DE3518062C2 - Keyring - Google Patents

Abstract

A small, handy key chain is capable of generating sufficient buoyancy after falling into water so that the key chain with the attached keys and/or other objects can safely reach the water surface and be recovered. This key chain has a housing (31) which encloses an elastic means (32) held under pre-tension, two separate chambers (33, 34) and an inflatable cover (35). A housing section (36) consists of a material which loses its structural strength when in contact with water. After sufficient exposure to water, this housing section gives way, whereupon the elastic means causes the separation between the two chambers to be eliminated and the respective chamber contents react with one another to produce a gas which inflates the cover beyond the housing contour.

Description

The invention relates to a key chain with a housing in which there is a buoyancy device that can be activated by contact with water, for which purpose a material is provided that reduces its strength when it comes into contact with water. Such a key chain is known from DE-OS 28 36 790.

Keys are usually made of metal. A metal key that has accidentally fallen into the water will sink. To prevent this, well-known key chains are designed as floating bodies. In order to ensure the necessary In order to provide buoyancy, such a float must be relatively large, which considerably limits the ease of use and universal applicability. To remedy this, according to the above-mentioned, well-known proposal (cf. DE-OS 28 36 790), the float can be attached to the key chain using both a line and a water-soluble material. If this arrangement accidentally falls into the water, the float can detach from the key chain and still remain connected to it via the line. The key chain with the keys attached can sink while the float rises to the water surface. The latter can then be pulled to the water surface together with the objects attached to it via the connecting line between the float and the key chain and recovered.

This means that the float can be kept smaller because its buoyancy does not have to carry the entire key chain with the attached bunch of keys or similar to the water surface. However, the familiar key chain is still quite bulky because the key chain housing has to accommodate the float.

For further information on the state of the art, please refer to the following publications.

DE-PS 4 56 665 relates to a swimming and rescue device which has an inflatable float. In the description of the state of the art therein, mixtures of substances are mentioned which can generate a gas under water, independent of the atmospheric air, which can be used to fill supporting bodies. For example, calcium carbide or mixtures of tartaric acid with bicarbonate etc. can be used to generate gas, i.e. the gas development is always brought about by bringing together two reaction components such as calcium carbide with water, bicarbonate with an acid etc. However, the separate storage of the reaction components, which is always necessary before the gas development reaction is initiated, and the mixing of these together when necessary, is said to require complicated arrangements, which is said to have a negative impact on operational safety.

US-PS 12 90 927 relates to a lifebuoy or the like with a gas generating device. The gas generating device contains calcium carbide and a pre-tensioned spring which can act on a valve arrangement with a valve plate. In the normal position, the valve plate closes - against the pre-tension of the spring - a chamber containing the calcium carbide. The spring is released after sufficient contact with water has dissolved a dissolvable member or at least weakened it sufficiently so that the spring force of the spring can break this dissolvable member. This dissolvable member can be, for example, a block of sugar or any other suitably soluble substance. The relaxing spring presses the valve plate into the system on a second valve seat, preventing further access of water and allowing the water which has already penetrated the gas generating device to come into contact with the calcium carbide. The lifebuoy is inflated with the acetylene which is then formed.

US-PS 21 35 095 also relates to a lifebuoy or the like, the inflatable cover of which is connected to a gas source. The gas source can be a container whose interior is divided into two chambers. The two chambers contain different substances which, after mixing and reacting, produce a gas. The two chambers are separated from one another by a plate with a valve arrangement. In order to remove the initial separation of the two chambers by the valve arrangement, the user of the lifebuoy must apply mechanical pressure to the container or press a button against the preload of a spring.

In contrast, the object of the present invention is to provide a small, handy key chain which nevertheless generates sufficient buoyancy in water so that the key chain with the attached keys and/or other objects can safely reach the water surface and be recovered.

Starting from a key chain with a housing in which there is a buoyancy device that can be activated by contact with water, for which purpose a material is provided that reduces its strength when it comes into contact with water, the solution to the above problem according to the invention is characterized in that an inflatable cover serves as the buoyancy device, the gas required to inflate the cover can be generated by at least partial combination and reaction of two substances that were initially kept separate and are located within different chambers separated within the housing, the material that reduces its strength when it comes into contact with water forms a housing section that has a sealing effect on one or more connecting openings between the two chambers without the action of water, and which, when exposed to water and the strength of the housing section is reduced, releases this connecting opening(s) with the aid of an elastic means, so that the respective chamber contents can react with one another to inflate the cover beyond the housing contour.

Just a few grams of appropriately selected substances, kept separately in the two chambers, produce a sufficient amount of gas when combined to inflate a balloon that generates a buoyancy of 200 g or more in water. Since the inflated balloon that serves as a float is only formed when needed, after the key chain has fallen into the water, all components of the key chain according to the invention, including the required substances, can be accommodated in a small, handy housing. An exemplary key chain according to the invention has a cylindrical housing with a length of just 4 cm and a diameter of about 1.8 cm, weighs less than 30 g and is nevertheless able to generate a buoyancy of 200 g or more in water.

Advantageous embodiments and further developments of the invention emerge from the subclaims.

Thus, the housing of this key chain can preferably be designed as a hollow cylinder closed on one side, and the housing section which reduces its strength when in contact with water is a disk which closes the open hollow cylinder end. The housing can be made of thin, drawn sheet metal or of plastic, in particular a plastic which can be molded using an injection molding process. Suitable plastics for the housing are, for example, high-density polyethylene, nylon, selected polycarbonates and polyimides.

The housing section or the disc is made of a material whose strength is reduced or completely eliminated when it comes into contact with water. Suitable materials include water-soluble and/or water-swelling substances such as gelatin, water-soluble shellac, starch, water-soluble wood glue in sheet form and the like. These substances can be modified. For example, adding polyvinyl alcohol increases elasticity; furthermore, adding fillers such as silica can increase the compressive and breaking strength of gelatin or wood glue sheets. For example, pressed or cast discs made from a mixture of gelatin or dextrin and polyvinyl alcohol are well suited. Pressed parts made from powdered substances, in particular water-soluble substances such as sodium chloride, glucose, potassium bromide and the like are also well suited. Sheets made from cellulose, for example in the form of reinforced cardboard or pressed materials made from sawdust and water-soluble wood glue are also well suited.

Two chambers, initially separate from one another, are formed within the housing cavity. The first chamber preferably forms a container which is arranged so as to be movable within the housing. Despite the movable arrangement, a gas- and liquid-tight seal of the container with respect to the housing inner wall is provided, for example via an additional sealing means, such as an O-ring inserted within a groove on the outer wall of the container.

The other or second chamber then fills the remaining housing interior and is delimited by the closed housing end, the adjacent housing wall section and the adjacent end wall of the container; alternatively, the delimitation of the second chamber by the closed housing end can be replaced by a piston arranged displaceably within the housing.

The elastic means is preferably a helical spring subjected to compression. This helical spring consists of a spring-elastic material, such as steel, stainless steel or a selected plastic.

A valve arrangement with a valve seat and a valve body serves to at least initially separate the two chambers. The elastic means is preferably arranged and clamped in such a way that it tries to move the valve body from the closed position to the open position of the valve arrangement. In the closed position, the valve body is preferably supported on the housing section, which reduces or completely loses its strength when it comes into contact with water. After sufficient exposure to water, this housing section gives way and allows the valve body to be moved, opening the valve arrangement so that the separation between the two chambers is eliminated. In this process, at least one or more connecting openings between the two chambers are released so that the respective contents of the two chambers can mix with one another and react with one another. In other words, the housing section which reduces its strength upon contact with water acts in the absence of water to seal one or more connecting openings between the two chambers, and upon exposure to water this housing section reduces its strength and releases this connecting opening(s) with the aid of an elastic means so that the respective chamber contents can react with one another to inflate the shell beyond the housing contour.

A combination of substances is selected that react with each other at room temperature under normal conditions and produce a gas that can inflate the envelope into a balloon. To ensure a rapid reaction, a solid and a liquid component are preferably selected. The solid component is preferably housed inside the container that can be moved in the housing.

A number of substance combinations are known which react with one another to form gas and which can be used in the context of the present invention. Suitable substance combinations include, for example, diluted inorganic acids, such as sulfuric acid or hydrochloric acid in combination with a carbonate compound, such as sodium carbonate, sodium bicarbonate or ammonium carbonate. Such a substance combination can be stored separately for practically any length of time and, when in contact with one another, quickly forms carbon dioxide, i.e. an odorless and non-flammable gas. Such a substance combination is preferably used.

Other suitable combinations of substances include the diluted inorganic acids mentioned in combination with a metal powder, such as zinc powder, so that hydrogen is formed when the reactants are brought together. Another suitable combination of substances includes the reactants carbide and water, which react with each other to form acetylene.

A particularly preferred gas-generating system is the combination of dilute inorganic acid, namely hydrochloric acid or sulphuric acid, in conjunction with sodium bicarbonate. A volume ratio of about 2 parts by volume of liquid to 1 part by volume of sodium bicarbonate powder is preferably used. The sodium bicarbonate can be used in the form of a loose, gas-permeable powder or in the form of a pressed article which is provided with recesses to ensure gas extraction.

The gas produced by the reaction of the two substances is fed into a shell and inflates it into a balloon. The expanding shell pushes the housing section, which has become softened and deformable due to the action of water, out of its holder so that the balloon can expand beyond the contour of the key chain and generates the necessary buoyancy to bring the key chain with the objects attached to it to the water surface. Without being limited to this, the amount of gas-generating substances is selected so that at least 200 g of buoyancy is generated.

As explained, the present invention provides a small, handy key chain that can be handled safely under normal conditions. Under normal conditions of use, the preferably provided disc made of a material that reduces its strength when in contact with water securely closes the open end of the housing and also withstands the mechanical stresses and temperatures of at least 100°C that are typically to be expected. Only after intensive contact with liquid water, for example if the key chain has fallen into water, does the strength of this material decrease. It is not necessary for the material to dissolve or otherwise degrade. Rather, because this disc is under the mechanical pressure of the elastic means, a significant reduction in its strength is sufficient for the material to give way under the combined effect of water and pressure and to allow the valve arrangement to open under the mechanical pressure of the elastic means, thereby releasing the connecting opening(s) between the two chambers.

In the following, the invention will be explained in more detail by means of preferred embodiments with reference to the drawings; the latter show

Fig. 1 shows a schematic sectional view of a first embodiment of a key fob according to the invention;

Fig. 2 shows a schematic sectional view of a second embodiment of the key fob according to the invention; and

Fig. 3 shows a schematic sectional view of a third embodiment of the key fob according to the invention.

The embodiments described below with reference to the drawings serve to further explain the invention without limiting it.

Fig. 1 shows a first embodiment of a key chain 10 according to the invention. This key chain 10 has a hollow cylinder housing 11 that is essentially closed on one side and has the cylindrical side wall 26 , the closed end 27 and the open end 28. A projection with an eyelet 29 for attaching a spring ring (not shown) can be formed on the closed end 27 , which in turn serves to attach the keys and/or other objects. Alternatively, the eyelet 29 could also be guided as a curved hole through a section of the housing 11. The housing 11 can be made of conventional durable materials, for example non-corrosive sheet metal or plastic. It is particularly simple and expedient to produce the housing using an injection molding process from a suitable plastic.

Two separate chambers 13 and 14 are formed within the housing 11. The separation causes a valve arrangement with the valve seat 17 and the valve body 18. In the present case, the valve seat 17 is formed by an annular projection protruding inwards from the housing side wall 26. The valve body 18 is formed by the peripheral edge section of the end wall 18 of the chamber 13. A sealing means such as an O-ring 19 can be inserted between the valve seat 17 and the valve body 18 .

The chamber 13 is formed within a container 13 which is movably arranged within the housing interior.

The escape of gas and/or liquid through the annular gap between the inner wall of the housing and the outer wall of the container is prevented by a further sealing means 20. The container has a stable upper end wall 18 and a stable lower end wall 21. The side wall between these two end walls 18, 21 is provided with sufficiently large openings or perforations through which liquid can pass and react with the solid within the chamber 13. For example, the upper section of this "side wall" can be designed as a cage with adjacent webs, between which sufficient gaps remain for the liquid to pass through.

The lower end wall 21 of the chamber or container 13 is provided with a central opening which is delimited by a short nozzle 22. The inflation opening of an envelope 15 , such as a small balloon, is attached in a pressure-tight manner to the outer circumference of this nozzle 22 .

The lower end wall 21 of the container or chamber 13 is supported via an annular spacer 23 on the inside of a plate 16 made of a material that reduces its strength when in contact with water. This disk 16 can consist, for example, of a cast plate made of dextrin and polyvinyl alcohol. The disk 16 is inserted along its circumference into a groove cut out on the inner wall of the housing, with preferably only a comparatively narrow disk edge section being supported.

A pre-stressed elastic means, for example a helical spring 12 subjected to compression, is inserted between the upper end wall 18 and the closed housing end 27. The helical spring 12 exerts a permanent pressure on the displaceably arranged container 13 , which in turn is supported on the disk 16 via an annular spacer 23. As long as the strength of the disk 16 is not reduced by the effects of water, the disk 16 not only withstands the stresses normally expected of a key fob, but also a multiple of the pressure exerted by the spring 12 .

Such dimensions and manufacturing measures are provided that the valve arrangement ensures a liquid-tight seal between the chambers 14 and 13. Only after a significant decrease in the strength of the disk 16 is the spring 12 able to displace the container 13 to such an extent that liquid can pass between the valve seat 17 and the edge of the upper end face 18 and reach the chamber 13 in order to react there with the solid material to form gas.

In an exemplary embodiment, the volume of the chamber 14 is just under 4 cm ³ and is filled with dilute inorganic acid, for example 20% hydrochloric acid or 2 normal sulfuric acid. The volume of the container 13 is approximately 2 cm ³ and is filled with powdered sodium bicarbonate. The entire key chain 10 has a length of 4 cm. If this key chain with a weight of, for example, 200 g attached were to be thrown into the water, the key chain would initially sink, but would float back to the water surface after approximately 5 to 15 minutes due to the buoyancy generated by the inflated balloon 15 .

Fig. 2 shows a second embodiment 30 of a key fob according to the invention. The key fob 30 is essentially constructed in a similar way to the key fob 10. Again, a hollow cylindrical housing 31 closed on one side is provided, in the interior of which the two separate chambers 33 and 34 are formed.

The chamber or container 33 is arranged displaceably within the housing and is supported by an annular spacer 43 on a plate 36 which closes the open end of the housing and consists of a material which reduces its strength when in contact with water. The lower end wall 41 of the container 33 has a central opening delimited by a short nozzle 42 to which the mouthpiece of an inflatable balloon 35 is attached. The edge section of the upper end wall 38 of the container 33 serves as a valve body opposite a valve seat 37 .

In contrast to embodiment 10 according to Fig. 1, the upper chamber 34 intended for receiving liquid is delimited at its upper end - remote from chamber 33 - by a movable plunger 44 which is sealed liquid-tight against the inner wall of the housing by means of the seal 45. The compression spring 32 is inserted into the remaining space between the movable plunger 44 and the closed housing end 47. Within the cavity enclosed by the helical spring 32 , a spring guide made of fitting pieces 46, 48 can be provided on the inner wall of the housing end and on the top of the plunger 44 , which rest against one another and thus relieve the spring 32 as long as the disk 36 is not deformed. In this way, the contact pressure of the valve body 38 on the valve set 37 can be kept greater than the counter pressure of the spring 32 .

After exposure to water has reduced the strength of the disk 36 , this disk 36 gives way and the compression spring 32 moves the movable plunger 44 towards the open end of the housing. This not only moves the container 33 , thereby opening the valve arrangement 37 and 38 , thereby releasing the connecting opening between the two chambers 33 and 34 , but the plunger 44 moved under the spring pressure also pushes the liquid in the chamber 34 through the open valve arrangement into the chamber 33 , so that an accelerated reaction with the solid material located there can take place.

Fig. 3 shows a further embodiment 50 of a key chain according to the invention. The key chain 50 is also constructed essentially analogously to the key chain 10 according to Fig. 1. Again, two chambers 53 and 54 separated from one another by a valve arrangement are formed within a hollow cylindrical housing 51 closed on one side. The chamber or container 53 is arranged displaceably within the housing 51. The lower end wall 61 of the container 53 is provided with a central opening through which a hollow sleeve 62 projects into the interior of the container. The mouthpiece of an inflatable balloon 55 is attached to the lower end section 64 of the sleeve 62. The sleeve 62 is provided with a number of openings 63 through which the gas developed within the container 53 can flow in order to inflate the balloon 55. At the upper end of the sleeve 62 there is a T-shaped head piece which forms the valve body 58 of the valve arrangement. The valve seat 57 is formed by a suitable bulge 69 in the upper end wall 65 of the container 53. To increase the tightness, a sealing agent 59 can be inserted between the valve seat 57 and the valve body 58. Cotton wool 66 can be located within the bulge to ensure that the valve can move relative to the valve seat 57 and to better distribute the liquid that has penetrated through the connecting opening 60 .

The valve body 58 is supported by the sleeve 62 on the disk 56 which closes the open end 68 of the housing 51 and which consists of a material which reduces its strength when in contact with water. The open housing end 68 is flanged inwards so that an abutment for the compression spring 52 results. As shown, this compression spring 52 is inserted between the lower, open housing end 68 and the lower end wall 61 of the container 53 and attempts to push this container upwards onto the chamber 54 filled with liquid. The mechanical pressure exerted by the spring 52 acts via the hydrostatic pressure in the chamber 54 through a connecting opening 60 in the bulge 69 of the upper end wall 65 on the head piece at the upper end of the sleeve 62 . The sleeve 62 transfers this pressure to the disk 56 , so that after the disk strength has decreased, the hydrostatic pressure displaces the head piece and thus the valve body 58 downwards and opens the valve arrangement, so that the liquid in the chamber 54 can enter the chamber 53 through the connecting opening 60 under the mechanical pressure of the spring 52 and react with the solid present there, developing gas.

Claims (19)

1. Key chain, with a housing in which there is a buoyancy device that can be activated by contact with water, for which a material is provided that reduces its strength when in contact with water, characterized in that
an inflatable cover ( 15, 35, 55 ) serves as the buoyancy device,
the gas required to inflate the envelope can be produced by at least partial combination and reaction of two initially kept separate substances which are located within different chambers ( 13, 14; 33, 34; 53, 54 ) separated within the housing ( 11, 31, 51 ),
the material which reduces its strength on contact with water forms a housing section ( 16, 36, 56 ) which, without the action of water, has a sealing effect on one or more connecting openings between the two chambers and which, when exposed to water and the strength of the housing section is reduced, releases these connecting openings ( 60 ) with the aid of an elastic means ( 12, 32, 52 ) so that the respective chamber contents can react with one another to inflate the casing beyond the housing contour. 2. Key chain according to claim 1, characterized in that
the housing ( 11, 31, 51 ) is a hollow cylinder closed on one side, and
the housing portion ( 16, 36, 56 ) which reduces its strength in contact with water is a disc which closes the open hollow cylinder end. 3. Key chain according to claim 2, characterized in that the disc ( 11, 31, 51 ) is supported only along a narrow edge section. 4. Key chain according to one of claims 1 to 3, characterized in that the housing section ( 16, 36, 56 ) consists of a molded material containing polyvinyl alcohol. 5. Key chain according to one of claims 1 to 4, characterized in that the first chamber ( 13, 33, 53 ) is a container which can be moved within the housing ( 11, 31, 51 ). 6. Key chain according to one of claims 1 to 5, characterized in that the first chamber or the container ( 13, 33, 53 ) is filled with a powdered solid. 7. Key chain according to one of claims 1 to 6, characterized in that the elastic means ( 12, 32, 52 ) is a compression-loaded helical spring. 8. Key chain according to claim 7, characterized in that the helical spring ( 12, 23 ) presses the first chamber or the container ( 13, 33 ) in the direction of the housing section ( 16, 36 ). 9. Key chain according to one of claims 5 to 8, characterized in that the second chamber ( 14, 34, 54 ) in the remaining hollow cylinder is formed adjacent to the end wall ( 18, 38, 64 ) of the container ( 13, 33, 53 ) adjacent to the closed hollow cylinder end ( 27, 47 ). 10. Key chain according to one of claims 5 to 9, characterized in that the second chamber ( 34 ) is formed between the end wall ( 38 ) of the container ( 33 ) and a displaceable stamp ( 44 ) within the legal hollow cylinder space. 11. Key chain according to one of claims 1 to 10, characterized in that the second chamber ( 14, 34, 54 ) contains a liquid. 12. Key chain according to one of claims 1 to 11, characterized in that a valve arrangement with valve seat ( 17, 37, 57 ) and valve body ( 18, 38, 58 ) serves to separate the two chambers ( 13, 14; 33, 34; 53, 54 ). 13. Key chain according to claim 12, characterized in that a projection protruding inwards from the hollow cylinder inner wall serves as the valve seat ( 17, 37 ), and the edge section of the end face of the container ( 13, 33 ) serves as the valve body ( 18, 38 ). 14. Key chain according to claim 12 or 13, characterized in that
the end face ( 21, 41 ) of the container ( 13, 33 ) adjacent to the disc ( 16, 36 ) is provided with an opening,
e this opening is limited by a nozzle ( 22, 42 ), and
the casing ( 15, 35 ) is attached to this nozzle ( 22, 42 ) in a gas-tight manner. 15. Key chain according to one of claims 12 to 14, characterized in that an annular spacer ( 23, 43 ) is inserted between the end face ( 21, 41 ) of the container ( 13, 33 ) and the disc ( 16, 36 ). 16. Key chain according to claim 11, characterized in that
a section of the end face ( 65 ) of the container ( 53 ) provided with an opening ( 60 ) serves as the valve seat ( 57 ),
a sleeve ( 62 ) extending through the container end wall ( 61 ) is arranged within this container ( 53 ), and
this sleeve ( 62 ) has a T-shaped head piece serving as a valve body ( 58 ). 17. Key chain according to claim 16, characterized in that
the sleeve ( 62 ) is provided with a number of openings ( 63 ), and
the cover ( 55 ) is attached to the end of the sleeve ( 62 ) which projects beyond the container end wall ( 61 ). 18. Key chain according to claim 17, characterized in that the end of the sleeve ( 62 ) is supported on the disc ( 56 ). 19. Key chain according to one of claims 11 to 18, characterized in that a sealing means ( 19, 39, 59 ) is inserted between the valve seat ( 17, 37, 57 ) and the valve body ( 18, 38, 58 ).