WO2015144353A1 - Wheel having a fluid-filled tire and having a device for setting the tire pressure, and bicycle, motor vehicle, or aircraft equipped with such wheels - Google Patents

Abstract

The invention relates to a wheel (1), comprising a fluid-filled tire (2) and a device (3) for setting the tire pressure, which device has a system (4) for providing a fluid pressure that is higher than the current tire pressure and a controllable valve assembly that is functionally connected to the system, to a tire chamber (2a), and to the surrounding atmosphere. The system (4) has a pump assembly (6), which is rigidly connected to the wheel (1) and which rotates with the wheel.

Description

 Wheel with a fluid-filled tire and a device for adjusting the tire pressure and equipped with such wheels

 Bicycle, motor vehicle or aircraft

The present invention relates to a wheel with a fluid-filled tire and a device for adjusting the tire pressure according to the preamble of patent claim 1. Such a wheel is known from DE 10 2010 039 854 AI. Furthermore, the present invention relates to a bicycle, a motor vehicle or an aircraft, which are equipped with such wheels according to the invention.

In order to achieve optimal driving characteristics for vehicles with air-filled tires, the tire pressure is of considerable importance. It is directly related to the payload of the vehicle; but also with different roadway properties, especially in non-paved roads or roads, an adjustment of the tire pressure makes sense. The sinking of a vehicle in loose sand, for example when driving on the beach or in the desert, can be reduced by lowering the tire pressure so far that increases the contact surface of the tires on the ground. As a result, the weight per unit area, ie the contact pressure, which the tire exerts on the ground, causing it to sink less deeply on loose, unpaved ground, and the traction is increased. When the track with loose ground is finished, the tire pressure should be increased again.

On the other hand, a wrongly selected tire pressure adversely affects the driving behavior of a vehicle and exposes the tire to increased wear. The tire pressure should therefore, without having to control a gas station in the usual way, can be controlled by the driver and actively adapted, if circumstances require. This topic concerns both motor vehicles and bicycles.

In order to achieve optimal traction and at the same time the lowest possible frictional resistance in cycling, especially in "mountain biking", the tire pressure to be selected is also a crucial component. It is directly dependent on the type of tire (tread structure), from own body weight, of the soil condition and of the slope or the gradient of the traveled route. It thus represents a variable and should be precisely controllable and individually actively controllable while driving, without the use of an otherwise necessarily carry hand pump.

For motor vehicles, especially SUVs and vehicles used in agriculture, such as tractors and the like, there are already various rim designs and tire pressure monitoring and control devices with which a pressure regulation of a tire can be made.

The known tire pressure regulating devices, as are known, for example, from DE 10 2010 039 854 A1 or DE 100 44 886 B4, are designed exclusively for vehicles powered by engine power, have a relatively high weight and are technically complicated and accordingly expensive. Due to their weight and dimensions they are not suitable for bicycles.

From the cycling area, an active tire pressure control is known. This regulation works with a pressure bottle, which is carried along on the bicycle and with CO2 gas, which is under a very high pressure, namely about 58 bar, high pressure is filled. The CO2 gas can be fed via hoses while driving the tire dosed. The gas supply from the pressure bottle on the wheel hubs in the tire chambers is technically complex. In addition, a pressurized bottle under very high pressure is an immense source of danger, for example, when carrying the wheel in vehicles which may be exposed to high intensity solar radiation, so that the manufacturer of this system also advises extreme caution.

DE 10 2010 039 854 A1 describes a wheel with a fluid-filled tire and a device for adjusting the tire pressure, which comprises a system for providing a fluid pressure that is higher than the current tire pressure and a controllable, functional with the system, a tire chamber and the ambient atmosphere having connected valve assembly.

This device for adjusting the tire pressure is also designed exclusively for use in motor vehicles, has a relatively high weight and requires a special rim construction. This makes them relatively expensive and leads to a high overall weight. The present invention has for its object to provide a wheel with a fluid-filled tire and a device for adjusting the tire pressure, in which the device is relatively light, is also applicable to bicycles, no special rim design and no large external energy input, for example Wise by compressors or the like requires. This object is achieved by a wheel with a fluid- filled tire and a device for adjusting the tire pressure with the features of claim 1.

The subclaims are directed to features of preferred embodiments of the present invention.

The invention is further directed to a bicycle, motor vehicle or aircraft, which are at least partially equipped with the wheels according to the invention.

The present invention will be explained in more detail below with reference to the description of preferred embodiments with reference to the drawing. Show:

Figure 1 is a sectional view of a first embodiment of a

 wheel according to the invention;

 Figure 2 is a sectional side view of a second embodiment of a wheel according to the invention;

Figure 3 is a sectional view taken along A-A in Figure 2;

 Figure 4 is a sectional side view of a third embodiment of the wheel according to the invention;

 Figure 5 is a section along B-B in Figure 4; and

 6 shows a side sectional view through a fourth embodiment of the wheel according to the invention.

Figure 1 shows a first embodiment of the wheel according to the invention with a fluid-filled tire and a device for adjusting the tire pressure. Figure 1 is a cross section through the wheel 1 in a plane in which the longitudinal axis of the hub 1 1 is located. The hub 1 1, which is shown here only very schematically - there are no structural details shown - is connected via spokes 10 with the rim 9. On the rim 9 of the tubeless tire 2 is raised. The present invention is not limited to tubeless tires 2; Equally, tires with hoses can be used.

Together with the rim 9, the tire encloses a tire chamber 2a. The rim 9 is a commercially available rim having a valve bore in which a valve is usually used to inflate the tire. According to the invention, such a valve is replaced by a close-fitting nozzle, at the outer end of which a hose or pipe connection 24 is attached, whose other end opens into a bellows 7. This bellows 7 is arranged radially symmetrically between the rim 9 and the hub 1 1 in a closed housing within the Radspeichung 10 and forms a pump chamber 6a. The bellows 7 is preferably made of a gas-tight elastic plastic. The bellows 7, the hose or pipe connection 24 and the tire chamber 2a together form a closed volume in which a pressurized fluid, usually air, is below a certain nominal pressure. The filling of this volume with pressurized fluid takes place via a filling valve, which (not shown in FIG. 1) can be located on the bellows 7, on the hose or pipe connection 24 or on the rim 9.

The bellows 7 is part of a pump arrangement 6, which also has a compression mechanism 8, with which the bellows 7 can be compressed.

In this embodiment of the present invention, the compression mechanism 8 comprises a spindle drive 8a having a control shaft 17 terminating in a thumbwheel 17a driven by a remotely controllable electric motor 18. *** " The spindle drive 8a has a threaded rod, in the rotation, depending on the direction of rotation, an actuator moves in Figure 1 to the right or to the left can be. This actuator is connected to fins 8b or the like, which are articulated at the radially outermost end of the bellows 7 to a correspondingly executed holder. When the actuator 8a in FIG. 1 is moved to the left by the motor drive 18 by rotation of the spindle, the bellows 7 is compressed, its internal volume decreases, and the total pressure in the pump chamber 6a, the hose or pipe joint 24 and the tire chamber 2a increases yourself. If the direction of rotation of the spindle 8a is reversed, then the lamellae 8b in FIG. 1 move to the right, the bellows 7 can expand and the total volume described above increases, as a result of which the pressure in the tire chamber 2a also drops. Thus, the tire pressure can be varied steplessly from a pressure below a nominal tire pressure to a pressure value above the nominal tire pressure by actuation of the compression mechanism 8. The electric motor 18 is controlled by the driver of the vehicle to which the wheel according to the invention is mounted by appropriately designed switches.

In the case of a bicycle, especially mountain bikes, such a switch is preferably located on the handlebar of the bicycle or in the vicinity. There may also be an analog or digital pressure gauge attached, which is connected to a pressure sensor 31 which measures the pressure in the tire chamber 2a. The pressure sensor 31 can transmit its measured values via radio to the pressure display.

Figure 2 shows a second embodiment of a wheel according to the invention with a device for adjusting the tire pressure. In contrast to the embodiment shown in Figure 1, this is not a wheel with a rim, which is connected via wire spokes with a hub, but here form the hub 1 1, spars 13 and the rim 9 is a unit. This unit can be cast from light metal or is made of fiber-reinforced plastic or the like. According to Figure 2, the rim 9 is connected to the hub 1 1 via three star-shaped arranged spars 13. The spars 13 are formed as a hollow cylinder, which are connected via corresponding openings in the rim base with the tire chamber 2a. In the hollow cylinder formed as a Holmen 13 defines a piston 14, which is provided with a sealing lip 14a, a pump chamber 6a. The piston 14 is connected in the illustrated embodiment via a threaded rod with a spindle drive 15. At the other end of the threaded rod is located at the height of the longitudinal axis of the hub 1 1 (shown here only very schematically) an angular toothing.

In the embodiment shown, each of the spars 13 is equipped with a hollow cylinder, so that in each spar 13, a pump chamber 6a is located. The spindle drives 15 are driven by a to the hub 1 1 coaxially extending control shaft 17 by an electric motor 18. Depending on the direction of rotation of the electric motor 18, the volume of the pump chambers 6a is increased or decreased. Again, the pump chambers 6a and the tire chamber 2a together form a closed volume. This volume can be inflated via a filling valve (not shown in FIG. 2) with a pressure fluid, generally air. In the tire chamber 2a is preferably in turn

 Pressure sensor 31, which outputs its measurement results to a pressure gauge.

Just as in the first embodiment, the driver can control the electric motor 18 via appropriately designed and arranged switches so that the pistons in FIG. 3 either move up, reducing the overall volume 2a, 6a and increasing tire pressure, or vice versa below, thereby increasing the overall volume 2a, 6a, thereby decreasing the tire pressure. The angle teeth shown in Figures 2 and 3 and their

Drive to the hub 1 1 by an electric motor 18 is shown only very schematically in the form of a principle drawing. The exact structural design is within the skill of the art.

The embodiments of the present invention shown in Figures 1 to 3 are each closed systems forming a contiguous variable volume. The change in the closed volume leads to a change in the tire pressure. The change in tire pressure can be made by the driver while driving, that is, while the wheels are turning.

Figure 4 shows a third embodiment of the present invention in a side sectional view. Here, the pump assembly 6 is integrated into the hub 1 1. The pump assembly 6 here has the form of a 5-cylinder pump, wherein the pump chambers 6a are arranged in the manner of a star motor. The pump chambers 6a have hollow cylinders, which are aligned from the longitudinal axis of the hub 1 1 radially outwardly to the rim 9. In the hollow cylinders of the pump chambers 6a move piston 14, which are articulated on the one hand on an eccentric disc 20 and on the other hand in each case by a return spring 32 are pressed radially inwardly. The eccentric disc 20 has a free-running, ball-bearing axis of rotation, which coincides with the axis of rotation of the hub 1 1. If no additional forces are applied to the eccentric disc, it rotates synchronously with the wheel while driving. That is, the pistons in the pump assembly do not move and no pressure builds up. However, if the eccentric disc is braked (by operation of the driver) by a brake mechanism (not shown in FIG. 5) disposed on the fixed part of the hub 11, these differ Rotation speeds of the eccentric and the wheel and thus the pump chambers, so that it comes to a drive of the piston and a pressure in the pump assembly is constructed. The hollow cylinders of the pump chambers 6a are each connected at their radially outer end via check valves 23 with a ring line 22. Furthermore, the pump chambers have fluid valves 25 through which air is sucked out of the atmosphere into the pump chambers 6a during a radial inward movement of the pistons 14 when the check valves 23 are closed. In a radially outwardly directed piston movement, the fluid valves close 25 and the compressed air is pressed through the check valves 23 in the ring line 22. The ring line 22 is connected via a hose or pipe connection 24 with the rim 9 and thus the tire chamber 2a in conjunction. At the rim end of the hose or pipe connection 24, a two-way valve arrangement 5a is arranged. This valve assembly 5a is also controlled by radio, between a position in which the volume of the tire chamber 2a is completed, a position in which air from the tire chamber 2a can be discharged into the ambient atmosphere, and a position in the pressurized fluid generated by the pump assembly 6, can be pressed through the hose or pipe connection 24 in the tire chamber 2a.

FIG. 5 shows a section along the line B-B in FIG. 4 for further clarification of the control of the pump chambers 6a.

The embodiment shown in Figures 4 and 5 is an open system, that is, when the tire pressure in the tire chamber 2a is to be lowered from a nominal value, air is released into the ambient atmosphere. As the tire pressure increases, the pump assembly 6 draws air from the atmosphere, compresses it, and supplies it to the tire chamber 2a under pressure via the hose or pipe connection 24. FIG. 6 shows a fourth embodiment of the present invention, in which the pump arrangement 6 has a trochoid circuit pump 26 integrated into the hub 11. A rotary piston 26a moves in a pump housing 26b, driven via a gear connection consisting of a smaller with the axis of rotation of the hub 1 1 coaxial gear 26c. The rotary piston 26 a sucks air via an intake passage 28, which is compressed in the compression area 29. In the compression area opens a controllable vent valve 30, which can be opened or closed remotely by the driver. When the vent valve 30 is open, no overpressure builds up in the hose or pipe connection 24. If the driver wants to increase the pressure in the tire chamber 2a, he closes the controllable vent valve 30 and on the two-way valve assembly 5a is an overpressure for inflating the tire 2 at. To increase the tire pressure, the driver opens the two-way valve 5a and makes a connection between the hose or pipe joint 24 and the tire chamber 2a. Here, too, pressure sensors 31 are arranged in the tire chamber 2 a and in the compression area 29. The measured pressures are displayed via pressure displays.

If the tire pressure in the tire chamber 2a is to be lowered, the two-way valve assembly 5a is controlled so that air is released from the tire chamber 2a into the atmosphere. The wheel according to the invention with a fluid-filled tire and a device for adjusting the tire pressure can be installed in a bicycle, in particular of the mountain bike type, whereby it is possible to equip only one wheel or both wheels according to the invention. Also, the present invention has application to four- or multi-wheeled automobiles or aircraft, wherein also at least one axle or all axles can be equipped with wheels according to the present invention. The present invention is not to be limited to the embodiments described above, but includes all variants that fall within the scope of the appended claims.

LIST OF REFERENCE NUMBERS

1 wheel

2 tires

 2 a tire chamber

 3 Device for adjusting the tire pressure

 4 System for providing higher tire pressure

5 valve arrangement

5a two-way valve arrangement

 6 pump arrangement

6a pump chamber

 7 bellows

 8 compression mechanism

8a spindle drive

 8b slats

 9 rim

 10 spokes

 1 1 hub

12 spindle drive

 13 spars

 13a hollow cylinder

 14 pistons

14a sealing lip

15 spindle drive

 16 angle teeth

 17 control shaft

 18 electric motor

 19 wave

20 eccentric disc

 21 connecting rods

 22 ring line

23 check valves Hose or pipe connection fluid valves

Trochoid circulating pump output channel

intake port

compression region

controllable bleed valve pressure sensor

Claims

Patent claims

1. Wheel (1) with a fluid-filled tire (2) and a device (3) for adjusting the tire pressure, which has a system (4) for providing a higher fluid pressure than the current tire pressure and a controllable, functional with the system, has a valve arrangement connected to a tire chamber (2a) and the ambient atmosphere,

characterized in that

the system (4) has a pump arrangement (6) which is firmly connected to the wheel (1) and rotates with the wheel.

2. Wheel (1) according to claim 1,

characterized in that

the pump arrangement (6) has at least one pump chamber (6a) with a controllably variable volume, which communicates with the tire chamber (2a).

3. Wheel (1) according to claim 2,

characterized in that

the pump chamber (6a) is formed by a deformable bellows (7), the internal volume of which can be varied by a controllable compression mechanism (8).

4. Wheel (1) according to claim 3,

characterized in that

the wheel (1) has a rim (9), spokes (10) and a hub (11), and the bellows (7) is arranged in the space between the hub (11) and the rim (9) and its volume is determined by a Compression mechanism (8), which can be controlled via a spindle drive (12) on the hub (1 1), can be varied.

5. Wheel (1) according to one of claims 2 to 4,

characterized in that

the pump chamber (6a) and the tire chamber (2a) form a closed, variable, coherent volume, by changing the tire pressure from values below a nominal pressure to values above the nominal pressure.

6. Wheel (1) according to claim 2 with a rim (9) and a hub (1 1), which are connected to one another via star-shaped spars (13),

characterized in that

the bars (13) are designed as hollow cylinders, which communicate with the tire chamber (2a) via the rims (9) and in which pistons (14) can be moved in a fluid-tight manner via spindle drives (15), thereby forming pump chambers (6a) with variable volume become.

7. Wheel (1) according to claim 6,

characterized in that

the spindle drives (15) of the pistons (14) are controlled via angular gears (16) with a control shaft (17) which is coaxially mounted in the hub (11) and which is provided with a remotely operable adjusting wheel (17a).

8. Wheel (1) according to claim 2,

characterized in that

the pump arrangement (6) is constructed in the manner of a radial engine and is coaxially integrated in a hub (1 1) of the wheel (1), an eccentric disk (20) being arranged on a shaft (19), which connects the pistons via connecting rods (21). (14) can drive in star-shaped, radially arranged hollow cylinders (13a), the pump chambers (6a) all opening via check valves (23) into a ring line (22), which is connected to the tire via a hose or pipe connection (24). chamber (2a) is connected, and the pump chambers (6a) are provided with fluid valves (25) with which air is sucked in from the ambient atmosphere during a radially inward return movement of the piston (14).

Wheel (1) according to claim 8,

characterized in that

the eccentric disk (20) is ball-mounted and can therefore be freely rotated in its own movement, regardless of the rotation of the wheel, and can be braked via a fixed brake mechanism, whereby a relative rotational movement is generated between the eccentric disk (20) and the pump chambers (6a), so that in the Pump arrangement builds up pressure.

Wheel (1) according to claim 8 or 9,

characterized in that

At the mouth of the hose or pipe connection (24) into the tire chamber (2a), a remotely controllable two-way valve arrangement (5a) is provided, with which air is released to reduce the pressure in the tire (2) or to increase the pressure, air is released under high pressure from the pump arrangement (6). can be admitted.

Wheel (1) according to claim 2,

characterized in that

the pump arrangement (6) is a trochoidal circuit pump (26) coaxially integrated into the hub of the wheel, the discharge channel (27) of which is connected to the tire chamber (2a) via a hose or pipe connection (24) via a controllable two-way valve (5a) and the intake channel (28) of which opens into the ambient atmosphere, with compressed air from the pump (26) being admitted into the tire chamber (2a) to increase the tire pressure in one position of the two-way valve (5a) and air from the tire chamber (2a) being admitted in another position. released into the surrounding atmosphere.

Wheel (1) according to claim 1 1,

characterized in that

A remotely controllable vent valve (30) is provided in the compression area of the trochoidal circuit pump (26), which prevents pressure build-up in the hose or pipe connection (24) in an idle mode.

Wheel (1) according to one of the preceding claims,

characterized in that

pressure sensors (31) which can be queried via radio are arranged in the tire chamber (2a) and/or in the pump arrangement (6), the measured values of which can be displayed on an analog or digital display.

Wheel according to claim 1,

characterized in that

the pump arrangement (6) has a high-pressure chamber which can be connected to the tire chamber (2a) via an intermediate chamber provided with the valve arrangement (5).

Bicycle, in particular of the mountain bike type, with at least one wheel (1) according to at least one of the above claims.

16. Bicycle according to claim 15,

characterized in that

Pressure indicators for the tire chamber pressure and/or the pressure in the pump arrangement (6) as well as actuators for the remote-controlled valves (5, 5a) and actuators (18) are arranged on the handlebar or near it.

17. Motor vehicle or aircraft with two wheels per axle,

characterized in that at least one axle or all axles are equipped with wheels (1) according to at least one of claims 1 to 14.