WO2010028469A1

WO2010028469A1 - Heel with shock-absorbing mechanism

Info

Publication number: WO2010028469A1
Application number: PCT/BR2009/000291
Authority: WO
Inventors: Romeu Lehnen
Original assignee: Dakota S/A
Priority date: 2008-09-09
Filing date: 2009-09-08
Publication date: 2010-03-18
Also published as: BRMU8803472U2; BRMU8803472Y1

Abstract

A shock-absorbing mechanism comprises a hollow heel (1) with an upper cavity (11) and a base (12) with a vertical bore (13). An elastic body (2) is embedded in the upper cavity (11) of the heel. A piston (3) comprising a flat head (31) and a vertical tube (32) is arranged under the elastic body (2) such that the head (31) abuts against the base (12) of the heel and the tube (32) fits into the bore (13). The pin (41) of a heel top piece (4) is inserted into the lower end of the piston tube (32). This assembly creates a gap (F) between the top of the heel top piece and the lower side of the heel. Three embodiments of the shock-absorbing mechanism are described. In the first embodiment, a lower cavity (14) is provided under the base (12), into which cavity an upper portion (42) of the heel top piece (4) partially penetrates, and a cover (5) is fitted onto the upper cavity (11). In the second embodiment, the cover (5') has an undercut (51) with holes (52) for receiving screws (6) for fastening the heel (1'). In this embodiment, holes (17) are provided in the internal reinforcements (16) of the hollow heel (1'), and the elastic body (2') and head (31) of the piston have cut-outs. The third embodiment is a wedge heel (1'') having the same structures as the second embodiment, but with a modified shape.

Description

"JUMPING WITH DAMPING MECHANISM"

The present invention relates to a heel development developed for women's shoes which is provided with an internal damping mechanism.

High heels for women's shoes are known to be lined underneath by a heel. The heels are subjected to high loads, not only static but dynamic, especially compression and impact, resulting from the act of ambulation. Some important characteristics that must be met by the heel material are:

- abrasion resistance to prevent premature heel wear;

- hardness to ensure good anchorage of the heel securing stud in the heel;

- adherence to prevent user slippage and

- ductility to at least partially absorb the impact of the jump against the ground.

These fundamental heel properties require footwear to insistently pursue new blends of polymeric, elastomeric and / or plastomeric materials. A soft material that is capable of absorbing much of the impact tends to exhibit premature wear, excessive deformation and risk of tearing. Conversely, a material with great durability is very hard and uncomfortable to the user.

It is therefore an object of the present invention to develop a heeled development for women's footwear that is capable of effectively overcoming said limitations of the state of the art. This is achieved by a heel which is provided with an internal cushioning mechanism, the heel being hollow and with a perforated base in which an elastic body is positioned inside. A plunger formed of a flat head and a lower vertical tube is positioned under the elastic body so that its head rests on the heel base and its tube fits within a hole in the heel base. At the lower end of the plunger tube is mounted a heel pin, so that the heel is slightly spaced from the bottom surface of the heel, generating a clearance.

During ambulation the impact of the heel against the floor is transferred by the pin to the piston tube, whose head compresses the elastic body. Due to the characteristics of the elastic body material, absorption of the shock, generating a damping effect, which gives the user a feeling of comfort.

In a first embodiment variant the hollow heel may have a smaller lower chamber below the base, where partially penetrates an upper portion of the heel, guiding the vertical damping movement. The heel may have a cap that fits into the upper chamber mouth to better distribute the pressure of the heel against the footwear mounting sole.

In a second embodiment variant the cover is provided with a recess for matching the shape of the mounting insole and has holes for the passage of the securing bolts in the heel. The fastening of the lid by means of screws requires holes in the hollow heel wall which are made possible by the internal reinforcements in the heel. The elastic body features cutouts to accommodate the internal heel reinforcements. The plunger head also has cutouts.

In a third constructive variant the internal shape of the hop chamber and the corresponding geometry of the components that are confined in said chamber can be modified in order to better adapt the shape of the Anabela jump.

The heel enhancement for women's shoes with internal cushioning mechanism proposed by the invention results in the following advantages over prior art designs:

- reduces the impact of jumping against the floor;

- absorbs the shock resulting from ambulation;

- increases the feeling of comfort of the shoe;

- transfers less vibration to the user's spine;

- The damping mechanism employs few parts of great simplicity, facilitating the production and assembly and presenting long durability and low cost.

These and other advantages of the present invention will become more apparent from the following detailed description, which is based on the attached drawings, below, which illustrate preferred embodiments of the internal damping mechanism jump, which should not be considered limiting the invention:

Figure 1 - exploded perspective of the jump damping mechanism;

Figure 2 - longitudinal section of the mounted heel and without load application;

Figure 3 - longitudinal section of the mounted heel with applied load;

Figure 4 - longitudinal section of the isolated jump;

Figure 5 - exploded perspective of a first constructive variant of the jump;

Figure 6 - longitudinal section of the first variant of the mounted and unladen jump;

Figure 7 - longitudinal section of the first variant of the isolated jump;

Figure 8 - exploded perspective view of a second embodiment of the damping mechanism;

Figure 9 - longitudinal section of the second constructive variant of the isolated jump;

Figure 10 - top view of the second embodiment of the isolated balance;

Figure 11 - bottom view of the second embodiment of the isolated jump;

Figure 12 - longitudinal section of the second variant of the unloaded jump;

Figure 13 - longitudinal section of the second variant of the loaded jump.

Figure 14 - perspective of a third constructional variant of the sole with the damping mechanism;

Figure 15 - exploded perspective of the third sole variant;

Figure 16 - longitudinal section of the third sole variant without the damping mechanism.

Figures 1, 2 and 4 illustrate the internal damping mechanism, whose heel (1) is hollow, having an upper chamber (11) and a base (12) with a vertical hole (13). In the upper chamber (11) of the heel an elastic body (2) is embedded. A piston (3) formed by a flat head (31) and a vertical tube (32) is positioned under the elastic body (2) so that its head (31) rests on the base (12) of the heel. and its tube (32) fits within the hole (13). At the lower end of the piston tube (32) is mounted a stud (41) of a heel (4). This assembly results in a clearance (F) between the top of the heel (4) and the bottom surface of the heel (1).

Figure 3 allows to verify the behavior of the jump (1) under the load resulting from the ambulation (indicated by the arrow). The impact of the heel (4) against the floor is transferred by the pin (41) to the piston tube (32) whose head

(31) compresses the elastic body (2) embedded within the chamber (11) of the heel (1). The resilient characteristics of the elastic body material (2) cushion the shock of the heel (4) against the ground.

Figures 5 to 7 illustrate a first embodiment of the hollow outlet (1) having a lower chamber (14) below the base (12), partially penetrating an upper portion (42) of the heel (4), better guiding the vertical damping movement. The heel (1) of the variant has a cap (5) that fits into the upper chamber (11), and is designed to better distribute the pressure exerted by the heel against the footwear mounting insole.

Figures 8 to 11 illustrate a second embodiment of the internal impact damping mechanism, whose heel (1 ') is hollow, having an upper chamber (11') and a base (12 ') with a vertical hole (13') . In the upper chamber (11 ') of the heel an elastic body (2') is embedded. A plunger (3 ') formed by a flat head (31') and a vertical tube (32 ') is positioned under the elastic body (2') so that its head (31 ') rests on the base. (12 ') of the heel and its tube (32') fits inside the hole (13 '). At the lower end of the piston tube (32) is mounted a pin (41 ') protruding from the upper portion (42') of a heel (4 '). A cap (5 ') fits into the upper chamber (11') and is intended to better distribute the pressure exerted by the heel (1 ') against the footwear mounting bracket. The cover (5 ') is provided with a recess (51) for matching the shape of the mounting insole. This cover (5 ') has holes (52) for the passage of the bolts (6) in the heel (1'). The fastening of the lid (5 ') by means of screws (6) requires holes (17) in the hollow heel wall (1') which are made possible by the internal reinforcements (16) in the heel (1 '). The elastic body (2 ') has cutouts (21) for accommodating the internal reinforcements (16) of the heel (1'). The piston head 31 'also has cutouts.

Figure 12 details the interrelationship of the internal components of the jump mechanism, but without the application of the ambulation load, with the elastic body (2 ') not pressed and the piston head (31') resting on the base of the jump ( 12 '), leaving the heel (4') projected downward and partially outward.

Figure 13 details the compressed elastic body (2 ') with flattened height, as a result of the pressure exerted by the head (31 ') of the piston (3) and transmitted to it by the heel pin (41') as a result of the weight of the shoe wearer.

Figures 14 to 16 illustrate a third embodiment of the sole with the components of the internal impact damping mechanism, whose Anabela heel (1 ") is hollow, having an elongated upper chamber (11") and a base (12 "). with a tear (13 "). In the upper chamber (11 ") of the heel is embedded an elongated elastic body (2"). A plunger (3 "), also elongated, is composed of a flat head (31") and a foot (32 "), being positioned under the elastic body (2") so that its head (31 ") protrudes. rest on the base (12 ") of the heel and your foot (32") fits inside the slot (13 "). At the lower end of the plunger foot (32 ") are fitted two pins (41") protruding from the upper portion (42 ") of an elongated heel (4"). An elongated, flat cap (5 ") fits into the peripheral recess (15") of the upper chamber (11 ") and is intended to better distribute the pressure exerted by the heel (1") against the footwear mounting bracket. The cover (5 ") is provided with holes (52") for the passage of fastening screws in the heel (1 "). The fastening of the cover (5") by means of screws requires holes (17 ") in the wall. (1 ") which are made possible by the internal reinforcements (16") in the jump (1 "). The elastic body (2 ") has vertical cutouts (21") for accommodation in the internal reinforcements (16 ") of the heel (1").

Claims

1 - "DAMPING MECHANISM HEEL" characterized in that it comprises a heel (1) with an upper chamber (11) and a base (12) provided with a bore (13), having within the upper chamber (11) an elastic body (11). 2), under which a piston (3), formed by a flat head (31) and a vertical tube (32), is positioned, the piston head (31) being supported on the base (12) of the heel, while the plunger tube (32) fits into the bore base hole (13) and the lower end of the plunger tube (32) is fitted with a stud (4) of a heel (4), resulting in a clearance (F) between the top of the heel (4) and the bottom surface of the heel (1).

2. "DAMPING MECHANISM HEEL" according to claim 2, characterized in that the heel (1) has a lower chamber (14) below the base (12), which partially penetrates an upper portion (42) of the heel ( 4).

"DAMPING MECHANISM HEEL" according to one of claims 1 or 2, characterized in that it has a lid (5) which fits into the upper chamber (11) of the heel (1).

4. "DAMPING MECHANISM HEEL" according to one of Claims 1 to 3, characterized in that the lid (5 ') has a recess (51) and holes (52) for the passage of the heel fixing screws (6). (1 '), with hollow heel (1') having internal reinforcements (16) with holes (17) for threading the cap fixing screws (6) (5 ') and having the elastic body (2') cutouts ( 21).

A "SHOCKING MECHANISM HEEL" according to one of Claims 1 to 3, characterized in that the Anabela-type heel has an elongated upper chamber (11 ") and a base (12") provided with a slot ( 13 "), the elongate elastic body (2") being embedded in the upper chamber (11 ") and positioned over a piston (3"), the piston (3 ") also being elongated and comprising a flat head (31"). ) and a foot (32 "), with the foot (32") fitting within the heel slot (13 "), the heel (4") being elongated and with two pins (41 ") protruding from the upper portion (42 ") and for being the elongated and flat lid (5").