CN211996512U - Drinking water barrel with hexagonal prism structure - Google Patents

Abstract

The utility model discloses a drinking water barrel with a hexagonal prism structure, which comprises a barrel body, wherein the barrel body divides the side wall of the barrel body into a plurality of barrel body side walls positioned on different space surfaces along the circumferential direction of the axis of the barrel body; the barrel body is provided with a plurality of folds which are sequentially arranged along the axial direction of the barrel body on the side wall of each barrel body, each fold comprises a wave crest and fold side walls which are divided at two sides of the wave crest, and the connecting part of the fold side walls between two adjacent folds on the same barrel body side wall is formed into a wave trough; wave crests between two adjacent barrel side walls are arranged along the barrel in an axial staggered manner, and wave troughs between two adjacent barrel side walls are arranged along the barrel in an axial staggered manner. The bottle body has higher compressibility, and the phenomenon of local breakage of the bottle body is not easy to occur in the folding process of the bottle body.

Description

Drinking water barrel with hexagonal prism structure

Technical Field

The utility model relates to a liquid container technical field especially relates to hexagonal prism structure drinking water bucket.

Background

With the improvement of the quality of life, the large bottle drinking water barrel has the performances of being convenient to fold and recycle, and the like, and is gradually recognized by various industries. Large bottle drinking water containers are increasingly being designed with the body of the container in a compressible configuration.

For example, patent document No. 200908112758.1 discloses a bottle for water dispenser, which has a compressible body and solves the main technical problem of replacing drinking water in a barrel by compressing the body, so as to prevent air from entering the inside of the body of the water dispenser, thereby preventing the water dispenser from being polluted by air during use. Simultaneously, it has had concurrently the advantage that the body is also convenient for retrieve after being compressed.

However, the existing mineral water barrel is easy to deform unexpectedly (namely, the deformation amount is large) in the folding process, so that the compressibility of the bottle body (defined as the compressibility is the maximum compression degree) is reduced, or the compressibility of the bottle body is reduced due to the partial breakage of the bottle body; thereby leading to that a large amount of mineral water is trapped in the mineral water barrel and can not be taken out for drinking.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to provide a drinking water barrel with a hexagonal prism structure, the compressibility of the body is higher, and the phenomenon that the body is locally broken is not easy to occur in the folding process of the body; thereby improving the utilization rate of the mineral water in the bucket.

The purpose of the utility model is realized by adopting the following technical scheme:

the drinking water barrel with the hexagonal prism structure comprises a barrel body, wherein the barrel body is of the hexagonal prism structure; the side wall of the barrel body is divided into a plurality of barrel body side walls on different space surfaces by the barrel body along the circumferential direction of the axis of the barrel body; the barrel body is provided with a plurality of folds which are sequentially arranged along the axial direction of the barrel body on the side wall of each barrel body, each fold comprises a wave crest and fold side walls which are divided at two sides of the wave crest, and a wave trough is formed at the joint of the fold side walls between two adjacent folds of the same barrel body side wall;

by taking one barrel side wall of the barrel as a reference wall A, and the other two barrel side walls adjacent to the reference wall A are respectively an adjacent wall B and an adjacent wall C, folds on the barrel side walls are arranged as follows: the wave crests of the folds on the reference wall A and the wave crests of the folds on the adjacent walls B and C are sequentially arranged in a staggered manner along the axial direction of the barrel body, the wave troughs of the folds on the reference wall A and the wave troughs of the folds on the adjacent walls B and C are sequentially arranged in a staggered manner along the axial direction of the barrel body, so that the wave crests of the folds forming the reference wall A correspond to the wave troughs of the adjacent walls B and C, and the wave troughs of the folds forming the reference wall A correspond to the wave crests of the adjacent walls B and C;

the wave crests of the folds on the adjacent walls B and C corresponding to the same wave trough on the reference wall A are on the same horizontal plane, and the wave troughs on the adjacent walls B and C corresponding to the same wave crest on the reference wall A are also on the same horizontal plane;

the wave crests of the folds on the reference wall A are close to one end of the adjacent wall B and are respectively connected with one ends of the wave crests of the two folds staggered with the adjacent wall B; the wave crests of the folds on the reference wall A are close to one end of the adjacent wall C and are respectively connected with one ends of the wave crests of the two folds staggered with the adjacent wall C.

Further, the fold side wall between two adjacent folds of the same barrel side wall of the barrel is in a V-shaped, U-shaped, trapezoidal or rectangular structure.

Further, the fold lateral wall between two adjacent folds of the same ladle body lateral wall of ladle body is V-arrangement structure, just the fold lateral wall on both sides of fold also is V-arrangement structure, so that two adjacent folds of the same wall of ladle body are adjacent each other.

Furthermore, the folds are arranged from one end of the barrel body to the other end of the barrel body along the axial direction of the barrel body, so that all barrel body side walls of the barrel body can be completely folded.

Further, the diameter of the circumscribed circle of the barrel body ranges from 259mm to 270mm, the diameter of the inscribed circle of the barrel body ranges from 225mm to 240mm, the height of each corrugated section formed by folds on the same side wall of the barrel body ranges from 150mm to 180mm, and the diameter of the top of the neck of the drinking water barrel with the hexagonal prism structure ranges from 50mm to 60 mm; the drinking water barrel with the hexagonal prism structure further comprises a shoulder, a barrel body of the drinking water barrel with the hexagonal prism structure, the shoulder of the drinking water barrel with the hexagonal prism structure and the neck of the drinking water barrel with the hexagonal prism structure are sequentially connected, the shoulder and the barrel body are transited through an arc chamfer, and the radius range of the arc chamfer is 8-18 mm.

Further, the diameter of the circumferential outer surface wall of the neck portion gradually decreases along the direction in which the barrel body points to the neck portion, and the neck portion is provided with external threads at the circumferential outer surface wall of the neck portion, and the external threads gradually extend from the direction in which the neck portion points to the barrel body and gradually increase along the radial direction of the neck portion.

Further, the drinking water barrel with the hexagonal prism structure is of an integrally formed structure, and is made of one of PET, PET-G, HDPE, PP, PEN, PEF and PPT.

Compared with the prior art, the beneficial effects of the utility model reside in that:

1. in the hexagonal prism structure drinking water bucket of this application, because the lateral wall of ladle body along the circumference of self axis separates into a plurality of ladle body lateral walls that are located different space faces, based on this preceding condition, therefore can set to following structure: wave crests between two adjacent barrel side walls are arranged in a staggered mode along the axial direction of the barrels, and wave troughs between two adjacent barrel side walls are arranged in a staggered mode along the axial direction of the barrels. Therefore, when the barrel body is folded, the mutual extrusion degree between the wave crests of the adjacent barrel body side walls is smaller, and even the mutual extrusion is avoided; the mutual extrusion degree between the wave troughs of the adjacent barrel side walls is small, even the mutual extrusion is avoided; the mutual extrusion degree between adjacent barrel side walls is greatly reduced, so that the change rate of the inscribed circumference and the circumference of the circumscribed circle of the barrel is lower, the barrel of the drinking water barrel with the hexagonal prism structure can be linearly compressed in the actual use process, namely, the deformation amount is less, the compressible cruising ability of the barrel is sufficient, and finally, all folds of the barrel are completely compressed, so that the problem of reduction of the barrel compressibility caused by deformation change in the barrel compression process is solved, and the phenomenon of local fracture caused by excessive deformation of the barrel is avoided.

2. Due to its high compressibility, almost complete compression can be achieved to be able to solve the problem of a small amount of mineral water remaining in the tub last. Moreover, the drinking water barrel with the hexagonal prism structure can also prevent the phenomenon that the barrel body is deformed to cause grooves and then part of water is intercepted. And, because this hexagonal prism structure drinking water cask's ladle body compression process can not cause too big stress concentration, therefore can avoid the ladle body to break effectively, and the length of time is longer for barreled mineral water is generally used, prevents to take place the phenomenon of the damaged gas leakage of barreled mineral water cask (avoid gas to get into inside the ladle body promptly). It is also necessary to supplement that, because of the higher compressibility, the water volume remained at last is less, and the water body is replaced by the reduced volume, so that the faster water outlet speed can be still maintained; in fact, the whole water outlet process of the barreled mineral water barrel rarely or probably does not leak a little air into the barrel body, so that the water body can be more effectively prevented from being polluted by the air.

3. The degree of mutual extrusion of the corrugated side wall of the reference wall A, the corrugated side wall of the reference wall B and the corrugated side wall of the reference wall C is further and greatly reduced, so that the change rate of the circumference of the inscribed circumference and the circumscribed circle of the barrel body is lower, the barrel body of the drinking water barrel with the hexagonal prism structure can be linearly compressed in the actual use process, namely, the deformation amount is less, the compressible endurance capacity of the barrel body is sufficient, and finally, all the corrugations of the barrel body are almost completely compressed, so that the problem of reduction of the compressibility of the barrel body caused by deformation change in the compression process of the barrel body is solved, and the phenomenon of local breakage caused by excessive deformation of the barrel body is avoided.

4. The wave crests of the folds on the adjacent walls B and C corresponding to the same wave trough on the reference wall A are on the same horizontal plane, and the wave troughs on the adjacent walls B and C corresponding to the same wave crest on the reference wall A are also on the same horizontal plane. So, therefore make the fold on the ladle body be the equipartition structure for adjacent wall B is more similar with adjacent wall C's folding condition, thereby further improves the compressibility of ladle body.

5. The wave crests of the folds on the reference wall A are close to one end of the adjacent wall B and are respectively connected with one ends of the wave crests of the two folds staggered with the adjacent wall B; the wave crests of the folds on the reference wall A are close to one end of the adjacent wall C and are respectively connected with one ends of the wave crests of the two folds staggered with the adjacent wall C. Therefore, a large-area surface wall (a stress concentration surface formed by accumulation of large-area surface walls, namely stress concentration points) which hinders compression of the barrel does not exist at the junction of the adjacent barrel side walls, and the compressibility of the barrel is further improved.

6. The difficulty of the bottle blowing process and the compressibility of the barrel body are comprehensively considered, and the drinking water barrel with the hexagonal prism structure is more beneficial to the compression of the barrel body. Meanwhile, the circumferences of the outer contours of the cross sections of the horizontal planes of different wave crests and wave troughs on the barrel body of the drinking water barrel with the hexagonal prism structure are equal, so that the deformation amount generated when the barrel body is compressed is reduced, and the compressibility of the barrel body is further improved.

Drawings

Fig. 1 is a schematic structural view of a drinking water barrel with a hexagonal prism structure according to the present invention;

FIG. 2 is a front view of the drinking water barrel of FIG. 1 having a hexagonal prism configuration;

FIG. 3 is a schematic view of the structure of FIG. 2 at D;

FIG. 4 is a first state effect diagram of a finite element analysis experiment of the drinking water barrel with the hexagonal prism structure shown in FIG. 1;

FIG. 5 is a diagram of a second state effect of a finite element analysis experiment of the drinking water barrel with the hexagonal prism structure shown in FIG. 1;

FIG. 6 is a third state effect diagram of a finite element analysis experiment of the drinking water barrel with the hexagonal prism structure shown in FIG. 1;

FIG. 7 is a table of finite element analysis experimental data for the hexagonal-prism structured drinking water barrel of FIG. 1;

FIG. 8 is a schematic diagram showing an analysis of the water outlet process of the drinking water barrel with the hexagonal prism structure shown in FIG. 1;

FIG. 9 is a first horizontal plane cross-sectional view of the hexagonal-prism structured drinking water barrel of FIG. 1;

fig. 10 is a second horizontal plane cross-sectional view of the drinking water barrel of the hexagonal prism structure shown in fig. 1.

In the figure: 1. a barrel body; 11. folding; 111. wave crest; 112. a corrugated sidewall; 113. a trough of a wave; 12. a lamination area; 2. a shoulder portion; 21. reinforcing ribs; 3. a neck portion; 31. an external thread; 4. multiplying the folded layer; 5. a normal folded layer; 6. a first amount of water; 7. a first volume; 8. a second volume; 91. a first perimeter; 91a, a first side; 91b, a second side; 91c, a third side; 91d, fourth side; 91e, fifth side; 91f, sixth side; 92. a second perimeter; 92a, a seventh side; 92b, an eighth side; 92c, a ninth edge; 92d, tenth side; 92e, the tenth side; 92f, twelfth side.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the detailed description, and it should be noted that the embodiments or technical features described below can be arbitrarily combined to form a new embodiment without conflict.

Fig. 1 to 3 show a liquid container (a drinking water bucket with a hexagonal prism structure) according to a preferred embodiment of the present invention, which is an integrally formed structure. As shown in fig. 2, when the liquid container is placed horizontally, the liquid container includes, from bottom to top, a barrel bottom, a barrel body 1, a shoulder 2, and a neck 3, which are connected in sequence. The side wall of the barrel body 1 is divided into a plurality of barrel body side walls positioned on different space surfaces by the barrel body 1 along the circumferential direction of the axis of the barrel body 1; the barrel body 1 is provided with a plurality of folds 11 sequentially arranged along the axial direction of the barrel body 1 on each barrel body side wall of the barrel body 1, each fold 11 comprises a wave crest 111 and fold side walls 112 respectively arranged at two sides of the wave crest 111, and a wave trough 113 is formed at the joint of the fold side walls 112 between two adjacent folds 11 on the same barrel body side wall; the wave crests 111 between two adjacent barrel side walls are arranged along the axial direction of the barrel 1 in a staggered manner, and the wave troughs 113 between two adjacent barrel side walls are arranged along the axial direction of the barrel 1 in a staggered manner.

In order to interpret and analyze the effect of the present liquid container in more detail, it is necessary to incorporate patent documents of the prior art. Taking a bottle for a drinking machine disclosed in patent application No. CN200980112758.1 as an example (for easy understanding, please refer to fig. 3 thereof), in an original state, the minimum inner diameter and the maximum outer diameter of the bellows portion are fixed values, and in a process of compressing the bellows portion, the minimum inner diameter of the bellows portion will be continuously reduced, while the maximum outer diameter of the bellows portion will be continuously increased, so that the bottle body portion is gradually compressed linearly in a non-ideal compression process of the bottle body portion; and further, the bottle body is seriously deformed unexpectedly (i.e. seriously deformed), so that the compressibility of the bottle body is suddenly reduced, that is, the last water quantity of the bottle for the water dispenser cannot be taken out (a large amount of grooves on the bottle body remain water) in the actual use process, and the water source is wasted (that is, fig. 5 is an ideal situation). And, with the gradual enhancement of unexpected deformation, when the bottle body loses the performance of easy compression, the water outlet speed is reduced, even the water needs to be replaced by air, and finally, the problem that the water body is polluted by the air still exists.

In the liquid container of the present application, since the side wall of the barrel 1 is divided into a plurality of barrel side walls located on different spatial planes by the barrel 1 along the circumferential direction of the axis of the barrel 1, based on the aforementioned condition, the following structure can be set: the wave crests 111 between two adjacent barrel side walls are arranged along the axial direction of the barrel 1 in a staggered manner, and the wave troughs 113 between two adjacent barrel side walls are arranged along the axial direction of the barrel 1 in a staggered manner. Thus, when the barrel body 1 is folded, the mutual extrusion degree between the wave crests 111 of the adjacent barrel body side walls is small, and even the mutual extrusion is avoided; the mutually extruded degree between the wave troughs 113 of the adjacent barrel side walls is small, even the mutually extruded degree is not generated; the mutual extrusion degree between adjacent barrel lateral walls is greatly reduced, so that the change rate of the circumference of an inscribed circle and the circumference of an circumscribed circle of the barrel 1 is lower, the liquid container can be used in the actual use process, the barrel 1 is kept in linear compression, the deformation amount is less, the compressible cruising ability of the barrel 1 is sufficient, and finally, each fold 11 of the barrel 1 is completely compressed, so that the problem that the compressibility of the barrel 1 is reduced due to the deformation change in the compression process of the barrel 1 is solved, and the phenomenon of local fracture caused by the excessive deformation of the barrel 1 is avoided.

Obviously, the liquid container is suitable for barreled coca-cola, soy sauce bottle, peanut oil bottle, bottled coca-cola, etc. It can be understood that the liquid container is applied to different liquid containers, the problem that waste products occupy large space (for example, a pop can does not need to step on one foot manually) can be solved, and the phenomenon of local breakage of the barrel 1 can not occur in the process of extruding the barrel 1, so that unnecessary cleaning work is avoided. In addition, because the deformation amount of the barrel body 1 in the compression process is smaller, the barrel body 1 can be greatly compressed (namely, the compression degree of the barrel body 1 is higher), and the barrel is beneficial to carrying waste products by owners.

In addition, the liquid container is also very suitable for drinking water bottles, particularly barreled drinking water buckets, and can be almost completely compressed due to high compressibility of the liquid container, so that the problem that a small amount of drinking water is finally remained in the barrel body 1 can be solved. Moreover, the liquid container can also prevent the phenomenon that the groove and then part of water body are intercepted because the barrel body 1 is deformed. In addition, the compression process of the barrel body 1 of the liquid container can not cause excessive stress concentration, so that the barrel body 1 can be effectively prevented from being broken, the barreled drinking water is generally used for a long time, and the phenomenon of breakage and air leakage of the barreled drinking water barrel (namely, the phenomenon that air enters the barrel body 1) is prevented. It is also necessary to supplement that, because of the higher compressibility, the water volume remained at last is less, and the water body is replaced by the reduced volume, so that the faster water outlet speed can be still maintained; in fact, during the whole water outlet process of the barreled drinking water barrel, little or no air leaks into the barrel body 1, so that the water body can be more effectively prevented from being polluted by the air.

As a further preferred embodiment, taking one of the barrel side walls of the barrel 1 as the reference wall a and the other two barrel side walls adjacent to the reference wall a as the adjacent wall B and the adjacent wall C, respectively, the folds 11 on each barrel side wall are arranged as follows: the wave crests 111 of the pleats 11 on the reference wall A and the wave crests 111 of the pleats 11 on the adjacent walls B and C are sequentially staggered along the axial direction of the barrel 1, the wave troughs 113 of the pleats 11 on the reference wall A and the wave troughs 113 of the pleats 11 on the adjacent walls B and C are sequentially staggered along the axial direction of the barrel 1, so that the wave crests 111 of the pleats 11 forming the reference wall A correspond to the wave troughs 113 of the adjacent walls B and C, and the wave troughs 113 of the pleats 11 forming the reference wall A correspond to the wave crests 111 of the adjacent walls B and C. The sequential staggered mode is more beneficial to sequential folding layer by layer; if the horizontal plane at the wave crest 111 and the wave trough 113 of any layer of the barrel body 1 is cut into a horizontal cross section, the outer contour perimeter of the cross section is a fixed value; that is, the levels of the various layers of the barrel 1 are of equal circumference (e.g., FIGS. 9 and 10 are cross-sectional views of the barrel 1 taken at different peaks 111 and valleys 113 of the same barrel sidewall, with a first circumference 91 equal to the total length of the first, second, third, fourth, fifth and sixth sides 91a, 91b, 91c, 91d, 91e and 91f in a first horizontal plane, as shown in FIG. 9, and a second circumference 92 equal to the total length of the seventh, eighth, ninth, tenth and twelfth sides 92a, 92d, 92e and 92f in a second horizontal plane, as shown in FIG. 10; thus the first circumference 91 is equal to the second circumference 92); therefore, the folding process of the barrel body 1 is more regular and closer to linear folding; i.e. to further reduce the amount of malformation that occurs during folding of the bowl 1. In other words, when the barrel 1 is folded, the degree of mutual pressing between the folded side wall 112 of the reference wall a and the folded side walls 112 of the reference walls B and C is further and greatly reduced, so that the change rate of the circumference of the inscribed circle and the circumference of the circumscribed circle of the barrel 1 is low, and therefore, in the actual use process of the liquid container, the barrel 1 of the liquid container is kept in linear compression, that is, the deformation amount is less, the compressible endurance capacity of the barrel 1 is sufficient, and finally, each fold 11 of the barrel 1 is almost completely compressed, so that the problem of reduced compressibility of the barrel 1 caused by abnormal change in the compression process of the barrel 1 is solved, and the phenomenon of local rupture caused by excessive deformation of the barrel 1 is avoided.

In a further preferred embodiment, the adjacent walls B and the adjacent walls C corresponding to the same valleys 113 on the reference wall a have peaks 111 of the corrugations 11 on the same horizontal plane, and the adjacent walls B and the adjacent walls C corresponding to the same peaks 111 on the reference wall a have valleys 113 on the same horizontal plane. Thus, the folds 11 on the barrel 1 are uniformly distributed, so that the folding conditions of the adjacent walls B and C are more similar, and the compressibility of the barrel 1 is further improved.

As a further preferred embodiment, the peaks 111 of the corrugations 11 on the reference wall a are close to one end of the adjacent wall B, and are respectively connected with one ends of the peaks 111 of two corrugations 11 on the adjacent wall B, which are staggered with the adjacent wall B; the wave crest 111 of the corrugation 11 on the reference wall a is close to one end of the adjacent wall C, and is respectively connected with one end of the wave crest 111 of two corrugation 11 staggered with the adjacent wall C. Thus, a large-area surface wall (i.e., a stress concentration surface formed by accumulation of stress concentration points) which hinders compression of the barrel 1 does not exist at the boundary of the adjacent barrel side walls, that is, the compressibility of the barrel 1 is further improved. In other words, the peaks 111 and valleys 113 of the corrugations 11 are made to extend from one horizontal edge of the side wall of the tub body to the other opposite horizontal edge of the side wall of the tub body in the horizontal direction, so as to avoid the side wall of the tub body 1 from having high strength portions that hinder the compression of the tub body 1, i.e., to further improve the compressibility of the tub body 1.

The barrel 1 may have a quadrangular prism structure or an octagonal prism structure, or may have a polygonal prism structure or a polygonal pyramid structure with any even number of sides (here, it should be noted that, after the barrel 1 is horizontally cut, the outer contour of the cross section of the barrel 1 may be a polygonal prism structure). Alternatively, a polygonal structure formed by a straight edge and an arc edge may be used, that is, at least one edge of the polygonal structure is replaced by the arc edge (when converted into a surface structure, the surface is an arc surface, that is, the arc surface is provided with the folds 11).

In a finite element analysis experiment (the barrel body 1 is in a hexagonal prism structure), when the barreled drinking water barrel continuously discharges water, the change trend of the barrel body 1 changes in sequence as shown in fig. 4-6, and a corresponding experimental data graph is shown in fig. 7. Therefore, in the present embodiment, as a preferred embodiment: the barrel body 1 is of a hexagonal prism structure. Firstly, the polygonal prism structure is more advantageous for compression of the bowl 1 than a structure having curved sides. More importantly, it should be noted that in the bottle blowing process of the barreled drinking water barrel, the distances between the axis of the cylindrical barrel (the cylindrical barrel is equivalent to a polygonal column with innumerable sides) and each point on the curved surface are equal, that is, the maximum distance difference is 0, so that the bottle blowing difficulty is low. The distance between the edge between the adjacent side walls of the polygonal column and the axis of the polygonal column is defined as a first distance, the distance between the side walls of the polygonal column and the axis of the polygonal column is defined as a second distance, and the absolute value of the difference between the first distance and the second distance is gradually increased along with the decreasing of the number of the edges of the polygonal column, so that the difficulty of bottle blowing of the barreled drinking water barrel is high, and the manufacturing of the barrel 1 of the barreled drinking water (such as barreled mineral water) is not facilitated. However, since the barrel 1 in the present liquid container adopts the polygonal prism structure, and the wrinkles 11 on the different side walls of the barrel 1 can be provided in a staggered arrangement in the axial direction of the barrel 1. With this arrangement, the greater the area of the end portion of each two pleats 11 stacked (defined as the stacking area 12), the more difficult the barrel 1 is to compress. For easy understanding, referring to fig. 3, after the folded sidewall 112 is folded, the normal folded layer 5 and the doubled folded layer 4 appear at different positions, and obviously, the thickness of the doubled folded layer 4 is twice that of the normal folded layer 5; therefore, if the lamination area 12 at the multiply folded layer 4 is larger, the folding of the tub 1 is more disadvantageous. On the other hand, in the case where the circumscribed circles are equal, the larger the number of sides of the prism (the more the single variable is controlled), the larger the lamination area 12, the more difficult the barrel 1 is to be compressed. Thus, based on the preconditions: the wave crest 111 of the fold 11 on the reference wall A is close to one end of the adjacent wall B and is respectively connected with one end of the wave crest 111 of two folds 11 staggered with the adjacent wall B; the wave crest 111 of the corrugation 11 on the reference wall a is close to one end of the adjacent wall C, and is respectively connected with one end of the wave crest 111 of two corrugation 11 staggered with the adjacent wall C. And considering that the difficulty of the bottle blowing process of the hexagonal prism structure is smaller than that of the bottle blowing process of the quadrangular prism structure, and the compressibility of the hexagonal prism structure is larger than that of the octagonal prism structure, the obtained hexagonal prism barrel body 1 structure has obvious advantages. In addition, another principle needs to be added for explanation here. Referring to fig. 9 and 10, fig. 9 and 10 are cross-sections of the tub 1 at different horizontal planes, respectively; that is, under the precondition of the polygonal column structure, the peak 111 of the corrugation 11 on the reference wall a is close to one end of the adjacent wall B, and is respectively connected with one end of the peak 111 of two corrugations 11 staggered with the adjacent wall B; the wave crest 111 of the fold 11 on the reference wall A is close to one end of the adjacent wall C, and is respectively connected with one end of the wave crest 111 of two folds 11 staggered with the adjacent wall C; the first and second perimeters 91 and 92 may be made equal (the detailed structure is such that: fig. 9 and 10 are cross-sectional views of the bowl 1 taken at different peaks 111 and valleys 113 of the same bowl side wall, in a first horizontal plane, the first perimeter 91 equals the total length of the first, second, third, fourth, fifth and sixth sides 91a, 91b, 91c, 91d, 91e and 91f, as shown in fig. 9; in a second horizontal plane, the second perimeter 92 equals the total length of the seventh, eighth, ninth, tenth and twelfth sides 92a, 92c, 92d, 92e and 92f, as shown in fig. 10; thus the first perimeter 91 equals the second perimeter 92). Therefore, the folding process of the liquid container (or the barreled drinking water barrel) with the special hexagonal prism structure is smoother, and the compressibility of the liquid container is higher.

More importantly, finite element analysis experiments performed on the tub 1 based on the hexagonal prism structure resulted in an experimental table as shown in fig. 7. Wherein, the vertical axis is the volume (or volume), and the horizontal axis is the difference between the external atmospheric pressure and the air pressure in the barrel (i.e. the experimental data shows that the experimental data generates delicate negative pressure). It is mainly formulated according to the ideal gas state equation (PV = nRT). Wherein P is the gas pressure in Pa. V is the gas volume in m 3. n is the amount of gaseous material in mol, T is the system temperature in K. When the amount of water in the barrel body 1 is reduced to a first amount of water 6 (see fig. 8), the volume occupied by the air in the barrel is defined as a first volume 7 (the first volume 7 is defined as V1) (it should be added that any soft drinking water barrel leaves a factory, a part of space is reserved for containing a part of clean air, so that water can be conveniently pressed out, for example, the air pressure in the barrel body 1 is atmospheric pressure before the first amount of water 6). After the first quantity of water 6 is decreased, because the barrel 1 can not be folded nearly perfectly, the volume in the barrel 1 can not be reduced synchronously, so that the space occupied by the original gas in the barrel 1 is enlarged, namely, the gas pressure is reduced, the gas pressure is defined as the first gas pressure (at this time, the volume occupied by the original gas in the barrel 1 is the second volume 8, the second volume 8 is defined as V2, so that the gas pressure in the barrel is reduced to generate negative pressure), and therefore, the first gas pressure is smaller than the atmospheric pressure at the water outlet of the water dispenser. Therefore, in order to keep the water body flowing out continuously, because the water level difference is formed between the water level of the barrel body 1 and the outlet of the water dispenser, namely the gravity of the water can offset the negative pressure, namely G (water) = rho gh (wherein rho is the density of the water; G is the gravity unit; and h is the distance difference between the liquid level and the outlet of the water dispenser). Wherein S is the area of the water outlet of the water dispenser, and Delta P is the air pressure difference; thus: g = ρ gh =Δp = (nRT/V1-nRT/V2) × S. That is, when a negative pressure is generated in the bowl 1, the finite element analysis experimental data shown in fig. 7 is obtained mainly according to the ideal gas state equation. In the actual experiment process, the total volume of the barreled drinking water barrel is 11L, the gas volume is 1L, and the occupied water volume is 10L. According to the finite element analysis experimental data shown in fig. 7, the space occupied by the final gas is about 1L, i.e., the water in the tub can be completely taken out without leaking gas into the inside of the tub body 1. For more convenience of understanding, it should be additionally added here that, when the liquid is easily applied to the barreled drinking water, because the compressibility of the barrel 1 is high, the liquid reaches the first air pressure after the barrel 1 is folded highly (that is, the negative pressure is generated when the barrel 1 is folded highly, that is, most of the drinking water flows out), so that the remaining small amount of water can be completely taken out under the condition that the self weight overcomes the negative pressure, so that very little drinking water is trapped in the barrel 1, and the utilization rate of the drinking water is improved.

Further, the pleat side walls 112 between two adjacent pleats 11 of the same barrel side wall of the barrel 1 are in a V-shaped, U-shaped, trapezoidal or rectangular structure. The utility model discloses a fold lateral wall 112 is the V-arrangement preferably, sets up like this for each sideline of juncture between its two adjacent ladle body lateral walls of ladle body 1 is the regular arrangement of cockscomb structure equidistant, and the cockscomb structure does benefit to the folding of ladle body 1 very much, thereby has further improved the compressibility of ladle body 1.

Further, the wrinkle side wall 112 between two adjacent wrinkles 11 of the same barrel side wall of the barrel 1 is in a V-shaped structure, and the wrinkle side walls 112 on two sides of the wrinkles 11 are also in a V-shaped structure, so that two adjacent wrinkles 11 of the same wall surface of the barrel 1 are adjacent to each other. With this arrangement, the large-area surface wall (i.e., the stress concentration surface formed by the accumulation of the stress concentration points) that hinders the compression of the tub 1 does not exist in the tub side wall, i.e., the compressibility of the tub 1 is further improved.

Further, the plurality of folds 11 are arranged from one end of the barrel 1 to the other end of the barrel 1 along the axial direction of the barrel 1, so that each barrel side wall of the barrel 1 can be completely folded. In this way, it is further possible to have the absence of large area walls of the side walls of the bowl 1 that impede compression of the bowl 1. Meanwhile, the compressibility of the bucket body 1 reaches a limit value, so that a part of water body trapped inside the bucket body 1 is further prevented from being taken out.

Further, the barrel body 1 is a hexagonal prism structure, the diameter of the circumscribed circle range of the barrel body 1 is 260mm to 270mm (wherein, the diameter of the circumscribed circle of the barrel body 1 may be 261mm, 261.5mm, 262mm, 262.5mm, 263mm, 263.5mm, 264mm, 264.5mm, 265 mm, 265.5 mm, 266 mm, 266.5 mm), the diameter of the inscribed circle of the barrel body 1 may be 225mm to 240mm (wherein, the diameter of the inscribed circle of the barrel body 1 may be 226 mm, 227 mm, 228 mm, 229 mm, 230 mm, 231 mm, 232 mm, 233 mm, 234 mm, 235 mm, 236 mm, 237 mm, 238 mm, 239 mm), and the height range of each corrugation segment formed by the folds 11 on the same barrel body side wall is 150mm to 180mm (wherein, the height of each corrugation segment may be 155 mm, 160 mm, 239 mm, or both, 165 mm, 170 mm, 175 mm), the top caliber of the neck 3 of the liquid container is in the range of 50mm-60mm (wherein, the top caliber of the neck 3 of the liquid container can be also specifically 51 mm, 52 mm, 53 mm, 54 mm, 55mm, 56 mm, 57 mm, 58 mm, 59 mm). The shoulder 2 with adopt the circular arc chamfer to pass through between the ladle body 1, the radius scope of circular arc chamfer is 8-18mm (wherein, the radius of circular arc chamfer can also specifically be 9mm, 10 mm, 11 mm, 12 mm, 13 mm, 14 mm, 15 mm, 16 mm, 17 mm). It should be additionally added here that the drinking water container has a ring stretch ratio of 3.5 to 5.0. Wherein the equation for the ring stretch ratio is: the finished diameter is divided by the diameter of the preform (e.g., finished diameter 261.5mm, preform diameter 55mm, ring stretch ratio 4.75).

In addition, the shoulder part 2 is provided with a plurality of reinforcing ribs 21, and the reinforcing ribs 21 can be inwards sunken from the outer wall of the shoulder part 2 or outwards protruded from the outer wall of the shoulder part 2. A plurality of ribs 21 are arranged in a circumferential array around the axis of the shoulder 2. More specifically, a plurality of reinforcing ribs 21 are arranged in a uniform circumferential array around the axis of the shoulder portion 2.

Further, the diameter of the circumferential outer surface wall of the neck 3 is gradually reduced along the direction that the barrel body 1 points to the neck 3, so that the liquid container is favorably butted with the water dispenser, and the liquid container is conveniently taken out of the water dispenser. More specifically, the neck 3 is provided at its circumferential outer surface wall with an external thread 31, and the external thread 31 gradually extends from the neck 3 toward the bowl 1 and gradually increases in a radial direction of the neck 3. The sealing cover which is connected with the sealing barrel body 1 through the external thread 31 can reliably seal the sealing cover to the barrel body 1, and secondary pollution of water (such as bacterial colonies and floating and sinking gas outside the barrel) caused by gas leaking into the barrel body 1 is prevented; in addition, the threaded connection mode has a limit in-place hand feeling, and the assembly efficiency is improved. Wherein, the external thread 31 is provided with 3 and arranged at intervals. Each of the 3 external threads 31 is gradually extended from the neck 3 toward the tub 1, and gradually increased in a radial direction of the neck 3, thereby forming a triple thread structure.

Further, the liquid container is made of one or a mixture of more of PET, PET-G, HDPE, PP, PEN, PEF and PPT.

Wherein:

PET (Polyethylene terephthalate; English name: PET for short).

PET-G (modified polyethylene terephthalate).

HDPE (high density polyethylene material).

PP (polypropylene).

PEN (polyethylene naphthalate).

PEF (polyethylene furandicarboxylate).

PPT (polytrimethylene naphthalate).

In order to make the present liquid container more suitable for use with potable water. Specifically, when barreled drinking water is held on the water dispenser for use, the gradual reduction of the water amount in the barrel inevitably leads to the occurrence of slight unexpected compression deformation of the barrel body 1, thereby leading to the displacement of the gravity center of the water body in the barrel body 1, and at the moment, the liquid container has the hidden trouble of falling from the water dispenser. Therefore, further, the barrel 1 has a polygonal pyramid structure, and the circumscribed circle diameter of the barrel 1 gradually increases along the direction of the barrel 1 toward the neck 3. The gravity center of the drinking water barrel can be controlled to be right above the water dispenser as far as possible, so that the liquid container is effectively prevented from falling from the water dispenser.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are all within the protection scope of the present invention.

Claims (7)

1. Hexagonal prism structure drinking water bucket, including ladle body (1), its characterized in that: the barrel body (1) is of a hexagonal prism structure; the side wall of the barrel body (1) is divided into a plurality of barrel body side walls positioned on different space surfaces by the barrel body (1) along the circumferential direction of the axis of the barrel body (1); the barrel body (1) is provided with a plurality of folds (11) which are sequentially arranged along the axial direction of the barrel body (1) on each barrel body side wall, each fold (11) comprises a wave crest (111) and fold side walls (112) which are respectively arranged at two sides of the wave crest (111), and a wave trough (113) is formed at the joint of the fold side walls (112) between two adjacent folds (11) on the same barrel body side wall;

one barrel side wall of the barrel (1) is taken as a reference wall A, and the other two barrel side walls adjacent to the reference wall A are respectively an adjacent wall B and an adjacent wall C, so that folds (11) on the barrel side walls are arranged as follows: the wave crests (111) of the folds (11) on the reference wall A and the wave crests (111) of the folds (11) on the adjacent walls B and C are sequentially staggered in the axial direction of the barrel body (1), the wave troughs (113) of the folds (11) on the reference wall A and the wave troughs (113) of the folds (11) on the adjacent walls B and C are sequentially staggered in the axial direction of the barrel body (1) to form that the wave crests (111) of the folds (11) on the reference wall A correspond to the wave troughs (113) of the adjacent walls B and C, and the wave troughs (113) of the folds (11) on the reference wall A correspond to the wave crests (111) of the adjacent walls B and C;

the adjacent walls B and the wave crests (111) of the folds (11) on the adjacent walls C, which correspond to the same wave trough (113) on the reference wall A, are on the same horizontal plane, and the adjacent walls B and the wave troughs (113) on the adjacent walls C, which correspond to the same wave crest (111) on the reference wall A, are also on the same horizontal plane;

the wave crest (111) of the corrugation (11) on the reference wall A is close to one end of the adjacent wall B, and is respectively connected with one end of the wave crest (111) of two corrugation (11) staggered with the adjacent wall B; the wave crest (111) of the corrugation (11) on the reference wall A is close to one end of the adjacent wall C, and is respectively connected with one end of the wave crest (111) of two corrugation (11) staggered with the adjacent wall C.

2. The hexagonal-prism-structured drinking water barrel as set forth in claim 1, wherein: the folded side wall (112) between two adjacent folds (11) of the same barrel side wall of the barrel (1) is of a V-shaped, U-shaped, trapezoidal or rectangular structure.

3. The hexagonal-prism-structured drinking water barrel as set forth in claim 1, wherein: the folded side wall (112) between two adjacent folds (11) of the same barrel side wall of the barrel body (1) is of a V-shaped structure, and the folded side walls (112) on two sides of the folds (11) are also of the V-shaped structure, so that the two adjacent folds (11) on the same wall surface of the barrel body (1) are adjacent to each other.

4. The hexagonal-prism-structured drinking water barrel as set forth in claim 1, wherein: the plurality of folds (11) are arranged from one end of the barrel body (1) to the other end of the barrel body (1) along the axial direction of the barrel body (1), so that each barrel body side wall of the barrel body (1) can be completely folded.

5. The hexagonal-prism-structured drinking water barrel as set forth in claim 1, wherein: the diameter of an external circle range of the barrel body (1) is 259-270 mm, the diameter of an internal circle of the barrel body (1) is 225-240 mm, the height range of each corrugated section formed by folds (11) on the same barrel body side wall is 150-180 mm, and the diameter range of the top of a neck (3) of the drinking water barrel with the hexagonal prism structure is 50-60 mm; the hexagonal prism structure drinking water bucket still includes shoulder (2), the ladle body (1) of hexagonal prism structure drinking water bucket, shoulder (2) of hexagonal prism structure drinking water bucket, neck (3) of hexagonal prism structure drinking water bucket connect gradually, shoulder (2) with adopt the circular arc chamfer to pass through between ladle body (1), the radius range of circular arc chamfer is 8-18 mm.

6. The hexagonal-prism-structured drinking water barrel of claim 5, wherein: the diameter of the circumference outside table wall of neck (3) is followed the direction of ladle body (1) directional neck (3) reduces gradually, just neck (3) are equipped with external screw thread (31) in the circumference outside table wall department of self, external screw thread (31) are followed the direction of neck (3) directional ladle body (1) extends gradually to along the radial crescent of neck (3).

7. The hexagonal-prism-structured drinking water barrel as set forth in claim 1, wherein: the drinking water barrel with the hexagonal prism structure is of an integrally formed structure and is made of one of PET, HDPE, PP, PEN, PEF and PPT.

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