KR20080014306A - Balloon display system - Google Patents

Abstract

A balloon display system is provided to enable a user to configure the system fast, simply, and easily according to one's desired shape. A balloon display system includes: at least one frame(850) supporting the balloons and having at least one hole; at least one expanded chamber(801) positioned adjacent to the frame; and at least one connection member(810) for connecting the expanded chambers through holes that are so enough small as to block passing of the expanded chambers.

Description

Balloon display system {Balloon display system}

1A is a cross sectional view through a perforated frame of a pair of inflatable chambers connected through a hole in a balloon display system according to the present invention.

1B is a perspective view of the same structure as in FIG. 1A.

2 is a cross-sectional view through a bore with three inflatable chambers connected through holes in a balloon display system according to one embodiment of the invention.

3 is a cross-sectional view through a bore with a hole of three inflatable chambers connected through a bore of a balloon display system according to another embodiment of the invention.

4 is a cross-sectional view through a hole with a hole of five inflatable chambers connected through a hole in a balloon display system according to another embodiment of the present invention.

FIG. 5 is a cross-sectional view through a bore with a hole of ten inflatable chambers connected through a bore of a balloon display system according to another embodiment of the invention.

FIG. 6 is a cross-sectional view through a bore with an aperture of eight inflatable chambers connected through a bore of a balloon display system according to another embodiment of the invention.

FIG. 7 is a cross-sectional view through a perforated frame of twelve inflatable chambers connected through a bore of a balloon display system according to another embodiment of the invention.

8 is a method of assembling a balloon display system having one or more inflatable chambers with one set of chambers on each side of the perforated frame of the balloon display system according to the invention and a plurality of sets of chambers on the opposite side; Is a perspective view showing.

The present invention relates to a balloon and, in particular, to the decorative, informative and structural value of the balloon when used with a perforated frame.

 There are generally two types of balloons used for plus decoration and professional balloons with various patents.

Balloons have traditionally been made of natural latex. The molds are encased in a large liquid latex pail and some latex sticks to the mold. When the mold is taken out, the latex stuck is dried to form a film of high elasticity. The membrane is removed from the mold for use. The balloon thus produced is usually in the form of a bulb with one narrow round stem and a hole for inflation. Once inflated, the latex balloon is most commonly sealed by knotting the balloon's expanded stem. A less common method is to use a mechanical lock installed inside to seal the latex balloon itself. There are many different technologies and devices on the market that are used to provide structural decorative functions or to directly connect common materials or latex balloons to each other. However, relatively few systems are specifically designed and manufactured for this purpose.

The adhesive is generally applied to at least one of the surfaces to be joined and held until the surfaces are pressed together so that the adhesive can remain in sufficient contact without special assistance.

The adhesive is used in various forms including spray, liquid, temperature based adhesive and tape.

There are several mechanical ways to connect the balloons. These methods include twisting, tying, pinching or compressing the balloons directly into any structure used for general connection with each other or other balloons.

The balloons have their necks tied together for a long time. Long, thin balloons, called "pencil balloons" or "celebrity balloons," are pinched and twisted at points along their length. These twisted points are twisted together with those points in the same balloon or in other balloons. Balloons have long been tied up with items such as threads, ribbons, short fibers (plastic or nylon fishing lines), office buildings, and cable ties.

Balloons are often attached to a common structure by actually penetrating the surface of the balloon at a cross section of the balloon stem that is not used to seal each other or the air chamber. This is often done by paper clips, by hooks, by twisting or by another cross section of the string tied to each other or to the actual structures added.

The frame material is often used as well as plastic rods and tubes as well as plastic rods and tubes so that the balloons are strong enough to hold the planned arrangement and flexible enough to be shaped by hands or simple tools. When a large number of balloons must be included, they are often controlled by bags or nets.

The combination of specific techniques for using adhesives is very diverse and the complexity available in mechanical techniques is similar. When the two approaches are combined, the possibilities are amplified again.

For example, an adhesive can be used to bond the balloons together to form balloons in the form of sheets. The sheet may be bent to form a curved surface and the shape may be maintained by a mechanical connection. Such sheets can form decorative walls or ceilings or tunnels.

Helium-filled balloons can be mechanically connected to a light strip so they can float in an arc. The balloons stick to each other by adhesive to ensure that the balloons do not rotate around and hide important graphics on the surface.

The second type of balloon used for decoration is made by heat sealing two layers of thin, light and air filled film together along a line defining the outer edge of the balloon shape. The balloon is usually shaped like a bulb with a narrow tubular stem and a hole for expansion. Once inflated, the film balloons are most commonly sealed by heat sealing the open stem. Self-sealing valves within the stem of the film balloon are of increasing importance as the chosen sealing method. Tying the knot to the stems of the film balloons is becoming less common, and mechanical locks are also becoming less common with film balloons.

Various techniques and systems used in the field of connecting film balloons are similar to those used in latex balloons. One exception, however, is the use of other wire hooks or paper clips that pierce through the inflated stem of the latex balloon, since the films used in the balloon are generally torn once pierced, although they are quite strong.

The second exception is to pinch and twist the film balloon across the inflated chamber, because the relatively inelastic nature of the film makes such a process unrealistic.

Another approach to connecting and supporting balloons is to combine the balloon or its inflated chamber into a thread such as a bead thread. This is particularly popular with long and narrow balloons. These balloons are often twisted into wrought animals, flowers and other shapes. Similar activities are taking place in larger round balloons made to have two protruding stems. One is used to inflate the balloons and both are used to bind the balloons together and make them into threads. Balloon yarns are often twisted together with other balloons to create the shape of processing and other decorations.

Frames with holes have been used with balloons for some time for decoration, and there are generally three basic theoretical frames. The first theoretical framework uses holes drilled in sheet-like material. The selected holes hold the balloons by squeezing the balloon into the hole or passing a stem or bundle connected to the balloon through the hole and attaching the balloon to the material. While this cutout generally consists of an efficient mold cutting process, this theoretical framework results in significant waste from being cut out of the process. The frame member and the holes around the holes are essentially the same size as they are used, such as in manufacturing. The finished display system is limited to the sum of the protrusions and seat original size from the connected balloons.

The second theoretical framework is to assemble members using basically strong joints. Such an approach usually wastes less material than in the first theoretical framework, but adds the cost of making such a joint. The frame member and the holes around the holes are essentially the same size as they are used, such as in manufacturing. The finished display system is limited to the sum of the protrusions and seat original size from the connected balloons.

The third theoretical framework is to make holes in the form of expandable grids, usually cut out in rows parallel to the sheet material. This approach can use very efficient mold cutting processes to minimize material waste. The attributes of such a scalable system benefit from the compact storage and transportation. In general, the properties of the expandable system do not have the physical stiffness associated with strong joint systems.

There have been only a few such frameworks specially designed and produced for use with balloons. Different frameworks for balloon decorations were borrowed from other fields.

For example, in 1985 Marvin Hardy reported the use of wooden pegs as a frame to hold balloons by pulling their necks through small holes of regular shape in these synthetic wooden sheets. . A few years later he used grooved plastic discs to pinch the necks of the balloons and prevent them from being pulled back through the holes.

According to the August 1987 issue of "Balloons Today", Spony Morrill introduced the use of existing, flexible mesh grids as a framework for balloon graphics. The balloons were attached in layers by paper clips or by tying the balloons directly to the net.

Graham Louth (Graham Rouse) was introduced in March International Balloon artists, specially designed for the balloons being produced in association with the meeting "Grouse balloon art designer panels ^{(Rouse Balloon Art Designer Panels TM)} " 1988. These form a regular, semi-rigid, modular system with a series of holes that corrugate the board plate and keep the balloons connected in the form of a network for walls and other graphic and sculptural display systems. Balloons were generally attached by pulling the neck of the balloon through a hole, pulling it out into a groove radiated from an adjacent hole and pinching the neck into the groove.

In July of the following year, the Raus balloon art designer panel squeezed the balloons into a hole smaller than the natural diameter of the inflated balloon at the Flower Association Balloon Open House to keep the balloons in place for the graphic and sculpture display systems. Was exhibited as.

In 1990, Marvin Hardy began using his Zippy Strips ^™ , which stretched the necks and passed them through the holes, pinching the balloon's neck into an adjacent groove to keep it tight against the strips. Hazard (3/4) "is a wide strip of transparent plastic with grooves spaced at 1" intervals. The paper strips may be placed at right angles to form grids or groups of approximately parallel strips to cover large, irregular faces.

At that time, Kevin LaCount used lattice-fabricated wood lattice to hold the balloons and held them by squeezing the balloons into holes in the lattice. In application in commercial decor, David Gully used fabricated wire grids to squeeze balloons into the grid to create decorative shapes.

In 1933, Marvin Hardy introduced his MagriGrid ^™ . It is just like a rectangular grid wire fence made of heavy metal rods and bands. The size of the hole can be changed from one application to the next. The balloon lines are pressed at an angle (ie, maintained under pressure on both the top, bottom and sides) and enter the lattice. This construction hides most of the frame as well as the neck and improves appearance in the front-back direction.

James Stephen ski mask (James Skistimas) More recently in 1994 has introduced his ski mask design system Stevenage (Skistimas Design System ^TM). The system combines the concept of the above modular modular panel of size 24 "x 48" with a 6 inch square grid wire frame as used by David Gurley. The system adds a second layer of metal to each panel for increased strength and stability. It supports not only foil but also latex balloons and has the same appearance as the maggrid. Skistimas registered a patent (US Patent No. 5,533,285) for his system in the United States on 9 July 1996. He received a second related patent (US Pat. No. 5,675,922) on October 14, 1997.

In 1995, Graham Rouse introduced his "Rouse Matrix System ^™ ". This is an overlapping cutting expandable matrix (OCEM) specifically designed for use in balloons. Raus received a patent (US Pat. No. 6,332,823) for his system on December 25, 2001 in the United States.

The skistigmas patents are focused solely on the balloons supported in the holes of the frame by the air pressure of the balloons extending outward relative to the frame around it. The Raus patent focuses on the connected balloon set used in connection with the OCEM framework without requiring a special relationship between the balloon and the framework.

Indeed, the balloons used with the OCEM frame under the Raus patent are very commonly displayed while in the holes of the frame. However, the balloons do not depend solely on the air pressure of the balloons that extend outward relative to the surrounding frame to hold them in place. The balloons have anchors of connected balloons that help keep them in place. They also have special notches or framework surfaces that are specially handled to the surrounding frame, which generally helps to fix the balloons.

Indeed, the balloons exhibited on the Skistimas framework not only have the advantage of being trapped between the two sides of a two-ply grid to help them stay in place, but also depend on air pressure.

However, the conventional balloon display system is not easy to support the balloons in a fixed position and a considerable amount of effort is required to achieve the purpose.

The present invention is to provide a balloon display system having an improved structure to improve the problems of the conventional balloon display system to configure a display system of a desired form quickly, simply and easily.

The present invention addresses the relationship between balloons and support frames provided with holes. It does not depend on the air pressure of the balloon extended to the surrounding frame that holds the balloons in place. It does not depend on the use of the OCEM framework. The present invention is like a thread of beads connected, where at least one of the beads in the middle is forced through the button hole to fix the thread to which the beads are connected to the material around the button hole. In the present invention, the shortest thread is one ball that is forced through the hole and connected from each end of the bead to the end of the other bead on the other side of the hole. The smallest number of beads in that arrangement will be two. This is a simple ring. If it's not a ring, it's three beads. Whether two or three beads, or all beads, the expanded chamber is sized and positioned to prevent passage through adjacent holes.

"Inflatable chambers" or "inflated chambers" are used here instead of "balloons" because each of our two, three or more inflatable marbles are inflated but all chambers are made from one balloon. do. For example, if the frame has a series of small holes located close together, it is possible to inflate one long latex balloon and twist it into a series of inflated chambers that is very similar to the thread in which the beads are threaded. It is also possible for the seal, which is connected to the expandable chambers to allow fluid exchange between the chambers, to be made of a plurality of layers of film by applying at least one mold. If the connection paths between adjacent chambers are narrow, this single balloon can also look and act like a thread with beads. It is also possible for a seal of expandable chambers to be fabricated from a set of film layers so that the chambers are all connected by the film in which they are formed but each chamber is independently inflated.

In this application, we use the term "continuous balloon structure" to refer to a structure in which a series of inflatable chambers are made of a plurality of film layers so that the chambers are connected by the film in which the chambers are made. . The term applies whether or not there is an exchange of fluid between the inflatable chambers.

First, many of our developments and changes are possible if our first inflatable chamber is forced to a specific location. Other expandable chambers in the row can likewise pass through adjacent holes, or some can pass through the hole or be centered in the holes irrespective of other chambers. Rings containing two inflatable chambers can be combined and become their own thread. Multiple inflatable chambers can replace individual inflatable chambers that act as a bead. Members connecting the two chambers usually come from opposite ends of the chambers, which may be inflated, and two or more may be made. The connecting members are usually spaced widely above the inflatable chambers and penetrate the holes adjacent to the spaced apart locations. Connecting members existing from one position of the chamber which can be individually inflated are not in contact with connecting members existing from at least one of the other positions of the same chamber.

This approach of fixing the position of the inflatable chambers to the support frame with holes is tolerant of rapid, simple, effective and inflatable chamber size and location changes. Inflatable chambers centered in the perforated mold are more difficult to position properly and are more likely to get out of position unless they are expanded to the correct dimensions. Another approach to supporting the inflatable chambers in a perforated frame is not easy to support the balloons in a fixed position and requires considerable effort to achieve that goal.

For example, when balloons are picked up or tied to a frame with holes by paper, the balloons often bounce out of position with a slight wind. More sophisticated variations of the connection approach can add rigid frameworks to frameworks with more flexible holes. In such a case, the balloons may be tied closer to the perforated frame. The pressure of one balloon adjacent to several other balloons keeps the balloons in place. There is a similar approach to the field where two balloons on one side of a frame with holes have an interference portion of the frame with holes on the other side of the frame. Another variation is that two balloons are tied together on the same side of the frame and pass through different holes on the opposite side. Attaching the balloons to the frame or attaching them to each other through other holes to trim the balloons to the proper position is considerably more difficult than the process of the present invention.

Referring to FIG. 1, there is a balloon display system that uses balloon buttons 800. 1A is a cross-sectional view of a frame made of frame member 850. A plurality of sets of inflatable chambers 801 are connected through the holes by connecting members 810. The first set that can be inflated in this embodiment has a center of mass on top of the frame as shown in the figure. The first set includes one inflatable chamber, such as the second set of inflatable chambers. The second set has a center of mass at the bottom of the frame as shown in the figure. These sets include a plurality of inflatable chambers that are evenly distributed. Although two connecting members are shown between the inflatable chamber sets, the connecting members may be further provided. The connecting members are generally located at the periphery of the set of chambers that can be inflated. The inflatable chamber set is sized and shaped to enclose the frame member and prevent the chamber set from passing through the aperture. Placing the connecting member in the periphery is to connect two sets of inflatable chambers and to help center the set in the hole.

1B is a perspective view of one embodiment of the present invention arranged as in FIG. 1A. The perforated mold 850 is shown here as a single hole in the shape of a rectangle. Most such display systems are expected to include a plurality of apertures. Such display systems are not limited to rectangular holes. The holes may be of any shape that accommodates the finish design of the display system.

Referring now to FIG. 2, there is another balloon display system using balloon buttons 800. 2 is a cross-sectional view of a frame with a hole made of frame member 850. The plurality of inflatable chambers 801 are connected by connecting members 810. In this case, the connecting members pass through the holes and wrap around the connecting member more than 180 ° to reach the adjacent chamber located at the lower side of the frame. The inflatable chambers serve as anchors for the other chambers that can be inflated with the frame members. The inflatable chambers are connected to a pair of inflatable chambers in the position shown in FIG. 2 at the ends of the seal to attach a connection member to one of the connection members at the end of the seal. Or it is additionally held in place by means of positioning other positions for the inflatable chambers as mentioned elsewhere in this specification.

Referring now to FIG. 3, there is another balloon display system using balloon button 800. 3 is a cross-sectional view of a frame with a hole made of frame member 850. The plurality of sets of inflatable chambers 801 are connected by connecting members 810. In this case, the connecting members pass only about 90 ° around the connecting member to an inflatable chamber located opposite the frame. The inflatable chambers overlap with the frame members and serve as clamps for other chambers. The inflatable chambers are connected to a pair of inflatable chambers in the position shown in FIG. 1 at the ends of the seal to attach a connection member to one of the connection members at the end of the seal. Or it is additionally held in place by means of positioning other positions for the inflatable chambers as mentioned elsewhere in this specification.

Referring now to FIG. 4, there is another balloon display system using balloon button 800. 4 is a cross-sectional view of a frame with a hole made of frame member 850. The plurality of sets of inflatable chambers 801 are connected by connecting members 810. In this case, the connecting members pass only about 90 ° around the frame member to reach a swellable chamber located opposite the frame. In this case several inflatable chambers penetrate through the holes and wrap around the frame member more than 180 ° to an adjacent inflatable chamber located below the mold. The inflatable chambers overlap with the frame members and serve as clamps for other chambers. The inflatable chambers are connected to a pair of inflatable chambers in the position shown in FIG. 1 at the ends of the seal to attach a connection member to one of the connection members at the end of the seal. Or it is additionally held in place by means of positioning other positions for the inflatable chambers as mentioned elsewhere in this specification.

Referring now to FIG. 5, there is another balloon display system using balloon button 800. 5 is a cross-sectional view of a frame with a hole made of frame member 850. The plurality of sets of inflatable chambers 801 are connected by connecting members 810. In this case, not all chambers that can be inflated are in contact with the frame members. Some inflatable chambers are arranged as shown in FIGS. Some other inflatable chambers in the yarn form a ring away from the frame and use the other inflatable chambers as anchors for supporting the loop.

Referring now to FIG. 6, there is another balloon display system using balloon button 800. 6 is a cross-sectional view of a frame with a hole made of frame member 850. The plurality of sets of inflatable chambers 801 are connected by connecting members 810. In this case, there are chambers on both sides of the mold that can be inflated. The connecting members are from one swellable chamber having a size and shape that prevents the penetration of the adjacent holes from one inflatable chamber to another swellable chamber of similar size and shape that prevents the penetration of the adjacent holes. Penetrates. The display system as shown here can be achieved by combining the various arrangements shown in FIGS. Using a very flexible framework, the bilateral display system shown here contributes not only to the graphic display system but also to the intensity.

Referring now to FIG. 7, there is another balloon display system using balloon button 800. 7 is a cross-sectional view of a frame with a hole made of frame member 850. The plurality of sets of inflatable chambers 801 are connected by connecting members 810. In this case, there are chambers on both sides of the mold that can be inflated. The connecting members are from one swellable chamber having a size and shape that prevents the penetration of the adjacent holes from one inflatable chamber to another swellable chamber of similar size and shape that prevents the penetration of the adjacent holes. Penetrates. In this case, however, some of the inflatable chambers are larger than others. In one area towards the left end of the seal, large chambers 801b are above the frame and smaller chambers 801a are below the frame. In the other area towards the right end of the seal, small chambers 801a are on the upper side of the mold and larger chambers 801b are on the lower side of the mold. In each case, the frame and seal of the chambers rotate to face the smaller chambers. This approach provides a means to control the shape of the display system without the need for a strong reinforcement.

Referring now to FIG. 8, there is another balloon display system using balloon button 800. 7 is a cross-sectional view of a frame with a hole made of frame member 850. The plurality of sets of inflatable chambers 801 are connected by connecting members 810. In this case, there are chambers on both sides of the mold that can be inflated. The connecting members are from one swellable chamber having a size and shape that prevents the penetration of the adjacent holes from one inflatable chamber to another swellable chamber of similar size and shape that prevents the penetration of the adjacent holes. Penetrates. In this example, the set of inflatable chambers on each side of the mold includes two inflatable chambers 801c and 801d on the top of the mold and two inflatable chambers 801e on the bottom of the mold. 801f) is disposed. The frame member 850 is cut out from a large honeycomb matrix. The frame holes need not be hexagonal and may be of a suitable shape to suit the finishing design sought and suited to the size and shape of the inflatable chamber.

The balloon display system according to the present invention has the effect of being fast, simple, effective and tolerant of changes in the size and location of the inflatable chamber by fixing the positions of the inflatable chambers to the supporting frame having holes.

Claims (14)

A. at least one frame comprising a material surrounding at least one aperture, the at least one frame for supporting the balloons; B. iii) at least one inflated chamber, ii) at least one inflated chamber located adjacent to said at least one frame, and iii) at least one dimension larger than adjacent and equal to the dimensions of said adjacent hole. First set of fields; C. iii) at least one inflated chamber, ii) at least one inflated chamber located adjacent to said at least one frame, and iii) at least one dimension larger than adjacent and equal to the dimension of said adjacent hole. A second set of fields; D. at least one first connecting member penetrating said hole adjacent said first set of at least one inflated chambers between said first set of at least one inflated chambers and an additional set of said at least one inflated chambers; And E. at least one additional connection between the first set of at least one inflated chambers and the additional set of at least one inflated chambers iii) passing through the aperture adjacent to the first set of at least one inflated chambers And ii) at least one of the at least one first connecting members and at least one of the at least one additional connecting members do not contact each other. The method of claim 1, The at least one frame comprises a plurality of frame members. The method of claim 1, And the at least one mold comprises a material surrounding the plurality of holes. The method of claim 1, And the first set of at least one inflated chambers comprises a plurality of inflated chambers. The method of claim 1, And the first set of at least one inflated chambers comprises a plurality of sets of inflated chambers. The method of claim 1, And the additional set of at least one inflated chambers comprises a plurality of inflated chambers. The method of claim 1, And wherein the additional set of at least one inflated chambers comprises a plurality of sets of inflated chambers. The method of claim 1, And said additional set of said at least one inflated chambers has its center of mass on the other side of said at least one frame different from said first set of at least one inflatable chambers. The method of claim 1, And the additional set of at least one inflated chambers has its center of mass on the same side of the at least one frame as the first set of at least one inflatable chambers. The method of claim 1, Balloon display made of the same continuous material between at least one of said additional set of said at least one inflatable chamber and at least one of said first set of said at least one inflatable chamber and at least one connecting member system. The method of claim 1, Balloon display system with exchange of fluid between a plurality of inflated chambers. The method of claim 1, Balloon display system without exchange of fluid between a plurality of inflated chambers. The method of claim 1, And the at least one frame is an expandable model cut to overlap. The method of claim 1, And said inflated chambers are continuous balloon structures.

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