DE3928230A1 - Hydraulic hub brake with integrated pump and constriction - provides adjustments of fluid flow and resistance in housing connected by spokes to rim of wheel - Google Patents

Abstract

The housing (8) of the hub encloses a whirling-disc pump (6) with pistons (4) in a cylinder block (7) driving the hydraulic fluid through a constriction (13) adjusted hydraulically (20) by a needle (14) and spring (21). The brake lever also actuates the pump adjustment (22) by a smaller hydraulic cylinder (27) and piston rod (29) coupled to the disc support plate (9). A computer may be programmed for correcting the adjustment in response to measured speed. USE/ADVANTAGE - On motor-cycles. Safer braking is achieved with a maintenance-free, low-friction, mechanically insensitive, compact, dirtproof and environmentally acceptable appts. requiring little force.

Description

The invention relates to a wheel hub fluid brake for bicycles according to the preamble of the claim 1.

In bicycles, brakes are known in such a way that a braking effect by means of mechanical friction is achieved. These include drum, disc, Rim and friction block brakes as well as the back pedal hub brakes. With all these brakes the Braking force from the lever or operating pedal in Normally by means of mechanical translation, at the registration DE P 8 34 655 by means of hydraulics directly upset.

The functions to be performed are mentioned above Brake types not fully in several areas Fulfills. Subject to the principle of friction these brakes some wear. Alone this results in abrasion that is harmful to the environment, this is incriminating, delivered directly. The wear requires maintenance work in the form of readjustments and renewing brake parts. A not permanent Maintenance can also be safety question the brakes. Because with disc,  Rim and friction block brakes the braking elements exposed, they are against Moisture, dirt etc. unprotected and can in the braking effect until ineffectiveness be affected. The functional reliability is possibly also negatively influenced by the fact that the mechanical components the forces that occur can not record and z. B. bend, break; In addition, the effectiveness of the brake of depends on a sometimes high actuation force. For applications DE P 37 29 145.9 and DE P 8 34 655 the braking force is directly via cable or hydraulics applied to a drum or shoe brake; the disadvantage of being directly dependent on the braking force remains operating force.

The object of the invention is therefore to wear free, environmentally friendly, maintenance free, from Pollution influences independent, with little Effective, mechanically insensitive, executed in a space-saving compact design and thus create a safe brake for bicycles. In addition, the principle of the brake should Offer possibility of front and rear wheel Achieving the optimal braking effect at the same time  to operate (all-wheel brake) and beyond the braking effect on the individual wheels of the bike individually self-regulating to optimize for the given road conditions.

This object is achieved with a Wheel hub fluid brake for bicycles released. It consists of a liquid pump, if necessary with adjustable delivery volume, a liquid duct system, which may also serve as a throttle can be executed, a possibly adjustable Liquid flow restrictor and actuator (s) for liquid pump and / or liquid flow restrictor element. These components of the fluid brake are part of the wheel hub as a compact component; is the drive element of the liquid pump connected to the rim of the wheel. The brake according to claim 1 is a wheel hub fluid brake.

The task, one with little effort to achieve effective braking performance achieved in that by the actuators (e.g. brake lever / brake pedal) no braking forces to achieve the braking effect, but only  the control forces for adjusting the control elements the liquid pump and / or the liquid throttle element are needed.

In claim 8, the invention proceeds from the following Problem situation: During a braking process if the bike is on the road a brake pressure is built up in the fluid channel system. If there is suddenly no grip (e.g. with black ice) there is an abrupt braking effect ver lust with a simultaneous drop in brake pressure in the liquid channel system. This abrupt change in pressure as a pressure drop caused by a signal transmitter loosening in connection with control elements the brake, e.g. B. by opening the liquid flow throttle element. While claims 4- 7 general blocking when the brake load is too high prevent, claim 8 is an automatic regulated braking power when suddenly occurring reduced braking effect due to sudden reduced grip.

According to claim 9, the invention takes into account the mass to be braked, divided into the difference load of the individual wheel axles, and thus enables the braking power of the  different loads that arise can from the loading of the bike and the respective Weight of the driver and the increased weight load the front axle and the reduced weight load on the rear axle during braking, individual duel can be adjusted. Is z. B. the mass pressure transducer coupled to the pressure relief valve, so causes a higher weight load on the wheel axle a valve setting that can withstand higher pressures is the consequence of a higher braking effect. The pressure relief valve is used for lighter loads less resilient with the result that it only withstands a lower brake pressure and therefore a lower braking power is possible is.

Claim 10 invents an optimal braking effect in that the braking power of each Wheel brakes independently of each other Speed of the bike, weight load the wheel axles and the grip of the wheels is adjusted. This happens because the Movement of the bike via a motion detector regardless of the speed of the respective wheel that is measured separately, the wheel speeds  measured and driving speed and wheel speed speed and wheel speed with each other be compared. This can be done with the help of a Computer, be it electronic or mechanical, he consequences. The speed behavior is in the computer of the wheels at a given driving speed to achieve the maximum braking effect given as a program. Find in the calculator a comparison instead of between the entered Program and the data resulting from wheel speed and driving speed result. The result is Comparison of differences during braking to achieve maximum delay, e.g. B. slowly rotating, on braking effect put wheels at high driving speed, so the computer increases over control lines the controls on the respective control elements Influence of the liquid brake on the Delivery rate of the liquid pump and / or the throttle position of the liquid throttle elements; this can e.g. B. done via an electromagnetic control of a nozzle needle in the liquid chamber system.  

The advantages achievable with the invention exist alongside those in the task mentioned functions and properties in particular in that safety when cycling straight through the brake according to the invention at the speed that has become possible today and special uses (e.g. Off-road driving) and the high traffic density is significantly increased. Also suitable the brake according to the invention in particular Way that the fluid brakes on the front and rear wheel via the control elements simultaneously or out of phase in one Braking together with an actuator operate with little effort. In addition, the brake on each wheel individually on load and against blocking self-regulating. Sudden Loss of braking efficiency by changing the Grip of the wheel and related Difficulty steering the bike itself be reduced regulatively.

The regulation of the braking effect with inclusion the road grip of the wheels and the speed  speed of the bicycle and the speed of rotation of the individual wheels allows the wheels to work independently depending on each other optimally braked can.

An embodiment of the invention is in the drawing and is shown below described in more detail.

Fig. I shows a wheel consisting of rim ( 1 ), spokes ( 2 ) and wheel axle ( 3 ) with a wheel hub. The following are shown as components integrated in the wheel hub: The liquid pump as a swash plate piston pump, consisting of several pistons ( 4 ), connecting rod ( 5 ), swash plate ( 6 ), pivotable in the bearing ( 19 ) on the wheel axle ( 3 ), cylinder block ( 7 ), rigidly connected to the wheel axle ( 3 ) and drive element. This is firmly connected to the rim ( 1 ) via spokes ( 2 ) and consists of a wheel hub housing ( 8 ) and a swash plate support plate ( 9 ), which is pivotally mounted in a ball bearing ( 10 ) in the wheel hub housing ( 8 ). The rotational movement of the wheel hub housing ( 8 ) is transmitted to the swash plate support plate ( 9 ) by means of a tongue and groove connection ( 11 ); in addition there is the liquid channel system ( 12 ) as part of the cylinder block ( 7 ) and the wheel axle ( 3 ). The liquid throttle element is designed in the example as a bore ( 13 ) in the liquid channel system ( 12 ) and cross-section changing nozzle needle ( 14 ); the nozzle needle is guided in a longitudinal bore ( 15 ) in the wheel axle ( 3 ). The actuating element for positioning the nozzle needle ( 14 ) consists of a throttle actuator hydraulics ( 20 ), actuated by a brake lever and a return spring ( 21 ) on the nozzle needle ( 14 ). The control element for the positioning of the swash plate support plate ( 9 ) consists of a pump control hydraulic system ( 22 ), actuated by a brake lever; the hydraulic system ( 22 ) is connected in an axis longitudinal bore ( 23 ) and opens into an axis transverse bore ( 24 ). A groove ( 25 ) arranged around the transverse bore in the hub housing is sealed off from the axis by means of sealing rings ( 26 ); A hydraulic cylinder ( 27 ) connected to the groove ( 25 ) guides a hydraulic piston ( 28 ) which is connected to the swash plate support plate ( 9 ) via a support plate connecting rod ( 29 ) and determines the position of the swash plate support plate ( 9 ) depending on the brake lever pressure.

Fig. II: The wheel axle ( 3 ) is designed to prevent twisting due to braking torques by means of a molded square ( 16 ) in a dovetail guide ( 17 ) on the fork ends ( 18 ).

Fig. III shows an embodiment of a pressure drop control of the wheel hub liquid brake according to claim 8. It is shown: A liquid flow restrictor element ( 30 ) in the liquid channel system ( 31 ) with the pressure side ( 32 ) and a bypass ( 33 ). On the pressure side, a locking piston ( 34 ) with a locking spring ( 35 ) mounted in a locking cylinder ( 37 ) closes the bypass opening ( 36 ) to the pressure side ( 32 ). An actuating cylinder ( 38 ) with actuating piston ( 39 ) and actuating spring ( 40 ) is also mounted. The position of the actuating piston ( 39 ) in the actuating cylinder ( 38 ) depends on the pressure. In the event of a sudden drop in pressure in the liquid channel system ( 31 ), the actuating piston ( 39 ) is jerked back due to the action of the actuating spring ( 40 ). With sufficient energy, the position of the closing piston ( 34 ) is changed via a rocker ( 41 ) so that it releases the bypass opening ( 36 ) and is then pushed back into its original closing position by the closing spring.

Fig. IV shows based on claim 9: liquid channel system ( 31 ) with liquid flow throttle element ( 30 ), pressure side ( 32 ) and bypass ( 33 ). A nozzle needle ( 42 ) with a compression spring ( 43 ) in a cylinder bore ( 44 ) in the wheel axle ( 3 ) acts as a pressure relief valve in the bypass ( 33 ). The fork end ( 45 ) resting on the wheel axle ( 3 ) guides a fork piston ( 47 ) with a piston bore ( 48 ) in a fork cylinder ( 46 ). The piston bore ( 48 ) opens via an Achsquerboh tion ( 49 ) in the cylinder bore ( 44 ) of the wheel axle ( 3 ). The wheel axle ( 3 ) is mounted in the fork piston ( 48 ). A hydraulic fluid ( 50 ) in the fork cylinder ( 46 ), in the piston bore ( 48 ), the axle transverse bore ( 49 ) and the cylinder bore ( 44 ) gives the fork load in terms of pressure via a spring end plate ( 51 ) to the compression spring ( 43 ) and thus changes the preload force of the pressure relief valve.

Fig. V shows a signal diagram as a representation for the invention according to claim 10:
The speed of the bicycle is recorded without contact via an infrared motion detector ( 52 ), the individual wheel speeds via individual speedometer ( 53 ) by means of signal lines ( 54 ) from the computer ( 55 ) as actual values. These actual values are compared by the computer ( 55 ) with the target values programmed in it for maximum braking action and converted into control signals which are delivered via control lines ( 56 ) to control elements ( 57 ) for the purpose of regulating the control elements ( 58 ) on the liquid pump . The actuating elements ( 58 ) are positioned by actuating elements brake lever ( 59 ) and hydraulics ( 60 ) according to the desired braking effect. In case of a desired maximum braking effect of the computer (55) via control lines (56) and controls (57) corrects the predetermined over the actuating elements (59/60) position of the actuating elements (58) of the fluid brake (61).

As an embodiment of a control element according to claim 10, Fig. I shows an electromagnetic winding ( 62 ), which generates a magnetic field according to the current flow given by the computer via control lines ( 56 ) and accordingly influences the position of the nozzle needle ( 14 ) made of magnetic material as an adjusting element . A battery ( 63 ) provides the required energy.

Claims (10)

1.Wheel hub fluid for bicycles, consisting of a liquid pump, possibly with an adjustable delivery volume, liquid channel system, which may also be designed as a throttle point, an optionally adjustable liquid flow throttle element (e.g. valve, throttle valve), as far as this is shown as a separate component is, and control element (s) for the pump and / or throttle, characterized in that the liquid pump, liquid channel system and the liquid flow throttle element, if present, are placed as integrated components of the wheel hub on / around the axis of rotation of the wheel and the drive element of the liquid pump via z. B. spokes connected to the rim. 2. Wheel hub fluid brake according to claim 1, in order to achieve braking effect none direct braking force on the actuators, but only control force for the control elements the pump and / or throttle is applied, characterized, that the actuating elements (e.g. brake levers) about z. B. a hydraulic, Bowden cable with the  Control elements of the liquid pump for the Delivery volume (e.g. spindle) and / or with those for the position of the liquid flow restrictor element are connected. 3. Wheel hub fluid brake according to claim 1 and 2 in order to achieve good braking effect and maintenance of the steering ability of the This prevents the bike from locking up is prevented that the liquid flow in dependent liquid pressure through the delivery rate the liquid pump is regulated in a self-regulating manner becomes, characterized, that the liquid pump with a hydraulic Adjustment element is provided with the pressure side of the liquid channel system is connected. 4. Wheel hub fluid brake according to claim 1-3 where the wheels are locked in which prevents the fluid pressure depending on the liquid flow self-regulation rend is regulated, characterized, that the liquid flow restriction element in the liquid duct system designed as a pressure relief valve  is. 5. Wheel hub fluid brake according to claim 4, characterized, that the pressure relief valve in the liquid channel system with a hydraulic actuator is provided with the pressure side of the liquid channel system is connected. 6. wheel hub fluid brake according to claim 4, characterized, that the liquid flow throttle element with a bypass is bridged in which there is a pressure relief valve, which may be equipped with a hydraulic actuator is provided that with the pressure side of the liquid channel system connected is. 7. wheel hub fluid brake according to claim 4-6, characterized, that the liquid pump and pressure relief valve (s)  provided with a hydraulic control element is / are that with the pressure side of the liquid channel system is connected. 8. wheel hub fluid brake according to claim 1-7, where the wheel is blocked by The brake is released or prevented if the braking effect suddenly decreases due to reduced grip, the brake pressure in the system suddenly decreases characterized, that on the pressure side of the liquid flow restrictor mentes a signal generator for abrupt pressure drop (e.g. spring, sprung like a hydraulic accumulator Piston) is attached, which is connected to Control elements for the liquid flow (e.g. B. liquid flow throttle element, bypass valve). 9. wheel hub fluid brake according to claim 1-8, where the braking power is dependent from the axle load, characterized, that a mass pressure sensor (e.g. spring,  Hydraulic pistons) in, on, on the axle suspension and / or axis and via a control line (e.g. hydraulics) with the control elements (e.g. pressure relief valve) is connected. 10. Wheel hub fluid brake according to claim 1-9, where the braking effect of the bike, that with an energy storage or energy generator is equipped to operate the additional devices, is optimized by making it dependent is the speed of the bike and the grip of the wheels, characterized, that the bike with a motion detector Detection of the bike movement (e.g. Infra red motion detector) and the individual wheels with a speed indicator (e.g. Speedometer) are provided and movement and Speed detector via control line and a Steuerge advises (e.g. computer) are connected; the Stellele elements of the liquid pump and / or the liquid Speed current choke element are with control elements (e.g. electromagnet), which via Control lines with the control unit as a signal generator are connected.