KR20140086968A - Method and machines for transforming initial sealed packagings into irregular cubic or polyhedral packagings by means of sealing and cutting flaps - Google Patents

Abstract

It is transformed into a flexible container (solid optional) that contains a fluid from an initially sealed, stretchable container that usually has at least two sides that look like envelopes. It is deformed into a geometric shape to create a foundation that supports at least one part to stand stable. First, the first step is to push the surface of the initial container. The one or more impact bodies (6) press against the outer surface of the initial vessel against the fluid body to form one, two or more flaps or protruding triangles and one or more support regions. And the second step is to permanently fix the mold obtained in the first step by sealing (using sealing or sealing with a heat source and cutting clamp 8). It is possible to seal one, two or more flaps (preferably the intersection of the flap with the rest of the container) as many as desired. This flap can then be selectively cut. Also, once the flap is sealed, it is folded, attached or glued to the rest of the container. Alternatively, the flaps may not be sealed and, optionally, the flaps may be folded, attached or glued to the remainder of the container.

Description

[0001] METHOD AND MACHINES FOR TRANSFORMING INITIAL SEALED PACKAGINGS INTO IRREGULAR CUBIC OR POLYHEDRAL PACKAGINGS BY MEANS OF SEALING AND CUTTING FLAPS [0002]

It belongs to the packaging and container manufacturing industry. In particular, the invention relates to a procedure for transforming into a partially enclosed stretchable container, according to the first objective. The stretch container is capable of holding a product at least partially with a fluid (and without solid or solid), transforming the initial container into a safe final container, increasing the volume of the container, Lt; / RTI > The invention relates not only to the food industry, but also to the food sector, as well as to the industrial sector (cubic containers containing engine oils, chemicals, cleaning products, cosmetics, perfumes, skins, paints). For example, there is a new disinfecting plastic container, beverage container that can be frozen or chilled in a container, organ transplants, breakfast cereals, sauces, and Tetrabrik® style containers without external cartons.

In general, products are packaged in stretched containers through machines called so-called vertical or horizontal filling machines. Whether the container contents are partial liquids, liquids (liquid / pasty, gas and / or air ...), solid products such as air, powder form, grain,

These containers do not use a stable method such as a table when holding a fluid such as water, sauce, or the like. Also, when the contents are contained in the container, it can be complicated and the article may be dirty and not hygienic. Also, there is no consideration to prevent the contents from flowing out by making a generous container. On the other hand, these containers are large enough to contain solids such as cereal, cookies, etc., and do not consider the contents of the container to be stable. Also, when the stomach is flattened or has a lid, it is not effective when pouring or pouring a solid product.

In order to solve the above problem, the present invention provides a method of transforming (modifying) a flexible container into a container having:

A container having at least two sides defining the extent of the enclosed space and at the same time bounding these sides through the outer contour rim and the outer contour rim having at least one side edge.

A minimum of one line of sealing or folding area that closes at least one kind of fluid and any or all of the containers that may contain additional solids, particles or powder. The method is characterized in that it comprises one of the following steps:

- Use at least one impact body (6) for at least one part on the edge of at least one of the edges, or two side edges facing / in the middle, local area, whole area or area adjacent to one end or corner, (1), or two or more side edges or tails of the original package, or vice versa (including the impact body (6)), A portion of the fluid follows the contour of the container, increasing the pressure inside the container and creating a localized expansion effect, resulting in the following: < RTI ID = 0.0 >

At least one container support surface or an additional surface in the container area collides with the impact body to maintain the stability of the container bottom and to deform the geometry of the container.

At least one flap or triangular body contacts the support surface and at least two sides of the container are formed.

- a sealing step that permanently stabilizes the support surface or additional surface by sealing, for example, at least one surface of at least one flap with at least one surface using a heat source.

Drawing 1: shows machine model [a] in general view.
Drawing 2: shows machine model [a] in detail.
3: Adjustable horizontal cushion: Shown in view of the container holding system with model [b1 / b2].
4: Adjustable vertical cushion: Shows the factory view of the system when holding the container with model [b1 / b2].
Drawing 5: Quadruple / Triple clamp: Shows the factory view of cubic strain machine model [b1] with sealing / cutting and impact.
6 shows the factory view of the cubic-deformation machine model [b2] with a four-line sealing / cutting and impact clamp.
7 shows a detailed view of raising the machine [c] in the 3D vertical transducer.
Figure 8: Figure 7 shows a detailed view of raising the model [c] machine, but in this case the two impact clamps are braked as if the upper one is below (6) and the initial container is swollen. In this way we get the geometric shape but the four covers have not yet gone through the seal or cut (section).
9 shows a detailed view of raising the model [c] machine and was also added to adjust and support the trap door 10 to the desired height in the initial vessel (with respect to the holding clamp 3).
10 shows a perspective view of the right prismatic shape and the impact clamp 6 and the model [c] of FIG. 7 and FIG. 8 raising the machine.
Drawing 11: [c] shows a detailed view of raising the model machine.
Figure 12 shows a detailed view of raising the [c] model machine, [c] model machine performs two sets of rectangular prism shape and triple clamp.
Plot 13 shows the perspective of raising the [c] model machine with two triplets in detail:
Figure 14 shows the [e] model machine, where the [e] model has a triple or quadruple clamp set (6, 8) on the top and another triple or quadruple clamp set (6, 8) have.
15 shows a detailed view of raising the [c] model machine, in which a trap door 10 and a sweeping brush are added 14 and two triple clamps in the upper clamp set 6,8, And is fixed to the tappet of the revolving cylinder / engine for the dump truck.
Figure 16: [c] model This shows a detailed view of raising the machine, this [c] model has only a triple clamp set (6, 8).
FIG. 17 shows a detailed view of raising the [c] model machine, which sets the tappet of two triple clamps, rotary cylinder / engine 16, in the shape of a right angle prism.
Figure 18 shows a detailed view of raising the same machine of Figure 11, but in this case a linear deformation unit 17 is added to move the holding clamp / clip 3 from left to right, This new vessel moves when this objective is achieved - transformed into a cubic shape.
Figure 19: The same container as in Figure 30, but the initial container to be deformed in this case has a rectangular shape, an elongated shape, or a lesser width shape than a square shape.
Figure 20: Same as the container shown in Figure 40, but in this case the initial container to be deformed has a rectangular shape, a smaller width and a longer length than a square.
Figure 21: Container transformed into a rectangular prism shape and a stereoscopic shape. The initial container to be deformed in the future is a rectangular shape (four sides are straight angles) because the bottom portion of the initial container has a rectangular shape as well.
22: Two sets of multiple clamps of three linear clamps placed in different directions will seal and cut to two sides of the initial vessel.
Figure 23a: Initial container with square shape and four sides. A set of two multi-clamp clamps in straight lines that are sealed and cut into two sides. Two covers (left and right) are made and sealed, sealed and cut once they are used as the base of the container. The initial vessel will be transformed into the stereoscopic geometry of FIG.
Figure 23b: A set of multiple clamps (parallel twin only in a straight line in an oblique line) corresponds to the initial container and clamp set in Figure 23a, within which two adjustable sides and two sides of the initial container are sealed and cut will be.
Figure 24: Container deformed into an irregular polyhedral solid geometric shape with a shape similar to a pollen. The initial vessel to begin to deform has an irregular shape (all four sides with an angle are not straight and wider than their height).
Figure 25b: The same container as in Figure 25a, but in this case sealing and cutting were performed with multiple clamps one more time.
Plot 26: A container shaped like a dinosaur with an irregular polyhedron or cubic geometric shape. The initial vessel is an irregular shape (all four planes with angles are not straight, they are wider than their height and are closer to a square than a rectangle).
Drawing 27: A container that will be transformed into a three-dimensional geometric shape of irregular polyhedra in a similar shape, such as a bottle. The initial vessel to start deforming is irregularly shaped (the four sides are not straight angles, they are wider than their height or close to a square rather than a rectangle).
Drawing 28: A vessel deformed into a three-dimensional geometric shape of irregular polyhedra similar to a house with three vertexed roofs. The initial container to be deformed has an irregular shape (the four sides with each angle are not straight, they are wider than their height and are closer to a square than a rectangle).
Figure 29: A vessel deformed into a three-dimensional geometric shape of an irregular polyhedron similar to a flying saucer. The initial container to be deformed has an irregular shape (the four angled sides are not straight, they are wider than their height and are closer to a square than a rectangle).
Drawing 30: Container transformed into a three-dimensional geometric shape of an irregular polyhedron with a shape similar to the hull of an upside-down ship. The deformed initial vessel is irregular (all angles on the four sides are straight and wider than the height).
FIG. 31a: A container transformed into a rectangular prism shape and a stereoscopic shape higher than the width. The initial vessel to be deformed is a regular shape (four sides are straight angles).
Figure 31b: A container transformed into a three-dimensional geometric shape of an irregular polyhedron with a shape similar to a bottle. The initial container to be deformed is irregularly straight (four sides are not straight angles) (two sides are three times longer than the top and bottom sides).
Drawing 32: A container transformed into a three-dimensional geometric shape of an irregular polyhedron having a shape similar to a magic lamp. The initial container to be deformed has a regular shape (four sides are straight angles, wider than the height).
Figure 33: Container deformed into a cubic geometric shape of irregular polyhedra with a cube shape. The initial container to be deformed has a regular shape (four sides are straight angles).
34: Two sets of ejector clamps 20 can be adjusted and operated with a double effect with a straight clamp 9, a rotary clamp 16, or a double tappet.
Drawing 35: The immovable impact clamp and the two sealing clamps (8) or the sealing and cutting clamps (8) are self-aligning and located on the left and right sides of the impact clamp and do not move.
Plot 36: The two-sided (tube-like) extensional initial vessel is made of a machine that vertically fills a liquid or solid, and is available on the market today. This initial vessel has two seals with two perimeter seams (1) at the top and bottom. In addition, fluid (liquid / liquid and / or air / gas) may be packed with solid or packaged without solid within the container.
Plot 37: shows the view of raising the container with six sides, in this case plastic.
FIG. 38: As seen from the front view, the same view as the right angle prism container is shown, but in this case, the height is longer than the width.
Figure 39: Show the perspective of sealing and raising Cubic containers entirely.
Drawing 40: A container transformed into a geometric shape of an irregular polyhedron with a shape similar to a magic lamp. The initial container to be deformed has a regular shape (4 sides are straight angles, wider).
Plot 41 shows the perspective of raising a cubic container that is sealed with a rectangular prism (longer than its width) and is elastic and has six sides.
FIG. 42 shows the view of raising the container of a right angle prism (height is greater than the width) that is sealed and stretchable with a size equal to or similar to a Tetrabrik® type 1 liter container and has six sides.
Figure 43: Flexible initial containers with two sides made of machines that vertically fill liquids or solids can be found on the market today. This initial vessel consists of three seals: two perimeter weld seams (1) up and down and one end seam (4). In addition, the fluid (liquid / liquid and / or air / gas) is packed with solid or packed without solid in the vessel.
44 shows the same kind of view as the cubic vessel of FIG. 37, but in this case there is one more weld line. And a termination weld line 4 perpendicular to the center of the plane.
45: shows the same view as seen in FIG. 38, but in this case, there is one more weld line: a termination weld line 4 that is already perpendicular to the backside of the vessel or the front face of the already deformed vessel.
Figure 46: Drawing 39 The same kind of view as the vessel is shown, but in this case the cubic vessel has one more weld line or seal line. (4), which is close to the center of the back or top of the vessel, which has already been deformed.
Figure 47: Shows the perspective of stretching, sealing, and raising cubic containers entirely.
Drawing 48: Overall the same view as in FIG. 42 is shown, but in this case one more weld line is added. And a termination weld line 4 perpendicular to the center of the back or front surface of the vessel that has already been deformed in 3D. Also, no lid was attached.
Figure 49: Overall view of the same view as in Figure 41, but in this case one more weld line was added. And a termination weld line 4 perpendicular to the center of the back or front surface of the vessel that has already been deformed in 3D. In addition, a lid-cap is attached to the top of the container for the contents inside the container.
Drawing 50: A machine with two sides and a flexible initial vessel that vertically fills the liquid or solid was created and is available on the market today.
Figure 51: Overall view of lifting a container with six sides closer to the cube than a right angle prism.
Figure 52: Shows the perspective of stretching, sealing and raising cubic containers entirely. It will also be used as an ice cube in plastic containers that are small in size and contain water in the container.
Figure 53: shows an expansion view of lifting two sets of pinching clamps, which will seal and sever one of the edges in the vertical of the cubic vessel.
54 shows an overall view of raising the cubic vessel of FIG. 53, in which two pinching clamps will pick one of the vertical edges of the cubic vessel.
Drawing 55: A portion of the plastic material is used in the package. Otherwise, in a factory that produces containers with at least two sides, both containers are made in a vertical or horizontal filling machine.
Figure 56: A vessel deformed into a three-dimensional geometric shape of an irregular polyhedron with a shape similar to the sail of a ship. The initial vessel to be deformed later has an irregular shape (the four sides are not straight angles, they are longer than the width, and are closer to the rectangle than the square).
Figures 57-60 illustrate examples of variations that can be made to other configurations that the finished container can accommodate, particularly where sealing lines are made on the flaps or on the outside of the initial container in a modification procedure.

This invention is a procedure for deforming a flexible container according to the first object. Containers are basically three-dimensional (ie, not enveloped or flat), and have a side or backing that maintains stability.

The container to be transformed is also called the initial container. The initial container can be opened or closed, with a closed configuration being preferred. The contents may be partly fluid, such as liquid, broth and / or gas, air, and the like. Optionally, the content may be a solid product as mentioned above rather than a liquid.

The stretch container has at least two sides, which may add additional sides. Like a Stabilo pack® type container, it can have a side surface inside or outside, be sealed by two or more welds, or be folded into one, two, or more. The container is made of stretchy, elastic material of film type on the reel. It may be made of plastic only, or it may contain sheet or aluminum material. It can also be made into a single layer or a multi-layered form. On the other hand, it may be a film or a tube container. Especially, the reel is made of stretchy or elastic film. Although these elements are not essential, a flexible container is generally not an envelope-like container.

The initial vessel has an outer surface and an outer perimeter. The container is partially or at least closed to seal completely (because the container may be open).

The inventive procedure involves an initial step, which involves applying pressure using impact, rigidity, a semi-rigid body (also referred to as an impact clamp). That is, impact is applied to one or both of the outer circumferential lines on one or two or more sides of the outer circumferential line by one or more impact members, Or whether it is partially inflated. At least one flap, or trunk and outer perimeter of a three-dimensional structure, is examined at the same time to see if there is an affected part, a part restricted to the supporting surface or base circumferential line, or a surface added at the outer circumferential line. This allows the safety of the container to be measured and the geometrical configuration of the container to be modified.

Once the flap has a bearing surface, there is a second stage that maintains that bearing surface permanently (or an additional bearing on the outer margin). Two methods can be proposed. The first method is a sealing method, and the second method is a method of folding and attaching the flap to the rest of the container.

Particularly, in the first method, a part of one or more surfaces and / or the three-dimensional structure body is likely to be folded or sealed at the part of the outer circumferential line, so that the sealing clamp defined as the pressure step or the stiffness , A non-rigid sealing body is used.

The second method involves the second step of bonding the three-dimensional construct to the remainder of the flap, the container using an adhesive such as a cohesive adhesive or hot air, as well as including the three-dimensional construct in the first stage of folding the flap or the rest of the container.

The folding or bonding option can be done after the sealing procedure. Also, the sealed flap may be cut later or removed from the container to leave as large or small as desired.

As described above, the invention procedure allows a manufacturer to create a volume-tight container (not flat). Cubes, right-angled prisms, irregular polyhedrons can be made only of plastic, or they can be made without the use of sheets using stronger materials such as Tetra Pak's cardboard. This is because the procedure can introduce sealing seams and flaps. In fact, the flap can be removed later. And there is a cross between the container and the flaps so that it attaches to or adheres to the same container body so that the container becomes much harder and can maintain consistency. In addition, the invention of the procedure can create an unimaginably diverse and many vessels such as three-dimensional geometric vessel shape, cube, right angle prism, irregular polyhedron. It can also be used in restaurants because it can be made with stability and very small capacity (15ml, 25ml, 50ml etc) especially for source containers (ketchup, mayonnaise). There are also the following benefits:

a) The container can also be made of plastic. The weld seam of the seal and the incision section of the flap give the container rigidity and consistency. Therefore, it is not necessary to use a template cut sheet, such as a material marked with a predetermined groove on a sheet which is later wound or used in a vertical packaging machine.

b) There is no flap, so container weight is smaller and package size is smaller, which reduces logistics cost.

c) It is possible to save energy by not cutting trees, producing pulp extracts or reel papers, nor to distribute these materials produced in northern countries to other countries.

d) It is environmentally beneficial because it can reduce the amount of waste that is buried in the soil. It is possible to avoid being buried in the soil because the outer plate or sheet is removed and there is no flap sealing and cutting system and it is recycled according to proper procedures at the manufacturing plant.

e) This invention container can only be made of plastic material. In other words, it is not necessary to perform a board card layer of a typical container such as a Tetrabric. When this container is opened and the inner liquid is followed, it continually and continuously comes out, because the elasticity of the plastic packaging material allows it to adapt to the hole in the container.

f) There is a versatility in converting the inventive machinery because 3D containers can be made in different sizes and in many different ways with the same machine without the need for new elements or parts.

g) The inventive machinery can be applied in a comprehensive solution to other production facilities or chains that produce containers with at least two faces these days.

The parameters of the procedure described above allow to obtain a new flexible container with the properties mentioned. Therefore, the container object of another object having the characteristics described can be obtained by the procedure mentioned above.

According to another aspect of the invention, this invention is depicted as being perfect in the sophistication of a three-dimensional vessel. For example, it is possible to contain liquids such as juice, milk, etc., which are generally similar to Tetra Pak types. These containers are simultaneously filled in the vertical machine from the film reel sheet. The film of the reel can be pre-folded for convenient interchangeability of the container. In general, the container body can be obtained from the film wound first, and then the flap can be constructed out of the container body. When the film is displayed in advance, the flap is defined as a folding display means. The invention can be processed in the same manner as flaps previously mentioned with such flaps and the process of sealing such flaps can proceed. Alternatively, it can be folded and attached in analogue manner as mentioned above, or it can be sealed or cut later.

A machine that transforms the initial vessel into a three-dimensional geometric vessel

1. Model A of the deformation machine:

Step 1: Create an initial container with at least two faces in an inducible and natural way; It is a triangle with one, two, three, four, or more flaps or all the initial vessels, and also an initial vessel that transforms into a stereoscopic geometry at the same time.

Through a set of clamps made of a perfect cubic shape, we naturally make a cubic shape that we want to make at once. Do not press the clamp without closing it.

Step 2: Then there are two shock clamps, which are placed at right angles to place the free clamps as desired, not the automatic adjustment clamps and one or two clamps. They will be placed precisely between the flaps and the triangle through pneumatic or electric cylinders. At the same time, they can work together in such a way that containers with individual flaps can be joined together with one of each side, or with a double effect, with the same pneumatic or electric double tappet.

- They serve two purposes, helping to create a perfect cubic shape and allowing flaps or triangles to have the same size and shape in each container. They will also be used as a base or base for sealing and cutting flaps.

- And finally, one, two, three, or four actuators or an electric, pneumatic cylinder will be fitted with the brakes for each flap. They will each be sealed, and the sealing and cutting of the flap will be integrated, sealing in thermal mode (resistivity, ultrasonic, friction, laser) or sealing or cutting one, two, three or four flaps or triangles. Optionally, the flap may be left alone. It can be folded and attached, sealed and attached, or sealed without folding.

2. B1, B2 models of deformation machine:

Step 1: Make an initial container with at least two sides in an inductive and natural way; One, two, three, four, or more flaps or triangles are in every initial container, while the initial container is deformed into a three-dimensional geometric shape.

One or more fixed clamps, or one or more sets or two or more sets of fixed clamps, hold the initial vessel in place by locking, blocking, and / or moving it. (Vertically, horizontally, vertically on one side, vertically on another). It can then be used to shock one side, two sides, or more of the surrounding sides, flap one or two flaps, or hit the corners, two corners, three corners, It happens. At the same time, the initial vessel is swollen or the capacity is increased (in a souffle manner), so we can get the 3D geometry we want.

Step 2 :

To maintain the intended stereoscopic geometry, immediately seal or clamp the flap or triangle to seal or cut. Connect the flap, body and rest of the container at an angle to the flap. Optionally, the flap may be folded and attached, sealed, folded and attached, or left unsealed.

3. 3D container vertical deformation machine C Model:

This machine is designed to place or switch the initial vessel to a vertical position. In addition, all clamps and all of its components are moved and positioned relative to the initial container. Any machine, machine, or invention machine may be added, at least the following parts, devices, and parts.

A) Height adjustable trap door under the initial container, under the clamp, or in the initial container.

B) Fixed bar with two ways of laying down or supporting under the fixed clamp: C) Blocking fence vertically fixed at the top of the small door.

D) A guide clamp is set on a taper of a straight cylinder or a rotating cylinder.

E) sweeping on one edge of the side longer than the small door Brushes .

F) Air trigger to push out the container and flap.

G) Dump Truck Rotating Cylinder / Engine.

H) Linear deformation unit to switch cylinders, clamps or other devices or parts on the side of the machine.

I) Optical sensors such as movement, position, and infrared.

J) Valve to control the movement and strength of the cylinder.

Procedures of the 3D vertical vessel deformation machine:

The initial vessel is changed to a vertical state. For example, standing vertically or lying down, with one side lying vertically or one side lying. All clamps, cylinders, devices, actuators, parts or parts will be part of the vertical conversion machine of the initial vessel of the inventive 3D solid container: they will be in the air support type around the initial vessel. This procedure involves three steps:

Step 1 :

The initial container is placed between the stationary clamp 3 and the vertically standing position. The clamp 3 fixes the initial container accurately in the transverse direction so that the container or a portion of the container is approximately the same up and down. Next, the clamping clamp 3 fixes and holds the initial vessel at a constant pressure (by putting the liquid or the air / gas contents itself or the end of the initial vessel or one side end of the vessel) (by means of the impact clamp 6 Fix the cushion together with the cushion to increase the volume of the container when swollen or to relieve it when swollen.

- Clamps or two or more fixed clamp sets (3) - Clamps required for each machine - are propelled by straight cylinders (9) or rotary cylinders (16) or double effect cylinders and double tappets. Depending on the position (whether standing vertically, standing sideways, lying down, or standing at an angle), the clamping clamp (3) may be placed in a different shape. From bottom to top vertically or vice versa, from left to right horizontally or vice versa.

- In all conversion procedures of the initial container, the clamping clamp (3) will hold or hold the container untied. Finally, when the container is switched to the desired shape, such as cubic, rectangular prism or irregular polyhedron, it will only release when the desired flap is sealed, sealed and cut.

Step 2 :

The initial container may be cubic, rectangular prism, irregular polyhedron or three or more faces.

This is obtained when the clamping clamp 3 hits one side or two sides (the other side or the other side) of the opposite side or the edge-corner-top of the initial vessel. It is therefore inflated, so that a 3D stereoscopic shape can be obtained as desired, since it results in the creation of one, two, three, four or more flaps or triangles, and naturally when the initial container hits the clamps 6 have. Each flap made can be independently inflated individually in a soufflé manner of the container and can be sealed or cut independently of the flap.

The impact flap 6 is propelled by a straight cylinder or rotary cylinder 16 (pneumatic or electric) and is located above and / or below the initial vessel and / or to the left and / or to the right. And then immediately the sealing or sealing and cutting clamps 8 are connected or struck at the sides of the impact clamp 6. Therefore, one, two, three, four or more flaps / triangles already made are sealed or sealed and cut.

4. D model to transform machine with robot:

Step 1 : Create an initial container with at least two sides in a natural way: one, two, three, four or more flaps or triangles are in all the initial containers, while at the same time the initial container is a three- Shape.

The robot handle, together with the clamping clamp, catches or blocks the initial container and also presents or steers it. It therefore forms more than one side or corner of the initial container: one or two floating and / or mobile impact clamps that produce one or two flaps, and / or against / in / against.

The initial container is caught in either the center or the center, or the side on which the flap or triangle shape is made and / or the side end or side opposite. This clamp can be of any specific width and length desired to make a flap or triangle, depending on the width: larger than the impact clamp width, the larger will be the flap. Therefore, while creating more than one flap or triangle, the initial container has at least two sides: the part will be inflated (larger than the flap, greater than the container capacity, while the package size is smaller, . By transforming the container in a natural way, the initial container can be made into a stereoscopic geometric shape.

Step 2 : A flap or triangle is made, or it is made in the following way: it is adjusted with two seals or a seal and a cutting clamp, which seal one, two, three, four or more flaps / It will be sealed and cut. Optionally, the flap may be folded and attached, sealed, and left sealed without folding or folding.

5. E model of two robot deformation machine:

Step 1 : Make an initial container with at least two sides in an inducible, natural way: one, two, three, four or more covers or triangles are in every initial container, .

The first robot has its own robot handle or one or more fixed clamps. The second robot is attached to any part, device, or part of a deformation machine that makes the initial container a 3D container of the invention, as well as clamps of one, two or more double / triple / quadruple clamp sets.

The first robot on the 5/6 axis has the function of guiding the initial vessel to a specific fixed location or guiding it to the correct position (also, if the robot is used in a deforming machine, it can rotate the container itself, From side to side). Once the initial container has been caught, made, blocked and / or immobilized, it may have an adjustable cushioning function.

Three robots can also be used: one robot can grip the initial container and prevent it from guiding and / or moving, and the other two robots can be used as a set of clamps for the robot handles and strike with impact clamps on the side of the initial container In front of the robot).

Step 2 : The same procedure as described in the previous section to transform the machine into a robot.

6. Procedure for making flaps or triangles that are later attached to the container body or the rest of the container already obtained in 3D geometric shape:

This procedure is divided into two phases:

Stage 1 : One or more shock clamps (6) bump against each other at / against the midway point (which is the desired part between two corners or edges). (Leaving only the desired point of one of the corners or corners), the end point (with only the desired vertex or corner portion), or the finished point (completely collided), or vice versa, In this way, one or more flaps or triangles or one or two flaps or triangles by each side, and also simultaneously immediately inflate the initial vessel and increase its capacity. This is because the package size of the initial container is small and the contents in the container are kept the same amount (depending on the size of each clamp or triangle formed because the flap becomes large and the deformed capacity becomes large). This happens in a natural way, so the initial container is transformed into a 3D geometric shape with more than three faces as desired.

Step 2 : Immediately after the desired flap (s) or triangle (s) are made, the initial container is obtained in the stereoscopic shape that we want to obtain, because the flaps or triangles (as many as we want) are permanently folded And is attached to the rest of the container. Optionally, the flaps or triangles (at the intersection of the flaps and the container) can be sealed with one or more sealing clamps before the flaps are attached to the container.

7. Procedure for folding an empty container into a three-dimensional geometric container:

An initial vessel having at least two sides can be transformed into a three dimensional geometric vessel having only air and / or gas therein. This is a modification / adaptation to a vertical / horizontal packaging machine for making the initial container, and is nowadays part of the market for liquids (liquids, agriculture and / or air / gas) and solid / powder / Gas) is packed or filled only in the interior of the initial container. Next, this initial vessel will be deformed into the desired three-dimensional geometry, leaving air and / or gas in the vessel and folding itself in this manner. It will then be packaged and eventually transported to another manufacturing plant to fill the desired target.

- It also attaches to the top of a container of the same type as the "input cap" of the terabit brick type, which makes it easy to actually fill / pack containers and empty the geometric geometry of the air.

In any case, these caps are optional. This is because it only introduces the neck part into which the content is put, or in some cases it can be made in advance. So the filling machine is vertical, making a hole in the plastic neck. Because you can introduce what you want to wrap by it later, and once you have finished filling it, you'll have to seal or seal the neck with this hole.

8. Welding lines of vessels and inventions already transformed into stereoscopic shapes.

- Surrounding weld line (1)

In the invention, any vessel transformed into 3D has at least one or more peripheral weld lines, whether vertical, horizontal or other angles. These weld lines 1 lie along a vessel that has already been deformed into a three-dimensional shape in 3D: center of the vessel or half or center of each face of the vessel. Therefore, when the container is cut along this weld line 1, it is always divided equally into two parts in half. In this way, the container is divided into two and is placed vertically standing: one on the front face of the 3D transformed container that you are already trying to get, and the other on the back face of the container. These weld lines 1 may be associated with an initial vessel: at the side periphery 1 of the initial vessel. One, two, three, four or more sides (1) in each container are when the initial container is irregularly shaped, is not cubic, or is not a right angle prism.

- Vertical weld line (2)

The vertical weld line 2 is the result of sealing, sealing and severing a preformed flap or triangular shaped body. It will be as many flaps or triangles that can be made in the initial vessel and in each 3D vessel modifier. The weld line (2) is perpendicular to the peripheral side or weld line (1).

Is more optimized when it is sealed, sealed and cut at (approximately) the point of intersection between the flap and the rest of the container. These weld lines 2 can also be made by other methods. For example, you can create many lines in different directions with straight, oblique, curved, semicircular, elliptical, concave, convex, corrugated, saw blade, desired angle and shape.

Also, if you start with an initial vessel sealed to the outside perimeter from the center of the weld line 2 when making the flap, you will see it marked vertically on this weld line (1). This is because the peripheral weld line 1 intersects the vertical weld line 2 (when a vertical / horizontal fill machine is made which creates an initial vessel having at least two sides) when making sealing or sealing and cutting of flaps or triangles .

- Edge weld seam (3)

The vessel modified in the 3D of the invention may have at least one edge weld line (3).

These weld lines 3 can be horizontal, vertical or inclined at different angles and are always placed or positioned at the end or side of the vessel which has already been deformed in 3D. These are done with two sets of pinching clamps 19 holding the desired portions of the edges, which remain as a result of the weld seam by the desired burr / flap amount. These welds are optionally performed after the initial vessel has been transformed into a 3D shape.

These seams 3 also serve to provide strength and consistency to the container.

- Termination weld line (4)

The vessel modified to invention 3D may have at least one or more termination weld lines (4). In the initial vessel, this weld line (4) is located at the front one and / or the other one on the back side, precisely in the middle part, from top to bottom, from top to bottom, if we look closely at the container.

These weld lines 4 are located in a container that has already been deformed in a three-dimensional geometry (vertical position and side view when the container is viewed in detail). One is on the front side and / or the other on the back side, which is the vertical position (or other vertical oblique angle). To be precise, it is at the midpoint vertically from top to bottom or top to bottom.

- Multiple welds (5).

The vessel modified in the invention 3D has at least one or more multiple weld lines 5 at a vertical, horizontal or other inclination angle. The weld lines (5) are in a container that has been deformed into 3D already in 3D, either on the side or top side, on one side and on both sides, on the support base, or even on the side edge at the bottom part of the 3D container. These weld lines 5 may be in the initial vessel: it may be on the peripheral side, but the upper peripheral side and / or one side of the side portion and the other part of the initial vessel are further optimized when sealed and cut. The peripheral side is the lower side of the initial vessel, which can be sealed, sealed and cut. In most cases, it is sealed, sealed and cut, since this side will later be supported (when the initial container is deformed in 3D), mounted on a 3D container, supported on a stable basis, or used as part of a face.

These multiple weld lines 5 may show different shapes. For example, it can be created as desired in a straight line, a diagonal line, a semi-circle, a curve, an oval, a convex, a concave, a waveform, a saw blade, and several different directions and angular shapes (straight lines, waves, curves, semicircles).

Other procedures or techniques of the invention

9. Multiple clamps for sealing and cutting

The procedure of the initial vessel with at least two sides will be transformed into several different stereoscopic shapes. Because of its complex polyhedral shape, it is transformed into a unique and special container, and in most cases superior neck and / or tip / apexes are made in a dispenser manner, which dispenser is made from a burr or peripheral flap Tear the gap so that the contents can be poured in the initial container.

It is therefore only necessary to carry out the initial vessel - this also means that once the initial vessel has been deformed, the flap side is never selected or sealed or cut with two sets of clamps (one is sealed and cut and the other is initialed with an impact clamp or a general clamp One or more parts of the container or the transverse portion of the top of the initial container (you may add it to any side of the bottom or any other side of the initial container), if the initial container is a square rectangle Two or three sides are adjustable and can hit. If it is not and the initial container is irregularly shaped with four or more faces / corners, more faces can be adjusted. Sealing and cutting in various different shapes and combinations can be performed between different line types. Other line types include diagonal, straight, curved, curved, elliptical, diagonal, serpentine, and saw. In addition, it can be circular or made to the desired size, which can be used to make holes in containers that have already been transformed into a stereoscopic geometry.

- The procedures and procedures described in the Preamble section - in the same way - are two sets of clamps and packs of vertical fills and packages to produce an initial container with at least two sides of the type of clamps of various shapes and orientations Lt; / RTI >

10. Shock and multi-sealing or sealing and cutting clamps.

The sealing or sealing and cutting of the flaps or triangles is generally transversal and is performed in the connection area or line where the flaps and the container body or the rest meet together. This can be not only a straight line, but also a slant, a curved line, an ellipse, a semicircular shape, a concave shape (when viewing a corner from inside) or a convex shape (when viewing a corner from outside), and a top end shape. Depending on whether you make one choice or another, you may have only four, or only one, two, or three flaps (or a maximum amount can be made). It is assumed that the shape of the container has already been deformed into a stereoscopic shape, and that the container can be effectively deformed even in a different shape and irregular weld line, that is, a three- have. In most cases, the already deformed container changes its shape again (more curved, arcuate, with corner, apex or tip, etc.). The container may retain its original shape without much modification. This means that if we have two types of clamps, sealing or sealing, cutting clamps and impact clamps associated with each flap and triangle, can have an elliptical shape in a horizontal position. Because they attach one to the other so that the four flaps are sealed, sealed and cut, and each flap draws an arc on the outside, rounding the initial vessel of the four sides and two sides in the shape of a rectangle) You can. Thus, the initial vessel is transformed into a three-dimensional geometric shape in a cylindrical or elliptical shape.

11. Release clamp.

We want to be packaged inside the initial container by a process or method that accurately regulates the amount of fluid (liquid / liquid and / or air / gas). Therefore, the package size of the initial container is adjusted and standardized with respect to the amount of fluid (liquid / liquid and / or air / gas) desired to be packed inside the initial container.

- It can be installed with sealing or sealing and cutting clamps, one of which can be slightly more horizontal with respect to the horizontal position and sealing or sealing and cutting clamps. Therefore, it can be carried out in such a way that the two sides of the initial container with at least two sides collide in a manner of upward adjustment. In this way, we can adjust the amount of fluid we want (liquid / concentrate and / or air / gas) to be discharged in the upward direction and also released inside the initial vessel, not yet sealed at the top. Conversely, at the same time, we can release all of the residual foam that may remain in the initial vessel with at least two sides.

12. Flap or triangle to release the clamp.

Optionally, the same system already described in the dictionary section can also be used in one of the flaps or triangles, which is sealed and usable before being cut. By connecting the impact clamp with the seal or seal and the cut clamp. If the clamps (6, 8) are not the same, larger or larger than the size of the cover or triangle, fold the two surfaces or flaps (when connecting the sealing clamps and the sealing and clamping clamps) in a natural way. So that the contents (wrapped inside) that can remain between the two sides of the flap can be released.

Therefore, this process can be provided in a more effective way. Rather, it may be more appropriate because no solids or fluids (liquid / concentrate and / or air / gas) remain in the flaps or triangles.

13. Pinching clamp.

I have also developed a container system or process. Once the container has been transformed into the desired geometric shape (although it is not necessary) it gives more stability, strength, and consistency, and I call this process a pinching clamp as described below:

This is done to perform any edge of cubic, rectangular prism, or irregular polyhedron. There is a fold in the burr and / or weld line which is always left out of the edge. This is achieved with a set of pinching clamps (one is impact and the other is sealed), grabbing on the left and right of the edge (the desired part), so that a burr or weld line is created and remains in the container

As a result of the burr the seal of the container is guaranteed and will remain in the desired millimeter in the container.

14. Multiple Clamps and Straight Clamps.

Clamping devices (or two parallel clamp sets) that seal and cut vertically and horizontally a container (or an initial container) with at least two sides are two different clamps (or two parallel twin clamp sets) of sealing and cutting, The parallel twin clamp set is a parallel twin clamp set that seals and cuts in a straight line in the horizontal position (usually used) and the other of the twin parallel clamps of the seal and cuts will be of the multiform type (if this is different and different shapes, Such as one or more straight lines, one or more curves, one or more waveforms, one or more straight lines with one or more curves, one or more straight lines, one or more straight lines with one or more top stops, two or more straight lines, You can combine any shape with the desired direction and the desired bevel angle. Two or more in an amount or to be more lines, one or more semi-circular and / or oval-shaped concave or convex, at least one elliptical concave or convex in combination with at least one straight line at a desired tilt angle, and so on). These two different twin parallel clamps work together in a crossed and coupled mode method. One after the other, they work with each other in each manufacturing cycle (two parallel straight clamps or three brakes) (1st: 2 parallel straight clamps, 2nd: 2 multiple parallel clamps, 3rd: same 2 Parallel straight clamp sets) are manufactured alternately at the same time: an initial vessel or two different sealed vessels with at least two sides are named "OFF" vessels and "ON" vessels.

15. Secondary light welds with a vertical / horizontal filler machine that manufactures two-sided containers that can be found on the market today.

Although secondary welding is optional, it can be carried out very close (1, 2, 3 mm) to the next or below the peripheral weld line 1 of the outer circumferential line of the initial vessel, .

This secondary light weld can be made with little heat transfer to use less plastic, which can later be used to seal or seal the flaps or triangles. This ensures better sealing and increased resistance at the center of the cross-weld line 2 or the center of the flap / triangle where the two weld lines 1, 2 occur.

Contents of the design

I have prepared the contents of the design to help me better understand the nature of the invention. The design was not restricted to the following, but the way of looking at and explaining the drawings was taken.

Drawing 1: shows machine model [a] in general view.

Drawing 2: shows machine model [a] in detail.

3: Adjustable horizontal cushion: Shown in view of the container holding system with model [b1 / b2].

4: Adjustable vertical cushion: Shows the factory view of the system when holding the container with model [b1 / b2].

Drawing 5: Quadruple / Triple clamp: Shows the factory view of cubic strain machine model [b1] with sealing / cutting and impact.

6 shows the factory view of the cubic-deformation machine model [b2] with a four-line sealing / cutting and impact clamp.

7 shows a detailed view of raising the machine [c] in the 3D vertical transducer.

Between the two-sided initial vessel and the holding clamp 3, the water-sealed inside of the initial vessel is trapped (in the intermediate transverse zone), which is the starting point at which this initial vessel changes to 3D. Each set of triple clamps (6, 8) is connected by a pneumatic or electric straight cylindrical tab. At the same time, the two sets (up and down) are pushed into a pneumatic or electric cylinder with the ability to be connected to the same frame and to withdraw the two triplets aside. Therefore, the space is set so that the initial container can be introduced in the holding clamp 3 (mainly on the holding clamps and on the upper part) whether the robot arm or the machine arm is placed on the conveyor belt or slide so as to place the initial container in the correct place do. In this case the two impacts 6 and the seal 8 or the seal and cut 8 clamps have a triangular prism shape.

Figure 8: Figure 7 shows a detailed view of raising the model [c] machine, but in this case the two impact clamps are braked as if the upper one is below (6) and the initial container is swollen. In this way we get the geometric shape but the four covers have not yet gone through the seal or cut (section).

9 shows a detailed view of raising the model [c] machine and was also added to adjust and support the trap door 10 to the desired height in the initial vessel (with respect to the holding clamp 3). This has a sweeping brush, which helps to keep the cubic containers on the clamps 6, 8 already on the side of the trap door 10 from side to side. The blocking fence 12 allows the initial container to meet at the top and sides of the trap door and stand exactly where it meets the blocking fence 12. At the top, the three sets of clamps are not considered as moving cylinders, allowing free space at the top of the holding clamp / clip. In this case, the impact body is braked (6), the initial vessel is inflated and the cubic shape is obtained in this manner, but the four flaps have not yet been sealed or cut.

10 shows a perspective view of the right prismatic shape and the impact clamp 6 and the model [c] of FIG. 7 and FIG. 8 raising the machine. In addition, a trap door 10 and two fixed bars are added to define the precise location of the initial vessel. Two sets of triple clamps 6 and 8 are connected to the same frame to be braked in the same cylinder and in this way the initial container can be placed without difficulty between the stationary bar 11 and the upper trap door 10 Allow enough space. In addition, the sealing and cutting clamps 8 are attached to the impact clamp 6 in pneumatic or pneumatic mini cylinders that are precisely secured to the impact clamp 6 on both sides (front and rear). The trap door 10 can be opened in the other direction. Two vertical line support is added to the side, allowing support for infrared or optical sensors. The fixing bar (11) will also be used to support the trap door (10) and the holding clamp (3).

Drawing 11: [c] shows a detailed view of raising the model machine. The model machine can only be carried out on both the impact clamp 6 and the two sealing clamps 8 and the sealing and cutting clamps 8 and can not move up and down on all the clamps 6,8. Only the impact clamp 6 can not move with a cylindrical shape (6) (because it can not move). In addition, the impact clamp is fixed to the two pillars (left and right). In this case, they form a crossed shape (left and right) at V (visible downward).

Each of the sealing clamp 8 or the sealing and cutting clamp 8 is fixed to the left and right pillars supporting the entire machine.

The machine has a guiding clamp 13 which is fixed to the tab of the rotating cylinder 16 and moves the container already deformed in 3D to the outside (conveyor belt, barrel, etc.) A holding clamp 3 fixed to the straight cylinder 9 is provided.

Figure 12 shows a detailed view of raising the [c] model machine, [c] model machine performs two sets of rectangular prism shape and triple clamp. A clamp set (6, 8) is attached to the rotating cylinder / motor for the dump truck and a clamp set (6, 8) is fixed to the column at the upper part of the right prism, and a cylinder shape (large initial Lt; / RTI > suitable for containers). At the same time, each of these sets is fixed to the tappet of the revolving cylinder / engine. In addition, an air trigger 15 is added, in this manner, to the outside or the conveyor belt (pushed down precisely) and sent to the already deformed container in 3D.

Plot 13 shows the perspective of raising the [c] model machine with two triplets in detail:

- A triple set is also fixed on the two pillars (left and right) because the impact clamps on the bottom do not move with the cylindrical shape (6) (they do not move). In this case, the two supports (left and right) form a V (crossed down) cross shape.

Each of the sealing and cutting clamps 8 are secured to the left and right pillars supporting the entire machine.

- At the top, the triple set (6) in which the impact clamp moves with a cylindrical shape is fastened to the oblique platform at the highest point. At this time, move the triple set in a vertical cylinder (pneumatic or pneumatic) that moves. And crosses platform 18 with (adjustable) screws at the midpoint and midpoint of this platform (each clamp 6, 8 can follow independently and is independently on the platform). Only the two linear deformation units and the platform allow the free space to be precisely secured at the upper portion of the holding clamp 3. In this way, the initial vessel can be placed at these holding clamps or at the starting point.

The holding clamp 3 is also fixed to the linear deformation unit 17, which causes them to move from left to right and allows the moving container already deformed in 3D to be installed exactly below the conveyor belt, ) Are opened so that the already deformed container in 3D can be deformed so that it exactly falls onto the conveyor belt.

Figure 14 shows the [e] model machine, where the [e] model has a triple or quadruple clamp set (6, 8) on the top and another triple or quadruple clamp set (6, 8) The two are self-adjusting vertically and separated from each other by at least longer than the initial vessel length. In this way the initial vessel can proceed to deform in 3D and is introduced between triple or quadruple clamp sets. The impact clamp (s) 6 of each triple or quadruple clamp set 6, 8 are secured to the tappet of the rotary cylinder 16 and are connected to the sealing of the respective triple or quadruple clamp sets 6, The cutting clamp 8 is fixed to the impact clamp 6. Here, the initial vessel is connected to the top of the impact clamp (6), whether pulled into the air or towed by a machine arm or a robotic arm, to make two flaps. The sealing and cutting clamp 8 then seals these two flaps but does not cut them. The container is thus supported by two clamps (6, 8). In the same way, since the upper impact clamp 6 is fixed to the tappet of the rotary cylinder 16, the container rotates 180 degrees below. Once the vessel is running downwards (with the clamps 6, 8), it is positioned between the two impact clamps 6 of the two sets of clamps 6, 8, which are connected to the impact clamp 6 6) is moved downward (because the rotary cylinder 16 moving the rotary clamps 6 and 6 is fixed at the same time to the rectilinear cylinder 9 in the vertical position) and the impact clamps 6 of the triple or quadruple clamp sets 6, It is possible to make the other two flaps of the container on the vertical side of the bottom of the container against / and /. Thereafter, the sealing of the lower clamp sets 6, 8 and the cutting clamp 8 seal one or two flaps of the lower portion of the container. At the same time, at the same time, the container top flap caught by the clamps 6, 8 at the top will be cut, and in this way the sealing of the clamp set 6, 8 at the top and the cutting clamp 6 will be braked , Will open itself and return to the starting point; The impact clamp 6 of the lower part (holding the two covers of the lower part of the container) and the two sealing and cutting clamps 8 are moved 180 degrees downward (the rotating cylinder 16 moving the impact clamp 6 simultaneously (As it is fixed in the straight cylinder 9 in the vertical position) and in this way it will touch the top of the conveyor belt which hangs down and almost exactly beneath the initial vessel which has already been deformed into the desired geometrical shape. Finally, one or two flaps that have been caught immediately next will be cut and the container finally falls vertically onto the underlying conveyor belt.

15 shows a detailed view of raising the [c] model machine, in which a trap door 10 and a sweeping brush are added 14 and two triple clamps in the upper clamp set 6,8, And is fixed to the tappet of the revolving cylinder / engine for the dump truck. In this way, the initial container gets a space between the holding clamps / clips and the starting point. The sensor 1 feels that the initial container has come in between the holding clamps 3 and in this way the initial container begins to deform into a stereoscopic geometry.

Figure 16: [c] model This shows a detailed view of raising the machine, this [c] model has only a triple clamp set (6, 8). The impact body 6 has a cylindrical shape and is connected to the same tappet of a straight cylinder 6 connected to move up and down so that the container can be moved out of the active area of the holding clamp 3. [ Further, the straight cylindrical tappet is fixed to the rotary cylinder / engine tappet. In this way, rotations of up to a quarter or more are achieved, and in this way the already deformed containers in 3D can be placed comfortably on the conveyor belt or barrel.

FIG. 17 shows a detailed view of raising the [c] model machine, which sets the tappet of two triple clamps, rotary cylinder / engine 16, in the shape of a right angle prism. Wherein the upper cylinder 16 provides a space for the initial vessel to enter into the holding clamp 3 or machine and the lower vessel cylinder 16 has a vessel already deformed into a three dimensional geometric body Allowing them to be placed comfortably in a conveyor belt or barrel.

Figure 18 shows a detailed view of raising the same machine of Figure 11, but in this case a linear deformation unit 17 is added to move the holding clamp / clip 3 from left to right, This new vessel moves when this objective is achieved - transformed into a cubic shape. Clamps 6 and 8 are not exactly above when holding clamp / clip 3 is opened in this way. In this way, the new Cubic container is pushed downward to fall onto the Conveyor belt, which is located exactly below it.

Figure 19: The same container as in Figure 30, but the initial container to be deformed in this case has a rectangular shape, an elongated shape, or a lesser width shape than a square shape. In this way the already deformed vessel in the hull form of the overturned ship is used as the base of the lowest part of the already deformed vessel, either extending further upward or doubling its length.

Figure 20: Same as the container shown in Figure 40, but in this case the initial container to be deformed has a rectangular shape, a smaller width and a longer length than a square. In this way, a container that has already been deformed into a jug with a neck portion is either upwards or twice as high. Further, in this case, both side surfaces (sealed and cut without flap) parallel to the base surface are sealed, sealed and cut together with the twin parallel pinching clamp set, edge weld line 3 .

Figure 21: Container transformed into a rectangular prism shape and a stereoscopic shape. The initial container to be deformed in the future is a rectangular shape (four sides are straight angles) because the bottom portion of the initial container has a rectangular shape as well. The straight line is sealed and cut in a horizontal position on the peripheral weld line (1). Thereafter, four flaps or triangles (weld line 2) are made in this initial vessel, sealed and cut. Two of these are the bottommost sides (or containers with two sides that have already been transformed into 3D or cubes), like the top of this initial container. The edge weld line 3 is also made and sealed with two twin parallel pinching clamps 19 on two sides parallel to the top surface (where the flap is made, cut or unsealed). In addition, the vessel with a right-angled prism shape or the initial vessel to be deformed has a termination weld line 4 at one of its vertical sides. In this case, the initial vessel to be deformed later in a three-dimensional geometric shape was not made with a straight line (1) lying vertically to the left as shown on the right. In this rectangular prismatic container, one side will be lifted above the top of the container to provide space for the contents to be contained inside (more preferably a solid such as a gun, potatoes, or pastry) Will be. In this way, the cover can be easily separated from the peripheral weld line 1 and the edge 3.

22: Two sets of multiple clamps of three linear clamps placed in different directions will seal and cut to two sides of the initial vessel. In this way, multiple forms of irregular polyhedra are created, leaving the end of the container or dispenser neck to be later transformed into a container with a later geometric shape. In this section, once the initial vessel is deformed and two covers are created, sealed and cut from the lower side or portion, the initial vessel will be deformed into a three-dimensional geometry in FIG.

Figure 23a: Initial container with square shape and four sides. A set of two multi-clamp clamps in straight lines that are sealed and cut into two sides. Two covers (left and right) are made and sealed, sealed and cut once they are used as the base of the container. The initial vessel will be transformed into the stereoscopic geometry of FIG.

Figure 23b: A set of multiple clamps (parallel twin only in a straight line in an oblique line) corresponds to the initial container and clamp set in Figure 23a, within which two adjustable sides and two sides of the initial container are sealed and cut will be.

Figure 24: Container deformed into an irregular polyhedral solid geometric shape with a shape similar to a pollen. The initial vessel to begin to deform has an irregular shape (all four sides with an angle are not straight and wider than their height). This is because the lowest part of the initial vessel was sealed and cut into multiple clamps by the part marked with the weld line 5 and two sides. Was sealed and cut to a straight line position from the horizontal position corresponding to the weld line (1). Thereafter, two flaps or triangles (weld line (2)) were made, sealed, and cut from the side used as a base. This is because the initial vessel has been transformed from 3D to geometric irregular polyhedral containers similar to pollen. In this case, the initial vessel to begin to deform into a three-dimensional geometry was not made (although feasible) with a longitudinal weld line (4) and a straight weld line (1)

Figure 25a: A vessel transformed into a cubic geometry of irregular polyhedra similar to the body of a bison / cow. The initial vessel to begin to deform has an irregular shape (all four sides with an angle are not straight, but wider than the height). This is because it is sealed and cut into multiple clamps by the upper and two sides indicated by the weld line (5); A straight line was sealed and cut at the bottom of the initial vessel and placed in a horizontal position on the peripheral weld line (1). Later, two flaps and triangles (weld line 2) were made, sealed, and severed on the side of this initial container that was used as the basis, so this initial container was transformed from 3D to geometric irregular polyhedra, similar to bison or cow- .

Another option - before the deformation - this initial vessel from the very beginning on the top side of the vessel, number 1 (5 times destroyed), has a square or rectangular shape. Sealing and cutting at two sides corresponding to the weld line (5) perpendicularly to the right of the vessel were later performed with multiple clamps. The vessel has already been transformed into a stereoscopic geometry. In this case, the initial vessel to be later deformed into a three-dimensional geometry was neither made to the straight weld line (1) nor to the end weld line (4), even though it could be done.

Figure 25b: The same container as in Figure 25a, but in this case sealing and cutting were performed with multiple clamps one more time. In this irregular polyhedral container, a higher line and an oblique line from left to lower can be seen on the weld line (5). This weld line 5 can be carried out together when manufacturing the initial vessel. Otherwise, it is carried out in an initial vessel which has already been deformed into a stereoscopic geometry.

Plot 26: A container shaped like a dinosaur with an irregular polyhedron or cubic geometric shape. The initial vessel is an irregular shape (all four planes with angles are not straight, they are wider than their height and are closer to a square than a rectangle). As can be seen from the weld line (5), it was sealed and cut with multiple clamps on both sides and above, a straight line was sealed and cut at the bottom of the initial vessel and placed at the corresponding horizontal position at the peripheral weld line (1). Thereafter, two flaps and triangles (weld line (2)) were made on the side used as the base, sealed and cut. Thus, this initial vessel was transformed into an irregular polyhedron with a stereoscopic geometry similar to dinosaurs. Another option is that the initial vessel, which is the first of the sides of the highest part of the vessel to be deformed (the other three of which are 5), has the shape of a rectangle or square. Sealing and cutting were done with multiple clamps in two faces that corresponded to the weld line (5) with a diagonal line (one on the left and two on the right). Immediately afterwards, the container was transformed into a stereoscopic geometry. In this case, the initial vessel to be deformed later in a three-dimensional geometric shape was not made (although it could be executed) with straight line 1 and line 4 welded vertically on both the right and left sides.

Drawing 27: A container that will be transformed into a three-dimensional geometric shape of irregular polyhedra in a similar shape, such as a bottle. The initial vessel to start deforming is irregularly shaped (the four sides are not straight angles, they are wider than their height or close to a square rather than a rectangle). With two sets of multiple clamps, the straight line was obliquely sealed and severed at oblique angles (10 or 15 degrees); At the top (either left or right), the two sides are marked with a weld line (5); A straight line, which is the lowermost part of the initial vessel, was cut and sealed in conformity with the peripheral weld line 1. Then, three flaps and triangles (weld line (2)) were made in this initial vessel, sealed and cut. Two on the lowest part of the base used, and one on either the highest part or side of this container (or the initial container) (left or right). Alternatively, once the container has already been transformed into the same shape and two sets of multiple clamps and a stereoscopic geometry, it can also be sealed and cut. This is to create a straight line or the same weld line 5 in the oblique line at an angle of 10 or 15 degrees, as already explained previously. In this case, the initial vessel to be deformed later in a three-dimensional geometric shape was not made (even if it could be done) with a straight weld line 1 or a longitudinal weld line 4 lying vertically on both the right and left sides.

Drawing 28: A vessel deformed into a three-dimensional geometric shape of irregular polyhedra similar to a house with three vertexed roofs. The initial container to be deformed has an irregular shape (the four sides with each angle are not straight, they are wider than their height and are closer to a square than a rectangle). As shown by the weld line (5), the two lines in the oblique line were sealed and severed by multiple clamps and the highest part and two sides; A straight line was horizontally sealed and cut at the bottom of the initial vessel and matched to the peripheral weld line (1). Thereafter, three flaps or triangles (weld line 2) were made, sealed and cut. Two on the side of the lowest part used as a base, and one on the right or left of the highest part of this container (or initial container). In this case, an initial vessel to be deformed later in a three-dimensional geometry was not made (although it could be done) with a straight weld line 1 or a longitudinal weld line 4 lying vertically on both the right and left sides.

Figure 29: A vessel deformed into a three-dimensional geometric shape of an irregular polyhedron similar to a flying saucer. The initial container to be deformed has an irregular shape (the four angled sides are not straight, they are wider than their height and are closer to a square than a rectangle). Two straight lines in the diagonal line were sealed and severed by the multiple clamps, the highest part and both sides as indicated by the weld line (5); A straight line was sealed and cut in the horizontal position at the lowest part of the initial vessel and fitted to the peripheral weld line (1). After that, two flaps or triangles (weld line 2) were made on the side used as the base (or the lowest part), sealed and cut. This initial vessel was then transformed into a three-dimensional geometric irregular polyhedral container with a shape similar to a flying saucer. Another option is that the side 1 of the highest part of the container (the other two 5) is deformed and the initial container is square or rectangular in shape. Sealing and cutting were later performed with multiple clamps by two faces that matched the weld line (5) in the oblique lines on the right and left sides of the vessel, once the vessel had already been deformed in 3D. In this case, the initial vessel to be later transformed into a three-dimensional geometry was not made (though it could be done) with a straight weld line 1 or a longitudinal weld line 4 lying vertically on both right and left sides.

Drawing 30: Container transformed into a three-dimensional geometric shape of an irregular polyhedron with a shape similar to the hull of an upside-down ship. The deformed initial vessel is irregular (all angles on the four sides are straight and wider than the height). A straight line corresponding to the peripheral weld line (1) was sealed and cut on both sides in both low and high horizontal portions. Thereafter, two flaps or triangles (weld line 2) were made into the initial vessel on the side used as the base (or lowest part), sealed and cut. Therefore, this initial vessel was transformed into a three dimensional geometric irregular polyhedral vessel similar to the hull of an inverted ship. In this case, the initial vessel to be later transformed into a three-dimensional geometry was not made (though it could be done) with a straight weld line (1) or a longitudinal weld line (4) perpendicular to both the right and left sides.

FIG. 31a: A container transformed into a rectangular prism shape and a stereoscopic shape higher than the width. The initial vessel to be deformed is a regular shape (four sides are straight angles). The initial vessel had no rectangular shape at the high and low portions, and a straight line corresponding to the peripheral weld line (1) was horizontally sealed and cut. Thereafter, four flaps or triangles (weld line 2) were made in this initial vessel, sealed and cut. The two are either on the sides (or on two sides of the vessel, or 3D already transformed into a rectangular prism) from both the high and low parts. In this case, the initial vessel to be deformed later into a three-dimensional geometry (together with a straight weld line 1 or a rear weld line 4 on the right and left sides of the initial vessel, But it was not created). You can also attach a lid or straw to this rectangular container. Holes can be made from the top in advance, and you can try the straw where the straw is placed or where the contents are packed inside, such as a drink.

Figure 31b: A container transformed into a three-dimensional geometric shape of an irregular polyhedron with a shape similar to a bottle. The initial container to be deformed is irregularly straight (four sides are not straight angles) (two sides are three times longer than the top and bottom sides). A straight line was sealed and cut with a diagonal line at two sets of multiple clamps and at several bevel angles (10 or 15 degrees). Both sides (left or right) nearest to the highest part as indicated by weld line (5); At the lowest part of the initial vessel, a horizontal straight line matching the surrounding weld line (1) was sealed and cut. Thereafter, three flaps or triangles (weld line (2)) were made in this initial vessel and sealed and cut: two on the right of the lowest part used as the foundation, and one on the right ) Side or the highest part of this container (or the initial container). As another option, it can also be sealed and cut into a set of multiple clamps having the same shape in a container that has already been deformed in a stereoscopic geometry. In this way, as already mentioned, it is possible to create a straight line of oblique line 5 or 10 or 15 degrees of slope. In this case, the initial vessel to be deformed into a three-dimensional geometry was not produced (although it could be done) with a straight weld line (1) or a longitudinal weld line (4) perpendicular to both the right and left sides.

Drawing 32: A container transformed into a three-dimensional geometric shape of an irregular polyhedron having a shape similar to a magic lamp. The initial container to be deformed has a regular shape (four sides are straight angles, wider than the height). It has a square or rectangular shape on both the highest and lowest parts of the initial vessel. A horizontal straight line corresponding to the peripheral weld line (1) was sealed and cut. Thereafter, three flaps or triangles (weld line 2) were made in this initial vessel, sealed and cut. Two on the side of the lowest part used as the base, and one on the side (right or left) or the highest part of this container (or the initial container). In this case, the initial vessel to be later transformed into a stereoscopic geometry was not produced (though it could be done) with a vertical weld line 1 or a vertical weld line 4 vertically on both the right and left sides.

Figure 33: Container deformed into a cubic geometric shape of irregular polyhedra with a cube shape. The initial container to be deformed has a regular shape (four sides are straight angles). It has a square shape at the highest part and the lowest part of the initial container. A straight line corresponding to the peripheral weld line 1 was placed horizontally, sealed and cut. Thereafter, four flaps or triangles (weld line 2) were made in this initial vessel, sealed and cut. The two are on the sides of the highest and lowest parts of this initial vessel (or on two sides of the container, already transformed into cubes or 3D). In this case, the initial vessels that would later be transformed into a three-dimensional geometry were not produced (though may be performed) with the vertical weld line 1 or the vertical weld line 4 perpendicular to both the right and left sides of the initial vessel.

34: Two sets of ejector clamps 20 can be adjusted and operated with a double effect with a straight clamp 9, a rotary clamp 16, or a double tappet. Before operating the two seals and cutting clamps on the two ejector clamps, you can see how the schematic shows how the two ejector clamps 20 have already begun to crush the two sides of the initial vessel. The initial container is exactly in the middle between the ejector clamps 20.

Drawing 35: The immovable impact clamp and the two sealing clamps (8) or the sealing and cutting clamps (8) are self-aligning and located on the left and right sides of the impact clamp and do not move. The two sealing or sealing and cutting clamps 8 can be operated with a double effect with a straight clamp 9, a rotary clamp 16, or a double tappet. You can see how the two designs of the seal (8) or seal and cut clamp (8) to seal or seal and cut the two flaps or triangles work, exactly on the impact clamp and vertically positioned. The sides of the lowest part of the initial vessel are attached between the non-moving impact clamps. In this way, two flaps or triangles are created on each side (left and right) of the immobile impact clamp. This initial vessel can be exactly on the impact clamp or the impact clamp in the following way:

- Strategically drop directly from a vertically filling machine or Conveyor Belt to produce an initial vessel with at least two sides exactly above it.

 - The house is attracted by the forceps of the robot arm in advance.

- Cut off the upper area or the upper part of this initial container and attract to the impact clamp (6).

Plot 36: The two-sided (tube-like) extensional initial vessel is made of a machine that vertically fills a liquid or solid, and is available on the market today. This initial vessel has two seals with two perimeter seams (1) at the top and bottom. In addition, fluid (liquid / liquid and / or air / gas) may be packed with solid or packaged without solid within the container.

Plot 37: shows the view of raising the container with six sides, in this case plastic. In this case there is a weld line as follows: There are two welds (1) on the highest and lowest sides of the perimeter weld line (1) of the initial vessel with two faces in figure 1. It also has four preformed four flaps in the initial container of figure 1, deformed into a container shape with a right angle prism by the deforming machine in the inventive 3D, and four vertical weld lines 2 belonging to the sealing and cutting of the triangle. There is one lid on the top (using a material such as adhesive) to measure the contents inside.

FIG. 38: As seen from the front view, the same view as the right angle prism container is shown, but in this case, the height is longer than the width.

Figure 39: Show the perspective of sealing and raising Cubic containers entirely. It is made of plastic containers with water inside and is small in size because of ice cube. The container is intentionally made of a small-sized seam (or flap-burr), and both the sealing and cutting (2) of the four flaps are two peripheral or center weld lines (1). I do not attach the lid on the top, because I do not put water in the container.

Drawing 40: A container transformed into a geometric shape of an irregular polyhedron with a shape similar to a magic lamp. The initial container to be deformed has a regular shape (4 sides are straight angles, wider). The width of the surface used as a base is equal to or shorter than the height of the container. One straight line was horizontally sealed and cut in conformity with the peripheral weld line 1 at the highest and lowest portions of the initial vessel. Thereafter, three flaps or triangles (vertical weld line (2)) were made, sealed and cut, two on the side of the lowest part used on the base and one on the peripheral side, (Either left or right). In addition, both sides or edges (flaps made or sealed and not cut) are parallel to the underlying surface, with one edge weld line 3 and two pinching clamps 19 parallel at each edge. Also, no lid was attached or added in this case. Therefore, it can be opened by making a gap in the burr part at the end of the container or at the highest part of the vertex. Also, in this case, the initial vessel to be transformed later in 3D into a geometric shape was not produced (although it could be done) with a peripheral weld line 1 or a longitudinal weld line 4 perpendicular to both the right and left sides. Plot 41 shows the perspective of raising a cubic container that is sealed with a rectangular prism (longer than its width) and is elastic and has six sides. In this case there is a weld line as follows:

- two peripheral or center weld lines (1) at the highest and lowest sides belonging to the peripheral weld line (1) of the initial vessel with two faces in figure 1.

 - four vertical weld seams (2) in the transducer of the invention, which are in the shape of a rectangular prism container and belong to the sealing and cutting of four flaps or triangles prefabricated in the initial vessel in figure 1;

- Four edge weld lines (3): vertically located on the sides and edges of four vertically oriented containers with a rectangular prism. On the other hand, there is no lid and there is a straw hole.

FIG. 42 shows the view of raising the container of a right angle prism (height is greater than the width) that is sealed and stretchable with a size equal to or similar to a Tetrabrik® type 1 liter container and has six sides.

There are the following weld seams:

- Two perimeter weld lines (1): There are two perimeter weld lines (1) in the middle vertically on the highest and lowest sides of a vessel that has already been deformed by a rectangular prism. All these weld lines 1 belong to or are shown in the peripheral weld line 1 of the initial vessel with two faces in FIG.

Four Vertical Seams (2): There are four vertical seams (2) belonging to the sealing or cutting of four preformed lids or triangles in an initial vessel transformed into a container with a right-angled prism shape by the 3D conversion machine of the invention.

- Four edge weld lines (4): There are four edge weld lines horizontally at the side (or edge) in the highest and lowest parts where the flap is made, sealed and not cut Dog on the lowest side).

- Four edge weld lines (3): There are four edge weld seams (3) on four sides or edges vertically in a vessel that has already been transformed into a rectangular prism shape.

There is one lid on the top side (like a close adhesive) to insert the contents inside the container.

- Three edge weld lines (3): Three edge weld lines (3) are available where burrs, flaps or clips can be folded, made of two pinching clamps (19). Although you can make it directly from the filling machine vertically when making the initial container. In addition, this edge weld line 3 will provide high strength and stability to the vessel already deformed in 3D. And, one lid is attached to the highest part.

Figure 43: Flexible initial containers with two sides made of machines that vertically fill liquids or solids can be found on the market today. This initial vessel consists of three seals: two perimeter weld seams (1) up and down and one end seam (4). In addition, the fluid (liquid / liquid and / or air / gas) is packed with solid or packed without solid in the vessel.

44 shows the same kind of view as the cubic vessel of FIG. 37, but in this case there is one more weld line. And a termination weld line 4 perpendicular to the center of the plane.

45: shows the same view as seen in FIG. 38, but in this case, there is one more weld line: a termination weld line 4 that is already perpendicular to the backside of the vessel or the front face of the already deformed vessel.

Figure 46: Drawing 39 The same kind of view as the vessel is shown, but in this case the cubic vessel has one more weld line or seal line. (4), which is close to the center of the back or top of the vessel, which has already been deformed.

Figure 47: Shows the perspective of stretching, sealing, and raising cubic containers entirely. There are the following weld seams:

- Four vertical weld lines (2): four vertical weld lines (2) when two flaps or triangles are made and sealed and cut on both the lowest and highest sides of the vessel already deformed in 3D.

- Termination weld line (4): Vertical termination weld line (4) at the back or front half of the already deformed vessel in 3D.

- Four edge weld lines (4): Horizontally (two on the highest face and two on the lowest face) The four edge weld lines (4) are the lowest, where the four flaps are made and sealed and not cut (Or edge) of the plane and the highest plane. There is also a lid for the contents in the container.

Drawing 48: Overall the same view as in FIG. 42 is shown, but in this case one more weld line is added. And a termination weld line 4 perpendicular to the center of the back or front surface of the vessel that has already been deformed in 3D. Also, no lid was attached.

Figure 49: Overall view of the same view as in Figure 41, but in this case one more weld line was added. And a termination weld line 4 perpendicular to the center of the back or front surface of the vessel that has already been deformed in 3D. In addition, a lid-cap is attached to the top of the container for the contents inside the container.

Drawing 50: A machine with two sides and a flexible initial vessel that vertically fills the liquid or solid was created and is available on the market today. This initial vessel consists of four seals: four perimeter seams (1) are horizontally up and down and one vertically to the left and right. Also, a fluid or packaged fluid (liquid / liquid and / or air / gas) is contained in the container with or without solid.

Figure 51: Overall view of lifting a container with six sides closer to the cube than a right angle prism. In this case, the container is made of plastic only and has the following weld seams:

- Four perimeter weld lines (1): There are four perimeter weld seams (1) on the vertical side of the highest and lowest sides, and also on the left and right sides and vertically on both sides. All weld lines 1 belong to and are already shown in the peripheral weld line 1 of the initial vessel with two faces in FIG.

Four vertical weld lines (2): four vertical weld lines (2), which are deformed into a rectangular prism shape in the inventive 3D transducer and belong to the sealing and cutting of four lids or triangles already made in the initial vessel in figure 50. A lid is attached to the top surface (such as a close adhesive) for the contents in the container.

Figure 52: Shows the perspective of stretching, sealing and raising cubic containers entirely. It will also be used as an ice cube in plastic containers that are small in size and contain water in the container. In addition, the vessel is made of a small size weld line (or flap-bar) with four flaps sealing and cutting 1 with four center and circumferential weld lines 1. There is no lid or cap on the top. It is not necessary to follow the water in the container.

Figure 53: shows an expansion view of lifting two sets of pinching clamps, which will seal and sever one of the edges in the vertical of the cubic vessel. Burrs or folds at the center of this clamp are made according to circumstances with a pinching clamp 19, which means sealing and cutting edges.

54 shows an overall view of raising the cubic vessel of FIG. 53, in which two pinching clamps will pick one of the vertical edges of the cubic vessel.

Drawing 55: A portion of the plastic material is used in the package. Otherwise, in a factory that produces containers with at least two sides, both containers are made in a vertical or horizontal filling machine. Two containers with two sides can be connected in a straight line from two diagonal clamps (twin and parallel) to a set of two clamps (twin and parallel), or two clamps (twin and parallel) You can create one periodically. Therefore, one is 'ON' in the initial vessel and 'OFF' in the other vessel. In this case, both containers have the same shape. The container above was sealed and not cut by two straight clamps (twin and parallel) still horizontal.

Figure 56: A vessel deformed into a three-dimensional geometric shape of an irregular polyhedron with a shape similar to the sail of a ship. The initial vessel to be deformed later has an irregular shape (the four sides are not straight angles, they are longer than the width, and are closer to the rectangle than the square). The line was sealed and cut with two sets of multiple clamps at about 45 to 60 degrees diagonal: two on the side near the top (either right or left) marked by the weld line (5). A straight line horizontally in the lowest part of the initial vessel was sealed and cut in conformity with the peripheral weld line 1. Thereafter, two flaps or triangles (weld line (2)) were made, sealed and cut on the side used as the basis (or lowest part) of this initial vessel. Therefore, this initial vessel was transformed into a three-dimensional geometric shape of an irregular polyhedron having the shape of a ship sail. In this case, the initial vessel to be transformed later into a three-dimensional geometry was not made (although it could be done) with a straight weld line 1 and a longitudinal weld line 4 perpendicular to both the right and left sides.

Figures 57-60 illustrate examples of variations that can be made to other configurations that the finished container can accommodate, particularly where sealing lines are made on the flaps or on the outside of the initial container in a modification procedure. For example, one of the faces of the finished container may have two flaps: one or two are sealed and cut. On the other hand, the other side of the front also has two flaps, one or two (not sealed or sealed at the intersection between the flaps and the container) of cubic shape or fully stereoscopic (cube, right prism, irregular polyhedron, etc.) It is attached to the body or the rest of the container with adhesive. In addition, containers can be modified into various shapes that can be left in the manufacturing process with a deformation machine with the same characteristics, one or two flaps or triangles can be made without sealing or cutting and used at the end of the dispenser. Therefore, it can have at least one, two or three weld line types (2) that correspond to two or three flaps or triangles.

Special achievement of invention

Next, the specific achievements of the invention will be explained, so that the above-mentioned data will be supplemented.

According to the first object of the invention, the process of transformation of the initial stretch container into the final stretch container is shown. The initial container may be open or closed. There are at least two sides, an outer and an outer perimeter, at least the peripheral side being partially filled, or at least one being sealed and folded closed. The container may also be partially or completely capable of containing the contents of the fluid, which may be liquid / liquid and / or air or gas and optionally solid / powder / granules.

The procedure of the invention includes the first step. The first step includes applying pressure using at least one of the impact body 6, the rigid body, and the semi-rigid body. That is, by one or more impact members (6) in one or two or more lateral directions of the outer circumferential line, an intermediate portion, an end portion, a partial region, or a front surface . Or vice versa (against the circumference of the clamp / impact body 6 against the side). In this way, you will see if a part of the fluid exits the container or is partially inflated. At least one lid, or the trunk and the outer perimeter of the three-dimensional structure, at the same time, whether there is an affected part, a part restricted to the supporting surface or the base circumferential line, or an outer perimeter. This allows the safety of the container to be measured and the geometrical configuration of the container to be modified. The cover can also be made without changing the final result of the vessel modified in 3D as desired to be obtained one by one, two, three, four or more at a time.

Thereafter, there is a second step, which maintains the same composition obtained in the first step.

There are two alternatives for performing the second step:

The first proposed alternative is to seal one or more of the sides and / or the outer perimeter. The at least one flap or triangular component is provided with an additional surface or circumferential line defined by at least an outer circumferential line at least as a source of heat, using a sealing clamp 8 or a sealing rigid body, a non-rigid body, To keep the face permanently.

It is also possible to cut the flaps or triangular shaped portions to leave burrs and / or welds in the desired millimeter after first performing the sealing. Further, it is possible to carry out a process of folding, attaching and bonding the flap or triangular shape to the body / rest of the container after first sealing.

A second alternative is to perform a folding process on the remainder of the container with the flap or triangular component. Such a flap or such a triangular component may be adhered to the remainder of the container using an adhesive or heat source.

In any case, it is preferred that the sealing of the flaps or flaps be performed at the portion where the rest of the container and each flap meet. Depending on the situation, the flap may be cut thicker, or thinner, or not at all, leaving burrs.

In either case, the first step of applying pressure may be performed so as to attract the impact vessel 6 to the initial vessel. It may be done manually or other automation systems may be used, such as a robotic gripping the container.

On the other hand, as shown in the figure, it is necessary to add pressure inside the container or inside the container to apply pressure to the liquid packed from the inside of the container to the end of the container circumference, in order to transform the container having at least two sides into a 3D container, May be combined. A region that is not adjacent to the peripheral side on which the flap or triangular component is made using one or more holding clamps (3) or one or more holding clamp sets (3) is preferred. The holding clamp 3 is made to be able to enter by the cushion or the like when the impact body 6 is operated. In this way, the container may swell up or change to the desired geometric shape.

Depending on the preferred embodiment, the step of applying pressure includes not only making holes but also the supporting and / or impact surfaces working in different directions and / or the perimeter of the container (6) And pushing and blocking two or more of the sides. In particular, as shown and described in Figures 1 and 2, there are a plurality of, i.e., impact bodies 6 in pairs. There are a pair of impact bodies (6) operating in different directions (usually perpendicular) around the vessel defining the mentioned hole. In this way, flaps are created by pushing the container.

- Depending on the preferred embodiment, the step of applying pressure includes using two sets of clamps or two clamps (one for impact clamps 6 and the other for sealing or sealing and cutting clamps 8). The clamps are self-adjusting, diagonally placed and oblique to the sides (left and right) with respect to each corner, edge or vertex of the initial vessel with at least two sides. The two clamps 6 and 8 are actuated and propelled forwardly into the straight cylinder 9 or the rotary cylinder 16. In this way, two adjacent sides of each corner, corner, or vertex of the initial container are hit or hit against each of them against / and /. This creates a flap or triangular shape.

Thereafter, sealing and sealing and the cutting clamp 8 will seal, seal and sever the flap at the horizontal line or intersection (or approximately) between the flap or container body or container rest. Each flap is independent of the other. In other words, flaps can be made, sealed, and severed one by one, two, three, four, or more.

In this way, larger and smaller flaps or triangles will then appear and be made at the same time, depending on the two sets of clamps (6, 8) and pushed into the sides of the sides close to the corners or edges Will be transferred to the body of the container or to the rest of the container) and will remain outside the body or the rest of the container. Flaps or triangles are formed because one of the two adjacent sides where each corner or corner is made is folded inward or outward until it is connected or nearly in contact with the same corner, edge, or other side of the other side close to the end. Therefore, the flap or triangle is left and left behind the container. (Completely or almost entirely) on the sides or sides of the already deformed container.

According to another aspect of the invention, perfection is shown which shows the sophistication of a three-dimensional vessel. For example, Tetrapack, SIG, ipi, and the like generally contain liquids such as juice, milk, and the like. Also, some fluids are packed with solids. Such a container is obtained from a vertical machine in a sheet of film reel and is filled at the same time. The film of the reel may be folded (to a hole or indentation) to be pre-displayed to facilitate the construction of the container. Generally, the first container body is obtained as a wound film, and then the flap is formed in the container body. When the film is displayed in advance, the flap is predetermined as the folding mark. The invention proposes to treat these flaps in the same manner in which the flaps referred to above are processed. In other words, once the flaps are made by other procedures, proceed to seal these flaps. Alternatively, the flaps may be folded and attached in analog fashion as previously described, or the flaps may be sealed and cut. In particular, the proposed procedure involves the following steps:

- make the container body from the reel film;

- the flap, trunk, or triangle from the body of the container consists of a face and an outer perimeter; It is characterized by the following additional steps:

- In order to seal one or more faces and / or outer circumferential lines, at least one part or one flap or triangular constituent part, a sealing clamp (8) with at least a heat source or a rigid or semi-rigid body So as to permanently retain an additional surface made of a limited part or outer perimeter by the support surface or support line.

And, optionally:

Fold the flap or triangular component into the rest of the container, and

- Attach these flaps or triangular components to the remainder of the container using an adhesive such as adhesive or hot air.

With the same modification procedure as described above, this procedure may also include the additional step of partially or completely cutting at least one of the flap or triangular components using a cutting or cutting tool, such as a blade installed in a cutting clamp

In accordance with a further aspect of the invention, various achievements of the machines used to modify the vessel will continue to be described with the aid of the drawings as described above.

Depending on the performance of the first work, a machine with at least two sides, an outer surface, and an outer circumferential line is opened to open or close the flexible container. At least the peripheral side being partially and completely sealed to contain the contents of the container. (Liquid / liquid and / or gas or air) and optionally solid / granules / powder. The machine can be characterized according to the contents of the machine as follows:

- The cylinder or clamp is fixed according to the means of transport. The means of transport include, for example, one, two or more pillars or one or more platforms 18, one or more straight lines 17 in one, two or more clamp tappets,

- One or more sensors (1) will observe the initial vessel (or other element, part operation of the machine). Once this is introduced and placed between any machine or holding clamp 3 of the invention;

At least one impact clamp or impact body 6, a rigid, non-rigid, movable, ie, straight cylinder 9 or rotary cylinder 16 and / or at least one impact clamp or impact body 6, , Non-rigid, floating. One or more impact members 6 are struck against the outer perimeter of two or more sides of the outer peripheries against / between and / so that when the outer perimeter is pushed in one direction or two or more directions of the outer perimeter, One of the initial vessels, at least one of two or more outer perimeters, or at least one of the perimeter of the sides, is made of a geometric portion of a lid or triangle;

One or more sealing clamps 8 or sealing and cutting clamps 8 (which are actuated with propulsive forces such as straight cylinders 9 or rotary cylinders 16). Seal or cut one flap or triangular configuration segment, even on one or more sides and the outer perimeter segment. As specified in the previous step, a sealing clamp 8 or a rigid or semi-rigid seal is used, which allows at least a heat source to permanently retain the additional surface created in the area or outer perimeter indicated by the support surface or support dashed line .

According to the second achievement, a machine with at least two sides, an outer surface, and an outer circumferential line is opened to open or close the flexible container. At least the peripheral side being partially and completely sealed to contain the contents of the container. (Liquid / liquid and / or gas or air) and optionally solid / granules / powder. The machine can be characterized according to the contents of the machine as follows:

- The cylinder or clamp is fixed according to the means of transport. The means of transport include, for example, one, two or more pillars or one or more platforms 18, one or more straight lines 17 in one, two or more clamp tappets,

- One or more sensors (1) will observe the initial vessel (or other element, part operation of the machine). Once this is introduced and placed between any machine or holding clamp 3 of the invention;

- one, two or more sets (triple and / or quadruple clamps (6, 8)) and / or one (one or two double sets) impact clamps (6) A quadruple set is moved and operated with a driving force such as a straight cylinder 9 or a rotary cylinder 16 (and / or a double linear or rotary effect with a clip cylinder / double tappet cylinder). The impact clamps 6 and the impact bodies of these clamp sets 6 and 8 are provided on one side of the outer circumferential line, one side in the two side directions, one side in the outer circumferential line of two or more side circumferences, By striking and pressing against the impactor 6, or vice versa, one or more flaps or triangular geometric bodies of circumferential or lateral circumference of the initial vessel are created; And

The sealing clamp 8 or the sealing and cutting clamps 8 are made of at least one of a surface and / or a portion of an outer circumferential line, at least one flap or triangular constituent, using a sealing clamp 8 or a rigid, Seal or seal and cut. It has at least a heat source and can permanently maintain the area indicated by the additional surface or circumferential line on the outer circumferential line between the sealing clamp 8 and the impact body 6 being selected as follows:

- a shock body (6) arranged with the sealing clamp (8) and the sealing clamp;

- an impact body (6) intermediate between the two sealing clamps (8) and the sealing clamps (8) aligned with the sealing clamps (8), and

- two impact bodies (6) between the two sealing clamps (8) and the middle of the sealing clamps (8) aligned with the sealing clamps (8).

Two clamp sets (triple and / or quadruple (6, 8)) and / or (one or two double clamps) are aligned or aligned and there is at least a minimum separation between them. A container or an initial container is introduced between them and optionally also a small door 10 (operated by a straight and / or rotating cylinder) is located exactly under the holding clamp 3 of the initial container. Therefore, before the initial container is deformed, the trap door is adjusted to the height where it is used as the base, and the initial container is placed at the desired height. In this way, the holding clamp 3 grips the initial vessel, holding the initial vessel, which is located close to the center, the edge, or the side around which the lid or triangular geometry is made.

According to the third achievement, a machine which deforms into a flexible container is shown, wherein one, two or more additional holding clamps (3) or one or more sets of two or more clamps or holding clamp pairs (3) . In this way, pressure is applied to the inside or the inside of the container to move the fluid (packaged inside the container) to the end of the outer circumferential line of the container and the holding clamp 3 in the area not adjacent to the area of the flap or triangular component To help form the flap or triangular geometric body when the impact body (6) is operated.

According to the fourth achievement, a machine is shown that deforms the open or closed stretch container with at least two sides together with the outer surface and outer perimeter. There is at least one peripheral side, at least partially filled with the contents of the container closed and sealed. The container contents may include a fluid (liquid / liquid and / or gas or air) and optionally a solid / granule / powder, wherein the machine is characterized as comprising:

Two or more pillars or one, two or more platforms 18, one, two or more straight transmission units 17, At least one cylinder or at least one clamp;

At least one sensor for sensing the performance of the initial vessel and / or machine;

- a triple or quadruple clamp set (6, 8) (or two double clamp sets (6, 8)) on the top, and

- a set of triple or quadruple clamps (6, 8) (or two sets of double clamps (6, 8)) on the bottom, a set of clamps (6, 8) on the top and bottom, There is a minimum separation between them. The already deformed container or initial container can pass through or enter the two sets of clamps 6,8.

The impact clamp 6 of each set [(triple and / or quadruple) and / or one or two double sets] is fixed to the tappet of the rotary cylinder 16 (this double / triple / quadruple set The impact clamp 6 of the linear cylinder 9 may or may not be fixed to the tappet of the rectilinear cylinder 9 which is vertical. And the sealing clamp 8 or the sealing and cutting clamp 8 of each triple / quadruple of clamps 6, 8 is fixed to the corresponding impact clamp 6.

Here, the initial container is hit, and one or two covers are made at the top of the impact clamp (6) whether it is dropped into an open space or driven by a mechanical arm or a robotic arm. Thereafter, the sealing or sealing and the cutting clamp 8 are operated to selectively hold the formed flap but not cut (sectioned). Therefore, the container is caught by both clamps 6 and 8, and immediately after this method, 180 占 (since the impact clamp 6 is fixed to the tappet of the rotary cylinder 16) does not fall downward, and then another parallel side (Or vice versa) against the other impact clamps (6) on the underside.

As a result, a flap or triangular geometric body can be formed on both sides and the other can be sealed, sealed and cut by a seal 8 or a seal and a cutting clamp. Optionally, the flap may also be sealed, glued, folded or attached.

Once the initial container has been transformed into the desired 3D geometric body or shape, the impact clamp will place the container on the conveyor belt, barrel, and box below 180º.

This 3D transformation machine is further optimized when used with large initial vessels. For example, when a liquid or a broth is packed in half-liter, one liter, and two liters.

The machine can integrate with the vertical column where two sets of clamps (double, triple, quadruple) are fixed and the impact clamp 6 of one clamp is connected to the tappet of the rotary cylinder 16. This forms a straight line angle relative to the column and is fixed in the horizontal position. This cylinder rotates 180 degrees or 360 degrees. The two sets of clamps are perfectly aligned with the others symmetrically below. The distance between them depends on the height of the initial container standing vertically. That is, the initial container must be able to be fixed or passed between these two clamps without touching the set of clamps. There is also an optical and infrared sensor 1.

The container to be obtained is an additional object of the invention according to the method proposed above and the achievement of the special achievement of such a method for the modification of the container includes the first step or the pressure step of determining the flap and the following:

- folding the flap and attaching / bonding the flap to the rest of the container;

- seal the flap;

- After sealing the flap, fold the flap to the rest of the container and attach / bond;

- Seal the flap and then fold the flap.

The resultant container may differ in that the vertical sealing line 2 seals the perimeter or outer circumferential line of the initial container according to the contents depicted in the drawings as different achievements are seen.

A vertical machine model that transforms an initial vessel into a vessel with a three-dimensional geometry.

Step 1 :

The initial container should be placed in a vertical position between the holding clamps (3). The holding clamp (3) (working with a clip cylinder or two straight cylinders (9) or double tappet or dual effect) will hold the initial container at the desired location and will not move, I prefer the portion of the container or the center portion (or near) of the initial container.

Other methods are also performed:

A) The Conveyor Belt carrying the initial container is properly connected so that it can be rotated sideways to the side when the subject is correctly placed under the Conveyor Belt and blocks the course. In this way, the initial vessel remains vertically but still on its side.

Then, a second straight conveyor belt (which does not rotate and also has a stiff bar or a high surface on each side and a sufficient height so that the initial container can always stand vertically without tilting to either side) It is running on the side of the belt, so that this initial vessel can be received vertically but laterally.

- Next, it will be in the vertical position (as it is already), ie the same horizontal position as the lever so that it can stand, not on the side. They rotate by about a quarter when the lower part is blocked by the remaining bar lying horizontally relative to the second conveyor belt.

- Once the initial container is in the vertical position, it will be stacked and will eventually fall or lie precisely between the holding clamps (3) when the trap door is opened (10). In addition, the initial vessel can be dropped vertically into a second conveyor vessel with a separator and / or pedestal.

B) The initial container transferred horizontally on the first conveyor belt will be pulled directly by the 5/6-axis robot arm-gripper. In this way, the initial vessel can be placed exactly in the holding clamp (3) (working with a clip cylinder or two straight cylinders (9) or a double tappet or double effect) or used as a human hand or a 4/5 / So that the upper portion of the initial portion is picked up and placed between the holding clamps 3.

 - You can choose either:

The height adjustable trap door (10) will be in the machine or under the holding clamp (3). This trap door only has the ability to place the initial container at the correct height. Accurately, the holding clamp 3 moves precisely to the center or intermediate portion of the initial vessel in the vertical position, so that the same amount of the initial vessel remains above and below the holding clamp.

 (A) The trap door is essential in the option.

 (B) option does not require a trap door - although you can have a trap door - Robot arm movement is introduced up to the millimeter (computer and digital camera introduced parameters), so the exact position (left or right) and accurate It can be easily found that the robot holds the retained initial container and later the holding clamp 3 (working with a clip cylinder or two straight cylinders (9) or double tappet or double effect) .

Step 2

The impact clamp 6 acting on the holding clamp 3 in this machine or under the initial container and / or on the straight cylinder 9 or the rotating cylinder 16 is actuated obliquely and diagonally, The initial vessel will be transformed into a stereoscopic geometry.

- thereafter the sealing or sealing and the cutting clamp 8 will operate. In this way, one, two, three, four or more (the initial container to be deformed has an irregular shape than four corners) will be sealed or sealed and cut / sectioned. (It can also be done by folding or folding / attaching one of the flaps or triangle to the body or the rest of the container)

In this way, the already deformed container will remain in the stereoscopic geometry desired to be obtained.

- The two clamps (6, 8) can be fixed on / on the same frame or they can be separated separately.

In either case, it will be placed in the following way:

The impact clamp 6 can be fixed or attached to one or two posts that are directly at a vertical / horizontal / different inclination angle. Conversely, the clamp is fixed to the straight cylinder 9 or the rotary cylinder 16, And can be fixed or attached to both tappets of the rotary cylinder 16 and the rectilinear cylinder 9 of the platform 18 operated on the conveying unit 17 such as a sash.

The sealing and cutting clamps 8 are connected to the impact clamp 6 by a double tappet or double effect or clip cylinder or straight cylinder 9 attached to a platform managed by two linear transmission units, Can be fixed or attached to one of the pillars at different inclination angles. Conversely, the clamp 8 may be fixed or attached to two tappets of a straight cylinder 9 or a rotary cylinder 16 such as a frame or a chassis fixed and attached to a rotary cylinder 16 or a straight cylinder 9 have.

On the other hand, both clamps may also be attached to the same column.

- If another clamp set (6, 8) is attached, but not on the same frame, it will be associated with the initial container in the following way:

The double clamp set is placed diagonally at the end of the initial vessel and consists of an impact clamp (6), a seal and a cutting clamp (8).

The triple clamp set lies parallel to the weld line, edge, and sides of the two sides of the initial vessel (one on the top and one on the bottom). It consists of an impact clamp 6 in the center and two sealing and cutting clamps 8 on the left and right sides of the impact clamp 6.

The triple clamp set is located on the front and parallel to the weld line, edge, and sides of the two sides of the initial vessel (one on the top and one on the bottom). This consists of two shock and mini clamps (6) connected in between and between them, two seals and a cutting clamp (8) on the right and left sides of the clamp (6).

They work in the following ways :

Immediately after the first step, the impact clamp 6 is actuated by a cylinder or an actuator (straight or rotating) so that the portion near the four corners of the initial vessel below and / or above the initial vessel and the middle region / Will be attached to / over the stomach.

An adjustable cushion system, such as a spring, is connected between the tappet and this clamp (6) connection to ensure homogeneity of the container produced. In this way, since the impact clamp 6 is hit against and retracted against the holding clamp 3, this clamp 6 will always remain in the holding clamp 3 and be attached. In this way, the clamp 6 will be pushed by the amount of the sides of the initial container or the amount of the interior.

- Each time a hit occurs, one or two flaps or triangles are created for each impact clamp (6), and at the same time the initial container is swollen like a souffle. Thus, a stereoscopic shape desired to be deformed is obtained.

Therefore, the size of the flap is determined depending on how much the impact clamp 6 pierces the interior of the initial container. So we can get deformed containers bigger and more stereoscopic. Conversely, the package wrapping the container will be small. Also, since the larger flaps are made, sealed, sealed and cut, the initial container is deformed into a smaller 3D geometric shape that widens wider and wider.

In addition, other factors may also be affected, such as the width of the impact clamp 6 (larger width = smaller lid) in relation to the width of the initial vessel, the solid / granule / powder or solid (Liquid / liquid and / or air / gas).

In either case, the impact bump action will occur with the impact clamp 6, and in the same way, the initial container will naturally swell like a souffle and will be sealed, cut and sealed independently of other flaps or triangles.

The impact clamps (6) will be carried on both sides and at the ends of the clamp (8) based surface. Rubber or other materials will ensure the high performance of the system or the welding method to be used.

- Impact clamp (6) can be of two kinds:

1) One set.

2) You can align yourself with two separate sets and attach one to the other in one of the following ways:

(a) Two or more fixed ends are connected to both sides (6).

b- Double tappet and double (6) connection to pneumatic or electric mini cylinder. In this way, it moves out and opens (until it comes in contact with the sealing and cutting clamps 8, which are precisely positioned and aligned). It works without folds or wrinkles that form in the area of the line or container connected between the flap and the rest of the container, so that the flap is well formed. This also helps flaps form or complete well. At the same time, it helps to push the fluid (liquid / broth and / or air / gas) out of the flap, with or without solid.

- The impact clamp 6 can also be attached to the surface or to the outer side. Where the impact clamp will receive a bump impact from the milling and cutting clamps. If welding is used without rubber, other materials can not guarantee that the system performance, method or operation is good.

- but in any case all kinds of impact clamps (6) have the same purpose: they make the flap and deform the container into the desired geometrical shape and serve as the backing surface for the sealing and cutting clamps (8). Also, if the clamps 6 and 8 are not connected to the same frame, the impact clamp will point to where the seal and cutting clamp 8 are positioned (so that the line can be aligned).

Momentarily and at the same time the sealing clamp or the sealing and cutting clamp 8 will be operated as an actuator or a straight cylinder 9 and / or a rotary clamp 16 or a pneumatic or pneumatic clip cylinder. With this method, the impact clamp 6 is hit against or bumped against the bumper 6, 8 at the same time, and the lid is then held between the clamps 6 and 8 and then heated by a heat source or welding system (resistance, ultrasonic, laser, ) The flap will be sealed and cut. In 3D, the remaining portion of the vessel that has already been deformed into a three-dimensional geometry and the horizontal line, side or portion of the intersection of the flaps are preferred.

Flap cutting can be done using a blade.

This clamp 8 can also be performed between the tappet and the clamp itself. The cushion system can be connected or hammered against the impact clamp 6 in a spring-like manner. This may also be at the end of the tappet, which may be fitted or introduced into an empty hemisphere lid or cushion (smaller than half of the empty sphere) and secured to the sealing clamp 8 or the back of the seal and cutting clamp 8 will be.

- The holding clamp (3) always holds the container in all the processes. It is released only when the container has already been deformed into the desired geometric shape.

- All kinds of clamps, elements, devices or parts, or the machine can be adjusted as high as a straight line.

- Clamps (6, 8) or sets of double, triple, quadruple clamps or all flaps or triangles can be operated or sealed by themselves - as many as the number on each machine - simultaneously all independently, one, two, three, four , More than that. This does not at all affect the end result of the stereoscopic vessel we would like to initially have.

- It may also be added to this vertical deformation machine of the initial vessel in 3D. Or combinations of at least two of the following elements, devices, components, or clamps:

A) Trap door (10): The trap door lies under the holding clamp (3) of the initial container and is used as a supporting base for the initial container. (Different height), the holding clamp 3 is used to precisely align the center portion or midline (equally horizontally divided) of the initial vessel in a vertical position.

This actuates the pneumatic or electric cylinder 9 and the pneumatic or electric rotary cylinder 16 to be fixed to one of the pillars.

B) Fasteners (11): Fasteners determine the precise location of the initial container.

In this way, the initial vessel is clamped in the holding clamp to help seat it before it is pressurized, allowing the bottom of the initial vessel to be perfectly vertical without breaking or bending.

It is only necessary if the initial container tends to fold or bend. It does not matter whether it is made up of several gauges (50-60), or the size of the initial vessel is significant, and whether it is one-liter or half-liter in weight.

C) Lock Bar (12): The lock bar helps the initial container, placed on the top and side of the trap door, and the initial container should be in the correct position indicated by this bar. This system is used to prevent the clamps 6, 8 from moving forward or backward on the holding clamp 3.

D) Guide clamp (13): The guide clamp is only used to remove the already deformed container out of the machine in cubic shape. The container remains supported on the lower clamps 6,8. The machine no longer requires a device such as the transfer unit 17, the dump truck revolving cylinder 16, or simply a straight cylinder.

The guide clamp 13 is connected to a straight cylinder 9 or a pneumatic / pneumatic rotary cylinder tappet.

The clamp 13 has a straight line or a curve of about 20 占 between the straight line. The initial container, which has already been deformed into a new cubic shape, is pulled out by the guide clamp 13 and falls straight on the conveyor belt, barrel and box.

E) Sweeping Brush 14: The sweeping brush performs the same function as the guide clamp. That is, it functions to push the already deformed container out of the machine in cubic shape. In this case, however, the brush is connected to or fixed to one of the two sides of the trap door 10, which is longer than the trap door 10. They fall.

F) Air Shooter (15): The Aventurator is located below the vertical machine, functioning precisely to push the already deformed container to the box, barrel, Conveyor belt in cubic shape.

It is fixed to the pillar and is at the same height as the vessel already deformed in cubic shape.

G) Dump Truck Rotation Cylinder / Engine (16): A pneumatic or pneumatic cylinder / engine is fixed or attached to one of the columns. It has two functions:

g1) If it is in the upper clamp, it is used to secure the space (rotating upwards) so that the initial container can be introduced between the holding clamps 3 without difficulty.

g2) When placed below the lower part, strike the initial vessel, which has already been deformed into a cubic shape, to cause the initial vessel to turn downward and fall onto the conveyor belt, barrel, and box.

H) Linear transfer unit (17): The pneumatic pneumatic linear transfer unit is attached or fixed to the column. There are two types of functions:

h1 ) Two linear transmission units (17) with platform (18) are parallel and paired to the machine right and left.

Clamps (6, 8) are installed / placed on / on this platform. In this way the clamp (on the top) on one side leaves space so that the initial container is placed in the holding clamp (3). And on the other hand, if two straight transmission units and platform 18 transmit the clamps 6, 8 at the top of the lower part, they seal and cut the already deformed container and the desired flap in a cubic shape, Belts (properly placed under the machine), barrels, boxes and so on.

h2 ) One independent linear transmission unit 17 transmits the holding clamp 3 and simultaneously transmits the initial container. In this way, it is possible to move everything exactly on the clamps of the clamp sets 6, 8. In this way, the holding clamp 3 is opened, and the cubic container is dropped onto the conveyor belt, cylinder and box.

Step 3 [c ]:

The flaps or triangles are already sealed, cut and separated in a container that has already been deformed into a three-dimensional geometry, as follows:

a) Break into a specific place.

b) Drop it directly on the floor or drop it onto the box-box. This is because there is no conveyor belt or protection under the vertical machine. If a vertical machine is equipped with a conveyor belt, the following may be possible:

c) From one conveyor belt to another conveyor belt. The flap is always small and there is enough room to fall onto the floor or cask.

d) Because there is a large hole in the hourly conveyor belt, the flap may fall into the bottom of the cylinder.

- containers that have already been transformed into a three-dimensional geometry are separated in the following way:

a) Drop directly into a barrel or box. This is because vertical machines do not have a conveyor belt or anything to protect.

b) Drop directly onto the conveyor belt. The conveyor belt was installed on the inventive vertical machine side and / or below. The conveyor belts are installed in the linear transfer unit 17 and the linear transfer unit 17 guides or transfers the holding clamp 3 and the container since they are fixed or attached to the transfer unit 17 from left to right to be. In this way there is space at the bottom of the clamps 6, 8, the parts of the vertical machine,

c) drop it to the trap door (10) or drop it directly from one conveyor belt to another conveyor belt, box or barrel.

d) Robot arm clamps or mechanical arm clamps.

e) Attempt to push the already deformed container into the air space by the air shooter 15.

d) Use the guide clamp (13).

A pinching clamp 19,

To create a sophisticated container along with the preferred performance performance, a pinching clamp 19 is added to the outer surface of the container to create at least one line of the edge type 4 by sealing to provide strength and stability of the container.

They fold or bump into any edge of a container that has already been transformed into a stereoscopic geometry. A burr or flap is made out of the edge and then the set of all two pinching clamps seals the burr and the flap from the edge. Optionally, the burr may be sealed, cut, sealed and attached at the end of the vessel.

- The purpose of this technique and process is to provide high consistency and stability to vessels already transformed into stereoscopic shapes. But this process is not necessary. Without this optional process, the vessel is already safe, consistent and self-sustaining.

- Two sets of pinching clamps (one for impact and one for sealing and cutting), respectively, can usually be operated and performed similar to the movement of two sets of clamps. It is also possible to perform a movement similar to a regular clip.

These pinching clamps 19 will be gripped and held between the two pinching clamps at either edge of the container once the container is held and can not move and deformed into a stereoscopic shape. Thereafter, the two pinching clamps 19 connect both sides of the edge and the housing / seal is sealed, sealed and cut at the desired edge / burr. The pinching clamp set 19 can be moved and operated in the following manner:

6.1) by means such as one or more straight cylinders (9) or rotary cylinders (16) or clips in a straight line in front of the edges.

In this case there are two possible actions and moves:

6.1.1: Two sets of pinching clamps (19) placed in front of either edge can be moved forward (as desired) to strike two sides / sides close to the edge. One of the two pinching clamps 19 is fixed to the tappet of the straight cylinder 9, and at the same time, the two straight clamping cylinders are connected to the straight cylinder 9 Since it is fixed to the tappet of the rotary cylinder 16]. In this manner, a burr or flap is formed and the burr or flap is sealed or sealed and cut, leaving only the desired millimeter.

However, this is also optional. Once the two clamps 19 hold the flaps or burrs before the flaps or burrs are sealed, sealed and cut, the two clamps can go back and stretch the flaps or burrs to fit the purpose. This way you can stretch more flaps or burls without wrinkles or folds.

6.1.2: The two sets of pinching clamps (19) are exactly aligned on one side of the edge, so that they can be two sides or two sides close to the edge. So you can make a burr or a flap. Immediately thereafter, these two parallel pinching clamps seal, seal or cut the burr or flap, leaving as many millimeters as desired. One of the pinching clamps 19 can be fixed or attached to the tappet of the straight cylinder 9. [ Otherwise, it can also be fixed or attached to a double-tappet, dual-effect, straight cylindrical tappet.

However, this is also optional. One of the two clamps 19 can hold the flap and burr before the flap and burr are sealed, sealed and cut, and the two clamps can go back and stretch the flap to create the intended flap. In this way, the flap can be stretched without wrinkles or folds for better results.

6.2), but it can be propelled by means of a double effect with one or more straight cylinders (9) / rotary cylinders (16) and / or double tappets. A double-tappet and dual-effect cylinder or otherwise two clamps 19 are provided between the clamp 19 and the clamp 19, with the two clamps 19 in the middle, and between the clamp 19 and the back, Push one and connect two straight cylinders (9) that are vertical. Therefore, while this is going (as much as desired) and striking two sides or sides adjacent to the edge, it can open itself or fully open in advance. In this way, a burr or flap is created, and immediately thereafter, these two parallel pinching clamps can seal, seal and cut the burr or flap, leaving as many millimeters as desired.

However, this is also optional. One of the two clamps 19 can hold the flap and burr before the flap and burr are sealed, sealed and cut, and the two clamps can go back and stretch the flap to create the intended flap.

Following this with the help of the drawing, several preferred achievements can follow. In particular, many attractive containers can be obtained.

1.- Modified containers can be made in an initial container of square or rectangular shape. It is possible to obtain a container in which two flaps are made, attached, sealed, sealed, adhered or sealed and cut, with a bearing surface of a rectangular or square shape.

2. It is made in an initial container of a rectangular or square shape. Not only can three flaps be made, attached, sealed, sealed, adhered or sealed and cut to obtain a parallelepiped shaped container with a rectangular or square shaped receiving surface, as well as one more flap. Contrary to the backing surface, this flap can be made into a dispenser neck or a protruding neck without being sealed or cut.

3. It is made in an initial container of rectangular or square shape. Four flaps can be made, attached, sealed, sealed, adhered or sealed and cut to obtain a parallelepiped shaped container.

4. - Two flaps are made on the opposite side of the oblique side, with the oblique side and the three adjacent sides being made of a rectangular container with a vertical shape. A polyhedral container can be obtained, which has a dispenser neck pointing to the oblique side end, and the supporting surface on the opposite side of the oblique side has a rectangular or square shape.

Finally, there is a particularly exciting case, a set of containers that incorporate the stretch containers already described, while being all described with respect to the invention. All flaps were sealed and cut, and the container was sterilized further and could contain an icable liquid. The container set includes a packaging material for packaging at least one container to maintain sterilization of the container. This means that after each use, the product can be put into a freezer and stored in a product requiring sterilization, that is, frozen food or beverage.

Procedure for making one or more neck parts, ends, or extruded vertices to easily open in a dispenser manner to a container deformed into a stereoscopic geometry:

1.1) seal and cut two sets of multiple clamps (Figures 22, 23 and 24) (one for the sealing and cutting clamps (8) and the other for the impact clamps (6) Works on both sides]. One or more desired portions of the initial container or the top or bottom (also possible on the bottom, or in addition to any surface that the initial container may have). If the initial container is four-sided and rectangular or square in shape, two or three adjacent sides may be trapped or struck. Also, if the initial container has more than 4 sides / corners, it is applied to more adjacent sides.

Multiple seals and cuts, as well as other forms with different types of lines, are possible. For example, bevel lines (figures 22 and 23), straight lines, curved lines, curved lines, elliptical lines, oblique lines, waveforms, saw blades and the like. In addition, it can be round, it can create any size, and it can be used to make a hole to hang a container that has already become a stereoscopic shape.

Depending on the section (sealing and cutting) that has already been done in the initial vessel, a number of other irregular polyhedrons can be created which are very interesting. In addition, since the peripheral weld line (1) in the shape of a letter or object can be defined as an initial container and divided into sections, a letter shape or object can be produced.

Next, let's take a look at the types and shapes of containers:

It can be seen in the schematic or drawings 25/26/27/28/29/30/31/32/33;

There are also some examples of letters, such as <M>, <B>, and <H>; You can also make a crown, which can be made up of two or more corners / ends projecting upward. It is also possible to use a baseball glove, a teapot, a chimney of a steamer, a bottle with a neck, a bottle, a crocodile, a motor yacht, a sail, a neck shirt, a hair comb, a trident, Animals, and a statue of liberty.

The two sets of clamps (8, 6) of the section of the initial vessel with two sides paralleled (not just horizontal straight lines and horizontal lines) sections can have different shapes or can be connected between them with one or more other straight lines You can place it at different tilt angles or in different directions. In other words, it can be connected and fixed to two straight multiple clamps 6, 8 or a desired inclination angle.

You can repeat this many times in as many combinations as you like (you can add a lot of sets of two multi-directional clamps (6, 8)). All two sets of multiple clamps 6, 8 can be straight, curved, oval, curved, oblique, wavy, saw blade,

- This irregular section section and multiple clamps (6, 8) are applied to the initial vessel and affect the final result of the vessel in the geometric shape to be obtained, with the following characteristics:

- Several different shapes or irregular polyhedra shapes of a three-dimensional geometric container can be created and tailored. To create such a container, only two flaps and triangles will be made, sealed, sealed and cut at the bottom of the lower part of the bottom of the initial vessel.

This new and many different designs of containers will be a very important part of marketing. This is because certain brands can participate in robust products. The unique geometric vessel of unique and luxurious design is indeed unique, practical and attractive.

- the upper part of the already deformed initial vessel (one or more transverse sides and also one or more sides adjacent to the transverse), a protruding end / apex / neck part is made, which can be used as one or more of the apex- . In particular, it may flow inside the container with the contents of the fluid (liquid / liquid and / or air / gas) with or without solid in the container, or it may come out of the container.

This gives more consistency and strength to vessels that have already been transformed into a stereoscopic geometry.

- It is possible to remove the contents inside the container and use it cleanly and conveniently. This is possible because of the end / apex / vertex, which makes the container cubic and allows it to come out. What can be placed inside the container is often available in food products such as sauces, jams, honey, syrups, cleaning products and perfumes.

- You can add a method that can be easily opened by creating a small groove at the edge (1) of the apex, end, or corner of the corner that can be made from a container with a cubic geometry or an irregular polyhedron shape. In this way, you can dig a groove and use the contents inside the container. It may also be provided with a dispenser such as a lid, valve, nozzle, aluminum strip, and the like.

Any of the machines modified to the 3D of the invention may be subjected to a dispenser process from the top of the initial vessel to the sealing and cutting sections after the first, second and third stages. In this case, the initial vessel should be performed exactly in the desired position. In other words, the initial container must be placed vertically in the holding clamp 3.

This process can also be performed in a more complex way: after the initial container has already been transformed into a three-dimensional geometric shape with three or more faces, the same type of clamps (6, 8) are used to seal, seal and cut Align and align the desired two sides of the container with one and a mobile impact clamp to seal, seal and cut the selected area.

For this reason, irregular sections or sealing and cutting can be performed on the upper part of the initial vessel, as already explained in the first step procedure of the second (b1) and third (b2) transformation machines. This should be done prior to the start of the first phase of the first (a), fourth (c), and fifth (d) machines. The initial container can be picked up with one or more holding clamps 3 and one or more sets of two or more holding clamps 3 as described in the first step b1, b2.

- As the container in FIG. 28 is shown as a section of the top (or one of the sections) of the initial container (in this case a straight line 2 in the oblique line, as shown in FIGS. 23 and 24) Using multiple clamp sets).

In this way, an irregular three-dimensional polyhedron container was made in the shape of a house with a three-sided roof. The three-sided roof has the uppermost triangular shape. On the other hand, this plane can be divided into three mini-planes with a triangular shape.

In addition, two vertices / vertices / vertices with a slope projecting 45º upward on this same high side and three quarters of the same plane upwards are sealed in two parallel clamp sets 6, 8). There are also two multi-clamp sets (6, 8) with an oblique line that has a vertex, an end, and a vertex protruding to the left in the left portion of the already deformed container, sealing and cutting the vertical side of the left portion of the initial container It is precisely matched to a certain point.

1.2) One or two flaps or triangles of at least two sides of the initial container are made and sealed or sealed and not cut, leaving one or two dispensers on the top of the container, already transformed into a stereoscopic shape, Neck or protruding end - Makes vertices on the left and / or right.

A practical description with two views was used for an initial container of two sides and four sides of a rectangle or square. If you want to get a deformed container with only the dispenser neck on the right, left, and top, make two flaps or triangles on the side of the lowest part of the initial container. And only one flap on the side of the highest part of this initial vessel should be made, sealed and cut to the left or right.

Therefore, we can obtain a container that has been deformed into a stereoscopic shape, as described in the design or drawing 40.

- If you want to get a deformed container with two dispenser necks on the top, two flaps or triangles should be made on the side of the lowest part of the initial container.

And there should be no flaps or triangles made from the highest side of the initial vessel and sealed and cut. Therefore, the point should be left as it is.

Therefore, we can obtain a container that has been deformed into a stereoscopic shape, as described in the design or Figure 30.

1.3) Combine the procedures of sections [1,1 and 1.2] or both methods. In this case, once the initial container has already been transformed into a container with an irregular polyhedron shape with one or more ends, corners or dispenser necks. On the topmost or topmost side, this initial container is made of two flaps or triangles, sealed, sealed and cut (one on the left side and / or one on the right side).

In this way we can get a container that has been transformed into a stereoscopic shape. In the first irregular polyhedron it may be changed, but it still gets its original irregular polyhedron shape. They can be triangles, triangles, rectangles, diagonal triangles, isosceles triangles, angled triangles, and so on.

2 - The procedure described in the previous section, ie the desired section in the initial vessel, can be sectioned. With the same method / mechanism / action, multiple and multi-directional clamp types can be directly connected, which can be connected to two sets of clamps of a vertically packed and filling machine producing an initial container with at least two sides.

2A - Functional multiple clamps and horizontal straight clamps are in a vertical / vertical filling machine that produces an initial container with at least two sides. :

For efficiency and efficient methods, two parallel clamps of two different sets of sets are sealed, but the initial vessel with two sides coexists: one set of two straight clamps in a horizontal position and the other set up On one side of the part, one does not interfere with the other and works separately. When sealing and cutting the initial vessel on two sides, it is necessary to replace one and the other and to combine the two at the same time.

In each machine cycle , there are two sets of clamp sets (multiple and horizontal straight lines) and interact in the following way:

1st: Two sets of straight clamps in the horizontal position operate sealing and cutting. It is used on any machine in a vertical / horizontal machine and is available in the market today.

SECOND: Two sets of multiple clamps, sealing and cutting - operate as described in section 1 in the previous section. It will never have only a horizontal straight line that seals and cuts all widths of the initial vessel.

3rd: Two linear clamps are activated again in the horizontal position, same as the first step.

Fourth: Two multi- and multi-directional clamp sets are activated, the same as the second stage.

In this way, an irregular polyhedral initial container is obtained. In other words, it did not have a rectangular or square shape.

Therefore, with this procedure, we can see that the parallel clamps of two kinds of sets work alternately (one is horizontal and the other is multiple), and we use the same vertical / horizontal machine At the same time, the following shows the type of initial container:

2A.1: The same initial vessel can be duplicated twice in each production cycle using two sets of clamps. One of the two sets of clamps is a straight clapper in a horizontal position and the other is a multiple clamp in which the desired tilt angle and length are straight at an oblique position.

Therefore, two initial vessels can be obtained in each cycle. The initial vessels are in front of one another at the moment of manufacture, but they look exactly at the sides of the initial vessels that are straight at the diagonal position. Therefore one of the early vessels is looking in the opposite direction.

In this way, vessels with similar shapes are manufactured from the initial shape, and shape is similar to windsurfing sails.

2A.2: Conversely, if we use two parallel multiple clamp sets that are not straight but have more than one line or plane (in this case, no shape, length, width, any bevel angle, Which can be obtained in each cycle of the two sets of clamps. The two initial vessels (not a rectangle or a square) have different shapes compared to one another. One or more sides will have a different shape and will be placed in a different way and the other side will have the same shape and be placed in the same place.

Next, we can get two different initial container models in two or more sets of multiple clamps, each of which will use only a straight set of clamps in a horizontal position with a different set of clamps.

Therefore, we will always get two other initial vessels in each cycle of these clamp sets. At the same time, two flaps are made and sealed, sealed and cut at each horizontal side of the lower part of each initial vessel to be deformed into a stereoscopic geometry.

Thus, each pair of these different initial vessels and a couple of other vessels that have already been transformed in 3D will be called positive and one named negatively, also called <ON> and <OFF>:

2A.2.1)

Multiple clamp sets : Straight sides (also can be curved, elliptical, wavy, semi-cylindrical, top, oblique, etc.) in a horizontal position, a desired length, Shaped, oval, wavy, semicylindrical, top, oblique, etc.) and can be connected to any of the ends of the aforementioned plane, which is a straight line in the horizontal position:

- Initial vessel OFF : The side face at the bottom of the initial vessel will be transformed into a solid geometric shape in the forward direction. The supporting surface of the vessel will be straight (also curved, elliptical, wavy, semicylindrical, top, ), The desired length and horizontal position.

One side that may be on the left or the right is a curved (also curved, elliptical, wavy, semi-cylindrical, top, sloped, etc.) (Which may be curved, elliptical, wavy, semicylindrical, sawed, oblique, etc.) in a straight line (also in a vertical position, but smaller than on the other side).

And two on the sides of the center and top of the initial vessel are connected to one side of the straight line (which may also be curved, elliptical, wavy, semicylindrical, top, oblique, etc.). One side is oblique with the desired inclination angle and length facing outwards and upwards, and the other side is in a horizontal position with the desired length.

Finally, only two flaps or triangles will be made and sealed or cut on the side of the lowest part that will be used as the bearing surface of the already deformed container.

- Initial container ON : The bottom side of the initial container is used as the supporting surface of the container deformed into the geometric shape of the future in the future. It can be used as a straight line (also curved, elliptical, wavy, semicylindrical, , Which is horizontal with the desired length.

One side that may be to the right or to the left is a straight line (which may also be curved, oval, wavy, semi-cylindrical, top, oblique, etc.) and perpendicular to the desired length. And the other side that may be on the right or on the left is a straight line (which may also be curved, oval, wavy, semi-cylindrical, top, oblique, etc.), but smaller than the other side.

There are two straight sides in the center or top side of the initial vessel (which may also be curved, elliptical, corrugated, semi-cylindrical, top, oblique, etc.) And the other side is obliquely directed to the outside and the bottom with the desired inclination angle and length.

Finally, in this initial container, only two flanks or triangular components will be made on the side to be used as a bearing surface, tangent and attached to the container, sealed and attached to the container, sealed, sealed and cut.

Product or Container: A product or container made of a stretchable material and sealed by at least two sides of the initial container, prepared by a deforming machine and procedure, contains a fluid (liquid / concentrate and / or air / gas) and a solid / It may or may not be together. A vessel transformed from 3D into a geometric vessel that is entirely three-dimensional in shape resembles a vessel's sail and is characterized by a container with five sides. The container can vary in size, as small as an eraser, or as large as a microwave oven. You can make any number of containers of desired length, width, and height.

The container can be made of any kind of stretchable material. It can be a single layer, a multi-layer, a tube, a half tube, a laminate, or any number of layers.

All sides of the container may be flat without flaps or triangles if flaps or triangles are sealed and cut.

- The highest part of the vessel is the sail of the ship and can be straight (also curved, elliptical, wavy, semi-cylindrical, top, oblique, etc.), angled at an oblique angle of approximately 45º to 65º .

- The left part or face is oblique and open to the outside. Approximately 60º to 85º depending on the size of the flap or triangle at an angle of inclination (a large flap will be made, sealed, sealed and cut, the larger will be an external slope).

- The part or face on the right is obliquely upwards and forms an angle of approximately 45º of inclination.

The area or plane of the lowest part of the container is a flat surface, which can be square, rectangular, curved, or elliptical.

- In addition, the container, which has already been deformed in a three-dimensional geometry, has wedge-shaped features at the same time, since the highest part at the end is flattened until the two sides of the container are connected (forming one edge) to be. And as it goes down, the container is widened, the capacity is increased, and the lowest part is widest, flat and calm, and used as a foundation to support the container until it reaches the end.

The container with the shape of the sail of the ship standing vertically in front of us (lift perspective) has the outline and weld line (indicated by the side perimeter) as follows:

a) There is a seam line (1) at the top or a straight line at an oblique position about 45º to 65º upward.

b) The left side is oblique between approximately 60º and 80º tilt angles and is open to the outside. In addition, there is optionally a peripheral weld line 1 in the center and in the longitudinal direction.

c) The front and back sides are two irregularly flat polyhedrons with a sail-like outline (may be more rectangular or square) of the ship. It has an angle of approximately 30º to 80º, but when it is optimized further, it becomes a 45º to 60º slope. Optionally, it can also have [longitudinal weld line (4)] and / or [weld seam (4) on the back side), vertically to the center.

d) A flat face used as a base (square, rectangle, circle, ellipse, etc.) in the lowest region has two perimeter weld lines (2) at the periphery with a circumferential weld line (1) have.

Optionally, the two flaps are not sealed or sealed and may or may not be attached to the remainder of the container.

In this particular case, as described in Figure 71, an initial vessel having two sides of a rectangle or square was used to make this vessel and has only two peripheral weld lines 1 horizontally. In addition, it is also possible to use one or more of the following: [one or two end seam lines (4) and / or back side] on the front and / or [ (One weld line 1).

- One or two vertical weld lines (2) may not be perpendicular to the straight line (90 ° considered weld line (1)). This way you can create other shapes. For example, curved, elliptical, semi-cylindrical, triangular saw blades, square lines, and waveforms can be created.

Claims (36)

How to transform (modify) a flexible container into a container with the following:
A container having at least two sides defining the extent of the enclosed space and at the same time bounding these sides through the outer contour rim and the outer contour rim having at least one side edge.
A minimum of one line of sealing or folding area that closes at least one kind of fluid and any or all of the containers that may contain additional solids, particles or powder. The method is characterized in that it comprises one of the following steps:
- Use at least one impact body (6) for at least one part on the edge of at least one of the edges, or two side edges facing / in the middle, local area, whole area or area adjacent to one end or corner, (1), or two or more side edges or tails of the original package, or vice versa (including the impact body (6)), A portion of the fluid follows the contour of the container, increasing the pressure inside the container and creating a localized expansion effect, resulting in the following: &lt; RTI ID = 0.0 &gt;
At least one container support surface or an additional surface in the container area collides with the impact body to maintain the stability of the container bottom and to deform the geometry of the container.
At least one flap or triangular body contacts the support surface and at least two sides of the container are formed.
- a sealing step that permanently stabilizes the support surface or additional surface by sealing, for example, at least one surface of at least one flap with at least one surface using a heat source. The method of claim 1, wherein the sealing step is performed in a region where the flap or triangular body shape intersects the support surface or the container pedestal. A method according to claim 1 or 2, comprising the additional step of cutting all or part of the at least one flap or triangular body shape. The method according to claim 1 or 2, characterized in that the following additional steps are included:
- Folding the flap or triangular body against the supporting surface or container pedestal.
- attaching or flipping the above-mentioned flap or triangular body to the container pedestal using an adhesive medium. How to transform a flexible package into a container with the following:
A container having at least two sides defining the extent of the enclosed space and at the same time bounding these sides through the outer contour rim and the outer contour rim having at least one side edge.
A minimum of one line of sealing or folding area that closes at least one kind of fluid and any or all of the containers that may contain additional solids, particles or powder.
The method is characterized in that it comprises one of the following steps:
- Use at least one impact body (6) for at least one part on the edge of at least one of the contours, or two side edges facing / to the middle, local zone, zone or area adjacent to one end or corner So as to apply pressure to the closed space inside the container. (One side, two sides, or more) of the original container, or vice versa (there is a side edge facing / inside / between / facing the impact body 6) Moving along the edge of the container increases the pressure inside the container and generates a local expansion effect, resulting in the following:
At least one container supporting surface or an additional surface in the container area collides with the impact body so that the container can be stably erected.
At least one flap or triangular body contacts the support surface and at least two sides of the container are formed.
- Folding the flap or triangular body against the supporting surface or additional surface.
Attach or flip the aforementioned sleeve (flap) or triangular body to the container pedestal using an adhesive media. The method of any one of claims 1 to 5, wherein the pressing step is performed by manually guiding the container to the inside of the impact body according to a selected operation of manual operation and automatic operation using mechanical means such as, for example, a robot gripper Lt; / RTI &gt; Method according to any one of the preceding claims, characterized in that, prior to the step of pressing with the impact body (6), the flap area to which the impact body is applied along the contour of the container and the fluid filled in the container Further comprising the step of securing the container to retard or apply pressure to the container. In this case, when the impact body 6 is used, there is an additional step in which the container is free (or releasing, but still attaching to the container and locking the container), causing the container to expand and form a three-dimensional geometry body. The method according to any one of claims 1 to 5, wherein the following phenomenon occurs and the step of applying pressure by simultaneously using the impact body in two or more different directions is included in the pressing step Features: A hole is created and the original container in this hole is shaped to have the same shape. The impact body according to any one of the preceding claims, characterized in that the impact body comprises two impact gogs (6, 8) and comprises an impact body (6) and a sealing gog (8) or sealing and cutting gog &Lt; / RTI &gt; The two impact bodies (6) have the following characteristics: they are located facing each other while exerting pressure on the contact borders of both sides, with the boundaries of the flaps being restricted between the lateral borders. The method of claim 1 or claim 5, comprising the additional step of using a gripper (19) on at least one edge or outer surface of the container: one side adjacent to one edge or outer surface of the container (3) that is formed by folding or sealing one of the sides of the container (1) to provide rigidity and stability to the container. Development and improvement of a three-dimensional shape container made of a coil material of flexible material type including the following steps or other methods:
- Making a container body using coil film.
Constructing a flap or protruding triangular body shaped container body.
Characterized in that it further comprises the following steps:
Sealing at least one, two, three, four or more flaps or triangular body features using at least one side of at least one flap, at least one side, of at least one flap, for example using a sealing method such as a heat source. 12. The method of claim 11, wherein the sealing step is performed in a region where the flap or triangular body shape intersects the face of the support or the pedestal of the container. The method according to claim 11 or 12, comprising the additional step of cutting all or part of the at least one flap or triangular body shape. The method according to claim 11 or 12, characterized in that the following additional steps are included:
- folding the flap or triangular body against a supporting surface or other container.
Attaching or affixing the aforementioned flap or triangular body to the container pedestal using a viscous medium; Improving or upgrading a filling machine that has at least two sides and produces at least one kind of fluid (liquid / dough and / or air / airframe) plus a package or original sealed container capable of holding solids, granular or powder The method includes:
- How to make container body using coil film.
- at least one device consisting of a pair of clamps or two parallel clamps for sealing and cutting the original container with at least two sides in the lateral and horizontal directions (up and down).
Characterized in that it comprises:
- a pair of parallel and twin grips with two sealing and cutting forceps designed to create a container or original container with at least two sides by sealing and cutting horizontally at the top and bottom in a straight line in a horizontal position. .
- a multi-foam stretch (not on a single horizontal line) for sealing between the top and bottom at the intermediate position of the container and making two containers of mutually complementary shapes that can be of two forms in each production cycle: Two twin pliers and two parallel pliers for seals and cuts equipped with:
- The resulting container / original container has two complementary shapes of different shapes, which are called "ON" container and "OFF" container. Multi-form grippers are not a straight line.
The resultant container / original container has two complementary shapes of the same shape, and the multi-form tongs are one linear shape arranged with oblique slopes of the desired slope. A machine for transforming a flexible container into the aforesaid container with:
At least two sides bounded by an outline edge defined by at least one edge.
A minimum of one sealing line or folding line to close the container.
It may contain at least one fluid in the package plus additional solids, granules or powder.
The machine in this case is characterized in that it comprises:
- At least one sensor (1) designed to sense at least one support, original container or container initially inserted.
At least one mobile impact body 6 (driven by a linear displacement 9 and / or a rotation 16) and / or a stationary impact body 6: one, two or more of the outer edge corners It is intended to create one or more side edges from at least one flap or triangular body shape by applying lateral pressure.
- driven by a linear displacement (9) and / or a rotation (16) to seal or cut at least one part of at least one of the flap or triangular body features and one or more of the sides and / or outline contours or side edges At least one sealing clamp (8) or sealing and cutting forceps, which is used for the purpose of providing a seal. The sealing clamps 8 permanently fix the supporting surface or the further created surface using one or more heat sources. A machine according to claim 16, characterized by using the sealing clamp (8) and the impact body (6) selected from:
Consisting of two pairs of clamping jaws comprising sealing clamps 8 or sealing and cutting clamps 8 and an impact body 6 aligned (or to be aligned) with sealing clamping and cutting clamps 8 A pair of tweezers.
- an impact body located at the center of the two sealing tongues 8 and the sealing tongs 8 or the sealing and cutting tongs 8 and aligned (or aligned) with respect to the sealing tongs or the sealing and cutting tongs 8 6) A set of three tongs.
Two impact tongues 8 and two impact bodies 6 located in the middle of the sealing tongs 8 or the sealing and cutting tongs 8 and aligned with the sealing tongs 8 or the sealing and cutting tongs 8 ), A set of four tongs.
The pair must be aligned or aligned so that the original container can be inserted between the pegs, except when the pair of pegs intersect at the same side edge. 18. Machine according to claim 16, characterized in that it comprises two tabs (6.8) arranged to be aligned and the container or original container intended to be deformed is able to enter between the clamps.
Tongs (6.8) choose from the following suit:
In this case, the impact tongs (6) are movable (linear displacements (1), (2) and (3) (Driven by means 9 and / or rotation 16) and / or may be stationary. A machine according to claim 16, 17 or 18, characterized in that it comprises at least one additional step before inserting the original container between the clamping clamps (3), as follows: at least one impact The body 6 and / or at least one sealing clamp 8 or the sealing and cutting clamp 8, at least one pair of clamps 6, 8, 3, 4. In some cases: the tongue 3 must be replaced and then returned to the starting point using mechanical drive means or linear cylinder 9 and / or rotation means 16, or by means of linear movement device 17: The purpose of the container is to allow only a space that can be easily inserted into the point or position where the machine is started, and at this point or position the original container is transformed into the 3D geometric body shape we want Characterized in that it comprises at least one clamping clamp (3) or at least two clamping clamps (3) according to claim 16, 17 or 18, A machine designed to apply pressure on the flap area to which the impact body is applied, and the fluid filled inside the container at a distance. In this process, the clamping forceps are folded or unfolded (or unfolded, but the container is still pressed by the container) and the container expands into a geometric three-dimensional body shape. Pressure also improves flap molding. Machine according to claim 16, 17 or 18. (10) which is driven by linear displacement and / or rotation for the purpose of being placed below the original container or clamp (3) to serve as a support base for the package prior to transformation of the original package, Characterized in that the machine comprises flap elevation means designed to adjust the height of the original container and to place the original container at the correct height that we desire. To this end, the clamping clamp 3 fixes the original container from the start of the flap to the central area, end or non-contact area of the side border. 18. A machine according to claim 16, comprising:
- At least one support
- At least one sensor (1) designed to detect the original container or the container first inserted into the machine
- A set of three or four tongs at the top (6.8)
- a triple or quadruple (6.8) [or one or two (6.8) tongs (6.8)] on the top and a tongue
Should be vertically aligned or aligned, and at least as long as the already deformed container or original container is spaced such that it can pass or enter between the two clamps (6.8) and each impact clamp (6) A pair of fastening clamps (6.8) on the top and a pair of fastening clamps on the stem of the rotating cylinder (16).
The upper rotating cylinder 16 is attached vertically to the stem of the linear cylinder 9).
The sealing tongs or sealing and cutting tongues of the tongs (6.8), each with a set of three or four tongs, are fixed to the individual impact tongs (6).
The original container will crash or crash as follows: -
First, one or two tabs are formed due to impact or collision with the upper part of the impact forceps (6).
- the flap is bent by the forceps (6.8) on the second side parallel to the side.
(Driven by the upper linear cylinder 9) against the impact clamp 6 located at the bottom, resulting in another one or two flaps.
When the sealing tongue 8 or the sealing and cutting tongs 8 serve as a lasso and are fixed to the container, the containers are trapped between the two tongs 6.8 by the container side flaps.
Clamping tongs (6) is a container to the bottom 180 ^o purpose of rotating by [Impact clamp 6 is rotated due to adhere to the stem of the cylinder (16) since the impact index and the top of the container when it is down to the bottom or discharge 180 ^o Rotated to return to the starting point. At least two sides, one, two, three, four or more parts are sealed by welding or sealing and can contain at least one fluid (liquid / dough and / or air / gas) A complementary pair container is a filling machine that manufactures containers or original containers that can contain solids, granules, or powders. Consists of:
- Medium to make container body with coil film.
- at least one device consisting of a pair of clamps or two parallel clamps for sealing and cutting the original container with at least two sides in the lateral and horizontal directions (up and down).
Characterized in that it comprises:
- a pair of parallel and twin grips with two sealing and cutting forceps, sealed and cut from above and below horizontally to form a container or original container of at least two sides and placed in a straight line in a horizontal position.
- Two parallel and twin grippers for sealing and cutting with multi-foam trenches (not on a horizontal straight line) for sealing two containers at the same time as they are sealed at an intermediate position between the top and bottom of the container suit. A flexible container, characterized in that it is manufactured by the method described in any one of claims 1 to 4. A flexible container, characterized in that it is manufactured by the method described in claim 5. A flexible container characterized by being manufactured by the method described in claim 10. A flexible container produced by the method as claimed in any one of claims 11 to 14. A flexible container, characterized in that it is manufactured by the method described in claim 15. A flexible container in the form of a three-dimensional geometric body capable of containing at least one kind of fluid and additionally solid, granular or powder. If a part of the original container is square or rectangular and two flaps are created, then the process is as follows: Use 2-line welding (2) or 2-line folding at the intersection between the flaps and the container support A flat support surface of a rectangular, rectangular or circular shape made of a continuous support surface and having a triangular shape in which two surfaces are protruded from the left end and the right end and are diagonally arranged from the outside to the top, Is formed by folding, attaching / sealing and attaching / sealing and cutting a container having a shape in which the hull of the ship is rolled in a direction intersecting with a corrugated line or weld line (2) which is orthogonal to the flat supporting surface. In addition, two faces protrude from the front and back sides to have a trapezoidal shape. There are 5 sides in the package. The original container has a single straight horizontal face and multiple faces that can be randomly combined or deformed in shape, length, width, or slope as desired (eg, created by sealing or cutting using multi-form clamps) (Straight, curved, elliptical, free-curved, semi-cylindrical, zigzag, zigzag, etc.) into this original container of four deformations with four 90 degree angles, Vertically, at a desired angle, etc.) to form a five-sided polyhedron of irregular dimensions, and when two flaps or triangular shaped bodies are produced, the following process is performed: Flexible container of three-dimensional geometry capable of containing solids, granules or powder: two welded strands 2 of orthogonal shape are created And the side surfaces of the base of the triangle are formed as flat surfaces, and the side surfaces of the base of the triangle are formed as flat surfaces, A container with a rectangular, square or circular flat support surface that intersects the corrugation line or weld line 2 orthogonal to the face is created by folding, attaching / sealing, sealing and attaching / sealing and cutting. A flexible container in the form of a three-dimensional geometric body capable of containing at least one kind of fluid and additionally solid, granular or powder. A part of the original container is preferably a square or rectangular shape and two flaps are formed as follows: folding and attaching / sealing, sealing and attaching / sealing and cutting to form a rectangular, A parallelepiped container with a square or circular flat support surface is created and additional tabs are created on the opposite side of the bearing surface to create a neck meter or protruding tip without sealing or cutting. A flexible container in the form of a three-dimensional geometric body capable of containing at least one kind of fluid and additionally solid, granular or powder. A portion of the original container is preferably rectangular or rectangular, and four flaps are created, with the following process: folding and attaching / sealing, sealing and attaching or sealing and cutting to form a six- A parallelepiped container is created. A flexible container in the form of a three-dimensional geometric body capable of containing at least one kind of fluid and additionally solid, granular or powder. At the outset, two flaps are made diagonally opposite one another in a portion of the original container, where the three contact surfaces are either mutually orthogonal or have rectangular and diagonal sides, as well as creating two weld lines 2 in an orthogonal form , With a continuum of support surfaces and forming a triangular body arranged diagonally at a desired angle with respect to the bearing surface from outside to the top in the left and right ends, the side surfaces of the base of the triangle having a corrugation Line or welding line (2)] is characterized in that it is subjected to the following process: folding and attaching / sealing, sealing and attaching / sealing the diagonally opposite face through sealing and cutting The diagonals are rectangular, square or circular with a prominent meter neck at one end of the diagonal Seongdoem. Container or container suit, characterized by:
- at least one flexible package as described in any one of claims 24 to 33. Preferably all flaps are sealed and cut so that on the one hand a more hygienic product can be produced and on the other hand a container with at least one side of the product having at least the following characteristics: Between the sheet and sheet of plastic material). Containers may contain a lid that can contain frozen liquid in a way that the outer surface is sterile and watertight and can cover the sterilized condition by covering at least one container at a time. 34. The flexible container according to any one of claims 24 to 34, wherein any one of a flap or a triangular shaped body of each container can be randomly arranged and the following alternatives can be combined:
- do not create anything in the container;
- folding, gluing or attaching to the container's pedestal;
- only sealed;
- Sealing, folding, gluing or attaching to the pedestal of the container;
- Sealing and cutting. 34. The flexible container according to any of claims 24 to 34, characterized in that at least one vertical welding line (2) among the 3D inventive containers can be machined not only straight but also in different forms, for example: It can be optionally arranged in a combination of random, curved, semi-cylindrical concave or convex, semicylindrical elliptical concave or convex, zigzag, oblique, wavy,

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