AT511822B1 - BRAKING DEVICE FOR SKIROLLER AND ROLLSKI - Google Patents

Abstract

The invention relates to a braking device for roller skis or roller skis with wheels or wheels (2) and by means of binding device (13) on the athlete's shoe detachable, partially releasably or permanently mounted scooter frame and at least one, hinged to a hinge joint brake shoe (7) with the braking a brake cable (4) is pulled onto at least one wheel or disc to be braked, the brake cable (4) being located above the shoe (14) from the front of the lower leg (16), knee, thigh, hip or upper body of the athlete, to at least one brake cable guide (5), a brake operating lever, a pretensioned brake cable (4) or a brake operation winch is guided in front of the ankle joint of the athlete and is operable by a reclining of the athlete.

Description

Austrian Patent Office AT 511 822 B1 2013-03-15

Description: The invention relates to a braking device for roller skis or roller skis with wheels or wheels and by means of binding device on the athlete's shoe detachably, partially releasably or fixedly mounted scooter frame and at least one, hinged to a hinge joint brake shoe braking when braking with a brake on at least a wheel to be braked or a brake disc is pulled.

Skiroller or Rollski, hereinafter always as " Rollski " are used by athletes who prepare for the winter season by training with skis in the snow-free time, or year-round to move similar to the ski. This applies to the entire summer alternatives for cross-country skiing, downhill skiing as well as for touring. Roll skis are used mainly on asphalt and, depending on which wheels are on the roller skis, also rolled off-road. Regardless of the running style on skis, safety is an important factor. The most important contribution with regard to safety on roller skis is provided by a perfectly functioning and precisely controllable braking system, which is rather rare in roller skis, and if so, then usually very poorly.

In the winter on snow can drift with skis and make sure to stay standing across or drive in the so-called snow plow. In addition, in a fall in the snow, the risk of injury is not as great as on solid surfaces without snow. Winter sports enthusiasts prefer to use their own winter ski boots for their summer training on roller skis as this is the only way they can simulate the conditions of winter on roller skis as exactly as possible. So that braking on a roller ski can be carried out effectively, the operation of the brake on a roller ski by pushing back the lower leg has proven to be the most effective method. If braking is initiated by pushing back the lower leg, the braking deceleration and the braking effect are automatically controlled so that the athlete neither falls backward during braking nor is he catapulted forward in an uncontrolled manner. This works by putting the athlete forward while braking and releasing the brake automatically. If the braking effect is too low, the athlete falls further back on the brake and the braking effect or the deceleration is increased. So with this method the brake can be controlled exactly. However, the braking device should not adversely affect the weight distribution on the roller skis. Mostly you run on skis with dissolved heel. When rolled with rolled skis with the heel loosened, it is better for a ski-like as possible rolling pleasure when the weight distribution of the roller skis before the binding device and behind the binding device with dissolved heel is balanced as possible. As a binding device on Rollski any binding device can be used, which is known from cross-country skis, touring skis or alpine skis. Similar binding systems as on the snowboard can be used for roller skis. For the alpine area, for steep slopes in the area, an exact controllable brake on the rear wheel would be awesome, because on steep terrain you could really drift around curves with well functioning brakes on the rear wheels, by controlled blocking of the rear wheels.

From US 6 082 768 A a brake system on a rolling ski can be seen, in which the brake release device is attached to the back of the shoe and presses a brake pad on the rear wheel when pushing back the foot. At the front wheel a retarding device is attached. For the brake operation on the rear wheel a special shoe is required and can not be used with a winter sports shoe.

DE 27 55 440 A1 shows a dry training device for cross-country skiing, with load-dependent backstops and the front wheel is a mudflap, which also serves as a brake shoe, but is to operate by hand. Thus, the braking deceleration and braking effect are not automatically compensated for each other and thus with this method no efficient braking is possible.

US 7,677,600 B2 shows a roller ski with a brake lever device on Rollskigestell behind the shoe. In this system, it is true that the brake is released by pushing back the lower part of the brake. ATP11 822 B1 2013-03-15

Legs operated and thus can be used with this system, a normal ski boot. The weight of such a brake lever device on Skirollergestell behind the floor space or binding device, however, makes very disturbing noticeable, since a roller ski compared to the ski is a lot shorter and thus on a roller ski shoe attachment, in relation to the ski, located much further forward and therefore comes with Rollskiern already significantly more weight to wear behind the shoe attachment.

The patent US 5 901 981 A shows a roller ski with a braking device in which a brake pad is pressed by means of handbrake lever on the ground. Is difficult to control and very susceptible to wear and acts differently on different surfaces.

US 5,374,071 A shows a equipped with brakes roller ski, the brake is operated with a cable, the cable However, by hand or by pushing forward of the lower leg is pressed. In this case, this is dangerous for the athlete, because the braking delay causes the athlete to push forward and the braking process is automatically increased uncontrollably and may already lead to a fall at a slightly higher speed.

US 4,943,075 A shows a pliers-like brake on the rear wheels of a Rollski's, which is operated by cable by hand. So the braking effect is also poorly dosed and you have the hands not free.

Similar to US Pat. No. 7,677,600 B2, US Pat. No. 4,037,596 A discloses a brake lever device on a roller ski behind the shoe.

US 2008/0231019 A1 shows, in addition to a steering device, a brake device on a roller ski, which presses a brake cable by pressing a lever forward, which presses a brake shoe on the rear wheel. This is a relatively complex construction with wrong acting brake operation. Is therefore also fall-dangerous for the athlete.

US 2002/0125649 A1 also shows a steering device on a roller ski and a cable operated brake device. The cable is fixed fixed to the side of the shoe and is indirectly by pressing back the lower leg, the fixed on roller ski-mounted shoe operated. The brake cable acts on a Bowden cable on a brake device on the rear wheel. However, this roller ski can not be used with a conventional ski boot or cross country boot.

DE 20014153 U1 describes a single-track roller skate with an acting at least on the foremost role, operable by bending the knee joint braking device, the outgoing by a knee cuff, in front of the lower leg and over a front of the ankle joint deflection forward Brake device guided pull rope is triggered.

FR 2627995 A also describes a roller ski with an actuatable by a pull rope, acting on the rear brake device. However, this brake is operated by pulling on the rope by hand or by leaning forward.

DE 299020057 describes a single-track skate with a braking device acting on a plurality of rollers, which is triggered by an outgoing from the skate shank, deflected over the toe backwards traction cable.

Thus, a roller skis can be braked by pushing back the lower leg, and yet can be used with normal boots or cross country boots and come to wear any additional weights behind the binding device, we have chosen the brake with at least one rope or rope / rod combination , The rope or a rope / linkage combination will hereinafter always be referred to as " brake rope " designated. The special feature of this brake is that with the on the front of the lower leg, releasably or fix, on a cuff, a cuff belt or a cuff construction, fixed brake cable by moving back the lower leg, a braking device on the rolling ski is precisely controlled. The brake cable may also be guided directly to a brake operating lever, a brake operating winch, a pretensioned brake cable or a brake pedal, a brake device on the roller ski. These brake device elements are explained in more detail in the description, together with the figures. The brake cable can be attached to the athlete also on the knee joint or even above the knee joint. So that the brake cable does not lose its position between and on the brake cable guides, it makes sense to attach a brake cable stop even before the first brake cable guide, after the brake cable attachment to the lower leg. Thus, the return springs of the brake shoes keep the entire brake cable in the area of the roll ski permanently on tension and subsequently in their intended positions of the brake side guides. The tensioned in the area of Rollski's brake cable can be fixed by the brake cable, which is operated by the athlete, somewhere in front of the ankle of the athlete.

The brake rope fixation on the athlete is advantageously carried out releasably A removable cuff or cuff construction around the athlete's lower leg is helpful. So that the brake rope fixing on the front of the lower leg maintains its position sustainable, a cuff construction with at least 2 cuff straps or a shoe cuff above the shoe is attached to the lower leg so that it can not slip uncontrollably or can be supported on the athlete's ski boot or cross-country boot. Next is at the cuff construction or shoe at least one detachable brake cable fixing. The cuff construction can be fixed with buckles, straps, straps or straps, quickly on the lower leg of the athlete, regardless of the roller ski and shoe. Ideally, there are several brake cable attachments at different heights on the cuff construction or shoe cuff. The brake cable can thus be fixed from above the ankle to the knee joint of the athlete on the cuff construction, regardless of the shoe. The closer to the ankle the brake cable is fixed the more force can be exerted by the athlete on the brake cable. Closer to the knee joint means - more way but less power on the brake cable, but also at the same time a more precise control of the brakes. Important is only the basic vote of the braking devices that the ratio between Bremsseilweg and Bremsbackenweg is tuned so that during a braking operation then the desired braking force on the wheel to be braked comes into their own. Regardless of whether the brake cable is operated by the lower leg, knee, thigh, hip or upper body.

With this solution, no uncomfortable heavy brake construction needs to be attached to the roller skis, the athlete can use his own ski boots or cross country boots and the braking intensity can be selected by the differently high placed brake cable fixations, depending on the desired braking effect intensity. With adjustable eyelets or other rope length modification options, the braking point is adjustable as of when the brake engages. The braking point can also be adjusted by a position on the roller frame or additional construction positionally fixed brake cable guide, or there are both settings for the braking point given. To ensure that the best possible braking deceleration is actually achieved during a braking operation, it is also necessary to shift the body weight as far as possible to the braked wheel during the braking process. If only the rear wheel is braked in a roller ski, the body weight can be increasingly shifted to the rear wheel during braking by pulling up the toes. However, the roller ski, due to the ski-like rolling behavior, longer, it is very difficult to shift the body weight sufficiently on the braked wheel. So that you can also optimize the braking effect on roller skis, it makes sense, not only the rear wheel, or if there are several rear wheels, the rear wheels brakes, but also the front wheels or a front wheel at the same time. With the brake cable operated by the lower leg, it is quite simply possible to simultaneously actuate a brake shoe acting on the front wheel. This can be done on the one hand by division of the brake cable to a brake cable connection or even equal over an extra-guided brake cable. The brake cable on the front wheel can be made elastic or it should be a spring or rubber hung between them, so that the braking effect of the front wheel can be adjusted to the rear wheel so that the front wheel does not start to block, because the front wheel would block, that would be dangerous. With an elastic brake cable on the front wheel, the main braking force can be guaranteed at the rear wheel. To optimize the 3/13 Austrian Patent Office AT511 822 B1 2013-03-15

Brake force distribution, it makes sense if the elasticity of the brake cable is designed to be adjustable for the front wheel. Thus, front and rear wheels can be braked simultaneously, still show variants in connection with the figures.

A brake shoe can also serve as a mudflap, which is hinged to the scooter frame at a transverse axis of rotation to the direction of travel. The articulation of the brake shoe must not necessarily be located directly on the scooter frame, this can also be attached to an additional construction, for example, already wearing a retarder or lock roller. The articulation joint for mounting the brake shoe on the scooter frame or on an additional construction can be replaced by a brake shoe elastic, an elastic region on the brake shoe, resiliently replaced. When mounting the brake shoe with articulated joint, a spring and stop for the brake shoe is needed anyway. Thus, the brake shoe is pressed by pushing back of the lower leg on the wheel to be braked, the brake cable is deflected via at least one attached to the scooter frame or additional construction brake cable guide or hinged to the brake shoe, that the brake cable pulls at least one brake shoe on at least one wheel to be braked or suppressed. The brake cable guide can be designed both as a brake cable sliding part or as a deflection roller. It makes a difference whether the brake cable pulls close to the articulated joint of the brake shoe or further away from it. The further the brake cable attachment pulls away from the articulated joint, the higher the contact pressure of the brake shoe on the wheel and thus also the braking effect. With the position variants of the brake cable attachment to the brake shoe and the lower leg cuffs, the braking effect can not only be optimized in its default setting but also, for example, be adapted to moisture, because when wet, the brake, depending on the brake shoe design, worse. It makes a difference in wet conditions, whether the brake shoe engages directly on the tread, acts on the tire sidewalls or engages in a, centrally on the wheel, radial verdautenden recessed area or even acts on a wheel located next to the wheel. Such a brake disc can also sit between 2 wheels. At the point where the brake shoe engages the wheel or brake disc, it makes sense to attach to the back of the brake shoe, a heat sink, preferably made of aluminum with cooling fins, to dissipate the braking energy during a prolonged braking process permanently and overheating of the brake shoe and subsequently to prevent a mess of the wheel. At the point where the brake shoe engages a rubber wheel, PU roller or pneumatic wheel, a material made of stainless steel, steel or precious metal such as copper or brass is ideal. Also high-quality aluminum alloys are well suited for this. All of these materials do not significantly rub the rubber or other plastic materials of a wheel and ideally dissipate the energy to a possibly existing heat sink. The brake cable operated by the lower leg can also be guided in the area of the roller ski in a Bowden cable and thus, for example, actuate a brake caliper which immediately engages the entire wheel during braking or brakes a brake disc Upper body of the athlete is an effective train on the brake cable comes about, it is necessary that the first brake cable guide brake shoe control is located in front of the ankle joint. For this purpose, the brake cable is fixed above the shoe on the front of the athlete's lower leg, knee, thigh, hip or upper body and leads from there on at least one brake cable guide, brake lever, preloaded brake cable or Bremsbetätigungswindenrad, in front of the ankle joint of the athlete. To attach the brake cable in the hip area, a seat belt, similar to mountaineering used. In the chest area, the belt is tightened like a vest from the front or back. The chest strap can also be designed as a body warmer, which then has at least one brake rope fixation on the front.

In order to increase the braking force on the brake shoes and also to be able to control the front and rear brake shoe simultaneously to each other in the desired intensity, it is helpful, the brake shoes operated by the lower leg, knee, thigh, hip or upper body brake cable pulley principle to press. In order to actuate the brake cable, the lower leg is usually referred to as representative of the previously mentioned body parts, but usually only 4/13 Austrian Patent Office AT511 822 B1 2013-03-15. For the pulley principle, the brake cable is deflected by the lower leg via at least one brake cable guide attached to the scooter frame, in front of the athlete's ankle joint, so that the brake cable pulls the brake shoe over at least one brake cable guide mounted on the brake shoe onto the wheel to be braked. The brake cable continues to lead to a further brake cable guide or brake cable attachment on the scooter frame. From a brake cable guide on the scooter frame, the brake cable can be continued on or in the scooter frame to a brake construction on the rear wheel. Thus, with only one rope, both the front wheel and the rear wheel, in mutually tunable intensity, are controlled. The intensity can be chosen arbitrarily with this pulley principle, since the ropes can be more often than once on cable guides on the brake shoe, from the scooter frame and back and then fixed to a brake cable fixation on the scooter frame or a brake cable guide to another, to be braked wheel continues. The more often the cable guide between roller frame and brake shoe, the higher is the braking force with which the brake shoe is pressed onto the wheel to be braked. If less braking energy is to be applied to the front wheel, the brake cable is guided at the front, for example, only once over the brake cable guide and over the rear brake shoe at least twice or more and so on.

The intensity of the braking force of a brake shoe on a wheel to be braked, can also be changed by means of an adjusting nut, with the adjusting of a return screw, the bias of the return spring, which presses the brake shoe after braking each back to its original position, are changed. A second ball nut or the head of the adjusting screw can form the stop for the return position of the brake shoe. The stronger the bias of the return spring, the more force is needed to brake shoe operation and the less braking force is then applied to the wheel to be braked. So with less bias of the return spring more braking force is exerted on the wheel to be braked.

Such a brake system for a roller skis can also be made available as a retrofit set without roller skis, as there are already many roller skis worldwide without functioning brakes in circulation.

Figs. 2 to 7 Fig. 9 Fig. 10 Fig. 11 Fig. 16 Fig. 16 shows a Rollski and foot of the athlete from the side view. partially shows roller skis from behind or from a rolling ski variant and foot of the athlete from the side view. shows the cross section of the cuff construction on the lower leg. shows a part of a Rollski's from the front. shows a section of a Rollski's dar side view with different brake shoe actuation. shows a section of a Rollski's and shoe from the side view with another Bremsbackenbetätigungsvariante.

As can be seen from Fig. 1, at the front and rear ends of the scooter frame (1) in each case the wheels (2) are articulated on a transverse to the direction of travel wheel axle (3). The binding device (13) holds the shoe (14) on the roller frame (1) detachably, partially releasably or firmly fixed. The brake cable (4) is releasably or permanently attached to the brake cable attachment (6) of the cuff belt (17) on the lower leg of the athlete, runs over at least one brake cable guide (5) on the scooter frame (1) in front of the athlete's ankle joint or over the front Wheel axle (3) on at least one brake cable guide (5) on or in the scooter frame (1) on at least one brake cable attachment (6) on the brake shoe (7). The rear brake shoe (7) is articulated as a possible variant on an additional construction (12) on a transversely extending to the direction of articulation joint (10). At the back of the brake shoe (7) sits a heat sink (11). The dashed brake cables (4b) to (4d) and (4g) show possible or additional cable guide variants, whereby one at the brake cable attachment (6b) to the shoe cuff (15) is shown , The at the brake cable connection (9) fixed brake cable (4b) for the additional brake shoe operation front can also be made elastic. Thus, a brake shoe (7) on the wheel (2) controlled controlled front. The brake shoe (7) front is also equipped with a heat sink (11) at the rear. With the adjusting eyelets (8), the brake cable (4) can be adjusted to the desired length. Several brake cable fixings on the brake shoe (7) and on the foot cuff (15) make it possible to optimize the braking effect on the wheel (2) to be braked. The braking movement arrow (18) indicates the direction of movement, in which the braking is initiated by moving the lower leg. The cuff belt (17) attached to at least one shoe strap (14) attached to the front of the lower leg (16), at least one shoe cuff (15) or at least one cuff construction (19) has the advantage that For the brake shoe operating mechanism on roller skis no weight comes to bear and the athlete can use his own ski boot from winter also for dry training. The strichlieft illustrated brake cable (4g) can both from the knee, thigh, hip or upper body of the athlete, by reclining the athlete, each to be controlled in this application brake element, also next to the brake pedal fixed to the lower leg, drive. The brake cable (4g) can be held by a cable reel (35) already between the athlete and the roller ski, in any posture, in the desired voltage. Thus, a disturbing fluttering of the brake cable (4) can be prevented.

FIGS. 2 to 7 show variants of how brake shoes (7) can act on a wheel (2) or brake disks (21) to be braked.

From Fig. 2 to 6 in each case a brake shoe (7) is shown in cross section next to a partially illustrated roller skis.

Fig. 2 shows a brake shoe (7) which engages in at least one groove between two wheels (2) on a braking surface or in a radially extending groove of a wide wheel (2), in the central region engages. This variant allows a more effective braking effect even in wet conditions.

Fig. 3 shows two adjacent wheels (2). The shape of the brake shoe (7) is designed so that is braked at both wheels (2) at the same time on the tire sidewalls. This version is particularly advantageous in the alpine area, as the braking surface is doubled and the athlete is offered a better staying power especially for downhill actions. It can also be 3 and more wheels (2) arranged on a roller skis side by side. The gap between the wheels (2) is kept clean by a cleaning pin held by the scooter frame (2) or an auxiliary structure (12) which points across the wheel axle (3) between the wheels (2), coarser debris and stones ,

Fig. 4 shows a wheel (2) with a flat overlying brake shoe (7). In this type of brake shoe, however, the running surface of the wheel (2), which is usually glued with dirt, is increasingly wiped out by the brake shoe (7) and picks up worse when it is wet.

Fig. 5 shows a V- or U-shaped running brake shoe (7) which engages mainly on the wheel side edges and so does not rub the most glued dirt tread. Provides an advantage even when wet.

Fig. 6 also shows a wheel (2) driven brake disc (21). The brake shoe (7) presses during braking either on the outer edge of the brake disc (21) or the brake disc (21) is taken from a Bremszage (23) in the pliers, similar to the wheel (2) in Fig. 7.

In Fig. 7 shows a piece of Bowden cable (22) with a brake caliper (23) via the brake cable (4) is operated so that the wheel (2) is thus braked on the outer sides. The brake caliper (23) is fixed to the caliper joint (24) on the roller frame (1) or to an additional construction (12). This braking principle can also be applied to a, sitting next to the wheel brake disc (21). In Fig. 8 can be seen for the most part Fig. 1, wherein in Fig. 8 at the wheel (2) behind another variant of the brake shoe (7), with the Brake shoe elastic (27) shows. At the wheel (2) at the front you can see an additional construction (12) in an alternative form. The brake surfaces (7a) on the brake shoes (7) consist, due to the good heat dissipation, mainly of precious metal. Next, in Fig. 8, the brake cable guide of the brake cable (4) via the brake shoes (7) executed in pulley principle. The brake cable (4) thus leads from the attached to the lower leg of the athlete or releasably secured cuff construction (19) on the not visible in Fig. 8 brake cable guides (5a) on the scooter frame (1) via the hinged on the front brake shoe or indirectly on the brake cable guide holder ( 26) hinged brake cable guides (5b) and (5c). From there, the brake cable (4) continues on the brake cable guide (5d) on or in the scooter frame (1) to the brake cable guide (5e) also on or in the scooter frame (1) on the rear brake shoe (7) and then on the brake cable guide holders (26 ) hinged brake cable guides (5f) and (5g) to the brake cable guide (5h) back to the brake cable guides (5i) and (5j) on the rear brake shoe (7) to the brake cable attachment (6) on the scooter frame (1). On the lower leg (16) you can see the sleeve construction (19) mounted on the lower leg (16). At the sleeve construction (19) are several brake fixings (6) for quick attachment of the brake cable (4). With the sleeve construction (19) the cuff straps (17) are held in position. With the sleeve construction (19), brake cable fixings (6) can or can be placed further in front of the lower leg (16). That is, with a greater distance to the lower leg (16).

The dashed line brake cable (4h) is a cable course variant on a, in the scooter area tensioned, brake cable (4), in this representation then instead of the brake cable guide (5a) or (5d) a brake cable attachment (6) on the scooter frame (1). needed. The cable course variant shown with the brake cable [41] shows the course over a brake cable guide (5k) guided before docking to the brake cable (4). With the docking angle between the brake cable (4) and (4i), the brake force distribution between the front and rear brake mechanism can be determined. With this roping variant, any braking mechanism mentioned in this application can be used for simultaneous braking for the front and rear.

In Fig. 9 can be seen at the cross section of the sleeve construction (19) in the amount of a cuff belt (17) the construction. In the front region, the sleeve construction (19a) is U-shaped or V-shaped in order to transmit the corresponding stability between the sleeve straps (17) for sufficient tensile force transmission during a braking movement according to the brake movement arrow (18). Depending on the type of production, the part between the cuff straps (17) can also be designed as a closed tube, forming tube, foam-filled, grid construction or full. The cuff construction (19b) runs in the areas of the cuff straps (17) approximately to the middle of the calf to the rear. The cuff belt (17) is pulled at the transition of the cuff construction (19a) to the cuff construction (19b) provided eyelets until the cuff belt fixation (20) on the sleeve construction (19) is applied. When the cuff construction (19) is fastened to the foot, the cuff belt (17) at the other end of the cuff construction (19b) is pulled through, turned over and cuffed together or closed by means of a buckle.

In Fig. 10 you can see the brake cable guides (5a) to (5d) and the over it brake cable (4). So cutout Fig. 8 in front view.

11 to 16 show further variants of the brake shoe (7) or brake shoe actuating mechanisms, in these variants, the brake shoe (7) in each case between its transverse to the direction axis of the articulated joint (10) or a brake shoe elastic (27) and the binding device (13), the respective Rollski's, arranged. Thus, the brake shoes (7) from the brake cable (4) can be powerfully operated on these variants with very simple technical solutions. In addition, these variants are also very well suited as retrofit sets for already existing roller skis, since in these variants only one, transverse to the direction of travel, bore or more, for attachment of the additional construction (12), need to be drilled. At least one such bore and at the wheel axle (3), or only at the wheel axle (3) then the additional construction (12) is attached. The adjusting screw (29) in these variants is then already attached to the additional construction (12), but can also be attached to the roller frame (1). The alignment of the adjusting screw (29) and the arrangement direction of the Anlenkgelenkfixierungen (35) are as parallel to each other as possible. So this braking concept can be adapted to different sized wheels (2) or to a wear of the wheel (2). The adjusting nut (25a) forms the stop for the return position of the brake shoe (7) after braking. The adjusting nut (25a) can also be replaced by a screw head of the adjusting screw (29). The height of this screw head is adjusted by turning the screw in a nut on the additional structure (12) or in the roller frame (1), which in turn determines the return position of the brake shoe (7), after braking. The adjusting nut (25b) determines the spring preload of the return spring (28). With the return spring (28) and the braking force of the brake shoe (7) on the wheel (2) can be influenced.

In these variants may be provided for the articulation of the articulated joint (10) of the brake shoe (7) on the additional construction (12) and a plurality of articulation possibilities. Thus, the position of the brake shoe (7) can be adapted to different sized wheels (2) or Radabnützungen. The articulation joint can also be replaced by a brake shoe elastic (27) in these variants.

In the variant shown in Fig. 11, the brake shoe (7) is actuated in pulley principle, just as in Fig. 8 on the front wheel.

In the variant of FIG. 12, the brake operating lever (31) is fixed to the brake shoe (7), which is actuated by the brake cable (4) during a braking operation and thus moves the brake shoe (7) onto the wheel (2) to be braked , The brake cable fixation on the brake lever (31) can be made adjustable adjustable in its position. When it comes to the rear frame of the Rollski's, the dashed brake cable (4f) is used, but is not so effective with this arrangement of the brake lever (31), since the angle of the brake cable (7), the ideal draft angle of 90 °, to the brake lever (31), clearly deviates.

The brake lever (31) can also be articulated to the additional structure (12), extending at a direction transverse to the axis of rotation, wherein on the underside of the brake lever (31) on the axis of rotation extending transversely to the direction of rotation an eccentric, short lever, a wheel or a small pulley is, which presses the or on actuation of the brake lever (31) from above on the brake shoe (7) and thus indirectly actuates the brake shoe (7).

In the visible in Fig. 13 variant one sees a Bremsbetätingtwinding wheel (32). The brake cable (4) is fixed on or in the brake actuation winch wheel (32) and wound in the basic position of the brake shoe (7) several times around the brake actuation winch wheel (32). When pulling the brake cable (4) is then driven with the Bremsbetätigungswindenrad (32), the brake actuation winch axis (33). The brake cable (4e) fixed to the brake actuation winch axis (33) pulls the brake shoe (7), in appropriate translation between the brake actuation winch wheel (32) and the brake actuation winch axis (33), onto the wheel (2) to be braked. The dashed line brake cable (4) shows the course of the brake cable (4) via a brake cable guide, if it is the back of a Rollski's.

The variant in Fig. 14 also shows a Bremsbetätigungswindenewheel (32) driven by the brake cable (7). With the Bremsbetätigungswindrad (32) a brake actuating spindle (34) is driven, which pulls the brake shoe (7) on the wheel to be braked (2) during rotation. In this case, on the brake shoe (7) a suitable for brake actuator spindle nut is attached.

Fig. 15 shows a variant in which the brake lever (31) extends the brake shoe (7) and so the braking force of the brake shoe (7) when pulling the brake cable (4) is higher than with a short brake shoe (7). In this figure you can see the brake cable stop (30), which holds the brake cable (4) in the area of the Rollski's tension, because only under a certain tension, the rope can be exactly in the desired positions of Bremsseilführun- 8/13

Claims (10)

Austrian Patent Office AT511 822 B1 2013-03-15 conditions. Fig. 16 shows both the articulated joint (10) and the brake shoe (7) closer to the binding device (13) than the wheel axle (3). This has the advantage that this variant is very compact and allows both the brake shoe (7), heat sink (11) and the brake lever in one piece to a brake shoe combination (7/11/31). In addition, due to the compact design between the brake cable attachments (6) and the articulated joint (10) to the brake shoe (7) an advantageous lever length ratio, so that the brake shoe (7) or brake shoe combination (7/11/31) with relatively light train on the brake cable (4), powerful on the wheel to be braked (2) can be pressed. Several brake cable attachments (6) on the brake lever (31) also allow the selection of a desired braking action of the brake shoe (7) on the wheel to be braked (2). The train of the brake cable (4) on the brake lever (31) takes place approximately at an angle of 90 °, because then the tensile force of the brake cable (4) on the brake lever (31) is the most effective advantage. This applies to all variants with brake lever. All in Figs. 1, 2, 3, 4, 5, 6, 7, 8, 10, 11, 12, 13, 14, 15 and 16 shown brake shoes and construction variants are both front and rear Rollskis replaceable. All, in any way, from the brake cable (4) moving parts are each moved back to their original starting position after a braking operation by appropriately required springs or rubbers, if not mentioned or shown in the description and in the figures , This Rollskier can be equipped with braking systems individually or in pairs. However, a more effective braking effect can be achieved simultaneously with braking with both skis. The articulation of a brake shoe on the scooter frame or on an additional construction can also be done laterally of the wheel, in a direction of rotation extending in the direction of rotation. This means that most of the brake mechanisms shown in this application, as the brake shoe is guided in each case on the wheel to be braked, also rotated by 90 ° perform their function as well. 1. The invention relates to a braking device for roller skis or roller skates with wheels or wheels and by means of binding device on the athlete's shoe detachable, partially releasably or permanently mounted scooter frame and at least one hinged to a hinge joint brake shoe braking when braking with a brake cable on at least one brake disc or brake disc is pulled, characterized in that the brake cable (4) above the shoe (14) from the front of the lower leg (16), knee, thigh, hip or upper body of the athlete, at least one brake cable guide ( 5), a brake operating lever (31), a pretensioned brake cable (4) or a brake operating gear wheel (32) is guided in front of the ankle joint of the athlete and is operable by a reclining of the athlete. 2. Braking device according to claim 1, characterized in that the brake cable (4) via at least one on or in the roller frame (1) fixed brake cable guide (5) on a brake shoe (7) is guided. 3. Braking device according to claim 2, characterized in that the brake cable (4) of the front-actuated brake shoe (7) via which at least one brake cable guide (5) on at least one further brake shoe to be actuated (7) is continued. 4. Braking device according to claim 2 or 3, characterized in that the brake cable guide (5) on the roller frame (1) or on an additional construction (12) is fixed in its position changeable. 9/13 Austrian Patent Office AT 511 822 B1 2013-03-15 5. Braking device according to one of claims 2 to 4, characterized in that on the back of the brake shoe (7) a heat sink (11) sits. 6. Braking device according to claim 5, characterized in that the brake lever (31) and the heat sink (11) are made in one piece. 7. Braking device according to claim 1, characterized in that the brake cable (4) on the lower leg (16) of the athlete on or with at least one sleeve belt (17) is releasably fixed. 8. Braking device according to one of claims 2 to 7, characterized in that the braking surface (7a) of the brake shoe (7) made of brass or other precious metal. 9. Braking device according to one of claims 2 to 8, characterized in that the brake shoe (7) engages in a between 2 wheels (2) or on the wheel (2) radially extending groove. 10. Braking device according to claim 1, characterized in that one of cuff straps (17) held on the lower leg sleeve construction (19) has a plurality of brake cable fixings (6). 3 sheets of drawings 10/13