초록 ▼

A vehicle having a chassis (1) and at least two mutually separated wheels arranged on a first side of the chassis and two mutually separated wheels on the opposite, second side of the chassis where the wheels on the first side are rotatable about axes that are substantially fixed in position in a ve

A vehicle having a chassis (1) and at least two mutually separated wheels arranged on a first side of the chassis and two mutually separated wheels on the opposite, second side of the chassis where the wheels on the first side are rotatable about axes that are substantially fixed in position in a vertical plane relative to the chassis and the wheels (5) on the second side are arranged on a frame part (6) that is pivotably arranged relative to the chassis about a central longitudinal axis (8) running between the first and second sides of the vehicle to create a stability area for the vehicle in the shape of a triangle in the horizontal plane. Means (17) is designed so that when the vehicle's tipping point reaches the boundary area of the stability triangle the means starts to gradually increase the resistance against the tipping of the frame part relative to the chassis about said axis on increasing departure of the tipping point from the triangle's centre and when the tipping point reaches a predetermined boundary to completely fix the frame part relative to the chassis and form a stability area to be defined by said wheels.

대표청구항 ▼

The invention claimed is: 1. Vehicle comprising a chassis (1), at least two mutually separated wheels (3) arranged on a first side (2) of the chassis and two mutually separated wheels (5) on the opposite, second side of the chassis (4), the wheels being arranged to support the chassis when resting

The invention claimed is: 1. Vehicle comprising a chassis (1), at least two mutually separated wheels (3) arranged on a first side (2) of the chassis and two mutually separated wheels (5) on the opposite, second side of the chassis (4), the wheels being arranged to support the chassis when resting on the ground, with the wheels on the first side rotatable about axes substantially fixed in position in the vertical direction relative to the chassis and the wheels on the second side arranged on a frame part (6) pivotably arranged relative to the chassis about a substantially central longitudinal axis (8) running between the first and the second sides of the vehicle to create a stability area for the vehicle in the shape of a triangle in the horizontal plane, an arrangement (12) to determine the position of the vehicle's tipping point (T) in relation to the stability area and thereby the vehicle's stability, and means (17) for fixing the frame part relative to the chassis on the order of the arrangement to increase the vehicle's stability area to be defined by said wheels, wherein said arrangement (12) is structured and arranged to continuously determine the position of the vehicle's tipping point (T), when the vehicle's tipping point reaches a boundary area (19) of the stability triangle, the fixing means (17) are structured and arranged to gradually increase the resistance against a pivoting of the frame part relative to the chassis about said longitudinal axis on increasing distance of the tipping point from the triangle's centre to gradually increase the stability area, and when said tipping point reaches a pro-determined boundary, said fixing means (17) are structured and arranged to completely fix the frame part (6) relative to the chassis (1) and form a stability area defined by said wheels, and said wheels (5) mounted on the second side are mounted underneath said pivotally-arranged frame part (6). 2. Vehicle according to claim 1, wherein the arrangement (12) is designed to receive parameters necessary for calculating the position of the vehicle's instantaneous centre of gravity from sensors (13-16) included in the vehicle and/or means for controlling the vehicle's operation, to calculate the position of the vehicles instantaneous centre of gravity, and the arrangement is arranged to determine the position of said centre of gravity by calculating the position of the vehicle's instantaneous centre of gravity. 3. Vehicle according to claim 1, wherein the arrangement is arranged to carry out calculations to determine the position of said boundary area (19) and pre-determined boundary while considering the vehicle's instantaneous velocity to reduce the area within the respective boundary as the vehicle increases its velocity. 4. Vehicle according to claim 1, wherein said means (17) for gradually increasing the resistance against pivoting of the frame part (6) relative to the chassis (1) on departure of the tipping point from the triangle's centre is arranged to engage a resistive force to act against the relative movement between the frame part and the chassis intermittently during time periods, whose length per unit time is controlled to increase in order to achieve said gradual increase. 5. Vehicle according to claim 4, wherein said means (17) is arranged to open and close the valve means (28) intermittently, in a controlled way when the vehicle's tipping point reaches said boundary area. 6. Vehicle according to claim 1, wherein said means (17) for gradually increasing the resistance against pivoting of the frame part (6) relative to the chassis (1) on departure of the tipping point from the triangle's centre comprises longitudinally variable, pressure-medium-influenced power means (23) arranged to act between the frame part and the chassis with two pressure chambers (25, 26) connected to one another via an outer bypass conduit (27) with valve means (28), and disposed on both sides of a piston (24), and the valve means are adjustable to affect the pressure medium's capability to flow from the first chamber to the second chamber and thereby the resistance against a displacement of the piston and a length change of the power means. 7. Vehicle according to claim 6, wherein the power means (23) is a hydraulic cylinder. 8. Vehicle according to claim 1, wherein it comprises a lifting unit (7) to lift heavy loads, and this lifting unit is arranged on said first side (2) of the chassis. 9. Vehicle comprising a chassis (1), at least two mutually separated wheels (3) arranged on a first side (2) of the chassis and two mutually separated wheels (5) on the opposite, second side of the chassis (4), the wheels being arranged to support the chassis when resting on the ground, with the wheels on the first side rotatable about axes substantially fixed in position in the vertical direction relative to the chassis and the wheels at the second side are arranged on a frame part (6) pivotably arranged relative to the chassis about a substantially central longitudinal axis (8) running between the first and the second sides of the vehicle to create a stability area for the vehicle in the shape of a triangle in the horizontal plane, an arrangement (12) to determine the position of the vehicle's tipping point (T) in relation to the stability area and thereby the vehicle's stability, means (17) for fixing the frame part relative to the chassis on the order of the arrangement to increase the vehicle's stability area to be defined by said wheels, and means (32) for attaching each said wheel (5) on said frame part (6) to: (i) fix the wheel in position relative to the frame part (6) and ensure the frame part has fixed distance to the ground on which the wheel is resting, on application of a load to the wheel below a pre-determined level, and (ii) allow a movement of the wheel towards the frame part when the load on the wheel exceeds the pre-determined level, storing potential energy and decreasing the distance between the frame part and the ground on which the wheel is resting, and said wheels (5) mounted on the second side are mounted underneath said pivotally-arranged frame part (6). 10. Vehicle comprising a chassis (1), at least two mutually separated wheels (3) arranged on a first side (2) of the chassis and two mutually separated wheels (5) on the opposite, second side of the chassis (4), the wheels being arranged to support the chassis when resting on the ground, with the wheels on the first side rotatable about axes substantially fixed in position in the vertical direction relative to the chassis and the wheels on the second side arranged on a frame part (6) pivotably arranged relative to the chassis about a substantially central longitudinal axis (8) running between the first and the second sides of the vehicle to create a stability area for the vehicle in the shape of a triangle in the horizontal plane, an arrangement (12) to determine the position of the vehicle's tipping point (T) in relation to the stability area and thereby the vehicle's stability, and means (17) for fixing the frame part relative to the chassis on the order of the arrangement to increase the vehicle's stability area to be defined by said wheels, wherein said means (17) are designed to co-operate with the arrangement (12) so that when the vehicle's tipping point reaches a boundary area (19) of the stability triangle the fixing means (17) starts to gradually increase the resistance against a pivoting of the frame part relative to the chassis about said longitudinal axis on increasing distance of the tipping point from the triangle's centre to gradually increase the stability area, and when said tipping point reaches a pre-determined boundary, to completely fix the frame part (6) relative to the chassis (1) and form a stability area defined by said wheels, and further comprising means arranged to communicate with said arrangement (12) and on obtaining information that said tipping point is located at a distance below a predetermined value from the stability area's outer boundary, lock the drive means of the vehicle to only be able to carry out movements of the vehicle having a stabilizing effect in order to move the vehicle's tipping point away from the stability area's outer edge. 11. Vehicle comprising a chassis (1), at least two mutually separated wheels (3) arranged on a first side (2) of the chassis and two mutually separated wheel (5) on the opposite, second side of the chassis (4), the wheels being arranged to support the chassis when resting on the ground, with the wheels on the first side rotatable about axes substantially fixed in position in the vertical direction relative to the chassis and the wheels at the second side are arranged on a frame part (6) pivotably arranged relative to the chassis about a substantially central longitudinal axis (8) running between the first and the second sides of the vehicle to create a stability area for the vehicle in the shape of a triangle in the horizontal plane, an arrangement (12) to determine the position of the vehicle's tipping point (T) in relation to the stability area and thereby the vehicle's stability, means (17) for fixing the frame part relative to the chassis on the order of the arrangement to increase the vehicle's stability area to be defined by said wheels, and means (32) for attaching each said wheel (5) on said frame part (6) to: (i) fix the wheel in position relative to the frame part (6) and ensure the frame part has fixed distance to the ground on which the wheel is resting on application of a load to the wheel below a pre-determined level, and (ii) allow a movement of the wheel towards the frame part when the load on the wheel exceeds the pre-determined level, while storing potential energy and decreasing the distance between the frame part and the ground on which the wheel is resting, wherein said means (32) for fixing the wheels (5) to the frame part (6) are designed to attach the wheels (5) to the frame part (6) so that said pre-determined level of the load is adapted so that it is exceeded on driving the vehicle with the wheels in question over an obstruction at a velocity above a pre-determined velocity level. 12. Vehicle comprising a chassis (1), at least two mutually separated wheels (3) arranged on a first side (2) of the chassis and two mutually separated wheels (5) on the opposite, second side of the chassis (4), the wheels being arranged to support the chassis when resting on the ground, with the wheels on the first side rotatable about axes substantially fixed in position in the vertical direction relative to the chassis and the wheels at the second side are arranged on a frame part (6) pivotably arranged relative to the chassis about a substantially central longitudinal axis (8) running between the first and the second sides of the vehicle to create a stability area for the vehicle in the shape of a triangle in the horizontal plane, an arrangement (12) to determine the position of the vehicle's tipping point (T) in relation to the stability area and thereby the vehicle's stability, means (17) for fixing the frame part relative to the chassis on the order of the arrangement to increase the vehicle's stability area to be defined by said wheels, and means (32) for attaching each said wheel (5) on said frame part (6) to: (i) fix the wheel in position relative to the frame part (6) and ensure the frame part has fixed distance to the ground on which the wheel is resting on application of a load to the wheel below a pre-determined level, and (ii) allow a movement of the wheel towards the frame part when the load on the wheel exceeds the pre-determined level, while storing potential energy and decreasing the distance between the frame part and the ground on which the wheel is resting, wherein said means (32) for fixing the wheels (5) to the frame part (6) comprises a resilient member (33) for each wheel arranged between the frame part and a part (35) that carries the wheel's axle, the resilient member is arranged to be preloaded against stop means (34) arranged to prevent the resilient member from releasing potential energy by distancing the frame part from the part carrying the wheel axle, and the degree of pre-loading of the resilient member is adjusted to determine the pre-determined level of load. 13. Vehicle according to claim 12, wherein the resilient member is a mechanical compression spring (33). 14. Method for controlling the stability of a vehicle against tipping and which comprises a chassis (1), at least two mutually separated wheels (3) arranged on a first side (2) of the chassis and two mutually separated wheels (5) on the opposite, second side of the chassis (4), the wheels being arranged to support the chassis when resting on the ground, with the wheels on the first side rotatable about axes substantially fixed in position in the vertical direction relative to the chassis and the wheels on the second side arranged on a frame part (6) pivotably arranged relative to the chassis about a substantially central longitudinal axis (8) running between the first and the second sides of the vehicle to create a stability area for the vehicle in the shape of a triangle in the horizontal plane, in which the position the vehicle's tipping point (T) in relation to the stability area and thus the vehicle's stability is determined and the frame part is fixed relative to the chassis when the result of this determination calls for an increase of the vehicle's stability area to be defined by said wheels, wherein when the determination results in that the vehicle's tipping point reaches a boundary area (19) of the stability triangle, a resistive force is gradually increased that opposes a pivoting of the frame part relative to the chassis about said axis on increasing distance of the tipping point from the centre of the triangle to gradually increase the stability area, and when the tipping point reaches a pre-determined boundary, the frame part is completely fixed relative to the chassis and creates a stability area defined by said wheels, and said wheels (5) mounted on the second side are mounted underneath said pivotally-arranged frame part (6). 15. Method according to claim 14, wherein said increase of the resistive force takes place by engaging a resistive force to act against the relative movement between the frame part (6) and the chassis (1) intermittently during time periods, whose length per unit time is controlled to increase in order to achieve said gradual increase. 16. Method according to claim 15, wherein said gradual increase of the resistive force against a pivoting of the frame part (6) relative to the chassis (1) takes place by intermittently, in a pulsing way, opening and closing valve means (28) arranged in an outer bypass conduit (27) that interconnects two pressure chambers (25, 26) that are disposed on opposite sides of a piston (24), to, in this way, affected the capability of the pressure medium disposed in the pressure chambers to flow from one chamber to the other chamber and thereby the resistance against a displacement of the piston. 17. A computer comprising internal memory and a computer program that is directly loaded into the internal memory of the computer and comprises software code parts to execute the steps of claim 14 when the program is run on the computer. 18. Computer readable memory with a registered program thereon, which is designed to cause a computer to execute the steps according to claim 14. 19. An apparatus for preventing tipping of a vehicle, comprising: a computer; a computer program provided at least partly via a network, directly loaded into internal memory of the computer and comprising software code parts when the program is run on the computer to execute the steps of a method for controlling the stability of the vehicle against tipping; the vehicle comprising a chassis (1); at least two mutually separated wheels (3) arranged on a first side (2) of the chassis and two mutually separated wheels (5) on the opposite, second side (4) of the chassis, with the wheels arranged to support the chassis when resting on the ground; the wheels on the first side rotatable about axes substantially fixed in position in the vertical direction relative to the chassis and the wheels on the second side arranged on a frame part (6) pivotably arranged relative to the chassis about a substantially central longitudinal axis (8) running between the first and second sides of the vehicle to create a stability area for the vehicle in the shape of a triangle in the horizontal plane; the program adapted to determine the position of the vehicle's tipping point (T) in relation to the stability area and thus the vehicle's stability and fix the frame part relative to the chassis by signaling a fixing means when the result of the determination calls for an increase of the vehicle's stability area to be defined by said wheels; wherein when the determination results in that the vehicle's tipping point reaches a boundary area (19) of the stability triangle, a resistive force is gradually increased that opposes a pivoting of the frame part relative to the chassis about said axis on increasing distance of the tipping point from the centre of the triangle to gradually increase the stability area; and, when the tipping point reaches a predetermined boundary, the frame part is completely fixed relative to the chassis and creates a stability area defined by said wheels. 20. Vehicle comprising a chassis (1), at least two mutually separated wheels (3) arranged on a first side (2) of the chassis and two mutually separated wheels (5) on the opposite, second side of the chassis (4), the wheels being arranged to support the chassis when resting on the ground, with the wheels on the first side rotatable about axes substantially fixed in position in the vertical direction relative to the chassis and the wheels at the second side arranged on a frame part (6) pivotably arranged relative to the chassis about a substantially central longitudinal axis (8) running between the first and the second sides of the vehicle to create a stability area for the vehicle in the shape of a triangle in the horizontal plane, an arrangement (12) to determine the position of the vehicle's tipping point (T) in relation to the stability area and thereby the vehicle's stability, means (17) for fixing the frame part relative to the chassis on the order of the arrangement to increase the vehicle's stability area to be defined by said wheels, and means (32) for attaching each said wheel (5) on said frame part (6) to: (i) fix the wheel in position relative to the frame part (6) and ensure the frame part has fixed distance to the ground on which the wheel is resting on application of a load to the wheel below a pre-determined level, and (ii) allow a movement of the wheel towards the frame part when the load on the wheel exceeds the pre-determined level, while storing potential energy and decreasing the distance between the frame part and the ground on which the wheel is resting, and means arranged to communicate with said arrangement (12) and on obtaining information that said tipping point is located at a distance below a predetermined value from the stability area's outer boundary, lock the drive means of the vehicle to only be able to carry out movements of the vehicle having a stabilizing effect in order to move the vehicles tipping point away from the stability area's outer edge.