NL7905297A - LONG-THROUGH BOTTLE BOTTLE, MADE FROM ARTIFICIAL RESIN. - Google Patents

Description

Jr YOSHINO KOGYOSHO CO., LTD., Tokyo, Japan

Oblong, thin-walled bottle; made of synthetic resin.

Summary.

An elongated, thin-walled bottle made of synthetic resin, and in particular a bottle made of polyethylene terephthalate resin, formed by biaxial stretching in a blow mold, which bottle is constructed in such a way that substantially half of the the height of the circumferential wall is formed by biaxial stretching, such that the thin wall in the circumferential direction is provided with an inwardly curved indentation and in that a bottom part of the circumferential groove thus pressed in is circumferentially provided with a projection curved in the opposite direction with a relatively small height.

The present invention relates to an elongated, thin-walled bottle made of synthetic resin in a blow mold and more particularly to an elongated, blow-molded biaxial stretch blow molded bottle of polyethylene terephthalate resin.

Today, a large number of elongated blown thin-walled bottles made of synthetic resin are used in particular as bottles for storing a liquid.

This stems from the insight that such bottles themselves are light, can be easily blow-molded, have a good appearance, have low production costs and the like. As a result of forming the bottle into a blow mold, which is called blow mold, the wall thickness of the circumferential wall of the bottle inevitably becomes thin.

In particular when the bottles are formed from polyethylene terephthalate resin as a synthetic resin, which material has good mechanical resistance, is resistant to acids and other chemicals, 790 52 97

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is mechanically durable and has several other properties, articles made therefrom must be sufficiently biaxially stretched in blow molding. For this reason, the wall thickness of the circumferential wall, which becomes the most biaxial in blow molding. stretched, relatively thin.

This creates the problem that the circumferential wall is a factor of insecurity in the resistance to internal pressure and in the mechanical strength in connection with the durability against pressure from above.

In particular, the external forces on the ora-stretch wall substantially tend to act concentrically on the middle portion at half the height of the circumferential wall. Thus, when an even external force is applied to the entire circumferential wall, the external force acts concentrically on a certain limited part and even if the circumferential wall has sufficient durability, it can lead to inconveniences such as deformation and even damage.

Therefore, heretofore, the wall thickness of the entire circumferential wall has been increased to such an extent that the circumferential wall can withstand the external forces acting thereon, so as to make up for the shortage of mechanical strength at said portion of the circumferential wall. . As a result, the amount of resin used to form one bottle increased significantly compared to the theoretical amount of resin needed for a bottle to serve as a container, which is extremely uneconomical.

As the thickness of the circumferential wall is increased, as indicated above, the pressure of the fluid (essentially compressed air) required for blow molding must also increase. Therefore, the pressure resistance of the compressed air of the system of compressed air supply ducts, the sealing force for the blow mold 30 as well as the capacity of the compressor must be increased.

Furthermore, especially when using polyethylene terephthalate resin, a preform molded article must be molded and cooled, after which the preform is uniformly heated to a temperature at which the preform can be biaxially stretched in a blow mold. When preheating the preform to a temperature where the preform can be biaxially blown 790 52 97

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3, however, the entire preform with the greater wall thickness must be reheated to a uniform, predetermined temperature, and this takes a long time, which reduces the production speed of the blow mold.

The increase in the wall thickness of the circumferential wall to compensate for its insufficient mechanical strength, as described above, gives rise to various inconveniences and drawbacks in view of the greater material consumption, the smaller capacity of the former and the lower production speed. Thus, there is a great need for means to overcome these drawbacks.

The object of the present invention is to overcome these drawbacks of the prior art. According to the invention, the middle part at half the height of a bottle on which external forces act from the outside concentrically on the circumferential wall of the bottle, is designed such that this middle part has a durable construction against these external forces, whereby the external forces- which act concentrically on the middle portion of the circumferential wall are spread to increase the mechanical strength of the circumferential wall.

Therefore, the general object of the present invention is to provide an elongated, thin-walled synthetic resin bottle which has a circumferential wall, which has a considerable mechanical durability without increasing the wall thickness.

Another object of the invention is to provide for easy handling of the bottle by placing the fingers in the circumferential depression, which depression is formed to increase the mechanical strength of the circumferential center portion without slip between the bottle and the user's fingers.

Another object of the present invention is to provide a bottle, which is given a different external appearance by forming a circumferential depression in the central portion of the circumferential wall.

The invention will be explained in more detail with reference to the drawing with an exemplary embodiment.

FIG. 1 is a front view of the bottle showing the appearance of the bottle in one embodiment of the bottle according to the invention; and 790 52 97 i ', 4 Fig. 2 is an enlarged longitudinal sectional view of a portion of the bottle surrounded by circle II in Fig. 1.

The present invention is directed to an elongated, thin-walled blow molded resin bottle and more particularly to an elongated biaxially stretched blow molded polyethylene terephthalate resin bottle. In a substantially centrally located part of the height of an entirely biaxially stretched thin circumferential wall 2 of an elongated blow molded bottle 1 is a narrowed part 3, which is compressed along a curved line over the entire circumference from that:'. center portion, which is formed in the form of a circumferential groove and a bottom portion of the constriction 3 is protruded in the opposite direction, protruding to form a circumferential projection 4.

When the bottle 1 is filled with liquid, the relatively strongly depressed constriction 3, which is formed substantially in the middle part of the height of the circumferential wall 2, serves to spread the internal pressure, which acts concentrically on the middle part of the circumferential wall 2, along both sloping side walls to the upper and lower part of the circumferential wall 2, whereby the internal pressure does not act concentrically on the middle part of the circumferential wall 2, but acts over a wide area of the circumferential wall 2.

For this reason, the internal pressure per unit area of the circumferential wall 2 is slightly higher than in the case where the constriction 3 is not formed, but the internal pressure per unit area on the constriction 3 has a much lower value than with a bottle where the constriction 3 is not applied.

Namely, by applying the constriction 3, the internal pressure acts substantially evenly over the entire area of the circumferential wall 2, and therefore it is not necessary to increase the wall thickness of the circumferential wall 2 in order to increase the strength of a limited portion of increase the circumferential wall 2. Thus, the entire circumferential wall 2 may have the small wall thickness, which can resist the above substantially uniform internal pressure.

The construction of the bottle is also such that the constriction 35, which is curved inward and depressed, is subject to easy elastic deformation by the biasing force or closing force acting axially on the bottle. 1 is exercised.

When the above biasing force or closing force is applied to the bottle 1, the constriction 3 is easily elastically deformed to absorb and bear the force before the circumferential wall 2 itself is deformed. Obviously, however, the ability of the constriction 3 to tolerate the elastic deformation caused by the biasing force or closing force is limited and therefore the deformation, as the biasing force or closing force gradually increases and the degree of elastic deformation of the constriction 3 will also gradually increases, eventually concentrating on the bottom of the constriction 3 and causing the bottom of the constriction 3 to buckle and break.

Therefore, according to the present invention, the circumferential projection 4 is formed in the bottom of the constriction 3, in order to increase the buckling strength of the constriction 3.

As can be seen from the entire construction of the constriction 3 and the circumferential projection 4, the circumferential projection 4 will not particularly influence a certain degree of elastic deformation of the constriction 3 due to the pretensioning or closing force along the axis of the bottle 1, but as the elastic deformation increases, the peripheral projection 4 itself will deform elastically in one direction, thereby preventing the increase of the elastic deformation of the constriction 3.

That is, the elastic deformation of the constriction 3 as a whole continues to displace the bottom 25 of the constriction 3 inwardly, while the deformation of the circumferential protrusion 4 continues in the outward direction. Therefore, the elastic deformation of the constriction 3 cannot possibly focus on the bottom or on the circumferential projection 4 and the entire constriction 3 including the circumferential projection 4 is deformed substantially evenly.

Since, as described above, the constriction 3 including the peripheral projection 4 is subjected to a uniform elastic deformation as a whole against the biasing force or longitudinal closing force, without the elastic deformation being able to concentrate on a particular part, it is possible , give the bottle an extraordinarily high kink-35 strength.

The greatest internal pressure acts on the part of the bottle, in which the circumferential projection 4 is arranged, namely because this circumferential projection 4 is arranged. However, because the major part of the internal pressure on the central portion of the peripheral wall 2, in which the constriction 3 is provided, is distributed in both the upward and downward directions 5, through the sloping sidewalls of the constriction 3, the part of the internal pressure acting thereon only small.

In order to further increase the buckling strength of the circumferential wall 2 as a whole against the longitudinal biasing force or closing force, it is advantageous to provide a number of small circumferential grooves 5 over substantially the entire surface of the circumferential wall 2, as is shown in the drawing. indicated.

However, these circumferential grooves 5 are not affected at all by the usual longitudinal biasing force or closing force, but only fulfill their function to the extent that they can possibly prevent breakage of the bottle 1, depending on the magnitude of the biasing force or closing force.

The reason is that in the state in which parts of the circumferential grooves 5 are subjected to elastic deformation, the uniform elastic deformation of the constriction 3 as a whole, including the circumferential protrusion 4, must already have reached its limit, and the durability at a bias force so great that the elastic deformation can continue is not necessary for the construction of the bottle 1.

Therefore, increasing the buckling strength of the circumferential wall 2 is a secondary purpose of the circumferential grooves 5, and the primary purpose thereof is to adorn the appearance of the bottle 1.

In the above-described construction of the bottle according to the invention it is possible to spread the forces, such as the pressure in the interior of the bottle 1 and the longitudinal biasing or closing force acting on the entire circumferential wall 2, substantially uniformly. elastic deformation due to the action of external forces can easily occur and thus local occurrence of said elastic deformation can be avoided. For example, the bottle can withstand these external forces extremely effectively and the bottle has an extraordinary mechanical durability.

Because, further according to the invention, a local concentration of external forces and local deformation can become positive 790 5 2 97

Claims (3)

Elongated blow-molded thin-walled synthetic resin bottle, characterized in that substantially the central portion in the height direction of the circumferential wall of the bottle is provided in the circumferential direction with an inwardly curved depression, which forms a constriction and the bottom of said circumferential constriction is provided with an oppositely curved projection of small height. Elongated, thin-walled bottle according to claim 1, characterized in that the synthetic resin consists of polyethylene terephthalate resin and that the bottle is formed by biaxial stretching in a blow mold. 3. Elongated, thin-walled bottle, substantially as described in the description and / or shown in the drawing. 7905297