameter D2 of the central portion 24b of the bottom step portion 24 is 0.14 to 0.22 times the maximum diameter D of the container body 11 (D2 / D = 0.14). 0.22), and the diameter D3 of the edge 24a of the bottom step 24 is 0.17 to 0.26 times the maximum diameter D of the container body 11 (D3 / D = 0.17-0.20). 26), and the depth H1 from the ground contact portion 22 to the edge 24a of the bottom step portion 24 is 0.04 to 0.10 times the maximum diameter D of the container body 11 (H1 / D = 0.0). 04 to 0.10), and the depth H2 from the ground portion 22 to the center portion 24b of the Sokodan portion 24 to the maximum diameter D of the container body 11 It 0.07 and satisfies 0.15 times (H2 / D = 0.07~0.15).

陥凹部23の直径D1が容器胴部11の最大直径Dに対して0.59倍より小さい場合(D1/D<0.59)、内圧により接地部22が半円状に変化しやすくなり、結果として接地径が小さくなるため、自立安定性が低下する。また、直径D1が最大直径Dに対して0.67倍より大きい場合(D1/D>0.67)、接地部22の幅が狭くなって平坦部分の面積が小さくなりすぎ、自立時の安定性が低下するおそれがある。 When the diameter D1 of the recess 23 is smaller than 0.59 times the maximum diameter D of the container body 11 (D1 / D <0.59), the grounding portion 22 is likely to change into a semicircular shape due to internal pressure, As a result, the ground contact diameter is reduced, so that the self-supporting stability is lowered. In addition, when the diameter D1 is larger than the maximum diameter D by 0.67 times (D1 / D> 0.67), the width of the grounding portion 22 becomes narrow and the area of the flat portion becomes too small, so that the stability at the time of self-standing May decrease.

底段部24の中央部24b直径D2が容器胴部11の最大直径Dに対して0.14倍より小さい場合(D2/D<0.14)、応力の分散が十分ではなく、所望する補強効果が発揮されないおそれがある。また、直径D2が最大直径Dに対して0.22倍より大きい場合(D2/D>0.22)、平坦部分が広くなりすぎて容器内部の圧力を十分に分散させることができなくなるおそれがある。 When the diameter D2 of the central portion 24b of the bottom step portion 24 is smaller than 0.14 times the maximum diameter D of the container body portion 11 (D2 / D <0.14), the stress is not sufficiently distributed and desired reinforcement is achieved. The effect may not be demonstrated. Further, when the diameter D2 is larger than 0.22 times the maximum diameter D (D2 / D> 0.22), there is a possibility that the flat part becomes too wide to sufficiently disperse the pressure inside the container. is there.

底段部24の端縁部24a直径D3が容器胴部11の最大直径Dに対して0.17倍より小さい場合(D3/D<0.17)、傾斜部分が小さく容器内部の圧力を十分に分散させることができないおそれがある。また、直径D3が最大直径Dに対して0.26倍より大きい場合(D3/D>0.26)、応力の分散が十分ではなく、所望する補強効果が発揮されないおそれがある。 When the edge portion 24a diameter D3 of the bottom step portion 24 is smaller than the maximum diameter D of the container body 11 by 0.17 times (D3 / D <0.17), the inclined portion is small and the pressure inside the container is sufficient. There is a possibility that it cannot be dispersed. In addition, when the diameter D3 is larger than 0.26 times the maximum diameter D (D3 / D> 0.26), the stress is not sufficiently distributed, and the desired reinforcing effect may not be exhibited.

接地部22から底段部24の端縁部24aまでの深さH1が容器胴部11の最大直径Dに対して0.04倍より小さい場合(H1/D<0.04)、陥凹部23の凹みが浅く、容器内部の圧力を十分に分散させることができなくなるおそれがある。また、深さH1が最大直径Dに対して0.10倍より大きい場合(H1/D>0.10)、深さH1の増加に伴う圧力分散効果の向上が見込まれない。 When the depth H1 from the ground contact portion 22 to the edge 24a of the bottom step portion 24 is smaller than 0.04 times the maximum diameter D of the container body portion 11 (H1 / D <0.04), the recess 23 There is a possibility that the pressure inside the container cannot be sufficiently dispersed. Further, when the depth H1 is larger than 0.10 times the maximum diameter D (H1 / D> 0.10), the improvement of the pressure dispersion effect with the increase in the depth H1 is not expected.

接地部22から底段部24の中央部24bまでの深さH2が容器胴部11の最大直径Dに対して0.07倍より小さい場合(H2/D<0.07)、底段部24の深さが浅く、応力の分散が不十分となり、所望する補強効果が発揮されないおそれがある。また、深さH2が最大直径Dに対して0.15倍より大きい場合(H2/D>0.15)、深さH2の増加に伴う圧力分散効果の向上が見込まれない。 When the depth H2 from the grounding portion 22 to the central portion 24b of the bottom step portion 24 is smaller than 0.07 times the maximum diameter D of the container body portion 11 (H2 / D <0.07), the bottom step portion 24 There is a possibility that the desired reinforcement effect may not be exhibited due to insufficient depth of stress distribution. Further, when the depth H2 is larger than 0.15 times the maximum diameter D (H2 / D> 0.15), the improvement of the pressure dispersion effect with the increase of the depth H2 is not expected.

次に、ポリエチレンテレフタレート樹脂からなるプリフォームを後述する各試作例1ないし4に応じた金型に入れて延伸ブロー成形し、容器底部の構造を異ならせた成形後の容器重量が15g、容器底部の重量が1.6gとなる600mL用の樹脂製包装容器(試作例1ないし4)を試作した。各試作例1ないし4の底溝部の数は、それぞれ8本である。   Next, a preform made of polyethylene terephthalate resin is placed in a mold corresponding to each of prototype examples 1 to 4 to be described later and stretch blow molded, and the container weight after molding with a different structure of the container bottom is 15 g. A 600 mL resin packaging container (prototype examples 1 to 4) having a weight of 1.6 g was manufactured. The number of bottom grooves in each of the prototype examples 1 to 4 is eight.

図6(a)に示す試作例1の容器底部20は、図4等に示した本発明形状からなり、Dを69mm、D1を44mm、D2を12.0mm、D3を15.9mm、H1を4.95mm、H2を7.6mmとした。従って、D1/Dが約0.64、D2/Dが約0.17、D3/Dが約0.23、H1/Dが約0.07、H2/Dが約0.11である。   The container bottom 20 of Prototype Example 1 shown in FIG. 6A has the shape of the present invention shown in FIG. 4 and the like, and D is 69 mm, D1 is 44 mm, D2 is 12.0 mm, D3 is 15.9 mm, and H1 is It was 4.95 mm and H2 was 7.6 mm. Therefore, D1 / D is about 0.64, D2 / D is about 0.17, D3 / D is about 0.23, H1 / D is about 0.07, and H2 / D is about 0.11.

図6(b)に示す試作例2の容器底部20Aは、湾曲壁部21Aと、接地部22Aと、接地部22Aから樹脂製容器の内部側に内部方向へ湾曲しながら陥入する陥凹部23Aと、陥凹部23Aの中心に形成され樹脂製容器の内部側に内部方向へ湾曲しながら陥没する底段部24Aと、底溝部25Aとを備えた形状からなり、Dを69mm、D1を50mm、D2を6.0mm、D3を9.0mm、H1が5.0mm、H2を6.5mmとした。従って、D1/Dが約0.72、D2/Dが約0.09、D3/Dが約0.13、H1/Dが約0.07、H2/Dが約0.09である。   The container bottom portion 20A of Prototype Example 2 shown in FIG. 6 (b) has a curved wall portion 21A, a grounding portion 22A, and a recessed portion 23A that indents while curving inward from the grounding portion 22A to the inside of the resin container. And a bottom step portion 24A that is formed in the center of the recessed portion 23A and sinks while curving inward on the inner side of the resin container, and a bottom groove portion 25A, D is 69 mm, D1 is 50 mm, D2 was 6.0 mm, D3 was 9.0 mm, H1 was 5.0 mm, and H2 was 6.5 mm. Therefore, D1 / D is about 0.72, D2 / D is about 0.09, D3 / D is about 0.13, H1 / D is about 0.07, and H2 / D is about 0.09.

図6(c)に示す試作例3の容器底部20Bは、湾曲壁部21Bと、接地部22Bと、接地部22Bから樹脂製容器の内部側に内部方向へ湾曲しながら陥入する陥凹部23Bと、陥凹部23Bの中心に形成され樹脂製容器の内部側に内部方向へ湾曲しながら陥没する底段部24Bと、底溝部25Bとを備えた形状からなり、Dを69mm、D1を49mm、D2を8.0mm、D3を11.7mm、H1を4.9mm、H2を8.0mmとした。従って、D1/Dが約0.71、D2/Dが約0.12、D3/Dが約0.17、H1/Dが約0.07、H2/Dが約0.12である。   The container bottom portion 20B of Prototype Example 3 shown in FIG. 6C has a curved wall portion 21B, a grounding portion 22B, and a recessed portion 23B that indents while curving inward from the grounding portion 22B to the inside of the resin container. And a bottom step portion 24B that is formed in the center of the recessed portion 23B and that is recessed while curving inwardly on the inner side of the resin container, and a bottom groove portion 25B, and D is 69 mm, D1 is 49 mm, D2 was 8.0 mm, D3 was 11.7 mm, H1 was 4.9 mm, and H2 was 8.0 mm. Therefore, D1 / D is about 0.71, D2 / D is about 0.12, D3 / D is about 0.17, H1 / D is about 0.07, and H2 / D is about 0.12.

図6(d)に示す試作例4の容器底部20Cは、湾曲壁部21Cと、接地部22Cと、接地部22Cから樹脂製容器の内部側に内部方向へ湾曲しながら陥入する陥凹部23Cと、陥凹部23Cの中心に形成され樹脂製容器の内部側に内部方向へ湾曲しながら陥没する底段部24Cと、底溝部25Cとを備えた形状からなり、Dを69mm、D1を44mm、D2を8.0、D3を10.5mm、H1を5.0mm、H2を7.0mmとした。従って、D1/Dが約0.64、D2/Dが約0.12、D3/Dが約0.15、H1/Dが約0.07、H2/Dが約0.10である。   The container bottom portion 20C of Prototype Example 4 shown in FIG. 6 (d) has a curved wall portion 21C, a grounding portion 22C, and a recessed portion 23C that indents while curving inward from the grounding portion 22C to the inside of the resin container. And a bottom step portion 24C formed in the center of the recessed portion 23C and recessed while curving inwardly on the inner side of the resin container, and a bottom groove portion 25C, D is 69 mm, D1 is 44 mm, D2 was 8.0, D3 was 10.5 mm, H1 was 5.0 mm, and H2 was 7.0 mm. Therefore, D1 / D is about 0.64, D2 / D is about 0.12, D3 / D is about 0.15, H1 / D is about 0.07, and H2 / D is about 0.10.

上記試作例1〜4の樹脂製包装容器をそれぞれ20本ずつ用意し、各容器に内容物として水を充填して20℃の恒温室一定時間保管した後、落下試験を行った。落下試験では、1.5mの高さから容器を正立状態で鉄板に落下させる試行を1本当たり3回繰り返し行い、目視にて底割れの有無を確認した。各容器の評価結果は表1に示す。なお、表1において、分母が検体数の20本であり、分子がそのうちの底割れが生じた容器の数である。   Twenty resin packaging containers of each of the above prototypes 1 to 4 were prepared, each container was filled with water as a content, stored at a constant temperature room at 20 ° C., and then subjected to a drop test. In the drop test, an attempt to drop the container on an iron plate in an upright state from a height of 1.5 m was repeated three times per bottle, and the presence or absence of a bottom crack was confirmed visually. The evaluation results of each container are shown in Table 1. In Table 1, the denominator is 20 of the number of specimens, and the numerator is the number of containers in which the bottom crack occurred.

Figure 0006209465
Figure 0006209465

表1に示すように、試作例1では、20本すべての容器で底割れが発生しなかった。試作例2では、20本の容器のうち3本の容器で底割れが発生した。試作例3では、20本の容器のうち1本の容器で底割れが発生した。試作例4では、20本の容器のうち5本の容器で底割れが発生した。   As shown in Table 1, in Prototype Example 1, no bottom cracks occurred in all 20 containers. In Prototype Example 2, bottom cracks occurred in three of the 20 containers. In Prototype Example 3, a bottom crack occurred in one of the 20 containers. In Prototype Example 4, bottom cracks occurred in 5 of the 20 containers.

試作例1にあっては、D1/Dが約0.64、D2/Dが約0.17、D3/Dが約0.23、H1/Dが約0.07、H2/Dが約0.11である。従って、D1/D=0.59〜0.67、D2/D=0.14〜0.22、D3/D=0.17〜0.26、H1/D=0.04〜0.10、H2/D=0.07〜0.15のすべての条件を満たしていることにより底割れが発生せず、底部20の衝撃に対する耐性を十分に向上させることができると想定できる。   In Prototype Example 1, D1 / D is about 0.64, D2 / D is about 0.17, D3 / D is about 0.23, H1 / D is about 0.07, and H2 / D is about 0. .11. Therefore, D1 / D = 0.59-0.67, D2 / D = 0.14-0.22, D3 / D = 0.17-0.26, H1 / D = 0.04-0.10, By satisfying all the conditions of H2 / D = 0.07 to 0.15, it can be assumed that the bottom crack does not occur and the resistance to the impact of the bottom portion 20 can be sufficiently improved.

試作例2にあっては、D1/Dが約0.72、D2/Dが約0.09、D3/Dが約0.13、H1/Dが約0.07、H2/Dが約0.09である。従って、H1/D=0.04〜0.10、H2/D=0.07〜0.15の条件を満たしているものの、D1/D=0.59〜0.67、D2/D=0.14〜0.22、D3/D=0.17〜0.26の条件を満たしていないことにより底割れが発生し、底部20Aの衝撃に対する耐性を向上させることが不十分であったことがわかった。   In Prototype Example 2, D1 / D is about 0.72, D2 / D is about 0.09, D3 / D is about 0.13, H1 / D is about 0.07, and H2 / D is about 0. .09. Therefore, although the conditions of H1 / D = 0.04 to 0.10 and H2 / D = 0.07 to 0.15 are satisfied, D1 / D = 0.59 to 0.67, D2 / D = 0 .14 to 0.22, D3 / D = 0.17 to 0.26 by not satisfying the condition, bottom cracks occurred, and it was insufficient to improve the resistance to the impact of the bottom 20A all right.

試作例3にあっては、D1/Dが約0.71、D2/Dが約0.12、D3/Dが約0.17、H1/Dが約0.07、H2/Dが約0.12である従って、D3/D=0.17〜0.26、H1/D=0.04〜0.10、H2/D=0.07〜0.15の条件を満たしているものの、D1/D=0.59〜0.67、D2/D=0.14〜0.22の条件を満たしていないことにより底割れが発生し、底部20Bの衝撃に対する耐性を向上させることが不十分であったことがわかった。   In Prototype Example 3, D1 / D is about 0.71, D2 / D is about 0.12, D3 / D is about 0.17, H1 / D is about 0.07, and H2 / D is about 0. Therefore, although D3 / D = 0.17 to 0.26, H1 / D = 0.04 to 0.10, and H2 / D = 0.07 to 0.15 are satisfied, D1 /D=0.59-0.67, D2 / D = 0.14-0.22 is not satisfied, the bottom crack occurs, it is insufficient to improve the resistance to the impact of the bottom 20B I knew there was.

試作例4にあっては、D1/Dが約0.64、D2/Dが約0.12、D3/Dが約0.15、H1/Dが約0.07、H2/Dが約0.10である。従って、D1/D=0.59〜0.67、H1/D=0.04〜0.10、H2/D=0.07〜0.15の条件を満たしているものの、D2/D=0.14〜0.22、D3/D=0.17〜0.26の条件を満たしていないことにより底割れが発生し、底部20Cの衝撃に対する耐性を向上させることが不十分であったことがわかった。   In Prototype Example 4, D1 / D is about 0.64, D2 / D is about 0.12, D3 / D is about 0.15, H1 / D is about 0.07, and H2 / D is about 0. .10. Therefore, although D1 / D = 0.59-0.67, H1 / D = 0.04-0.10, and H2 / D = 0.07-0.15 are satisfied, D2 / D = 0 .14 to 0.22, D3 / D = 0.17 to 0.26 by not satisfying the conditions, bottom cracks occurred, and it was insufficient to improve the resistance to impact of the bottom 20C all right.

表1の結果から理解されるように、試作例1の樹脂製包装容器10において容器底部20の強度を十分に確保することができたのに対し、試作例2〜4の樹脂製包装容器10では容器底部の強度が不十分であった。すなわち、D1がDに対して0.59ないし0.67倍、D2がDに対して0.14ないし0.22倍、D3がDに対して0.17ないし0.26倍、H1がDに対して0.04ないし0.10倍、H2がDに対して0.07ないし0.15倍である条件をすべて満たすことにより、樹脂製包装容器10の容器底部20に極めて優れた強度を付与することが可能であることがわかった。   As can be understood from the results in Table 1, the resin packaging container 10 of Prototype Example 1 can sufficiently secure the strength of the container bottom 20, whereas the resin packaging containers 10 of Prototype Examples 2 to 4 Then, the strength of the container bottom was insufficient. That is, D1 is 0.59 to 0.67 times D, D2 is 0.14 to 0.22 times D, D3 is 0.17 to 0.26 times D, and H1 is D By satisfying all the conditions that 0.04 to 0.10 times with respect to H and H2 is 0.07 to 0.15 times with respect to D, the container bottom portion 20 of the resin packaging container 10 has extremely excellent strength. It was found that it can be granted.

以上図示し説明したように、本発明の樹脂製包装容器10の底部20の耐衝撃構造は、熱可塑性ポリエステル系樹脂組成物を延伸ブロー成形により容器底部20と容器胴部11とを一体に形成した自立型樹脂製包装容器において、容器底部20が、容器胴部11の下端から樹脂製容器10の底面15に向けて湾曲しながら縮径する湾曲壁部21と、湾曲壁部21の下端に形成され樹脂製容器10の自立時に接地する接地部22と、接地部22の内側に形成され該接地部22から樹脂製容器10の内部側に傾斜しながら陥入する円錐状の陥凹部23と、陥凹部23の中心に形成され陥凹部23よりもさらに樹脂製容器10の内部側に円錐台状に陥没する底段部24と、底段部24を中心として放射状に湾曲壁部21、接地部22、及び陥凹部23を経由して底段部24の端縁部24aに到達する底溝部25を備えており、底溝部25の溝深さは陥凹部23において接地部22から底段部24の端縁部24aにかけて漸次浅く形成されている。そのため、容器内部の圧力を効果的に分散させて圧力変化により容器が膨張しても破裂等を抑制することができるとともに、容器底部20の衝突時に生じる衝撃の応力を効果的に分散させて強度を向上させることができる。 As illustrated and described above, the impact resistant structure of the bottom 20 of the resin packaging container 10 of the present invention is formed by integrally forming the container bottom 20 and the container body 11 by stretch blow molding a thermoplastic polyester resin composition. In the self-supporting plastic packaging container, the container bottom portion 20 has a curved wall portion 21 that decreases in diameter while curving from the lower end of the container body portion 11 toward the bottom surface 15 of the resin container 10, and a lower end of the curved wall portion 21. A grounding portion 22 formed and grounded when the resin container 10 is self-supported, and a conical recess 23 formed inside the grounding portion 22 and inclining from the grounding portion 22 toward the inside of the resin container 10. A bottom step portion 24 formed in the center of the recess portion 23 and recessed further in the shape of a truncated cone on the inner side of the resin container 10 than the recess portion 23, a curved wall portion 21 radiating from the bottom step portion 24 as a center, Part 22 and recess 2 A bottom groove 25 that reaches the edge 24a of the bottom step 24 via the bottom groove 25. The groove depth of the bottom groove 25 extends from the grounding portion 22 to the edge 24a of the bottom step 24 in the recessed portion 23. It is formed gradually shallower. Therefore, even if the pressure inside the container is effectively dispersed and the container expands due to a pressure change, bursting or the like can be suppressed, and the stress of the impact generated when the container bottom 20 collides can be effectively dispersed to increase the strength. Can be improved.

特に、底部20の耐衝撃構造にあっては、陥凹部23の直径D1は容器胴部11の最大直径Dに対して0.59ないし0.67倍であり、底段部24の中央部24b直径D2は容器胴部11の最大直径Dに対して0.14ないし0.22倍であり、底段部24の端縁部24a直径D3は容器胴部11の最大直径Dに対して0.17ないし0.26倍であり、接地部22から底段部24の端縁部24aまでの深さH1は容器胴部11の最大直径Dに対して0.04ないし0.10倍であり、接地部22から底段部24の中央部24bまでの深さH2は容器胴部11の最大直径Dに対して0.07ないし0.15倍を満たしていることにより、当該包装容器10の肉薄化に対応して底部20の衝撃に対する耐性を効果的に向上させることが可能となる。 In particular, in the impact resistant structure of the bottom portion 20, the diameter D 1 of the recessed portion 23 is 0.59 to 0.67 times the maximum diameter D of the container body portion 11 , and the central portion 24 b of the bottom step portion 24. The diameter D2 is 0.14 to 0.22 times the maximum diameter D of the container body 11 , and the diameter D3 of the edge 24a of the bottom step portion 24 is 0. 0 relative to the maximum diameter D of the container body 11 . 17 to 0.26 times, and the depth H1 from the ground contact portion 22 to the edge 24a of the bottom step portion 24 is 0.04 to 0.10 times the maximum diameter D of the container body 11 , The depth H2 from the grounding portion 22 to the central portion 24b of the bottom step portion 24 satisfies 0.07 to 0.15 times the maximum diameter D of the container body portion 11 , thereby reducing the thickness of the packaging container 10. It is possible to effectively improve the resistance to the impact of the bottom 20 corresponding to the That.

また、底段部24の端縁部24aを、底段部24の中央部24bから陥凹部23にかけて樹脂製容器10の外側に向けて湾曲状に膨出させれば、底段部24による容器内部の圧力分散効果をより効果的に発揮させることが可能となる。   Further, if the edge 24a of the bottom step 24 is bulged out from the central portion 24b of the bottom step 24 to the recess 23 toward the outside of the resin container 10, the container formed by the bottom step 24 is used. It becomes possible to exhibit the internal pressure dispersion effect more effectively.

さらに、底溝部25を6ないし10本形成すれば、底部20の構造を複雑にすることなく、底溝部25による優れた補強効果を得ることができる。   Furthermore, if 6 to 10 bottom groove portions 25 are formed, an excellent reinforcing effect by the bottom groove portion 25 can be obtained without complicating the structure of the bottom portion 20.

加えて、底段部24の中央部24b直径を10ないし15mmとすれば、底段部24の補強効果をより良好に発揮させるとともに、容器内部の圧力を効果的に分散させることが可能となる。   In addition, if the diameter of the central portion 24b of the bottom step portion 24 is 10 to 15 mm, the reinforcing effect of the bottom step portion 24 can be exhibited better and the pressure inside the container can be effectively dispersed. .

なお、本発明の樹脂製包装容器底部の耐衝撃構造は、上記実施例に限定されるものではなく、発明の趣旨を逸脱しない範囲において変更可能である。   In addition, the impact resistance structure of the resin packaging container bottom part of this invention is not limited to the said Example, It can change in the range which does not deviate from the meaning of invention.

本発明の樹脂製包装容器底部の耐衝撃構造は、容器底部の構造の改善によって、これまで以上に耐衝撃性を高めることができる。よって、既存の樹脂製包装容器の代替として極めて有望である。   The impact resistance structure of the bottom of the resin packaging container of the present invention can improve the impact resistance more than ever by improving the structure of the container bottom. Therefore, it is extremely promising as an alternative to existing resin packaging containers.

10 樹脂製包装容器
11 容器胴部
20 容器底部
21 湾曲壁部
22 接地部
23 陥凹部
24 底段部
24a 底段部の端縁部
24b 底段部の中央部
25 底溝部
D 容器胴部の最大直径
D1 陥凹部の直径
D2 底段部の中央部直径
D3 底段部の端縁部直径
H1 底段部の端縁部までの深さ
H2 底段部の中央部までの深さ
DESCRIPTION OF SYMBOLS 10 Resin packaging container 11 Container trunk part 20 Container bottom part 21 Curved wall part 22 Grounding part 23 Depression recessed part 24 Bottom step part 24a Edge part of bottom step part 24b Center part of bottom step part 25 Bottom groove part D Maximum of container trunk part Diameter D1 Diameter of recess D2 Center diameter of bottom step D3 Edge diameter of bottom step H1 Depth to end of bottom step H2 Depth to center of bottom step

Claims (4)

熱可塑性ポリエステル系樹脂組成物を延伸ブロー成形により容器底部(20)と容器胴部(11)とを一体に形成した樹脂製容器において、
前記容器底部(20)が、
前記容器胴部(11)の下端から前記樹脂製容器の底面(15)に向けて湾曲しながら縮径する湾曲壁部(21)と、
前記湾曲壁部(21)の下端に形成され前記樹脂製容器の自立時に接地する接地部(22)と、
前記接地部(22)の内側に形成され該接地部(22)から前記樹脂製容器の内部側に傾斜しながら陥入する円錐状の陥凹部(23)と、
前記陥凹部(23)の中心に形成され前記陥凹部(23)よりもさらに前記樹脂製容器の内部側に円錐台状に陥没する底段部(24)と、
前記底段部(24)を中心として放射状に前記湾曲壁部(21)、前記接地部(22)、及び前記陥凹部(23)を経由して前記底段部(24)の端縁部(24a)に到達する底溝部(25)を備え
前記底溝部(25)の溝深さは前記陥凹部(23)において前記接地部(22)から前記底段部(24)の端縁部(24a)にかけて連続して漸次浅く形成されているとともに、
前記陥凹部(23)と前記底段部(24)との連接部分において、前記底段部(24)の端縁部(24a)が前記底段部(24)の中央部(24b)から前記陥凹部(23)にかけて前記樹脂製容器の外側に向けて湾曲状に膨出しており、
前記陥凹部(23)の直径(D1)は前記容器胴部(11)の最大直径(D)に対して0.59ないし0.67倍であり、
前記底段部(24)の中央部直径(D2)は前記容器胴部(11)の最大直径(D)に対して0.14ないし0.22倍であり、
前記底段部(24)の端縁部直径(D3)は前記容器胴部(11)の最大直径(D)に対して0.17ないし0.26倍であり、
前記接地部(22)から前記底段部(24)の端縁部(24a)までの深さ(H1)は前記容器胴部(11)の最大直径(D)に対して0.04ないし0.10倍であり、
前記接地部(22)から前記底段部(24)の中央部(24b)までの深さ(H2)は前記容器胴部(11)の最大直径(D)に対して0.07ないし0.15倍を満たす
ことを特徴とする樹脂製包装容器底部の耐衝撃構造。
In a resin container in which a container bottom (20) and a container body (11) are integrally formed by stretching blow molding a thermoplastic polyester resin composition,
The container bottom (20)
A curved wall portion (21) that decreases in diameter while curving from the lower end of the container body (11) toward the bottom surface (15) of the resin container;
A grounding part (22) formed at the lower end of the curved wall part (21) and grounded when the resin container is self-supporting;
Conical recess that the grounding unit is formed inwardly from (22) to invagination while inclined toward the inside of the resin vessel of the ground portion (22) and (23),
Sokodan unit that depressed the recess the recess is formed in the center of the (23) (23) frustoconical further inner side of the resin vessel than (24),
An edge of the bottom step portion (24) via the curved wall portion (21) , the grounding portion (22) , and the recessed portion (23) radially around the bottom step portion (24) ( Comprising a bottom groove (25) reaching 24a) ,
With a groove depth of the bottom groove (25) is gradually shallower in succession the over the edge of the Sokodan portion from the ground portion (22) in recesses (23) (24) (24a) ,
In the connecting portion between the recessed portion (23) and the bottom step portion (24), an end edge portion (24a) of the bottom step portion (24) extends from the central portion (24b) of the bottom step portion (24). It bulges in a curved shape toward the outside of the resin container over the recess (23),
The diameter (D1) of the recess (23) is 0.59 to 0.67 times the maximum diameter (D) of the container body (11) ,
The central diameter (D2) of the bottom step (24) is 0.14 to 0.22 times the maximum diameter (D) of the container body (11) ,
The edge diameter (D3) of the bottom step (24) is 0.17 to 0.26 times the maximum diameter (D) of the container body (11) ,
The depth (H1 ) from the grounding portion (22) to the edge (24a) of the bottom step portion (24 ) is 0.04 to 0 with respect to the maximum diameter (D) of the container body (11). .10 times,
The depth (H2 ) from the grounding portion (22) to the central portion (24b) of the bottom step portion (24) is 0.07 to 0.00 with respect to the maximum diameter (D) of the container body portion (11) . An impact-resistant structure at the bottom of a plastic packaging container characterized by satisfying 15 times.
前記底溝部(25)が6ないし10本形成されている請求項1に記載の樹脂製包装容器底部の耐衝撃構造。 The impact resistance structure of the bottom part of the resin packaging container according to claim 1, wherein 6 to 10 bottom groove parts (25) are formed. 前記底段部(24)の中央部(24b)の直径が10ないし15mmである請求項1または2に記載の樹脂製包装容器底部の耐衝撃構造。 The impact resistance structure of the bottom part of the resin packaging container according to claim 1 or 2 , wherein a diameter of a central part (24b) of the bottom step part (24) is 10 to 15 mm. 前記樹脂製容器が300〜900mLの内容量用の容器である請求項1ないしのいずれか1項に記載の樹脂製包装容器底部の耐衝撃構造。 The impact-resistant structure at the bottom of the resin packaging container according to any one of claims 1 to 3 , wherein the resin container is a container for an internal volume of 300 to 900 mL.
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