This invention relates to a plastic formed body for pouring out liquid, having a flow passage surface for flowing out such a liquid as oily liquid that highly wets the plastics.
Plastics are, generally, easier to form than glasses and metals, can be easily formed into a variety of shapes and have, therefore, been used in a variety of applications. Specifically, plastics are representatively used in a field of containers such as bottles and packings such as caps fitted to the containers.
Here, when a liquid is contained in the container, there inevitably arouses a problem of liquid dripping. Therefore, a contrivance is required such that, when the liquid contained in the container is to be poured out through a spout or a pouring nozzle of the cap, the liquid being poured out does not drip out creeping along an outer wall surface of a pouring port.
Various means have been proposed in an attempt to prevent the dripping of liquid. For instance, a patent document 1 is proposing a means of coating the pouring port with a fluorine-contained resin, and a patent document 2 is proposing a means of forming a rough surface in the pouring port.
The conventional liquid drip-prevention means as proposed in the above prior arts are capable of dispelling aqueous liquid content to a sufficient degree and of effectively preventing the drip of liquid from the pouring port. However, these means are not still capable of preventing the drip of liquid to a sufficient degree specifically in the case of liquids that are prone to highly wet the plastic materials, such as edible oils, liquid detergents containing surfactants, and liquors containing alcohols at high concentrations. In particular, means of forming a rough surface in the pouring port rather causes the liquid to drip more.
It is, therefore, an object of the present invention to provide a plastic formed body having a pouring port for pouring out highly wetting liquid that wets plastics to a high degree, effectively preventing the highly wetting liquid from dripping at the pouring port.
According to the present invention, there is provided a plastic formed body for pouring out liquid, having a pouring port for pouring out highly wetting liquid that wets plastics to a high degree, wherein:
at least either a surface that becomes a liquid-drip flow passage when said liquid drips at the pouring port or a surface that becomes a flow passage when said liquid is poured out, is coated with a fluorine-contained resin, and a surface of the fluorine-contained resin coating has an arithmetic mean roughness (Ra) in a range of 0.4 to 200 μm in the surface roughness measurement and an element mean height (Rh) in a range of 0.04 to 10 as defined by mean height (Rc)/element mean length (RSm) in the linear roughness measurement.
In the plastic formed body of the invention, it is desired that:
(1) An underlying surface coated with the fluorine-contained resin is a rough surface having the above arithmetic mean roughness (Ra) and the above element mean height (Rh), and the roughness is reflected on the surface of the fluorine-contained resin coating; and
(2) Said highly wetting liquid forms a contact angle of not more than 40 degrees relative to a polyolefin resin.
In the plastic formed body of the invention, further, it is desired that:
(3) At least the surface of the pouring port is formed of a polyolefin resin;
(4) The plastic formed body is a spout that is fitted to a bag-like container or a paper container;
(5) The plastic formed body is a cap fitted to a mouth portion of a container, the cap having a pouring nozzle with the pouring port for pouring out said highly wetting liquid contained in the container; and
(6) The plastic formed body is a bottle having the pouring port formed in a mouth portion of the bottle.
The plastic formed body of the invention has a portion that becomes a pouring port for pouring out liquid that is contained in a container. The plastic formed body is, specifically, used for pouring out highly wetting liquid that wets plastics to a high degree. The pouring port is coated with a fluorine-contained resin, and a surface of the fluorine-contained resin coating is a rough surface having an arithmetic mean roughness (Ra) and an element mean height (Rh) that lie within predetermined ranges. That is, in the invention, the fluorine-contained resin coating improves repellency against the highly wetting liquid (i.e., forms an increased contact angle). Besides, as a result of the fact that the surface of the coating is the rough surface satisfying predetermined conditions, the surface exhibits very improved slipperiness for the liquid and, therefore, very improved liquid-dispelling property as also demonstrated in Examples appearing later. Therefore, the plastic formed body is capable of effectively preventing the drip of liquid at the time of pouring out liquid that wets plastics to a high degree, i.e., at the time of pouring out edible oils and the like liquids.
Reference is now made to
The pouring port 110 comprises a surface (upper surface) 110a that becomes a flow passage when the liquid is poured out and a surface (back surface) 110b that becomes a liquid-drip flow passage when the liquid drips.
The pouring port 110 may be formed straight. Usually, however, the pouring port 110 has a curved shape that extends outward maintaining an upwardly facing convex shape so that the liquid that is poured out will not flow down along the outer surface of the nozzle 150.
The plastic formed body of the invention having the pouring nozzle 150 may be formed by using a known plastic material that can be formed in any predetermined shape, and is formed by using a suitable thermoplastic resin depending on the use thereof. In the field of packing containers, for instance, the plastic formed body is formed by using, in many cases, a polyolefin resin such as polyethylene or polypropylene or by using a polyester resin such as polyethylene terephthalate (PET).
In the invention, the liquid poured out from the pouring nozzle 150 highly wets plastics and, concretely, forms a contact angle of not more than 40 degrees relative to the polyolefin resin (specifically, polypropylene). The contact angle is measured by dripping the liquid on a smooth surface (having an arithmetic mean roughness (Ra) of not more than 0.1 μm) of a polypropylene plate.
As the highly wetting liquid, as described above, there can be exemplified various kinds of edible oils, liquids containing surfactant, dressings, liquors containing alcohols at high concentrations, and the like.
In the pouring nozzle 150 for pouring out the highly wetting liquid, the pouring port 110 is coated with a fluorine-contained resin. Namely, at the time of pouring out the liquid by tilting the pouring nozzle 150, the liquid may drip. Here, with the fluorine-contained resin being applied onto the back surface 110b of the pouring port 110 that becomes the liquid-drip flow passage and onto the upper surface 110a that becomes the flow passage when the liquid is poured out, these surfaces exhibit improved repellency against the wetting liquid that is poured out.
As the fluorine-contained resin that is to be applied, there can be used any one that has been known per se. For example, there can be used polytetrafluoroethylene (PTFE), polychlorotrifluoroethylene (PCTFE), polyvinylidene fluoride (PVDF), polyvinyl fluoride (PVF), perfluoroalkoxyfluorine-contained resin (PFA), ethylene tetrafluoride-propylene hexafluoride copolymer (FEP), ethylene-ethylene tetrafluoride copolymer (ETFE) and ethylene-chlorotrifluoroethylene copolymer (ECTFE), as well as commercially available fluorine resins, such as fluorine-contained resins of various kinds of grades like those of the Asahi Guard E-Series manufactured by ASAHI GLASS CO., LTD.
The fluorine-contained resin can be easily applied by preparing a coating solution by dissolving the resin in a suitable low-boiling organic solvent (e.g., hydrofluoroether, ethanol, etc.), and applying the coating solution onto the pouring port 110 followed by drying.
Further, the fluorine-contained resin is applied in a thickness of, usually, about 10 nm to about 1000 nm. The thickness that is too small tends to become uneven and may make it difficult to effectively impart liquid-repelling property. The thickness that is too large, on the other hand, makes it difficult to increase the effect of preventing the dripping any more causing the cost to rather increase and, besides, making it difficult to roughen the surface by a method that will be described later. That is, the rough surface formed in the mold is not reflected on the surface of the coating of the fluorine-contained resin.
To improve the adhesive strength between the fluorine-contained resin coating and the plastic material, further, there may be applied an acrylic resin or an acid-modified polyolefin resin as an underlying layer.
In the invention, it is necessary that the fluorine-contained resin coating has a rough surface.
Concretely speaking, it is necessary that the surface of the fluorine-contained resin coating has an arithmetic mean roughness (Ra) in a range of 0.4 to 200 μm, specifically, 0.4 to 150 μm in the surface roughness measurement and, further, has an element mean height (Rh) in a range of 0.04 to 10, specifically 0.04 to 8 as defined by mean height (Rc)/element mean length (RSm) in the linear roughness measurement. The roughness is measured in compliance with the JIS-B-0601-1994.
The arithmetic mean roughness (Ra) represents a mean absolute value of roughness in a region of a predetermined reference length while the element mean height (Rh) represents a mean height per a unit length of the element.
In the invention, coating the surface with the fluorine-contained resin and roughening the surface, help greatly improve the property for repelling the above-mentioned highly wetting liquid making it, therefore, possible to strikingly improve liquid-dispelling property and to effectively prevent the liquid from dripping.
Improving the liquid repellency by roughening the surface can be explained relying on the Cassie mode and the Wenzel mode.
In the Wenzel mode, on the other hand, the liquid droplet is in contact with the whole surface. Therefore, the liquid droplet has a large diameter R and its apparent angle θ* of contact is smaller than that in the Cassie mode. Therefore, the liquid repellency is small, too. Besides, the liquid droplet tends to remain on the surface despite it has flown down. Namely, despite the surface has been roughened, the Wenzel mode is assumed if the roughness is fine. Therefore, a favorable liquid-dispelling property is not realized, and the liquid is not prevented from dripping to a sufficient degree.
According to the present invention as will be learned from the above description, the surface of the fluorine-contained resin coating is so roughened that the above-mentioned arithmetic mean roughness (Ra) and the element mean height (Rh) lie within predetermined ranges, enabling the liquid droplet to assume a contact pattern in the Cassie mode in which air pockets are made present and, therefore, making it possible to realize excellent liquid repellency aided by the above-mentioned coating of the fluorine-contained resin and to effectively prevent the liquid from dripping.
If, for example, the arithmetic mean roughness (Ra) or the element mean height (Rh) is smaller than the above ranges, then the Cassie mode is not realized, the liquid repellency becomes unsatisfactory, and the liquid is not prevented from dripping to a sufficient degree. The larger the arithmetic mean roughness (Ra) or the element mean height (Rh), the larger the liquid repellency and the higher the effect for preventing the drip of liquid. If they become larger than the above ranges, however, the pouring port 110 tends to have a decreased strength, a decreased scratch resistance and, further, tends to be easily broken or deformed.
After having been coated with the fluorine-contained resin, the surface can be roughened by the after-treatment such as stamping or blasting. However, such a treatment is cumbersome and causes a decrease in the productivity. In the present invention, therefore, it is desired that a portion corresponding to the pouring port 110 of the mold used for forming the plastic formed body is subjected to the roughening treatment such as blasting or etching so that the rough surface complies with the above-mentioned ranges. Then by using the mold, the plastic material is formed and is coated with the fluorine-contained resin thus forming the roughened surface. In this case, the underlying surface of the pouring port 110 coated with the fluorine-contained resin has already been roughened, and the rough surface is reflected on the surface of the fluorine-contained resin coating.
In the invention mentioned above, it is most desired that the fluorine-contained resin is applied and the surface is roughened both over the upper surface 110a and the back surface 110b of the pouring port 110. However, the fluorine-contained resin may be applied and the surface may be roughened over either the upper surface 110a (surface that becomes the flow passage when the liquid is poured out) or the back surface 110b (surface that becomes the liquid-drip flow passage when the liquid drips).
The regions where the fluorine-contained resin is applied and the surface is roughened are suitably set such that the liquid can be effectively prevented from dripping. On either the upper surface 110a or the back surface 110b, however, it is desired that the fluorine-contained resin is applied and the surface is roughened so as to cover at least the curved portions.
By utilizing excellent liquid repellency and liquid-dispelling property exhibited by the pouring port 110, the plastic formed body of the invention can be realized in a variety of forms. Namely, the plastic formed body exhibits not only very high slipping property to the liquids but also very favorable liquid-dispelling property, effectively preventing the liquid from dripping. Therefore, it can be effectively used as a packing body for containing oily liquids that exhibit high degree of wettability to the above-mentioned plastic materials.
The plastic formed body of the present invention may have the flow passage 200 through which the above highly wetting liquid flows and have the pouring port 110 for pouring out the liquid. For instance, it may assume the form of a container (e.g., bottle) with a mouth portion through which the liquid content is directly poured out. Usually, however, the plastic formed body of the invention, most desirably, is fitted to a container and is used for discharging the liquid contained therein, i.e., is used as a spout being fitted to a bag-like container or a paper container, or is used as a pouring cap being fitted to the mouth portion of the container such as bottle or the like from the standpoint of utilizing the advantage of the present invention to its maximum degree.
On a lower part on the outer surface of the cylinder 1, there is formed an expanded portion 5 on which a film will be melt-adhered to form a bag-like container. On the expanded portion 5, there are formed a plurality of ribs 5a (three ribs in
By also making reference to
Referring to
With the lid body 10 being fitted due to the screw-engagement of the screw thread 7 with the screw thread and, further, with the upper end of the cylinder 1 being closed, the seal ring 19 is closely contacted to the inner surface 1a of the cylinder 1. Thus the flow passage is sealed, and the fluid substance is prevented from leaking to the exterior or foreign matter is prevented from entering into the container.
Further, in a state where the lid body 10 is fitted, the TE band 17 is positioned under the flange 9 on the outer surface of the cylinder 1. That is, the TE band 17 is continuous to the lower end of the skirt portion 13 via a breakable bridge portion. The TE band 17 is, further, forming protuberances 17a that are facing upward on the inner surface thereof. Therefore, if it is attempted to open the lid body 10 (disengage the screw-engagement) to remove it from the cylinder 1, the skirt portion 13 rises but the TE band 17 is prevented from rising due to the engagement of the protuberances 17a with the flange 9. As a result, the lid body 10 is removed while the TE band 17 is separated away from the skirt portion 13. With the TE band 17 being separated away, therefore, a general consumer is allowed to recognize the fact that the lid body 10 was opened. This makes it possible to prevent unauthorized use such as tampering and, therefore, to guarantee the quality of the content.
The spout for the paper container generally designated at 30 has a considerably simple structure. Basically, however, the structure is the same as that of the spout for the bag-like containers.
The spout 30 is made of a cylinder 31 that forms the flow passage, and space in the cylinder 31 serves as a flow passage 33 being defined by an inner surface 31a of the cylinder 31. Therefore, an upper end of the cylinder 31 serves as the pouring port.
By making reference also to
Namely, with this spout 30, the body 40 is screw-fixed to the cylinder 31. In this state, the lower part of the spout is inserted in the mouth portion of a paper sheet that forms the paper container shown in
The paper container interrupts light to a high degree and is used for containing, specifically, a content that is subject to be easily degenerated by light.
In
The cap body 61 includes a cylindrical side wall 65 and a top wall 67 having an opening A in the central portion thereof.
The upper lid 63 is linked through a hinge band 66 to an upper end of the cylindrical side wall 65.
An inner ring 69 extends downward from the lower surface of the top wall 67 of the cap body 61 and maintains a small gap from the cylindrical side wall 65. Namely, the mouth portion of the container such as bottle is fitted and fixed in space between the cylindrical side wall 65 and the inner ring 69.
On the other hand, a pouring nozzle 70 is provided on the outer surface of the top wall 67 so as to surround the opening A, and an engaging protuberance 71 of a small height is formed on the outer side of the pouring nozzle 70.
That is, when the upper lid 63 is closed by being turned with the hinge band 66 as a fulcrum, the circumferential edge of the upper lid 63 comes into engagement with the engaging protuberance 71, and the upper lid 63 is closed and, in this state, is firmly fixed.
As will be understood from
Further, though not shown in
In the pouring cap 60 of the above-mentioned structure, a flow passage 75 is formed by the inner surface 70a (and the inner surface of the cylindrical side wall 65) of the pouring nozzle 70, and the liquid contained in the container such as bottle is discharged flowing through the flow passage 75.
In this state as will be understood from
In the diagramed embodiment, the upper lid 63 is linked through the hinge. The upper lid 63, however, may be detachably provided by screw-engagement. In this case, a screw thread for screw-engagement is provided on the outer surface instead of providing the engaging protuberance 71. Further, at the time of discharging the content from the flow passage 75 formed in the pouring nozzle 70, the upper lid 63 will have been removed. Therefore, there is no need of partly decreasing the height of the pouring nozzle 70. Instead, the pouring port is formed by the whole circumference of the upper end of the pouring nozzle 70.
In the pouring fittings of the structures shown in
The above various kinds of plastic formed bodies inclusive of lid bodies thereof shown in
The plastic formed body of the invention may, as a matter of course, possess a multilayered structure including a gas-barrier resin layer as an intermediate layer and, desirably, includes a portion made of a polyolefin resin on at least the surface of the pouring port.
Excellent properties of the invention will now be described below.
In the following Experimental Examples, various measurements and evaluations were taken by the methods described below.
In a state where the containers (bottles) were erected, the sample caps prepared in Examples and Comparative Examples were so fitted that the pouring ports faced upward.
The state where the container was erected was regarded to be 0 degree. In case the container was tilted at an angle over a range of 70 to 75 degrees, the amount of the liquid content was so adjusted that the liquid content flew out while producing liquid droplets. At this angle, 20 liquid droplets were caused to flow out and thereafter the container was returned back to the state of 0 degree. This operation was repeated 5 times and if the liquid dripped was observed.
A test sample was cut out from the pouring mouth portion of the sample cap, and on which gold was deposited in vacuum to a thickness that would not affect the roughness. The test sample was then measured for its roughness by using the “Laser Microscope VK-X100 for measuring the shape” manufactured by KEYENCE CORPORATION.
The lenses were a standard 50.0× and NA 0.800 lens, and measurement was taken maintaining a pitch of 0.13 μm.
As for the range of analysis, the surface roughness was measured for 276.8 μm×200.0 μm, the linear roughness was measured for 320.0 μm, and the cut-off values were λs=0.25 μm and λc=0.08 mm.
A test sample was cut out from the pouring mouth portion of the sample cap, stored in an environment of 23° C. and 50% for 12 hours. Thereafter, by using a “Solid-Liquid Interface Analyzer, DropMaster 500” manufactured by Kyowa Interface Science Co., Ltd., a test solution maintained at 23° C. was dropped on the test sample in an amount of 1.0 μL from the tip of a syringe needle of 22 G (inner diameter of 0.4 mm). After seconds have passed therefrom, the contact angle was measured.
The measurement was based on the sessile drop method and the analysis was based on the θ/2 method.
The pouring mouth portion of the sample cap was checked for its ruggedness with the eye.
The caps were packed in a box of a corrugated cardboard measuring 435×320×320 mm maintaining an inner height over a range of 290 mm to 310 mm, and on which vibration was exerted in a random fashion for 15 minutes in compliance with the packed cargo—performance testing method specified under the JIS-Z-0200. Thereafter, the caps were checked with the eye for any scratches.
There were used the following test liquids.
“Milli-Q water” produced by Millipore Corporation.
“Nisshin Canola Oil” produced by The Nisshin OilliO Group, Ltd.
(contact angle to polypropylene of 25 degrees)
“Attack NEO” produced by Kao Corporation.
(contact angle to polypropylene of 30 degrees)
“Ethanol for precision analysis” manufactured by Wako Pure Chemical Industries, Ltd. was adjusted to 80 wt % with pure water (“Milli-Q water” produced by Millipore Corporation)
(contact angle to polypropylene of 20 degrees)
“Ethanol for precision analysis” manufactured by Wako Pure Chemical Industries, Ltd. was adjusted to 60 wt % with pure water (“Milli-Q water” produced by Millipore Corporation)
(contact angle to polypropylene of 40 degrees)
As the resin for forming, there was provided a polypropylene (Prime Polypro J226T manufactured by Prime Polymer Co., Ltd., MFR=20 g/10 min.).
By using an injection mold, the above polypropylene was injection-formed into a cap of a shape shown in
The pouring port of the thus obtained cap was evaluated for its liquid-dispelling property, roughness, contact angle, appearance and scratch resistance. The results were as shown in Table 1.
As the resin for forming, there was provided a blend of a polypropylene (WELNEX RFX4 manufactured by Japan Polypropylene Corporation, MFR=6 g/10 min.) and a polyethylene (Kernel KS560T manufactured by Japan Polyethylene Corporation, MFR=16.5 g/10 min.) at a weight ratio of 80:20.
The mold was blast-treated (with the HN20 manufactured by Nihon Etching Co., Ltd.) at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips. The above resin for forming was injection-formed in the same manner as in Comparative Example 1 but using the above mold. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
A coating solution of a fluorine-contained resin was prepared by dissolving 1 wt % of a fluorine-contained resin (AsahiGuard E-Series AG-E060 manufactured by ASAHI GLASS CO., LTD.) in 99 wt % of ethanol (ethanol for precision analysis manufactured by Wako Pure Chemical Industries, Ltd.).
The pouring port (upper surface 110a and back surface 110b) of the cap obtained in Comparative Example 1 was dipped in the above coating solution, and was dried in an environment of 23° C. and RH50% for 3 hours so as to be coated with the fluorine-contained resin.
The pouring port of the cap was evaluated for its properties in the same manner as in Comparative Example 1. The results were as shown in Table 1.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Comparative Example 3 but subjecting the mold to the blast treatment (with the HN23 manufactured by Nihon Etching Co., Ltd.) and to the gloss treatment at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Comparative Example 3 but subjecting the mold to the blast treatment (with the HM-DS02 manufactured by Nihon Etching Co., Ltd.) at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
As the resin for forming, there was provided a polypropylene (WELNEX RMG02VC manufactured by Japan Polypropylene Corporation, MFR=20 g/10 min.).
The mold was machined at portions corresponding to the upper surface 110a and the back surface 110b to form a rough surface having an arithmetic mean roughness Ra of 300.0 μm and an element mean height Rh (Rc/RSm) of 12.0.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Comparative Example 3 but injection-forming the above resin by using the above mold. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Comparative Example 3 but subjecting the mold to the blast treatment (with the Honing No 3 manufactured by Nihon Etching Co., Ltd.) at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Comparative Example 3 but subjecting the mold to the blast treatment (with the Honing No 7 manufactured by Nihon Etching Co., Ltd.) at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Comparative Example 3 but subjecting the mold to the blast treatment (with the Honing No 9 manufactured by Nihon Etching Co., Ltd.) at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Comparative Example 3 but subjecting the mold to the blast treatment (with the Satin No 1 manufactured by Nihon Etching Co., Ltd.) and to the gloss treatment at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
As the resin for forming, there was provided a polypropylene (WELNEX RMG02VC manufactured by Japan Polypropylene Corporation, MFR=20 g/10 min.).
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Example 1 but using the above resin for forming. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
As the resin for forming, there was provided a polypropylene (WELNEX RMG02VC manufactured by Japan Polypropylene Corporation, MFR=20 g/10 min.).
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Example 2 but using the above resin for forming. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
As the resin for forming, there was provided a polypropylene (WELNEX RMG02VC manufactured by Japan Polypropylene Corporation, MFR=20 g/10 min.).
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Example 3 but using the above resin for forming. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
As the resin for forming, there was provided a polypropylene (WELNEX RMG02VC manufactured by Japan Polypropylene Corporation, MFR=20 g/10 min.).
The mold was subjected to the blast treatment (with the HN20 manufactured by Nihon Etching Co., Ltd.) at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Comparative Example 3 but injection-forming the above resin by using the above mold. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Example 8 but subjecting the mold to the blast treatment (with the HN23 manufactured by Nihon Etching Co., Ltd.) at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Example 8 but subjecting the mold to the blast treatment (with the HN26 manufactured by Nihon Etching Co., Ltd.) at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
As the resin for forming, there was provided a polyethylene (Kernel KS571 manufactured by Japan Polyethylene Corporation, MFR=20 g/10 min.).
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Example 8 but using the above resin for forming. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
As the resin for forming, there was provided a blend of a polypropylene (WELNEX RFX4 manufactured by Japan Polypropylene Corporation, MFR=6 g/10 min.) and a polyethylene (Kernel KS560T manufactured by Japan Polyethylene Corporation, MFR=16.5 g/10 min,) at a weight ratio of 80:20.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Example 8 but using the above resin for forming. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
As the resin for forming, there was provided a polypropylene (WELNEX RMG02VC manufactured by Japan Polypropylene Corporation, MFR=20 g/10 min.).
The mold was machined at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips to form a rough surface having an arithmetic mean roughness Ra of 11.0 μm and an element mean height Rh (Rc/RSm) of 1.05.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Comparative Example 3 but injection-forming the above resin by using the above mold. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
The mold was machined at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips to form a rough surface having an arithmetic mean roughness Ra of 120.0 μm and an element mean height Rh (Rc/RSm) of 1.15.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Example 13 but effecting the injection-forming by using the above mold. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
The mold was machined at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips to form a rough surface having an arithmetic mean roughness Ra of 220.0 μm and an element mean height Rh (Rc/RSm) of 1.22.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Example 13 but effecting the injection-forming by using the above mold. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
The mold was machined at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips to form a rough surface having an arithmetic mean roughness Ra of 11.0 μm and an element mean height Rh (Rc/RSm) of 4.7.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Example 13 but effecting the injection-forming by using the above mold. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
The mold was machined at portions corresponding to the portion (upper surface 110a) that becomes the flow passage when the liquid content is poured from the pouring port and the portion (back surface 110b) that becomes the flow passage when the liquid drips to form a rough surface having an arithmetic mean roughness Ra of 11.0 μm and an element mean height Rh (Rc/RSm) of 8.9.
A cap having the pouring port coated with the fluorine-contained resin was obtained in the same manner as in Example 13 but effecting the injection-forming by using the above mold. The pouring port of the thus obtained cap was evaluated for its properties. The results were as shown in Table 1.
Number | Date | Country | Kind |
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2014-036361 | Feb 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/050585 | 1/13/2015 | WO | 00 |