This disclosure relates to umbrellas that can be used as a canopy to protect a user against rain or sunlight.
Umbrellas, or parasols, can be used as a canopy to protect a user from the sun, wind or rain. Umbrellas may be portable structures or may be fixed to the ground. Umbrellas may include a shaft that has a handle at one end and a canopy at the other end. A collapsible canopy support structure may be included to support the canopy and, when not in use, allows for the canopy to collapsed. The collapsible canopy support structure may also include multiple arms that radiate from the shaft to tension the canopy when erected. A problem with umbrellas is that they catch the wind and the force exerted by the wind on the underside of the canopy can turn the umbrella inside out (e.g. invert the collapsible canopy structure).
The above references to the background art do not constitute an admission that the art forms part of the common general knowledge of a person of ordinary skill in the art. The above references are also not intended to limit the application of the umbrella as disclosed herein.
Disclosed herein is an umbrella. The umbrella may comprise an elongate member having proximal and distal end portions. The umbrella may also comprise a support structure that is connectable to a canopy able to be disposed about the distal end portion of the elongate member. The support structure may be adjustable between an erect position, whereby the canopy is able to be tensioned by the support structure, and a collapsed position, whereby the tension in the canopy is able to be released. The umbrella may also include a collar having an interior channel formed therethrough, the channel being configured to receive therethrough the elongate member. The umbrella may further include a plurality of biasing means mounted to both the support structure and the collar. Each biasing means may be configured to bias the support structure towards, so as to maintain the support structure in, the erect position when a force is applied to an underside of the canopy to inhibit the support structure from inverting.
In some forms, each biasing means may be pivotally mounted to the support structure. This allows for the biasing means to move with the support structure when the umbrella is adjusted between its erect and collapsed positions.
In some forms, each biasing means may be resilient and curved along its length in its neutral position such that the biasing means is able to bend when the force is applied to the underside of the canopy and the resilience of the biasing means biases it towards its neutral position. Advantageously, the biasing means may oppose a force applied to the arms by a force (e.g. wind) that is applied to the underside of the canopy.
In some forms, when the umbrella is in an inverted position, each biasing means may be able to move towards its neutral position (i.e. by tending to straighten) upon release of the applied force such that the support structure is biased towards the erect position. This enables the umbrella to be self-righting.
In some forms, the support structure may comprise a slider connected to the elongate member. The slider may be able to move along the elongate member between locations intermediate the proximal and distal end portions of the elongate member. The support structure may also comprise a plurality of arms, each arm being disposed about and pivotally connected to the distal end portion of the elongate member. The support structure may further comprise a plurality of rods, each rod being disposed about and pivotally connected to both the slider and a respective arm. In use, movement of the slider along the elongate member towards the distal end portion of the elongate member can cause each rod to pivot the arm to which it is connected away from the elongate member such that the slider is able to adjust the support structure into the erect position. Further, movement of the slider along the elongate member towards the proximal end portion of the elongate member can cause each rod to pivot the arm to which it is connected towards the elongate member such that the slider is able to adjust the support structure into the collapsed position.
In some forms, each arm may comprise first and second ends. The first end may be spaced from the elongate member when the support structure is in the erect position. The second end may be pivotally connected to the distal end portion of the elongate member.
In some forms, each arm may comprise a first connector. The first connector may be mounted intermediate the first and second ends of the arm such that the first connector is fixed in position along the arm. Each arm may also comprise a second connector. The second connector may be mounted intermediate the first connector and the second end of the arm such that the second connector can be fixed in position along the arm.
In some forms, each rod may be pivotally connected to a respective first connector.
In some forms, each biasing means may be pivotally connected to a respective second connector.
In some forms, the second connectors may be fixed to the arms.
In some forms, the first connectors may each comprise an integral projecting finger. Each projecting finger may include an aperture adapted to receive a pin about which each rod may rotate.
In some forms, the second connectors may each comprise a single integral projecting finger. Each projecting finger may include an aperture adapted to receive a pin about which each biasing means may rotate.
In some forms, the biasing means may be bifurcated at its end to locate on cither side of the projecting finger of the second connector.
In some forms, the support structure may further comprise a plurality of canopy tensioners. Each canopy tensioner may be connected to the first end of a respective arm.
In some forms, each canopy tensioner may comprise a body having an internal cavity that is adapted to receive the arm to which it is connected. Each canopy tensioner may also comprise shoulders that are integrally formed with and extend away from the body. The shoulders may be configured to be received by and tension the canopy when the support structure is in the erect position.
In some forms, each canopy tensioner may comprise an alignment member having an internal cavity that is adapted to receive the arm to which it is connected; and shoulders that are integrally formed with and extend away from the alignment member, the shoulders configured to be received by and tension the canopy when the support structure is in the erect position. In some forms, the shoulders may be connected (i.e. not integrally formed with) the alignment member.
In some forms, each canopy tensioner may further comprise a resilient member that, in use, can be disposed about the first end of a respective arm. The resilient member may be constrained from movement along the arm by the body and a locater that is mounted to the arm. The locator may be spaced from the first end of the arm. This allows for the tension in the canopy and support structure to be limited in the event that the canopy inverts.
In some forms, each canopy tensioner may further comprise opposing resilient members that, in use, are disposed adjacent a respective arm, the resilient members being connected at either end and constrained from movement along the arm by the alignment member and a locater that is mounted to the arm, the locator being spaced from the first end of the arm.
In some forms, the resilient member may be a coil spring through which a portion of the arm extends.
In some forms, the resilient members are leaf springs that are integrally formed with the alignment member and the locator. In some forms, an outer portion of the leaf springs may form the shoulders of the canopy tensioner.
In some forms, an end of the spring may engage the locator and its opposite end may engage a wall of the body.
In some forms, the alignment member may be configured to telescopically translate along a respective arm when the support structure is adjusted between the collapsed and erect positions.
In some forms, the umbrella may further comprise a collar having an interior channel formed therethrough. The channel may be configured to receive therethrough the elongate member, a plurality of projections may be integrally formed with the collar. The projections may extend radially about the collar. The umbrella may also comprise a plurality of recesses. Each recess may be defined between adjacent projections. Each recess may be configured to receive therein an end of a respective biasing means such that the biasing means may be pivotally mounted to the collar.
In some forms, the collar may be slidably mounted to the elongate member and, in use, may be located intermediate (e.g. between) the slider and the pivotal connection between the arms and the elongate member.
In some forms, each projection may comprise a groove formed therethrough. The grooves may be adapted to receive a retainer that is disposed about the collar.
In some forms, each biasing means may comprise an aperture that is able to receive the retainer such that the biasing means can be pivotally mounted to the collar.
In some forms, the retainer may be a length of wire that is threaded through the projection grooves and the apertures of the biasing means.
In some forms, the umbrella may further comprise a locking means that is configured to lock the slider to the elongate member when the support structure is erected.
In some forms, the biasing means may be a leaf spring.
In some forms, the biasing means may be a sprung member.
In some forms, the elongate member may further comprise a handle located at the proximal end.
Also disclosed herein is an umbrella that may comprise an elongate member having proximal and distal end portions. A support structure that is connectable to a canopy may be disposed about the distal end portion of the elongate member. The support structure may be adjustable between an erect position, whereby the canopy is able to be tensioned by the support structure, and a collapsed position, whereby the tension in the canopy is able to be released. The umbrella may also comprise a plurality of canopy tensioners connected to the support structure. Each canopy tensioner may comprise an alignment member having an internal cavity that is adapted to receive a respective arm of the support structure and shoulders that are integrally formed with and extend away from the alignment member. In other forms, the shoulders may be connected to (i.e. not integrally formed with) the alignment member. The shoulders may be configured to be received by and thereby tension the canopy when the support structure is in the erect position.
In some forms, each canopy tensioner may further comprise opposing resilient members that, in use, are disposed about a respective arm, live resilient member being connected at either end and constrained from movement along the and by the alignment member and a locater that is mounted to the arm, the locator being spaced from an end of the arm.
In some forms, the canopy tensioner may be configured to reduce the hoop stress in the canopy when the support structure is adjusted between the erect position and an inverted position. In some forms, each alignment member may be configured to displace laterally with respect to its respective elongate member upon adjustment of the support structure between the erect position and the inverted position to thereby decrease a combined length of each canopy tensioner and its respective elongate member to thereby reduce the hoop stress in the canopy.
Also disclosed herein is an umbrella that comprises an elongate member having proximal and distal end portions. A support structure that is connectable to a canopy may be disposed about the distal end portion of the elongate member. The support structure may be adjustable between an erect position, whereby the canopy is able to be tensioned by the support structure, and a collapsed position. The tension in the canopy may be able to be released. The umbrella may also comprise a plurality of biasing means mounted to both the support structure and the distal end portion Of the elongate member. Each biasing means may be configured to bias the support structure towards, so as to return the support structure to, the erect position when the umbrella is inverted. Advantageously, this allows for the umbrella to be self-righting, in that the umbrella can return itself to the erect position in the event that that canopy and support structure are inverted (e.g. the umbrella is folded inside out).
Embodiments will now be described by way of example only, with reference to the accompanying drawings in which
In the following detailed description, reference is made to accompanying drawings which form a part of the detailed description. The illustrative embodiments described in the detailed description, depicted in the drawings and defined in the claims, are not intended to be limiting. Other embodiments may be utilised and other changes may be made without departing from the spirit or scope of the subject matter presented. It will be readily understood that the aspects of the present disclosure, as generally described herein and illustrated in the drawings can be arranged, substituted, combined, separated and designed in a wide variety of different configurations, all of which are contemplated in this disclosure.
Referring firstly to
The umbrella 1 includes a plurality of biasing means, in the form of leaf springs 13, mounted to both the support structure 9 and the distal end portion 7 of the shaft 3. Each leaf spring 13 is configured to bias the support structure 9 towards, so as to maintain the support structure 9 in, the erect position when a force (e.g. wind) is applied to an underside 15 of the canopy 11 to inhibit the support structure 9 from inverting (e.g. turning inside out). Each leaf spring 13 is pivotally mounted to the support structure 9. The leaf springs 13 are also able to bias the support structure 9 and canopy 11 towards the erect position in the event that the support structure and canopy are inverted (
Referring now to
Movement of the collar 17 along the shaft 3 towards the distal end portion 7 of the shaft 3 causes each spoke 21 to pivot the arm 19 to which it is connected away from the shaft 3 such that the collar 17 is able to re-position, or adjust, the support structure 9 into the erect position. Movement of the collar 17 along the shaft 3 towards the proximal end portion 5 of the shaft 3 causes each spoke 21 to pivot the arm 19 to which it is connected towards the shaft 3 such that the collar 17 is able to re-position, or adjust, the support structure 9 into the collapsed position.
The arms 19 include first 23 and second 25 ends. The first end 23 of the arms 19 is set away (e.g. spaced) from the shaft 3 when the support structure is in the erect position. The second end 25 of the arms 19 is pivotally connected to the distal end portion 25 of the shaft. The arms 19 have a first connector, in the form of mount 27. The mount 27 is mounted intermediate the first 23 and second 25 ends of the arm 19 such that the mount 27 is fixed in position along the arm 19. Referring now to
To inhibit the umbrella from inverting (e.g. folding itself inside out), each leaf spring 13 is resilient and curved along its length in its neutral position. The leaf springs 13 are able to bend when a force is applied to the underside 15 of the canopy 11. The resilience of the leaf springs 13 biases it towards its neutral position, whereby the radius of the curve in the leaf spring is greater than when it is forced into the bent (e.g. compressed) condition. When the support structure 9 is forced towards the inverted position, the first end 23 of each arms 19 bends (e.g. bows along its length) about mount 27. This movement forces the second end 25 of the arm 19 downwards, towards the shaft 3. The leaf spring 13 is compressed between its ends and bent (e.g. the radius of the curve of the leaf spring decreases). The resilience in the leaf spring inhibits the bending of the leaf spring and thereby the movement of the second end 23 of the arm 19 relative to the shaft 3. This inhibits or prevents the inversion process of the umbrella when a force is applied to the underside of the canopy. In alternative embodiments, the leaf spring can be replaced with other biasing means (e.g. an elastically resilient length of rubber, a coil spring).
The leaf springs 13 are also able to self-right the support structure 9 and canopy 11 in the event that the umbrella is inverted (e.g. when the force applied to the underside of the canopy is sufficient to invert the umbrella) The inverted, or inside out position, is shown in
Referring to
The connectors 29 also comprise a single integral projecting finger 33. The projecting fingers 33 include an aperture adapted to receive a pin 35 about which each leaf spring 13 is able to rotate relative to the connector 29. Each leaf spring 13 is bifurcated 37 at its end adjacent the arm 19. The bifurcated portion 37 of the leaf spring 13 locates on either side of the projecting finger 33 of the connector 29. The bifurcated portion 37 of the leaf spring also includes an aperture 39 that receives the pin 35. The bifurcated portion 37 receives the projecting finger 33 of the connector 29 such that the apertures of the projecting finger 33 and the leaf spring 13 align. In this way, the co-operating apertures are able to receive the pin 35 such that the leaf spring 13 and connector 29 are pivotally mounted to each other. A bifurcation mount is relatively simple, but other forms of pivotal mourning may be employed.
The support structure 9 may also include a plurality of canopy tensioners 41. Referring now to
Referring again to
In the detailed form, the compartments 47 are formed from a single length of material that extends about the entire periphery 49 of the canopy 11. This allows for a contrast in colour between the compartments 47 and the canopy 11. This also allows for the compartments 47 to be formed from a different, stronger, material to the canopy 11. In an alternate embodiment, the compartments are formed individually from separate pieces of material.
Referring again to
An alternative form of the canopy tensioner is shown in
In the event that the umbrella does invert, as is shown in
Referring now to
The umbrella also includes a locking means that is configured to lock the collar 17 to the shaft 3 when the support structure is erected. The locking means can be a conventional locking means used for umbrellas. For example, it can be a detent in the form of a spring-loaded protrusion provided on the shaft 3 that enables the collar 17 to be retained in position such that the umbrella may be locked in its erected position. The locking means can alternatively include a clamp, as will now be described with reference to
The locking means can alternatively include a locking collar, as will now be described with reference to
To unlock the locking mechanism, the handle 79 is pushed (i.e. slid down the shaft 3) by the user in the direction shown by arrow B in
In another alternative embodiment, the clamp 59 and engaging member 65 can each be formed from multiple bodies that each extend partially about the periphery of the shaft 3.
In the claims which follow and in the preceding summary except where the context requires otherwise due to express language or necessary implication, the word “comprising” is used in the sense of “including”, that is, the features as above may be associated with further features in various embodiments.
Variations and modifications may be made to the parts previously described without departing from the spirit or ambit of the disclosure.
Number | Date | Country | Kind |
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2014903753 | Sep 2014 | AU | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AU2015/000576 | 9/18/2015 | WO | 00 |