JP2006327629A - Paper-made molding container - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a paper-made molding container which has a step on a part of the container with a side face inclined toward the opening side of the upper face by drawing a sheet of paper raw material, and which can be stably stacked by utilizing the step. <P>SOLUTION: The paper-made molding container is characterized in that the container has a bottom face, a side face and a flange, the step part facing toward the outside of the container and being approximately in parallel to the bottom face is provided on the side face, and in addition, the side face has a tapered angle α in the vertical direction, the tapered angle β of the flange formed on the outer edge of the step part is smaller than α, and the relation between the thickness (paper thickness) t of the container and the height q of the flange to the step satisfies the following equation: t/sinα-t<q<t/sinα. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a paper container formed by drawing a single paper material used for food or the like. In particular, the present invention relates to a stackable paper molded container.

  Among various molded containers formed from resin used for food packs or the like, as an example of so-called trays, foamed polystyrene beads are molded, or expanded polystyrene sheets are press-molded EPS (styrofoam) trays, In addition, PS (polystyrene) trays, PP (polypropylene), PET (polyethylene terephthalate) trays and the like are widely used. In addition, there are trays mainly formed by press-molding thin metals such as aluminum. Foamed plastic containers have the advantage of being extremely lightweight and highly rigid.

  However, considering environmental problems, recycling problems, and resource saving in recent years, it can be recycled as an alternative to conventional plastic and metal trays, has low incineration heat when discarded, and has biodegradability. There is a need for a molded container made mainly of paper pulp.

  Conventionally, a container made of pulp mold exists as a container formed using paper pulp or a base material mainly composed of paper pulp and having a three-dimensional structure, for example, a tray shape. There is also a paper container formed by drawing paper used for food or the like, and a patent application has been filed by the present applicant (see Patent Document 1 below).

  Such a paper draw-formed container is obtained by loading a base paper with a ruled line between male and female molds and press-molding it with hot pressure. A so-called paper plate, which is formed by press forming a paper substrate very shallowly, falls into this category and is widely used as a simple plate or the like.

  However, in this type of paper-made container, by providing protrusions and steps on a part of the container, it is possible to make the container stable and stackable. It is required to improve workability and machine suitability.

The stable stacking property means that the containers do not sway when they are stacked, but overlap each other in a straight line at a constant interval.
This stacking property is particularly important when filling a container with contents and automatically packaging the contents.

  In general, when automatically filling and packaging the contents in a tray-like container, the tray-like container is loaded in a state where it is stacked on the container supply device, and the flange portion of the tray is gripped by the device. Each sheet is taken out and supplied to the line. At this time, if the containers are not vertically stacked and the flanges are inclined or the distance between the flanges is not constant, multiple feeds (multiple feeds are made without feeding the containers one by one) Troubles due to mishandling such as (status) occur.

Containers made of thermoplastics, metals, etc. generally have a high degree of freedom in shape, and the shape after molding is stable. (See Patent Documents 2 and 3 below).
Therefore, it is easy to impart stacking properties by providing protrusions or steps on part of the container.

However, in general, paper is poor in stretchability, spreadability, and stretchability compared to those made of thermoplastics, metals, etc., so in a tray-like container formed by drawing a single paper material, There are restrictions on the shapes that can be manufactured.
In addition, the shape after molding is unstable compared to the materials such as thermoplastics and metals, and it is difficult to impart stacking properties. There was a problem in mechanical suitability when filling the contents, and its use was limited.
JP 2002-179044 A JP 2004-196344 A Japanese Patent No. 2869683

  Accordingly, the present invention provides a paper container formed by drawing a sheet of paper material, and a protrusion or step is provided on a part of the container where the container side surface is expanded (inclined) toward the upper surface opening side. It is a problem to obtain a paper-made container that can be stably stacked using a stepped portion.

  As a result of various researches, the inventors of the present invention are flanged paper containers obtained by press-molding a single paper material, and the thickness of the paper container, the taper angle of the side of the container, the height of the flange, etc. It has been found that by making the shape satisfying a specific relational expression, it is possible to obtain a paper container that is easy to draw and can be stably stacked.

  In order to solve the above problems, the present invention proposes a paper container having the following shape.

That is, the first of the present invention is
A paper container formed by press-molding a sheet of base paper, having a bottom surface, a side surface, and a flange, the side surface is provided with a step portion substantially parallel to the bottom surface in the container outer direction, Further, the side surface has a taper angle α with respect to the vertical, the taper angle β of the flange formed on the outer edge of the step portion is smaller than α, and the thickness (paper thickness) t of the container and the step The paper molded container is characterized in that the relationship between the height of the portion and the flange (step difference) q satisfies the following formula.
t / sinα-t <q <t / sinα

The second of the present invention is
A paper container formed by press-molding a sheet of base paper, having a bottom surface, a side surface, and a flange, wherein the side surface has a lower step portion (first step) substantially parallel to the bottom surface facing the container outer side. Portion) and an upper step portion (second step portion), and a lower side surface (first side surface) between the bottom surface and the lower step portion (first step portion) is tapered relative to the vertical. The upper side surface (second side surface) between the upper surface of the upper step portion and the flange formed at the outer edge of the upper step portion has a taper angle α ′ with respect to the vertical, and the lower step portion (first step portion). ) And the upper step (second step), the taper angle β ′ of the inter-step side surface is smaller than both α and α ′, and the thickness (paper thickness) t of the container and the lower step The relationship between the height (step difference) q ′ of the upper portion and the upper step portion is a paper molded container characterized by satisfying the following formula.
t / sin α-t <q ′ <t / sin α

The third of the present invention is
The relationship between the height (step) q ′ of the lower step and the upper step, and the height (step) q of the upper step and the flange,
The paper molded container according to the second invention, wherein q ′ <q.

    Containers molded according to the present invention do not wobble when stacked, and can be stacked straight up in the vertical direction, and the flanges of the containers are parallel to each other at equal intervals. Therefore, it is excellent in mechanical suitability and particularly suitable for packaging by automatic filling. Further, the stacked upper container and the lower container do not come out of contact with each other. Furthermore, the container shape is not deformed by stacking even when it receives a load from above.

Next, the drawing container of the present invention will be further described with reference to the drawings. The container of the present invention is used for storing fresh foods such as meat and vegetables and various processed foods such as natto, side dishes, bento, confectionery, noodles, and other foods such as cosmetics, medicines, toys, and appliances. It is also possible to accommodate other things.
In addition, when using the container of this invention for the container which packs natto, the magnitude | size of a container upper part is 10 cm x 10 cm as an example, and the container depth is about 3 cm.

<Container shape>
The container of the present invention is a paper container obtained by drawing a sheet of base paper with a pair of convex and concave press dies, and spreads upward like a bowl. Is open. And the flange is provided in the outer edge edge part of opening. The flange may be formed by curling the tip edge upward or downward.
The outer shape of the container is a substantially square, rectangle, circle, ellipse or the like in a plan view. In the case of a square shape, the corner portion (corner portion) of the container is usually rounded.

In the figure, 1 is a container body, 2 is an opening, and 3 is a flange. Moreover, the container of this invention has the substantially flat bottom face part 4, and the side part 5 of the container is made into the taper shape which spreads upwards. If the bottom surface and the side surface are not tapered and the bottom surface and the side surface are vertical, drawing is difficult, and the molded containers cannot be stacked and stacked. The taper angle is preferably in the range of 95 to 130 °, more preferably 100 to 130 °, as measured from the bottom surface to the inside of the side wall.
When the angle is 95 ° or less, the extraction is not smoothly performed, and when it is 130 ° or more, the stacking tends to be unstable.

The container of the present invention is provided with one or two steps (steps) substantially parallel to the bottom surface on the side surface of the container. Reference numerals 6a and 6b denote steps (steps).
FIG. 1 shows an example in which one step is provided on the side surface of the container. Two or more steps can be provided on the side surface of the container, but it is not necessary to provide more than two steps. This is because it is difficult to form the stepped portion beyond two steps, and it is not necessary to provide two or more steps practically.

  When the containers are stacked, as described in the background art section, it is a condition for imparting good stacking properties that the containers do not sway, are straight in the vertical direction, and overlap each other at a constant interval.

  When the container according to the present invention is stacked, the flange 3 formed on the outer edge of the step part of the lower container that overlaps vertically, the step part 6a of the upper container, and the ridge part of the side part 5 of the lower container come into contact with each other. In addition, since the side surface portions 5 below the step portion 6 are in contact with each other, when the containers are stacked, the containers do not wobble, and the stacked upper container and the lower container are not engaged with each other and cannot be removed. Furthermore, the container shape is not deformed even if it receives a load from above by stacking. At the same time, the containers that overlap vertically overlap each other in a vertical direction with a certain interval. Therefore, the flange 3 is not inclined, the interval between the flanges is constant, the machine is suitable for taking out the container, and troubles due to gripping errors such as double feeding do not occur during packaging by automatic filling.

The relationship when stacking the container of the present invention is shown by a graph in FIG. 1, with the bottom corner of the reference container as the origin o. At this time, the thickness (paper thickness) of the container is t, and the distance between the bottom surfaces of the upper and lower containers is h.
The x and y coordinates (x, y) of the point P on the graph are x = htan α and y = h.
When the taper angle with respect to the vertical of the container side surface 5 is α, the height of the flange 3 formed on the outer edge of the step portion is q, and the taper angle β of the flange β <α, h = q + t,
y = 1 / tan α · x
= Sin α / cos α · x
It is.
h = t / sin α
Because
q <h <q + t
h-t <q <h
It is.
Therefore, the first container of the present invention is characterized in that the relationship between the stepped portion and the flange height q satisfies the following formula.
t / sinα-t <q <t / sinα
By satisfying such a relationship, at the time of stacking, the flange 3 of the lower container and the ridge portion formed by the step portion 6a and the side surface portion 5b of the upper container are in contact with each other, and the side surface portions 5 are in contact with each other. Stacking is stable.

  In the case of q ≦ t / sin α−t, when stacking, the side surfaces 5 come into contact with each other prior to the stepped portion, and the stepped portion 6a is floated, so that the effect of improving the stacking property is not obtained. Further, the interval between the flanges is not stable or the flange 3 is easily deformed. FIG. 3 shows a state where containers having such a relationship are stacked.

  On the other hand, when t / sin α ≦ q, when stacking, the flange 3 formed on the outer edge of the side surface portion 5b of the lower container and the ridge portion between the step portion 6a and the side surface portion 5b of the upper container contact each other. Thus, since the side surface 5a is in a floating state (see FIG. 4), stacking is not stable. In addition, the strength in the stacked state is weak. In addition, the shape of the container is easily distorted.

In addition, when α <β, the stacking performance is not improved because no contact occurs between the flange portion of the lower container, the step portion of the upper container, and the ridge portion of the side surface portion during stacking.
In the present invention, the preferable range of t is specifically 500 μm to 700 μm. When the thickness is less than 500 μm, the molded container may have sufficient rigidity, and when it exceeds 700 μm, the moldability may be inferior.

Next, another embodiment of the present invention will be described.
FIG. 2 shows a second embodiment of the present invention in which two steps are provided on the side surface of the container. In the case of this example, the same parts as those shown in FIG. That is, reference numeral 1 is a container body, 2 is an opening, and 3 is a flange. Moreover, the container of this invention has the substantially flat bottom face part 4, and the side part 5 of the container is made into the taper shape which spreads upwards. Reference numerals 6a and 6b denote steps (steps).
In the case of this example, the lower side surface 5a between the bottom surface 4 and the lower step (step) 6a and the upper side surface 5c between the upper step (step) 6b and the flange 3 each have a taper angle α with respect to the vertical. , And the taper angle of the inter-step side surface portion 5b between the lower step portion (step) 6a and the upper step portion (step) 6b is β. The taper angle β is smaller than both α and α ′.
When the step difference between the lower step portion and the upper step portion is q ′, the relationship with the thickness t of the container is characterized by satisfying the following formula.
t / sin α-t <q ′ <t / sin α
(However, h = q ′ + t,)
FIG. 2 shows the case where the relationship between q ′ and the distance q between the upper stepped portion and the flange is q ′ <q. In this relationship, the stacked containers are more stable and desirable because they contact each other at the two side surfaces 5a and 5c in addition to the stepped portions.

  In the case of t / sin α <q ′, the side surfaces are lifted apart from each other during stacking (see FIG. 5), so that stacking is not stable. In addition, the strength in the stacked state is weak. In addition, the shape of the container is easily distorted.

  FIG. 6 shows a state where the containers are stacked when α = β = α ′. FIG. 7 shows a state where the containers are stacked when α <β. In the case of α <β, since the upper step of the lower container and the lower step of the upper container do not contact at the time of stacking, the effect of improving the stacking property does not occur.

The one or two steps in the present invention may be continuously provided on the entire circumference of the container. However, if two or more steps are provided symmetrically according to the shape of the container, the stacking property is improved. It is effective.
For example, in the case of a quadrangular container, it is preferably provided at four corners. By providing such a step structure, not only the stacking property but also the rigidity and shape stability of the container can be improved.

<Container material>
In the above-described form of the present invention, in order to impart practically necessary rigidity to the container and to prevent breakage at the curved surface portion, the material constituting the container wall after drawing is low density and strength. It is necessary to use high-molded base paper. In order to obtain such a molded base paper, it is preferable to contain mechanical pulp in which a large amount of lignin remains as pulp used for paper. In addition, as a means to determine the presence or absence of mechanical pulp use, it is possible to detect mechanical pulp by the method of TAPPI T401-os-74, for example. Further, the amount of mechanical pulp used in the paper used for forming processed paper is preferably in the range of 5 to 100% by mass, more preferably in the range of 20 to 80% by mass, and most preferably in the range of 40 to 70% by mass. It is. When the mechanical pulp is 5% by mass or more, the molded base paper can be reduced in density, which is preferable. In addition, when it is desired to give the forming base paper particularly extensibility, the amount of mechanical pulp used is preferably 80% by mass or less, and preferably 70% by mass or less. In addition, the mechanical pulp usage-amount in paper can be prescribed | regulated using the means described in TAPPI T-401-os-74, Specifically, the following method is taken. First, the processed base paper is re-disaggregated with water or hot water. Next, the re-disaggregated pulp fibers are dispersed on a slide glass, and pulp fibers such as C stain solution, Herzberg stain solution, and Sellegen stain solution are dropped to stain the pulp fibers. Thereafter, the slide is observed with a microscope, and the fiber composition is determined based on the dyeability and morphological characteristics of the pulp fiber. At this time, while simultaneously scanning the slide at the same time, the pulp fibers present per certain area are counted for each type and converted into mass percentages by weighting factors.

In order to realize the physical properties of the container wall material after the drawing, the paper used for the forming base paper has a rice basis weight of 100 to 500 g / m ² , a density of 0.4 to 0.7 g / cm ³ , and a breakage. The elongation is preferably 1.5% or more. Furthermore, at least one layer high density layer is the density 0.7~0.9g / cm ^3, and a density preferably has at least one layer of a low density layer of 0.2 to 0.6 g / cm ^3. The density of the low density layer is more preferably 0.3 to 0.5 g / cm ³ .

By adopting the above configuration, a paper having the above-mentioned rice basis weight of 100 to 500 g / m ² , density of 0.4 to 0.7 g / cm ³ , and elongation at break of 1.5% or more is obtained. In order to increase the elongation to 1.5% or more, if necessary, NBKP having a long fiber length can be blended in the outer layer, and beating to an appropriate beating degree can be used.

As the paper used for the forming base paper, as the raw material pulp constituting the outer layer on the outer side of the container, it is possible to use a raw material having a breaking elongation of 3% or more when the raw pulp is made in a single layer. More desirable. (This single-layer papermaking condition is based on the TAPPI standard method.)
The paper layer on the outer side of the container is stretched more than the inner side at the time of draw forming, and therefore requires a stronger elongation at break than the inner side. Thus, cracking and tearing of the outer paper layer surface in the drawing can be prevented, and a deeper drawing can be performed. The breaking elongation of the paper used for the forming base paper can be adjusted by a known method such as blending NBKP having a long fiber length and adjusting the degree of beating as described above.

<Coating layer of forming base paper>
The forming base paper in the present invention can be provided with a coating layer composed of a pigment and an adhesive on one side or both sides as required. As the pigment used in the coating layer, known pigments such as calcium carbonate, kaolin, clay, talc, titanium oxide, and plastic pigment can be arbitrarily used. As the adhesive used for the coating layer, known ones such as starch, casein, SBR latex, and polyvinyl alcohol can be arbitrarily used. These coating layers can be formed in a single layer or multiple layers. The total coating amount is preferably about ²⁰ to 30 g / m ² . Further, when such a coating layer is provided, it is more preferable that the layer immediately below the coating layer has a higher beating degree and a smoother surface. Such a coating layer can be applied by appropriately using various known coating apparatuses. Moreover, it is possible to provide a printing layer further on such a coating layer.

<About molding method>
As a method for producing a paper-molded container of the present invention, a forming base paper is punched into a container blank sheet, ruled lines are put in necessary places, the blank sheet is sandwiched between press dies composed of a male mold and a female mold, and heated and pressurized. The so-called draw forming method is used. At this time, it is necessary to condition the moisture of the forming base paper in advance and adjust the water content of the base paper. The base paper moisture needs to be in the range of 10-20%, preferably 11-17%, most preferably 12-15%. The moisture of the base paper here refers to the mass% of the water with respect to the absolute dry mass of the total pulp in the processed base paper. If the moisture content of the base paper is within this preferred range, plasticization of the forming base paper occurs, the formability is improved, and breakage of the paper layer during molding can be reduced. As a result, it is possible to obtain a drawn container having a greater depth, a smooth and beautiful appearance, and high rigidity. If the water content of the base paper is less than 10%, sufficient rigidity cannot be obtained in the molded body. If the base paper content exceeds 20%, blisters are generated on the forming base paper and the paper layer of the base paper is peeled off. It takes time for drying and undesirably causes problems such as reduced productivity. In addition, as a method for preparing moisture of the base paper, there are a method of supplying moisture to the base paper immediately before press molding, a method of transporting and storing in a state where moisture is maintained after moisture is removed from the dryer when paper is made. Can be mentioned.

  Next, the process for producing a molded container from a blank sheet will be described. In the present invention, the drawing is performed by a pair of pressing dies. The pair of heating press molds are a convex mold having a convex shape corresponding to the inner volume of the molded product and a concave mold having a concave shape corresponding to the outer shape of the molded product. The pair of pressing dies can press the molded product by moving at least one of the dies in the front-rear or up-down direction.

It is a half sectional view showing the relation when stacking the container of the present invention having one step. It is a half sectional view showing the relationship when stacking the container of the present invention having two steps. The comparative example of the container of this invention which has one step part is shown. The comparative example of the container of this invention which has one step part is shown. The comparative example of the container of this invention which has two steps is shown. The comparative example of the container of this invention which has two steps is shown. The comparative example of the container of this invention which has two steps is shown.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Container body 2 Opening 3 Flange 4 Bottom face part 5, 5a, 5b Side face part 6a, 6b Step part

Claims (3)

A paper container formed by press-molding a sheet of base paper, having a bottom surface, a side surface, and a flange, the side surface is provided with a step portion substantially parallel to the bottom surface in the container outer direction, The side surface has a taper angle α with respect to the vertical, the taper angle β of the flange formed on the outer edge of the step portion is smaller than α, and the thickness (paper thickness) t of the container, A paper molded container in which the relationship between the stepped portion and the height q of the flange satisfies the following formula.
t / sinα-t <q <t / sinα A paper container formed by press-molding a sheet of base paper, having a bottom surface, a side surface, and a flange, wherein the side surface includes a lower step portion and an upper step portion that are substantially parallel to the bottom surface facing the outer side of the container. The lower side surface between the bottom surface and the lower step portion and the upper side surface between the upper step portion and the flange have a taper angle α and a taper angle α ′ with respect to the vertical, respectively, The taper angle β ′ of the side surface between the steps between the upper portion and the upper step portion is smaller than both α and α ′, the container thickness (paper thickness) t, and the height of the lower step portion and the upper step portion The relationship of the length q ′ satisfies the following formula: a paper molded container.
t / sin α-t <q ′ <t / sin α The relationship between the height q ′ of the lower step and the upper step, and the height q of the upper step and the flange is
The paper molded container according to claim 2, wherein q ′ <q.

Images