The present invention concerns a foil balloon adapter part, a foil balloon with such an adapter part and a foil balloon dispensing apparatus.
Automatic sales and dispensing apparatus for latex balloons which are filled with helium are known. On demand, a selected desired latex balloon is filled in the sales and dispensing apparatus with helium to a predetermined internal pressure and is then dispensed. The balloons may be attached to a stick or they may be attached to a string.
Furthermore, foil balloons are known which are available in a multitude of shapes, colors and designs and which are filled by a salesperson with helium or another gas just before they are handed over to a customer or which are filled with a gas before they are offered for sale.
DE 1903215 A discloses an automatic dispensing apparatus for air balloons consisting of rubber where pressurized gas is introduced into the balloon via a valve insert and a nozzle. Then the balloon neck lifts off the outer surface of the valve body of the valve insert and clears openings to radial channels in the valve insert. As soon as the supply of pressurized gas is stopped the balloon neck returns to its position in tight contact with the outer surface of the valve body and, in this way, closes the openings of the radial passages to keep the gas in the balloon.
US 2007/0084878 A1 discloses an adapter part for a balloon which is to be filled with gas, wherein the adapter part includes a mounting ring, through which the end of the balloon via which the gas is to enter the balloon extends, as well as a guide ring which is arranged co-axially with the mounting ring for inflating the balloon. The gas balloon which is in the form of a foil balloon is provided in a dispensing apparatus in a folded state and is guided by the guide ring. When the gas balloon is inflated and dispensed from the dispensing apparatus the guide ring can be released from the mounting ring and the balloon can be held by a string connected thereto.
U.S. Pat. No. 4,088,161 also discloses a gas balloon which is guided in a dispensing apparatus via an adapter part and which is inflated in the apparatus before it is dispensed. The adapter part comprises a mounting ring which remains with the gas balloon as well as a guide ring by which the balloon can be held by a hand after the balloon is released from the dispensing apparatus. The mounting ring and the guide ring are interconnected by a string.
It is the object of the present invention to provide a dispensing apparatus capable of automatically filling balloons with a gas and dispensing them. In particular the dispensing apparatus should facilitate the automatic dispensing of a gas-filled balloon.
In a foil balloon dispensing apparatus folded or rolled-up foil balloons are accommodated and are each provided with an adapter part including an attachment section connected to a foil balloon and a guide section which is removably connected to the attachment section and which is disconnected from the attachment section after the foil balloon is inflated. But the two sections remain interconnected by a string for holding and guiding the foil balloon after its removal from the dispensing apparatus.
The foil balloons which are automatically filled with gas and dispensed by the dispensing apparatus according to the invention have a foil skin which is not, or only slightly, stretchable, contrary to a latex balloon. The foil balloons are disposed in the automatic dispensing apparatus folded or in the form of a roll and are unfolded or rolled off while they are filled with gas. The material of which the foil balloons consist is for example a plastic foil or an aluminum foil.
A first aspect of the invention concerns a foil balloon adapter part which can be attached to a foil balloon and via which gas can be supplied to the interior of the foil balloon. The adapter part has an attachment section for attachment to the balloon and a guide section which facilitates its guiding in a guide track of the dispensing apparatus. The attachment section and the guide section are interconnected. The attachment section and the guide section are each in the form of a hollow body and include an internal flow passage for the gas by which the foil balloon is inflated. The attachment section is further provided with a discharge opening for the gas.
The adapter part consists preferably of a plastic material and can be produced by a plastic injection molding process.
The design of the adapter part in the form of an attachment section and a guide section permits a function-specific adaptation of each section. The attachment section is formed so as to permit the attachment to, and the filling with gas of, the foil balloon. The guide section is provided for guiding the foil balloon within the dispensing apparatus during storage and during inflation of the balloon with gas. Both sections together form a continuous flow passage for the gas with which the foil balloon is being filled and which flows into the interior of the foil balloon via the discharge opening in the attachment section.
The attachment section can be connected to the foil balloon before its storage in the dispensing apparatus. Upon placement of the foil balloon into the dispensing apparatus the guide section is inserted into the respective guide track in which the adapter part is slidably supported. Advantageously, the guide section is accommodated form-fittingly in the guide track within the dispensing apparatus so as to be movable over the full length of the guide track. The adapter part has thereby multiple functions: first, to guide the foil balloon within the dispensing apparatus, second, to provide support during the filling of the foil balloon with gas, and finally to provide for a durable attachment to the foil balloon also outside the dispensing apparatus.
The attachment section and the guide section are releasably inter-connected that is the guide section and the attachment section are joined for storage within the dispensing apparatus and the filling of the balloon with gas but can be separated from one another upon discharge of the balloon from the dispensing apparatus. When separated from one another the attachment section and guide section are still inter-connected but only by a string so that the guide section can be held by a hand while the foil balloon is retained via the string connected to the attachment section. Consequently the guide section forms a handle part outside the dispensing apparatus.
The weight of the guide section plus the weight of the attachment section may be greater than the lifting capability of the helium-filled balloon. In this way it is ensured that the helium-filled balloon will not unintentionally fly off.
In an advantageous embodiment the releasable connection between the attachment section and the guide section includes a pre-set breaking point. Via the pre-set breaking point the attachment and the guide section are integrally interconnected but can be broken apart upon application of a predetermined separating force. But the two parts are still joined by the string. Such an interconnection by a breaking point has also the advantage that the two sections can be manufactured as a single part, preferably of a plastic material and can be manufactured in a single manufacturing step, preferably by a plastic material injection molding process.
The attachment section and the guide section which are interconnected by a string are, in accordance with a further advantageous embodiment of the invention, each provided with an annular winding groove for accommodating the string. During storage within the dispensing apparatus the string is accommodated in each of the winding grooves. When the attachment and guide sections are separated the string is partially or completely unwound from the winding grooves.
It is also possible to provide only a single winding groove, either on the attachment section or on the guide section, onto which the string is wound during storage of the foil balloon in the dispensing apparatus.
The pre-set breaking point may for example be provided along an annular wall which delimits a winding groove. Upon breaking of the pre-set breaking point the winding grooves should remain intact.
According to a further advantageous embodiment the attachment section includes a cone-shaped flow guide part. The flow passage for the gas with which the foil balloon is filled extends through the cone-shaped flow guide part. The cone-shape of the flow guide part facilitates the insertion of the tip of the flow guide part into the foil balloon or into a valve provided on the foil balloon.
In place of a conical flow guide part also flow guide parts of other geometric shapes with internal flow passages may be used, for example cylindrical parts.
In a further advantageous embodiment the flow guide part is provided at its tip with an axial projection which serves as an aid for the insertion of the flow guide part into a gas supply opening on the foil balloon or into a valve provided on the foil balloon.
In still a further advantageous embodiment the flow guide section is provided with an annular guide groove by which the flow guide section is guided in the guide track of the dispensing apparatus.
Advantageously, the guide track includes two individual tracks arranged at opposite sides of the annular guide groove in the guide section and between which the guide groove extends in a form-fitting manner.
In still another advantageous embodiment, the adapter part, in particular the guide section, is provided with one or several engagement arms for holding the foil balloon in the folded or rolled-up state. The engagement arms engage the non-filled foil balloon and securely hold it on the adapter part while it is stored in the dispensing apparatus. It is generally sufficient to provide only one engagement arm which, if necessary, may be relatively wide to apply to a folded packet of non-filled foil balloons a holding force over a relatively large area.
Also, two engagement arms may be used to ensure a better and more secure engagement of the foil balloon. The engagement arm or arms may be formed integrally with the adapter part. Additionally, or as an alternative, the adapter part may be cemented to the foil balloon.
A further aspect of the invention concerns a foil balloon which is provided with an adapter part as described earlier, wherein the attachment section of the adapter part is attached to the foil balloon and the outflow nozzle of the attachment section can be brought into flow connection with the interior of the foil balloon. The foil balloon may for example be provided with a valve into which the outflow nozzle extends. The balloon valve may be for example in the form of a spout check valve which automatically closes and retains the gas volume in the interior of the foil balloon. The pressure of the gas supplied via the attachment section moves the balloon valve from the closed to the open position in which the gas can flow into the foil balloon. As soon as the supply gas pressure drops below a predetermined limit valve the balloon valve closes again automatically.
The foil balloon can be connected to the attachment section of the adapter part by cementing, by a mechanical structure for example by means of a clamping ring or by welding, especially if the foil balloon consists of a plastic material.
In an advantageous embodiment, the foil balloon is provided with a projecting strap via which it may be connected to the attachment section of the adapter part. The balloon strap may be attached by means of the string. The balloon strap may possibly include an inflow opening for the gas to be conducted into the balloon.
A further aspect of the invention relates to an automatic foil balloon dispensing apparatus for accommodating and dispensing one or several of the balloons described earlier. The dispensing apparatus includes the described adapter parts. The dispensing apparatus may be in the form of an automatic sales apparatus which, after insertion of money or another payment method, dispenses a balloon filled with a gas. In the automatic dispensing apparatus preferably a multitude of foil balloons can be stored in a non-filled state. Upon demand, a foil balloon is filled with gas and is then dispensed. In a non-filled state, the foil balloons are stored in the dispensing apparatus preferably in a space-saving manner either in the form of a roll or in a folded state.
The dispensing apparatus includes at least one guide track for accommodating and guiding the adapter part of the foil balloon. Advantageously, a plurality of such adapter parts including foil balloons can be guided in the guide track. It is further possible to arrange in the dispensing apparatus a rotatable magazine with several parallel guide tracks wherein each guide track accommodates a plurality of adapter parts including foil balloons. The various guide tracks are arranged distributed over the circumference of the magazine and can be moved to a dispensing position by rotation of the magazine about its longitudinal axis so that any particular desired foil balloon can be inflated and dispensed. Advantageously, each guide track includes balloons of only the same type. The balloon of different guide tracks may differ for example in size, color, or imprinted designs. This permits the customer to select from different types of foil balloons.
The dispensing apparatus further includes a nozzle which can be connected to a gas reservoir, in particular a gas cylinder which is preferably disposed within the dispensing apparatus but which also may be arranged without the dispensing apparatus. It is also possible to arrange several gas cylinders within the dispensing apparatus, for example five gas cylinders so as to permit a switch over to another gas cylinder when a gas cylinder is empty.
As gas for example helium is used. But another gas such as for example air may also be used. The gas is conducted from the gas reservoir via the adapter part and, if present, the balloon valve into the foil balloon. The nozzle is adjustable by a control drive between an advanced functional position, in which a flow connection to the adapter part is established and a retracted non-functional position, in which the gas flow to the adapter part is interrupted. The nozzle is connected to the gas reservoir preferably by a hose. In the hose or at the gas reservoir a valve may be arranged for controlling the gas flow. Gas is supplied to the interior of the foil balloon only in the advanced functional position of the nozzle to which it is moved by a control drive. In the retracted non-functional position the foil balloon can not be filled with gas.
The nozzle may be movable in two different directions, for example horizontally or vertically, preferably by two different drives. With the horizontal and the vertical movability the nozzle can be moved for example horizontally into the adapter part and vertically, together with the adapter part and the foil balloon, into a position suitable for filling the foil balloon with gas.
As control drive for moving the nozzle between the functional and non-functional positions, for example, a linear motor may be used.
Next to the guide track in the dispensing apparatus at least one ejector ramp may be arranged whose purpose it is to cause, during the movement along the guide track, the release of the still folded foil balloon from engagement by the holding arms of the adapter part, so that the foil balloon can freely unfold when it is inflated by the gas. The at least one ejector ramp, or for example two ejector ramps extend parallel to the guide track and are provided with a ramp-like section which is arranged at an angle with respect to the guide track.
In accordance with a further advantageous embodiment, a barcode is imprinted on the foil balloon with information regarding technical parameters which are specific for the particular foil balloon, for example information concerning the gas pressure and the filling amount. The barcode can be read by a barcode scanner and the respective information can be processed in a control unit and utilized for controlling the gas flow to the balloon.
A further aspect of the invention concerns a method for the operation of the above-described dispensing apparatus. Herein, in a first step, the nozzle is moved from a non-functional position, in which a gas flow connection between the nozzle and the adapter part is established so that the foil balloon can be filled with gas. Then, after completion of the inflation procedure, in a second step, the nozzle is first moved still further into the adapter part and subsequently pulled completely out of the adapter part. The movement of the nozzle further into the adapter part causes a release of the attachment section which is arranged directly on the foil balloon from the guide section which is guided in the guide track of the dispensing apparatus.
The gas-filled foil balloon may be taken for example out of a collection basket arranged at the outside of the dispensing apparatus. The guide section of the adapter part is coupled to the attachment section preferably by a string. After the full return of the nozzle, the guide section slides out of the guide tract so that the guide section can be manually grasped and the foil balloon can be held and guided via the string connection.
The invention will become more readily apparent from the following description of advantageous embodiments with reference to the accompanying drawings.
In the various figures identical components are designated by the same reference numerals.
The dispensing apparatus 1 is provided with a visual product display 2 and a selection display 3 as well as a money insertion arrangement 4. Above the money insertion arrangement 4, there is an arrangement for payment by credit or charge cards. By way of the selection display 3 a desired product as shown in the product display 2 can be selected. Optionally, a monitor 5 may be arranged on the dispensing apparatus 1. On the side of the dispensing apparatus 1 there is a collection basket 6 into which the filled foil balloons are released via a dispensing opening formed in the dispensing apparatus 1.
The design of the dispensing apparatus 1 is shown in greater detail in
In the dispensing apparatus are furthermore two gas cylinders 10 arranged which are filled with helium. Each of the gas cylinders 10 is connected via a hose 11, which includes a valve 12, with a nozzle 13 (
Each foil balloon 9 is provided with an attachment section 14a of an adapter part 14, which attachment section 14a is connected via a string 15 to a guide section 14b of the adapter part. The guide section 14b can be manually grasped in order to hold the inflated balloon and to carry it.
After the nozzle 13 is engaged in the adapter part 14, the nozzle 13 together with the adapter part 14 and the foil balloon 9 are moved vertically downwardly into a further track 18 by a further activation of the adjustment drive 16 so that the foil balloon is now in a position at the level of the collection basket 6. Then the valve 12 of the gas cylinder is opened so that gas flows from the gas cylinder via the hose and the nozzle 13 and the adapter part 14 into the foil balloon 9 and unfolds the balloon while inflating it (
In a further step as shown in
In a last step as shown in
At the outside of the conical attachment section 14a there is a wind-up groove 20a for accommodating the string 15. The wind-up groove 20a is arranged adjacent the guide section 14b which is also provided with a wind-up groove 20b so that the two wind-up grooves 20a and 20b of the two sections are positioned adjacent one another. While the foil balloon is stored in the dispensing apparatus the string 15 is wound up in the two wind-up grooves 20a and 20b.
The attachment section 14a is further provided with two retaining arms 21 which are parallel to each other and each extends from a wall that delimits the wind-up groove 20a. The two retaining arms are provided to hold the foil balloon in its folded or rolled-up state on the surface of the conical attachment section 14a. The two retaining arms are curved or, respectively, bent. With the introduction of gas into the foil balloon, the foil balloon is released from the engagement by the holding arms 21.
The guide section 14b has an annular shape. It is provided with an annular circumferential guide groove 22 via which the adapter part 14 is guided in the dispensing apparatus 1 in the guide track 8. The guide groove 22 facilitates the sliding of the adapter part 14 including the folded or rolled-up foil balloon 9 in one of the guide tracks along the guide track.
The attachment section 14a and the guide section 14b are a plastic component formed integrally in a common manufacturing process. They are joined by the breaking point 23. The breaking point by which the sections 14a and 14b are joined facilitates the disconnection of the two sections 14a and 14b when a sufficiently large separating force is applied to the sections 14a and 14b to separate them. This occurs—as described earlier—when, after inflation of the foil balloon, the nozzle 13 is moved so far into the guide section 14b that the front end of the nozzle abuts the attachment section 14a. Since the guide section 14b is held in the guide track, the impact of the nozzle results in a breaking of the breaking point 23 and the disconnection of the attachment section 14a from the guide section 14b.
It is furthermore shown in
In the embodiment of
By an additional application of cement, particularly in the form of a spot application, a section of the foil balloon 9 which is disposed directly on the cone of the attachment section 14a and cemented thereto may be cemented to additional layers of the foil balloon in order to secure the foil balloon in its folded state. Upon inflation of the foil balloon 9 the cemented spots 26 are ripped as the foil balloon is unfolded.
In the embodiment according to
The foil balloon 9 is rolled up also in the exemplary embodiment shown in
In the exemplary embodiment according to
In
In the shown exemplary embodiment only one engagement arm 21 is shown provided on the adapter part 14, which engagement arm 21 extends from the guide section at least approximately in axial direction. The engagement arm 21 is arranged spaced from the flow guide element of the attachment section 14a and parallel thereto. The folded foil balloon can be clamped that is held between the flow guide element of the attachment section 14a and the engagement arm 21.
The two delimiting walls of the wind-up groove 20b on the guide section 14b are provided with notches 31 and 32 for accommodating the string 15 by which the attachment section 14a and the guide section 14b are interconnected. The notches 31 and 32 are arranged angularly displaced. A further wall of the guide section 14b which delimits the guide groove 22 is provided with openings 33 permitting an attachment of the string.
The balloon strap 34 may be provided with an inflow opening 35 of the foil balloon (
The representations of
As apparent from the top view as shown in
1 foil balloon dispensing apparatus
2 product display
3 selection display
4 money insertion arrangement
5 monitor
6 collection basket
7 magazine
8 guide track
9 foil balloon
10 gas cylinder
11 hose
12 valve
13 nozzle
14 adapter part
14
a attachment section
14
b guide section
15 string
16 adjustment drive
17 seal ring
18 track
19 discharge opening
20
a wind-up groove
20
b wind-up groove
21 retaining arm
22 guide groove
23 breaking point
24 connecting groove
25 balloon valve
26 cement
27 spiral wire
28 clamping ring
29 clamping projection
30 projection (insertion aid)
31 notch
32 notch
33 opening
34 balloon strap
35 inflow opening
36 dispenser ramp
37 barcode
Number | Date | Country | Kind |
---|---|---|---|
10 2017 128 979.8 | Dec 2017 | DE | national |
This is a continuation-in-part application of pending international patent application PCT/DE2018/100940 filed Nov. 19, 2018 and claiming the priority of German patent application No. 10 2017 128 979.8 filed Dec. 6, 2017. Both the said international patent application PCT/DE2018/100940 and the said German patent application No. 10 2017 128 979.8 are incorporated herein by reference in their entireties as though fully set forth.
Number | Name | Date | Kind |
---|---|---|---|
3380490 | Ellenberg | Apr 1968 | A |
3536110 | West | Oct 1970 | A |
4088161 | Ikemoto | May 1978 | A |
4094267 | Davis, Jr. | Jun 1978 | A |
4094347 | Ikemoto | Jun 1978 | A |
4687458 | Handa | Aug 1987 | A |
4836128 | Walker | Jun 1989 | A |
5020467 | Van Patten | Jun 1991 | A |
5370161 | Shafer | Dec 1994 | A |
6109203 | Mears | Aug 2000 | A |
20070084878 | Handa | Apr 2007 | A1 |
Number | Date | Country |
---|---|---|
191322229 | Jun 1914 | GB |
144046 | Jun 1920 | GB |
Entry |
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English translation of the “International Search Report” for the corresponding International application No. PCT/DE2018/100940 dated Feb. 4, 2019 (2 pages). |
The English translation of the “Written Opinion of the International Searching Authority” for the corresponding international application No. PCT/DE2018/100940, (6 pages). |
The “Written Opinion of the International Searching Authority” for the corresponding international application No. PCT/DE2018/100940, (7 pages), in the German language. |
Number | Date | Country | |
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20190329143 A1 | Oct 2019 | US |
Number | Date | Country | |
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Parent | PCT/DE2018/100940 | Nov 2018 | US |
Child | 16504923 | US |