The invention relates to a motor vehicle with an at least partially movable roof that can be stowed in the body underneath a cover section, according to the preamble to claim 1 or claim 2.
The technique of moving a cover section of this type by means of drive elements, such as hydraulic cylinders, located in the sides of the body is known. With certain body shapes it is desirable for the drive elements to lie relatively low in the body in order to prevent the drive elements from colliding with lateral wheel housings, and in order to utilize available space efficiently with minimum decrease in the remaining trunk space. With this type of flat arrangement, especially during the final phase of closure of the cover section, the problem can arise that either the angle between the line that connects the point of force of the drive element to the pivoting axis of the cover section and the direction of force becomes very small and/or the line that connects the point of applied force and the pivoting axis of the cover section is very short, therefore the amount of torque applied by the drive element to the cover section is very small. This makes closing the cover section harder especially because in this process force must frequently also be applied against the elastic force of a seal, against which the closed cover section is pressing.
The object of the invention is to improve the movability of the cover section when it is nearly closed, with at least one drive element having a line of force that acts low in the body.
The invention attains this object with a motor vehicle having the characterizing features of claim 1 and with a motor vehicle having the characterizing features of claim 2. With respect to advantageous embodiments and further improvements of the invention, reference is made to the subordinate claims 2 through 11.
With the configuration of the invention of a power pull-down device according to claim 1, the tractive force of a drive element oriented essentially toward the front in the direction of travel is converted at least partially to a downward force acting against the front end of the cover section, thereby facilitating its closure. The power pull-down device can be moved by the drive element for the cover section, and thus does not require its own actuator or its own drive.
If a movable power pull-down device actuates the cover section only when the drive element is very near its retracted position, said cover section being held in a position that is beyond dead center when the drive element is fully retracted, then precisely when the power pull-down movement is near completion, a beneficial additional force is created that assists in closing the cover section.
The particularly advantageous positioning of the cover section beyond dead center in its closed position secures the cover section in a particular way that could not be accomplished by the retracted drive element alone.
Providing a pivotable gripper inside the power pull-down device allows said device to travel a considerable distance, grab a companion part for the cover section only a few degrees before the cover section reaches its closed position, and actively move said companion part downward by virtue of its pivoting.
If the drive element is configured as a hydraulic cylinder that is held on a control arm, which is capable of pivoting around a stationary axis on the body, said control arm is automatically pivoted on its axis when the hydraulic cylinder is retracted, thereby allowing the power pull-down device to be pivoted along with it. This enables a large transmission ratio.
A narrow installation space with unfavorable force lines can also be effectively utilized via at least one force-reversing adapter lever.
With a remotely actuatable lock for securing the cover section in its closed position by blocking the movement of the power pull-down device, the cover section can be reliably prevented from opening unintentionally.
The invention can be used to advantage in partially or fully convertible vehicles in which a relatively large cover section is provided, which can be pivoted in the described opening direction to reveal the stowage opening for the roof or the roof sections, and can be pivoted in the opposite direction to reveal an opening for loading or unloading luggage.
Further advantages and characterizing features of the invention are revealed in the exemplary embodiments of the object of the invention schematically illustrated in the set of drawings and described in what follows.
The drawings show:
The motor vehicle 1 according to the invention can be a four- or more passenger vehicle with at least one rear bench-type seat, or a two-passenger vehicle.
The roof 2 of the vehicle can be moved upward completely or only partially, for example only that section that can be moved between two fixed lateral frame pieces. Here, a fully retractable roof 2 of a fully convertible vehicle 1 is shown. This can comprise both fixed plate sections and a soft top that is covered with a flexible cover. The section to be opened, or the entire roof 2, can be moved manually or fully or partially automatically.
Below, the features of the first exemplary embodiment are described, however these apply correspondingly to the further exemplary embodiments.
The roof 2 can be opened and stowed in the rear area of the vehicle. To accomplish this, a stowage opening 3 is provided in the body 4, which can be at least mostly closed off at the top by the cover section 5.
The cover section 5 is capable of moving between its open position (e.g.
As shown in the first exemplary embodiment (
A lateral drive element 10, in this case configured as a hydraulic cylinder, is provided at least for the purpose of moving the cover section 5 to open or close the stowage opening 3 for the roof 2 (
The drive element 10 lies at least nearly in a vertical longitudinal plane of the vehicle, and flat underneath the cover section 5 in order to effectively utilize the space in a vehicle having a short rear area and a short rear overhang, and to prevent collision with the wheel housing 9. At least during the final phase of the movement to close the cover section 5 (
In the first exemplary embodiment, by way of example, in addition to the active power pull-down device 15 of the invention, which is described further below, a passive guide element 11 is arranged on each lateral side, fixed to the body, which, when the cover section 5 is in its closed position, is situated underneath the front end 13 of said cover section, and which comprises an ascending guide surface 12 that points essentially toward the rear.
The guide surface 12 is provided at the front end 13 of the cover section 5 to enable its interaction with side arms 14, which can be moved along the guide surface 12. These side arms 14 can be equipped with roller or gliding elements. At least during the final phase of the movement to close the cover section 5, the side arms 14 are pressed against the guide surfaces 12, which are structured with a component that is inclined upward, opposite the direction of travel F, causing said side arms to be automatically turned back downward, because additional forward motion is prevented by the guide surfaces 12, which are configured as sliding inclines. Because the side arms 14 do not strike the surface 12 perpendicularly, but instead are inclined relative to the direction of force, a downward force is exerted on the side arms 14 and thus on the front end 13 of the cover section 5.
In the first exemplary embodiment according to
In the final phase of the movement to close the cover section 5, the pin 19, by virtue of its downward motion, encounters the lower fork arm 20 of the gripper 18 and pivots it, thereby also pivoting the control arm 16 in the direction of the arrow 21. With this, the articulated joint 10a of the hydraulic cylinder 10 comes into line (
To secure the closed position (
In the second exemplary embodiment according to
In this case, the power pull-down device 115 comprises a first short and, for example, V-shaped pivoting control arm 116, which is capable of pivoting around a stationary transverse vehicle axis 117 on the vehicle body. The hydraulic cylinder 10 is movably held to this axis via the joint 10a. The pivoting control arm 116 comprises, at the end of its leg that faces away from the articulated joint 10a, an articulated joint 123 for an adapter lever 124, which in turn is movably connected via the joint 128 to a gripper 118, which is also fork-shaped in this case. Said gripper is provided for interaction with a companion element 119 of the cover section 105, according to the principle of the first exemplary embodiment. The very short lever 116, 124 allows the structural space required in the longitudinal direction of the vehicle to be kept very small.
During the final phase of the movement to close the cover section 105 (
In the first two exemplary embodiments, the power pull-down device 15, 115 can be moved directly or via the hydraulic cylinder in close proximity to its retracted position. In either case, an adapter lever 124, connected to the gripper 118, can be provided near the control arm 16, 116, on which the drive element 10 is arranged.
In the third exemplary embodiment, in contrast, a control cable connection 224 is connected between the hydraulic cylinder 210 and the gripper 218, wherein in this case the gripper can also be assigned to the cover section 205, although this is not imperative. The control cable 224 is held on a pin 230 of the cover section 205, which is situated in a gate opening 231 for the piston rod of the hydraulic cylinder 210, and in relation to which the control cable sheath 232 that is held on the piston rod of the hydraulic cylinder 210 can be moved.
During closure of the cover section 205, despite the retraction of the piston rod of the hydraulic cylinder 210, the relative position between the gate opening 231 and the pin 230 at first remains unchanged by virtue of the force of the spring 233. Only shortly before the closed position is reached is the spring 233 pressed in by virtue of the continued retraction of the piston rod, wherein the gate opening 231 is drawn essentially forward in the direction of travel F in relation to the pin 230. This then results in a relative movement between the control cable 224 and the control cable sheath 232, which effects the pivoting of the gripper 218, which in this case is assigned to the cover section 205.
The downward movement of the cover section 205 causes the gripper 218 to strike the pin 219, which in this case is allocated to the body. The movement of the control cable described above causes the gripper 218 to pivot around the axis of the joint 225 in the direction of the arrow 221. This joint 225 thereby reaches (transition from
While the best modes for carrying out the invention have been described in detail, those familiar with the art to which this invention relates will recognize various alternative designs and embodiments for practicing the invention within the scope of the appended claims.
Number | Date | Country | Kind |
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10 2004 061 828.3 | Dec 2004 | DE | national |
This application is a U.S. National Phase of International Application No. PCT/DE 2005/002147, filed Nov. 29, 2005, which claims priority to German 10 2004 061 828.3 filed Dec. 22, 2004. The entire contents of the above identified applications are incorporated herein by reference.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE2005/002147 | 11/29/2005 | WO | 00 | 6/22/2007 |