WALKING AID WITH FOLD-OUT SUPPORT LEGS FOR SITTING DOWN

Abstract

A walking aid for taking up a deployment supported force for supporting a person using the walking aid, comprising a support upper part for engaging around the person, a shaft and a support foot arranged at a lower end of the shaft and having multiple swivelable support legs which can be moved between a storage position in which they are folded out from one another at a predefined angle and the walking aid can be set down on the ground, and a use position in which the support legs are folded together and arranged next to one another and the walking aid can be used, characterized in that the support legs are swivelably retained at a lower end of the shaft, and in that they are designed for taking up the deployment supported force in the use position.

Claims

1. A walking aid for taking up an intended supporting force in order to support a person who is using the walking aid, with a support upper part serving for the person to engage with a shaft, a support foot arranged at a lower end of the shaft, and several pivoting support legs which are designed to take up the intended support force in the position of use and which can be moved between a setting-down position, in which they are folded out at a predefined angle and the walking aid can be set down on the ground, and a position of use, in which the support legs are folded together and arranged adjacent to one another and the walking aid can be used, wherein in the position of use, the support foot is formed exclusively by the support legs and the support legs are held in a pivoting manner at the lower end of the shaft, at a specific position that cannot be changed, wherein a sliding sleeve that can be moved in a longitudinal direction of the shaft is arranged at a lower end section of the shaft, wherein in the position of use the sliding sleeve is displaced towards the support foot in order to fold the support legs together and the sliding sleeve at least partially overlaps the support legs from the outside and holds them in the position of use, and in the setting-down position it is displaced, compared with the position of use, towards the support upper part and releases the support legs so that they can fold out.

2. A walking aid according to claim 1, wherein arranged between each support leg and the shaft is a limit stop, with which the predefined angle is set.

3. A walking aid according to claim 1, wherein each support leg is held on the shaft such that it can be pivoted around a pivot axis running crosswise to a longitudinal axis of the shaft.

4. A walking aid according to claim 1, wherein in or on the shaft is an electric motor as a drive element that is in drive connection with the sliding sleeve.

5. A walking aid according to claim 4, wherein the drive connection is formed by a crank mechanism with a first crank arm on a rotating shaft of the electric motor and a second crank arm which is connected in an articulated manner to the first crank arm, and which is pivoted on the sliding sleeve.

6. A walking aid according to claim 5, wherein a battery and operating elements are accommodated in the support upper part.

7. A walking aid according to claim 1, wherein the support legs are articulated on a cylindrical bearing element that is set into a lower, hollow end section of the shaft.

8. A walking aid according to claim 1, wherein in that the length of the shaft can be adjusted in a telescopic manner.

9. A walking aid according to claim 1, wherein in that the support upper part is designed as an elbow crutch with a forearm support and a hand grip.

10. A walking aid according to claim 1, wherein in that the support upper part is designed as an axillary crutch with an axilla support and a hand grip.

11. A walking aid according to claim 1, wherein arranged on or in the hand grip is an operating element for triggering a movement of the support legs into the position of use or into the setting-down position.

12. A walking aid according to claim 6, wherein arranged on the walking aid is an inductive charging unit for wireless charging of the battery.

13. A walking aid according to claim 1, wherein held on the lower end of the shaft is a central reinforcement element which, in the position of use, is situated centrally between the support legs.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0026] Further advantages and features of the invention result from the following description of an embodiment, wherein reference is made to a drawing, in which

[0027] FIGS. 1a and 1b show an exploded perspective view or side view of a walking aid according to the invention,

[0028] FIG. 2 shows a view of a support upper part of the walking aid according to FIG. 1,

[0029] FIG. 3 shows an enlarged perspective view of the support foot and of the lower area of the shaft,

[0030] FIG. 4 shows a perspective view from below onto the area shown in FIG. 3,

[0031] FIG. 5 shows a top view onto the partial area of the walking aid according to FIGS. 3 and 4,

[0032] FIG. 6 shows a side view of the area according to FIGS. 3 to 5,

[0033] FIG. 7 shows a sectional view along line VII-VII in FIG. 6,

[0034] FIG. 8 shows a similar view to FIG. 7, wherein the support legs are to some extent moved in the direction towards the position of use,

[0035] FIG. 9 shows a view similar to FIG. 8, wherein the support legs are in the position of use, and

[0036] FIGS. 10a, b and c show views of a walking aid designed as an axillary crutch.

DETAILED DESCRIPTION

[0037] FIGS. 1a, b show a walking aid according to the invention, which is shown disassembled into its individual parts, with a support upper part 2, a shaft 4 consisting of several parts, and a support foot 8. In this example, the support upper part 2 is shown as an elbow crutch with a forearm support 2a and a hand grip 2b. Alternatively, the support upper part 2 could be designed as an axillary crutch (“American crutch”), as shown in FIGS. 10a-c, with an essentially horizontal, slightly curved axilla support 2c, a horizontal hand grip 2b arranged below that, and a strut 2d that extends laterally from the shaft and bears one end of the axillary crutch, with the other end of the axilla support resting on the shaft 4. As a further alternative, not shown, two laterally projecting struts can be envisaged instead, which bear the axilla support at the top and converge at the bottom and are connected to the shaft, with the hand grip then being arranged centrally between the struts, below the axilla support.

[0038] In the variant that is shown, the shaft 4 consists of three part-sections: an upper shaft section 4a, a middle shaft section 4b and a lower shaft section 4c. The support upper part 2 is connected to the upper shaft section 4a, for example by means of screws or adhesive bond, and the upper shaft section 4a is connected to the middle shaft section 4b such that the length can be adjusted telescopically in an essentially familiar manner, wherein snap-in holes 10 are provided on the upper shaft section 4a, in order to enable a snap-in projection (not shown) that is held in a sprung manner on the middle shaft section 4b to engage with one of the snap-in holes 10, and to fix the two shaft sections 4a, 4b in a desired position relative to one another.

[0039] The middle shaft section 4b is firmly screwed to the lower shaft section 4c.

[0040] Set into a lower end of the lower shaft section 4c is a cylindrical bearing element 12 that is firmly screwed to the lower shaft section 4c. On the bearing element 12, several support legs 14, four in the embodiment shown here, are borne in a pivoting manner. In each case, bearing is effected by means of a cylindrical bearing journal 18 which is arranged crosswise to a longitudinal axis 4d of the shaft, and which is accommodated in corresponding locating holes in the bearing element 12, so that pivot axes 20 which are set by the bearing journals 18, and around which the support legs 14 can be pivoted, run crosswise to the longitudinal axis 4d and are unchanging and fixed relative to the shaft or at least relative to the lower shaft section 4c. FIGS. 8 and 9 show the pivot axes 20, wherein in FIG. 9, additionally the pivot axis 20 of the support leg 14 situated at the back in the direction of viewing is indicated as a broken line.

[0041] In the example shown, the lower shaft section 4c is designed as a cylindrical tube, wherein on the lower shaft section 4c, a sliding sleeve is held such that it can be slid along the longitudinal axis 4d, this sleeve being in drive connection with a drive motor 24 which is fitted in or on the lower shaft section 4c, in an upper area of the lower shaft section 4c, at a distance from the bearing element 12. In the embodiment shown, because of its size the drive motor 24 is fitted outside the lower shaft section 4c and is covered by a motor cover 26. The sliding sleeve 22 has an inner diameter that corresponds to an outer diameter of the lower shaft section 4c.

[0042] The support legs 14 are borne and designed such that in the folded-in state of use (FIG. 9), their outer surfaces 14a lie within a cylindrical surface whose diameter corresponds to an outer diameter of the lower shaft section 4c, so that the depending on its axial position, sliding sleeve 22 either overlaps only the lower shaft section 4c (FIG. 6, 7) or both this as well as the support legs 14 or their outer surfaces 14a (FIG. 8, 9) when they are in their folded-up position.

[0043] In their maximum folded-out position (FIGS. 3 to 7), the support legs 14 are arranged at a predefined angle 27 in relation to the longitudinal axis 4d of the shaft 4, about 30 degrees in the case of the example that is shown, with this angle 27 being set by a limit stop that limits a pivoting movement of the support legs 14.

[0044] In the embodiment shown here, the limit stop is formed by an inclined contact surface 14b on each support leg 14 on the one hand, and a ring-shaped limit stop 28 on the other hand, which can be held on the bearing element 12 or on the lower shaft section 4c, or can be designed in one piece with one of these elements.

[0045] Arranged in the area of each bearing journal 18 is a pre-tensioning spring 30, a torsion spring in the example shown here, which is arranged around the bearing journal 18 and which is braced on the one hand against the bearing element 12 and on the other hand against the respective support leg 14. Through this, the support legs 14 are pre-tensioned in the direction towards the folded-out setting-down position (FIG. 7).

[0046] The sliding sleeve 22 is cylindrical and is open on both sides, except for a cross bar 22c on an upper end of the sliding sleeve 22, which serves for connection with the drive motor 24. As FIGS. 1a and 1b show, the lower shaft section 4c is equipped with a longitudinal slot 32, in which the cross bar 22c is accommodated in a longitudinally movable manner.

[0047] FIGS. 7 to 9 elucidate the drive connection between the sliding sleeve 22 and the drive motor 24. A rotating shaft 34 of the drive motor 24, which can be either the rotational axis of a rotor of the drive motor or an output shaft of a gearbox, is connected to a first crank arm 36 that is connected in an articulated manner to a second crank arm 38, which in turn is articulated on the cross bar 22c of the sliding sleeve 22. Through this, a rotational movement of the rotating shaft 34 can be converted into a linear displacement of the sliding sleeve 22 in the longitudinal direction of the lower shaft section 4c, between an upper end position in which the sliding sleeve 22 does not overlap the support legs 14 (FIGS. 3 bis 7) and a lower end position in which the sliding sleeve 22 overlaps the support legs and brings them, against the force of the torsion springs 30, into the folded-in position of use (FIG. 9).

[0048] FIGS. 3 and 4 show a central reinforcement element 40 which is rigidly connected to the lower end of the shaft 4 or to the lower shaft section 4c. The reinforcement element 40 has the task of providing additional safety or reinforcement for the support legs 14 in the folded-up position of use, so that the support legs 14 maintain their alignment with the shaft 4 even when subjected to considerable stress crosswise to the longitudinal axis of the shaft 4, and cannot for example buckle crosswise. In the position of use of the support legs 14, in a preferred variant the reinforcement element 40 does not take up any part of the support force acting in the longitudinal direction of the shaft, but this could be envisaged in a variant in order to relieve the support legs.