阅读说明：本技术 驶上装置 (Driving device ) 是由 J-D·波齐 C·P·波齐 于 2019-01-23 设计创作，主要内容包括：本发明涉及一种用于车辆的驶上装置(100),所述驶上装置包括驶上楔形件(1),所述驶上楔形件包括：具有斜坡表面(6)的斜坡侧(2)；和与所述斜坡侧(2)相对置的、具有支撑表面(8)的支撑侧(3)；以及至少一个在斜坡侧(2)和支撑侧(3)之间延伸的肋条(4、4’),其中,在肋条(4、4’)的朝向斜坡侧(2)的端部上设有至少一个与肋条(4、4’)成角度的突出部(5、5’)。(The invention relates to a drive-on device (100) for a vehicle, comprising a drive-on wedge (1) comprising: a ramp side (2) having a ramp surface (6); and a support side (3) opposite the ramp side (2) having a support surface (8); and at least one rib (4, 4') extending between the ramp side (2) and the support side (3), wherein at least one projection (5, 5') is provided on the end of the rib (4, 4') facing the ramp side (2) at an angle to the rib (4, 4').)

1. A drive-on device (100) for a vehicle, comprising a drive-on wedge (1) comprising: a ramp side (2) having a ramp surface (6); and a support side (3) opposite the ramp side (2) having a support surface (8); and at least one rib (4, 4') extending between the ramp side (2) and the support side (3), characterized in that at least one projection (5, 5') angled to the rib (4, 4') is provided on the end of the rib (4, 4') facing the ramp side (2).

2. The drive-on device according to claim 1, characterised in that the support surface (8) is configured to be partially closed.

3. The ride-on device according to claim 1 or 2, wherein a plurality of ribs (4, 4') and a plurality of protrusions (5, 5') are provided.

4. The drive-on device according to claim 3, characterized in that the ramp side (2) has a plurality of openings (11, 11', 12').

5. The drive-on device (100) according to claim 4, characterised in that a plurality of diamond-shaped openings (12, 12') of the ramp side (2) and a plurality of star-shaped openings (11, 11') defined by the projections (5, 5') are provided, and that the openings (11, 11', 12') are arranged such that a pattern of a plurality of stars (39) and interspersed with diamonds (40) is formed on the ramp side (2).

6. The drive-on device (100) according to one of claims 1 to 5, characterised in that the drive-on wedge (1) has a plurality of steps (13, 13') at different heights (41, 42, 43).

7. The ride-on device according to claim 6, wherein the steps (13, 13', 13 ") are curved.

8. The ride-on device according to any one of claims 1 to 7, wherein elements (14, 14') are provided for improving the grip on the ramp surface (6).

9. The ride-on device according to any one of claims 1 to 8, wherein the ride-on wedge (1) has a rear side (15) inclined towards the ramp side (2), and wherein a handle (16) is provided on the rear side (15).

10. The ride-on device according to any one of claims 1 to 9, wherein the ride-on wedge (1) has side walls (17, 17') and recesses (18, 18') are provided in these side walls, each extending over the entire height (H) of the ride-on wedge (1).

Technical Field

The invention relates to a drive-on device for a vehicle.

Background

Drive-on devices are known. DE 202011051100U 1, for example, shows a drive-on device.

A disadvantage of the known drive-on devices is that their mechanical resistance and/or their tire contact area are often not optimal.

Disclosure of Invention

The object of the present invention is to provide a drive-on device which is improved with respect to at least one of the disadvantages mentioned above.

The object is achieved by a drive-on device as claimed in claim 1.

The drive-on device according to the invention for a vehicle comprises a drive-on wedge, which is also referred to in this context simply as a wedge.

The ride-on wedge has a ramp side and a support side opposite the ramp side. The ramp side has a ramp surface. The support side has a support surface. The ride-on wedge includes at least one rib extending between a ramp side and a support side. The ribs may also be referred to as tabs. At least one projection is arranged on the end of the rib facing the slope side and forms an angle with the rib.

In this way, a wedge with optimized mechanical resistance, in particular with respect to bending and pressure loads, can be provided and the contact area of the wedge with the vehicle tyre has an optimum size. In addition, a wedge may thereby be provided that is sufficiently flexible to accommodate an uneven substrate without being damaged.

The ramp surface preferably comprises the surface provided by the at least one projection.

The ramp surface and the support surface are preferably configured to be directed away from each other. The ramp side is preferably configured for contact with a tire of a vehicle, and thus the ramp surface is preferably configured as a tire contact surface. The support side is preferably configured for contact with the substrate. Therefore, the support surface is preferably configured as a substrate contact surface. The support side is preferably close to the ground when used as intended. The ramp side is preferably designed such that it can lift the tires of the vehicle into different height positions.

Preferably, the at least one projection overhangs the rib. The at least one projection preferably has a free end. This provides for a particularly suitable surface property of the ramp sides of the wedge.

The at least one projection preferably has a support element which supports the projection relative to the rib. Thereby increasing the load bearing capacity of the projection. The support elements are preferably not ribs. The support element preferably supports the free end of the projection on the rib from which the projection projects.

The at least one projection preferably does not bear on more than one rib. The projection preferably does not connect the rib to the opposing rib.

The at least one projection is preferably at an angle of about 90 ° to the rib.

The at least one projection has an at least substantially triangular shape as viewed from the ramp side.

The drive-on device is preferably used for vehicles with tires, in particular for campers or motor homes. The drive-on device is preferably used to level the height difference, in order to preferably be able to orient the vehicle horizontally even on uneven substrates. The driving wedge is preferably transportable.

The at least one rib preferably extends at least almost straight from the support side to the ramp side. Preferably, the height of the ribs corresponds at least approximately to the corresponding height of the wedge. The ribs can thereby contribute particularly to the resistance of the wedge to driving.

The term "height of the ribs" in the present context refers in particular to the dimension of the ribs in the direction of the height of the wedge. The term "length of the ribs" in the present context means in particular the longitudinal extension of the ribs perpendicular to their height.

The at least one rib preferably extends perpendicularly to the support side. In this way the ribs can contribute particularly to the resistance of the wedge.

Preferably, a plurality of ribs are provided. Preferably the ribs intersect at an intersection point. Preferably, a plurality of projections are provided.

The support surface is preferably larger than the total cross-sectional area of the ribs. The support surface is preferably greater than 10%, or greater than 20%, or greater than 25%, or greater than 35%, or greater than 40% of the total cross-sectional area of the ribs. The term "total cross-sectional area of the ribs" in the present context refers to the total cross-sectional area of all ribs in a cross-section extending parallel to the support side. Thereby preventing the wedge from sinking into the soft base. The support surface is preferably smaller than the reference support surface of the wedge. The support surface is preferably more than 10%, or more than 20%, or more than 25%, or more than 35%, or more than 40% smaller than the reference support surface of the wedge. The term "reference support surface" in the present context refers to the product of the length and the width of the wedge support side. In this way, a light wedge is provided which can be well adapted to the substrate.

Preferably, the support surface is partially closed. In this way, a compromise can be found between providing a sufficiently large support surface to distribute the weight of the vehicle over it so as to avoid sinking into the ground in most cases and on the other hand helping to make the ride-on wedge flexible enough to adapt to an uneven substrate without being damaged. The wedge pieces are prevented from sinking into the soft base by the partially closed support surfaces and still have a high resistance to mechanical loads, for example based on the weight of the vehicle.

The partially closed support surface is preferably designed in such a way that a closed region and an open region of the support side are provided, which are further preferably distributed uniformly, for example in a checkerboard-like manner, on the support side. The closed area may be closed except for an opening for e.g. rain water drainage.

Viewed over the length of the wedge, preferably in the middle region of the wedge, a plurality of ribs having a first length are provided. Preferably, ribs of a second length, which is preferably shorter than the first length, are provided in the front and further preferably in the rear region of the wedge. Preferably, at least one rib extends from one side of the wedge, further preferably unbent, to the other side of the wedge. Preferably all ribs of the first length extend from one side of the wedge, further preferably unbent, to the other side of the wedge.

Preferably, first ribs extending parallel to one another and second ribs extending parallel to one another are provided, wherein the first ribs do not extend parallel to the second ribs but the first ribs and the second ribs intersect one another. The first and second ribs may intersect at an angle of about 90 °. The first rib preferably does not extend in the direction of travel, but rather at an angle of 45 ° to it, clockwise when viewed from below. The second ribs preferably do not extend in the direction of travel but rather at an angle of 45 ° to them, counterclockwise when viewed from below.

The ribs, preferably the first and second ribs, preferably form between them a repeating shape, particularly preferably a rhombus.

Each rib preferably has a plurality of projections angled thereto.

The projections preferably each extend from one intersection point of the ribs to the next intersection point.

Each projection extends from the associated rib preferably in the direction of projection. Preferably, the protruding directions of adjacent protruding portions of the same rib are different. Particularly preferably, adjacent projections of one rib have opposite projection directions.

The ramp side preferably has a plurality of openings. Preferably, these openings reduce the size of the ramp surface.

In the preferred embodiment, the ramp surface is smaller than the reference ramp surface. Preferably, the ramp surface is more than 50%, or more than 70%, or more than 80%, or more than 90% smaller than the reference ramp surface. The term "reference ramp surface" in the present context refers to the product of the width and the length of the ramp side. In this way, for example, the static friction between the tyre and the wedge can be increased by: at least partial engagement between the ramp surface and the tire contour is possible and provides for a reduction in the overall weight of the wedge and material consumption. Preferably, the ramp surface is less than 95% of the reference ramp surface. In this way, pressure peaks acting on the vehicle tire during driving and on the wedge during parking are avoided and the tire is protected.

In a preferred embodiment, the ramp surface is preferably larger than the total cross-sectional area of the rib, at least also on the basis of the projection. Preferably, the ramp surface is greater than 5% or more, or 10% or more, or 20% or more, or 25% or more, or 35% or more of the total cross-sectional area of the rib. In this way, pressure peaks acting on the vehicle tire during driving and on the wedge during parking are avoided and the tire is protected.

The ramp side preferably has a plurality of openings that preferably reduce the size of the ramp surface and further preferably extend through the entire wedge. These openings are also referred to herein as "through openings". Preferably, the through openings each have a non-uniform size, which is preferably reduced in size in the ramp-side region by a projection. In this preferred embodiment, the reduction of the ramp surface caused by the through opening is greater than 5% or 10% or 15% or 20% or 25% or 30% or 35% or 40% of the reference ramp surface. In this preferred embodiment, the reduction of the ramp surface caused by the through opening is less than 50% or 40% or 30% or 20% or 10% of the reference ramp surface. The weight and material consumption of the wedge are reduced by the through-opening. It has been shown that the size of the through opening can be relatively large without compromising the stability of the wedge.

In this preferred embodiment, there are openings on the ramp side which do not extend through the entire wedge and through-openings on the ramp side, which are preferably distributed uniformly on the ramp side.

Preferably, the plurality of openings of the slope side have the same shape. Preferably, at least two different shapes of these openings are provided.

The ramp sides preferably have a plurality of diamonds and a plurality of star-shaped openings.

Preferably, an opening provided at the ramp side edge is provided with a ramp side and an opening not provided at the ramp side edge, i.e. a middle opening. The shape of the edge side opening may be different from the shape of the opening provided in the middle. Preferably, the centrally arranged opening already has at least two different shapes.

Preferably, the ramp side has an opening defined by a rib. These openings defined by the ribs preferably do not extend through the entire wedge. They are preferably arranged above the closed area of the preferably partially closed support surface. In an important embodiment, the openings of the ramp sides defined by the ribs are diamond-shaped.

Preferably, the ramp side has an opening defined in part or only by the projection. The openings defined by these portions or just the projections preferably extend through the entire wedge. They are preferably arranged above the open area of the preferably partially closed support surface. In an important embodiment, the opening defined by the projection is star-shaped.

The openings of the ramp sides are preferably shaped and further preferably arranged such that a pattern of a plurality of stars interspersed with diamonds is formed on the ramp sides.

The mechanical resistance of the wedge to rolling, in particular with respect to bending and pressure, can thereby be optimized, and the dimensions of the contact area with the tire can be optimized.

The star is preferably configured as a four-beam (strahlig) star. The two beams of the star preferably point in opposite directions. The two adjacent beams are preferably perpendicular to each other. The beam preferably tapers towards its end.

The sum of the ramp surface and the support surface, preferably at least also based on the through opening, is preferably smaller than the reference support surface of the wedge. In this way, a light wedge is provided which can be well adapted to the substrate. The sum of the ramp surface and the support surface is preferably less than 5% or more, or 10% or more, or 20% or more, or 30% or more, or 40% or more, or 50% or more of the reference support surface of the wedge.

In this preferred embodiment, the ride-on wedge has a plurality of steps at different heights. Further preferably, the step is curved. In other words, the ramp side preferably has a concave surface in the step region.

The bending of the step may result in improved contact with the tire.

Exactly three different steps at different heights may be provided. These steps may have the following heights: about 60cm, about 120cm and about 170 cm. Other numbers of steps, such as exactly four steps, may also be provided.

Preferably, elements are provided for improving the grip on the sloping surfaces. These elements are preferably used in particular to improve the grip of a rolling vehicle tire on the side of a slope, for example to avoid tire slip. The element may have teeth facing away from the ramp side. The element may be provided on the projection. The elements are preferably not arranged evenly distributed on the ramp side, but are further preferably arranged incrementally between the steps.

Preferably, the ride-on wedge has a rear side that is inclined toward the ramp side. The sloped rear side improves the stability of the ride-on wedge.

In the preferred embodiment, a handle is provided on the rear side of the ride-on wedge. The handle simplifies transport of the drive-on wedge and facilitates positioning of the drive-on wedge adjacent the wheel of the vehicle.

In this preferred embodiment, the ride-on wedge has side walls, and recesses are preferably provided in these side walls.

The recess extends in the height direction of the driving wedge and preferably further extends over the entire corresponding height of the driving wedge. The recess is preferably rounded and further preferably has a substantially semi-circular cross-section. The cross section may increase toward the slope side.

The ride-on means may be formed by a ride-on wedge.

The driving wedge can be formed in one piece.

The driving wedge preferably comprises or consists of plastic.

The wedge is preferably usable for vehicles having a maximum tire width of about 245 mm.

The maximum load carrying capacity of the wedge is preferably about 2500 kg.

Drawings

The invention will now be explained in more detail with reference to an embodiment shown in the drawings. Here, there are shown:

fig. 1 shows a perspective view of an exemplary embodiment of a drive-on device according to the invention;

fig. 2 shows a side view of the ride-on device of fig. 1;

FIG. 3 shows a view as in FIG. 2;

FIG. 4 illustrates a detail of FIG. 2 on an enlarged scale;

fig. 5 shows a plan view of the drive-on device of fig. 1;

FIG. 6 illustrates another detail of FIG. 2 on an enlarged scale;

FIG. 7 shows a bottom perspective view of the ride-on device of FIG. 1;

fig. 8 shows a perspective view of a part of the drive-on device of fig. 1 from diagonally behind.

Detailed Description

The exemplary embodiment of the drive-on device according to the invention shown and designated as a whole by reference numeral 100 is formed by a one-piece, transportable drive-on wedge 1. The drive-on device shown is designed for vehicles, i.e. campers or motor homes, in order to level out the height differences and thus to be able to orient the vehicle horizontally even on uneven substrates.

As shown in fig. 1 and 2, the driving wedge 1 has a ramp side 2 and a support side 3 opposite the ramp side 2. At least one rib 4, more precisely a plurality of such ribs 4, 4' (see for example fig. 7), is provided which extends between the ramp side 2 and the support side 3.

As shown in fig. 1 and 5, at least one projection 5 is provided on the end of the rib 4, 4' facing the ramp side 2, said projection being arranged at an angle to the rib 4. As shown, a plurality of such projections 5, 5' are provided.

The ramp side 2 has a ramp surface 6 and, as shown in fig. 5, the ramp surface 6 has a surface 7 provided by these projections 5, 5'.

Each projection 5, 5' extends from the associated rib 4, 4' in a projection direction 10, 10' (fig. 5). The adjacent projections 5, 5' of one rib 4, 4' have opposite projection directions 10, 10 '.

The projections 5, 5' project in an overhanging manner and each have a free end 20.

The projections 5, 5' each have a support element 19 which supports the projection, more precisely the free end 20 of the projection, relative to the rib 4 (see, for example, fig. 7 and 8). The projection is not supported on more than one rib. The projection does not connect the rib from which the projection projects and the opposing rib. The projections are each angled at approximately 90 deg. from the rib from which the projection projects.

Fig. 7 shows that the support side 3 has a partially closed support surface 8 comprising closed areas 21 and open areas 22 which are distributed uniformly and substantially tessellated. In the embodiment shown, the closed area 21 has an opening in the form of a circular hole, for example, for the drainage of rainwater.

The support surface 8 is larger than the total cross-sectional area of the ribs 4, 4' on the basis of the closed area 21. The support surface 8 is smaller than the reference support surface of the wedge 1 on the basis of the open area 22.

The ribs extend perpendicularly to the supporting side 3 from the supporting side 3 as far as the ramp side 2. The height H of the ribs corresponds to the corresponding height H of the wedge.

Over the length of the wedge, a plurality of ribs of a first length 23 are provided in the middle area 25 of the wedge. Ribs having a second length 24, shorter than the first length, are provided in the front and rear regions 26, 27 of the wedge. All ribs having the first length 23 extend without bends from one side 28 of the wedge to the other side 29 of the wedge.

First ribs 30 extending parallel to one another and second ribs 31 also extending parallel to one another are provided, the first ribs 30 not extending parallel to the second ribs 31 but intersecting them at an angle of approximately 90 °. The ribs do not extend in the direction of travel R, but rather the first rib 30 extends at an angle of approximately 45 ° to it, clockwise when viewed from below. The second ribs 31 also do not extend in the direction of travel R, but rather extend at an angle of approximately 45 ° to them, in the counterclockwise direction when viewed from below.

The ribs 4, 4 'meet at a junction 9, 9'. The projections 5, 5 'each extend from one intersection point 9 up to the next intersection point 9'. The direction 10 in which a projection projects from its rib is opposite in adjacent projections of the same rib (see, for example, fig. 5).

The projections 5, 5' have an at least substantially triangular shape as seen from the ramp side.

As shown in fig. 1 and 5, the ramp side 2 has a plurality of openings 11, 11', 12'. More precisely, a plurality of diamond-shaped openings 12, 12' of the ramp side 2 and a plurality of star-shaped openings 11, 11' defined by the projections 5, 5' are provided and these openings 11, 11', 12' are arranged such that a pattern of a plurality of stars 39 interspersed with diamonds 40 is formed on the ramp side 2. The star is configured as a four-beam star. The two beams of the star point in opposite directions. Two adjacent beams are perpendicular to each other. The beam tapers towards its end. The star-shaped openings 11, 11' are designed as through openings 36. The diamond shaped openings 12, 12' are configured so that they do not extend through the entire wedge opening 44. The ramp surface 6 is smaller than the reference ramp surface on the basis of the openings 11, 11', 12' of the ramp side 2. The ramp surface 6 is larger than the total cross-sectional area of the rib, in particular on the basis of the projections 5, 5'.

The ramp-side openings 44, which do not extend through the entire wedge, and the ramp-side through openings 36 are distributed uniformly on the ramp side 2.

An opening 45 provided at the edge of the ramp side 2 where the ramp side is provided and an intermediate opening 46 which is not provided at the edge of the ramp side, the shape of the opening at the edge being different from the shape of the intermediate opening 46. The intermediate opening 46 has been given two different shapes, namely diamond and star.

The intermediate diamond-shaped openings 12, 12 'on the ramp sides are defined by the ribs 4, 4' and do not extend through the entire wedge 1. They are arranged above the closed area 21 of the support surface 8.

The intermediate star-shaped opening 11, 11 'of the ramp side is delimited on the ramp side by the projection 5, 5'. They are arranged above the open area 22 of the partly closed support surface 8. They are configured as through openings 36, provide an opening area 22 on the support side and are delimited by ribs 4, 4' on the support side.

The sum of the ramp surface 6 and the support surface 8 is smaller than the reference support surface of the wedge 1.

As shown in fig. 3, the driving wedge 1 has a plurality of steps 13, 13', 13 ″ at different heights 41, 42, 43 and these steps are curved. The first height 41 may be approximately 60cm, the second height 42 may be approximately 120cm and the third height 43 may be approximately 170 cm.

In particular, fig. 4 shows that elements 14, 14' are provided for improving the grip of the tire on the ramp side 2. These elements comprise teeth directed away from the ramp side 2. These teeth are provided on the projections 5, 5'. They are not distributed uniformly on the ramp side 2 but are arranged incrementally between the steps 13, 13', 13 ".

Fig. 6 in particular shows that the driving wedge 1 has a rear side 15 which is inclined toward the ramp side 2. On the rear side 15, a handle 16 is provided, which is clearly visible in fig. 8.

The driving wedge 1 has side walls 17, 17 'and recesses 18, 18' are provided in these side walls, which recesses extend over the entire height H of the driving wedge 1. The recesses 18, 18' preferably extend in the direction of the height H of the driving wedge 1 and further preferably over the entire corresponding height H of the driving wedge 1. The recesses 18, 18' are rounded and have a substantially semi-circular cross-section. They increase in the direction of the ramp sides 2.

The width 35 of the ramp side may be between 260 to 230mm and about 245 mm. The length 34 of the ramp side is shown in fig. 1. The length 37 and width 38 of the support side 3 are shown in fig. 5. The maximum tire width 47 is shown in fig. 1.

List of reference numerals

100 driving device

1 riding on wedge

2 side of slope

3 supporting side

4. 4' rib

5. 5' projection

6 ramp surface

7 surface of ramp surface provided by projection

8 support surface

9. 9' intersection

10. 10' projecting direction

11. 11' opening

12. 12' opening

13. 13', 13' step

14. 14' elements for improving adhesion

15 rear side

16 handle

17. 17' side wall

18. 18' recess

19 support element for a projection

20 free end of the projection

21 closed area of supporting side

22 open area of supporting side

First length of 23 ribs

Second length of 24 ribs

25 riding on the middle region of the wedge

26 ride up the front region of the wedge

27 ride up the rear region of the wedge

28 riding on one side of the wedge

29 riding on the other side of the wedge

30 first rib

31 second rib

32

33

34 length of slope side

35 width of slope side

36 through hole

37 length of the supporting side

38 width of the supporting side

39 star shape

40 diamond

41 first height

42 second height

43 third height

44 do not extend through the entire wedge

45 openings provided at the side edges of the ramps

46 central opening

47 maximum tire width

height of h rib

Height of H wedge

Direction of driving