TECHNICAL FIELD

The present invention relates to a suspension system which can provide variable caster angle depending on the changing load in the vehicles.

PRIOR ART

Caster is the inclination made by the axle pin or the straight line, which joins the lower and upper suspension arm ball joints, towards the front or rear of vehicle when the vehicle wheels are viewed from the lateral side. When the wheel is viewed from the lateral side, the rearward inclination of the upper part of the pin is named as “Positive Caster” and the opposite is named as “Negative Caster”. Both conditions can be seen in the vehicles of the present art.

The aim of the caster angle is to provide movement stability. In vehicle wheels where positive or negative caster is given, when deviation occurs due to the condition of the path, the wheels can return to their prior position again. Caster angle is a system which decreases the pressure of the wheels towards the sides where the wheels press on the floor when the vehicle makes maneuver while the vehicle is moving fast, and which facilitates the complete pressure of the wheels to be exerted onto the floor and which provides stability of the steer during movement of the vehicle.

In the known state of the art, shock absorbers are positioned on the suspension arm group in suspension systems and in a horizontal manner to the vehicle movement direction. The right suspension arm and the left suspension arm provided in the suspension arm group oscillate in an independent manner from each other. Since the suspension arms realize horizontal oscillation with respect to the vehicle direction, caster angle cannot change. This angle is fixed in an independent manner from the condition and load of the vehicle. The caster angle is in general seven degrees. However, different values can be used according to the preferences and calculations of the companies. In tilting vehicles, the usage of a greater caster angle increases the travelling comfort of the vehicle. In cases where the vehicle is overloaded or speedy or the positive caster is excessive at the instant of braking, the holding of the front wheels on the ground is increased and thus driving safety is increased. Since the wheel distances in micro segment tilting vehicles are less, this characteristic becomes more precious.

In the literature, in the application with number US7487985, preferably a three-wheeled vehicle having bending mechanism is disclosed. In said application, the suspension is positioned in the wheels and the caster angle does not have a variable characteristic.

In the literature, another application is the patent application with application number DE102014101087 and with title “Inclined framed vehicle”. Said application comprises a vehicle structure comprising inclined frame for decreasing the bending trend. In the vehicle structure, the caster angle is fixed and there is no tilting characteristic.

As a result, because of all of the abovementioned problems, an improvement is required in the related technical field.

BRIEF DESCRIPTION OF THE INVENTION

The present invention relates to a suspension system, for eliminating the above mentioned disadvantages and for bringing new advantages to the related technical field.

The object of the present invention is to provide a suspension system which can provide a variable caster angle depending on the changing load in vehicles.

Another object of the present invention is to provide holding of front wheels on the ground while maneuvering by increasing positive caster angle and to increase driving safety in cases where the vehicle is over-loaded or over-speedy or in case of braking.

Another object of the present invention is to provide production of tilting narrower vehicles thanks to the suspension structure which allows the vehicle wheels to be closer to each other.

In order to realize the abovementioned objects and the objects which are to be deducted from the detailed description below, the present invention relates to a suspension system associated with a chassis and which has a suspension arm and a shock absorber associated with said suspension arm. Accordingly, the subject matter suspension system comprises an upper suspension arm and a lower suspension arm provided at said suspension arm, a carrier element which extends in the direction of the chassis between said upper suspension arm and said lower suspension arm, at least one suspension arm connection element which provides connection onto said carrier element through the middle of the surfaces of the upper suspension arm and the lower suspension arm facing each other, a chassis connection element provided at the end part of the carrier element which extends towards the chassis side and which provides connection to the chassis in a manner providing rotational movement around an axis C, at least one lower connection element provided at one end of said shock absorber and which provides connection to the surface of the carrier element which faces the upper suspension arm in a manner providing rotational movement around an axis B, at least one upper connection element provided at the other end of said shock absorber and which provides connection to the chassis in a manner providing rotational movement around an axis A. Thus, a suspension system is provided which can provide variable caster angle depending on the changing load in the vehicles.

In a possible embodiment of the present invention, said axis A, said axis B and said axis C are parallel to each other.

In a possible embodiment of the present invention, the suspension arm connection element is positioned at an upper front part, at an upper rear part, at a lower front part and at a lower rear part in the middle of the surfaces of the upper suspension arm and the lower suspension arm in order to provide connection of the suspension arm and the carrier element.

In a possible embodiment of the present invention, said suspension arm connection element comprises a housing provided on the carrier element, an opening provided on the suspension arm, a pin which provides connection in a manner providing rotation of said opening in said housing around the own axis thereof. Thus, when a wheel rises, the other wheel lowers symmetrically.

In a possible embodiment of the present invention, in order to provide connection of the suspension arm to the two wheel hubs which provide association of the suspension arm to the two vehicle wheels, the subject matter comprises a shaft connected in a parallel manner to said wheel hub surface and in a manner providing rotational movement in its own axis, a lower housing and an upper housing provided on said shaft, a lower end provided at the lower suspension arm connected to said lower housing and an upper end provided at the upper suspension arm connected to said upper housing. Thus, the suspension arm is connected to the wheel hub. BRIEF DESCRIPTION OF THE FIGURES

Figure 1 is a representative perspective view of the subject matter suspension system.

Figure 2 is a frontal representative perspective view of the subject matter suspension system.

Figure 3 is a left side representative perspective view of the subject matter suspension system.

Figure 4 is a right side representative perspective view of the subject matter suspension system.

Figure 5 is a representative lateral view of the subject matter suspension system.

Figure 6 is a representative top view of the subject matter suspension system.

Figure 7 is a representative lateral view where the caster angle of the subject matter suspension system has changed in a dependent manner on the load.

Figure 8 is a representative top view where the caster angle of the subject matter suspension system has changed in a dependent manner on the load.

Figure 9 is a representative frontal view where the subject matter suspension system is tilted without load and without maneuver of the steer.

Figure 10 is a representative frontal view where the subject matter suspension system is tilted with load and with maneuver of the steer.

Figure 11 is a representative top view where the subject matter suspension system is tilted with load and with maneuver of the steer.

Figure 12 is a representative top view where the subject matter suspension system is tilted while the steer is in a straight position. DETAILED DESCRIPTION OF THE INVENTION

In this detailed description, the subject matter suspension system (1) is explained with references to examples without forming any restrictive effect only in order to make the subject more understandable.

In Figure 1 , a representative perspective view of the subject matter suspension system (1) is given. The present invention relates to a suspension system (1) which can provide variable caster angle in a dependent manner on the changing load in vehicles. There is an upper suspension arm (21) and a lower suspension arm (22) associated with a chassis (50) in said suspension system (1). There is a carrier element between said upper suspension arm (21) and said lower suspension arm (22). The upper suspension arm (21) and the lower suspension arm (22) are connected onto said carrier element (30) by means of at least one suspension arm connection element (23) through the middle point of the surfaces of said upper suspension arm (21) and said lower suspension arm (22) which face each other. The carrier element (30) is connected to the chassis (50) in a manner able to realize rotational movement around an axis C (III) by means of at least one chassis connection element (32) provided at an end part of said carrier element (30). A shock absorber (10) is connected by means of a lower connection element (12), provided at one end thereof, to the other end of the carrier element (30) where the carrier element (30) is connected to the suspension arm

(20) such that said shock absorber (10) can make rotational movement around an axis B (II). An upper connection element (50), provided at the other end of said shock absorber (10), is connected to the chassis (50) in a manner able to realize rotational movement around an axis A (I). Said axis A (I), said axis B (II) and said axis C (III) are positioned in a parallel manner to each other.

In Figure 2, 3 and 4, the representative perspective views of the subject matter suspension system (1) are given. In the suspension system (1), the upper suspension arm (21) and the lower suspension arm (22) move in a parallel manner to each other. The carrier element (30) extends in the direction of the chassis (50) through the middle of the upper suspension arm

(21) and the lower suspension arm (22). The connection of the suspension arm (20) onto the carrier element (30) is provided by means of at least one suspension arm connection element (23). Said suspension arm connection element (23) comprises at least one opening (24) provided in the middles of the upper suspension arm (21) and the lower suspension arm

(22), a housing (31) provided in the carrier element (30) in a manner corresponding to said opening (24), and a pin (25) which provides connection in a manner providing rotation in its own axis in said housing (31). The suspension arm connection element (23) provides fixation of the suspension arm (20) to the carrier element (30) by means of an upper front part (231), an upper rear part (232), a lower front part (233) and a lower rear part (234) through the middle of the surfaces of the upper suspension arm (21) and the lower suspension arm (22). The suspension arm (20) can realize rotational movement in said pin (25) axis on the carrier element (30). Thus, when a wheel (60) rises, the other wheel (60) lowers symmetrically.

In order to provide connection of the suspension arm (20) to the two wheel hubs (40) which provide association to the two vehicle wheels (60), there is a shaft (41) connected in a parallel manner to said wheel hub (40) surface and in a manner able to realize rotational movement in its own axis. A lower housing (42) and an upper housing (43) are provided on said shaft (41). An upper end (26), provided at the ends of the upper suspension arm (21), is connected to said upper housing (43), and a lower end (27), provided at the ends of the lower suspension arm (22), is connected to said lower housing (42).

In Figure 7, a representative lateral view where the caster angle of the subject matter suspension system (1) has changed is given. The shock absorber (10) is connected to the chassis (50) in a rotatable manner in an axis A (I) by means of an upper connection element (11) from one end thereof. The other end of the shock absorber (10) is connected to the carrier element (30) in a manner able to realize rotational movement in an axis B (II) by means of a lower connection element (12). Thus, when the weight in the vehicle changes, the shock absorber (10) provides the upper connection element (11) to move with respect to axis A (I) and the lower connection element (12) to move with respect to axis B (II) and depending on this, the carrier element (30) can move with respect to axis C (III). Thus, depending on the changing load in vehicles, a suspension system (1) is provided which can provide a variable caster angle. As the vehicle load increases, the caster angle can be increased as suitable. For instance, the caster angle can be equal to zero when the vehicle is empty, it can be equal to 5-6 degrees when one person gets on the vehicle and it can be 7-9 degrees when two persons get on the vehicle. The vehicle can have a positive caster angle of 3 degrees when the vehicle is empty, and it can have a caster angle of 13 degrees when there is positive caster load of 10 degrees. The mentioned caster angle values can change according to connection distance of the chassis connection element (32) of the carrier element (30).

In cases where instant braking and maneuver is required while the vehicle moves rapidly and where braking is realized, load is exerted more to the front wheels (60). Thanks to the changeability of the caster angle, since the caster angle is going to automatically increase in case of instant braking, the holding of the vehicle on the ground increases while making maneuver. Thus, the driving safety is increased. Thanks to the suspension system (1) with single shock absorber (10), the vehicle wheels (60) can be closer to each other, and tilting vehicles, which are narrower, can be produced. The protection scope of the present invention is set forth in the annexed claims and cannot be restricted to the illustrative disclosures given above, under the detailed description. It is because a person skilled in the relevant art can obviously produce similar embodiments under the light of the foregoing disclosures, without departing from the main principles of the present invention.

REFERENCE NUMBERS

1 Suspension system 10 Shock absorber

11 Upper connection element

12 Lower connection element 20 Suspension arm

21 Upper suspension arm

22 Lower suspension arm

23 Suspension arm connection element

231 Upper front part

232 Upper rear part

233 Lower front part

234 Lower rear part

24 Opening

25 Pin

26 Upper end

27 Lower end 30 Carrier element

31 Housing

32 Chassis connection element 40 Wheel hub

41 Shaft

42 Lower housing

43 Upper housing 50 Chassis

60 Wheel

I- Axis A

II- Axis B

III- Axis C