奥地利专利AT513813A1 Boarding aid for a rail vehicle or a motor vehicle with three-point mounting

专利PDF首页>>奥地利专利

专利附录

专利说明

权利要求

类似技术

同族专利

引用文献

法律状态

优先权

专利摘要:
It is an entry aid (1) for a rail vehicle or a motor vehicle specified, which on rolling elements (30 .. 33) and / or sliding surfaces (16) pushed ver mounted footboard (2), and one with the footboard (2) coupled drive ( 6) for extending and retracting the running board (2). The rolling elements (30 .. 33) / Gieitflächen (16) are in exactly three spaced-apart and arranged in a triangular support areas (40..43) positioned. Alternatively, the rolling elements (30 .. 33) / Gieitflächen (18) on several rockers (20) angeord net be and bearing points (21) of the rockers (20) in exactly three spaced beab stood and arranged in a triangular support areas (40. .43 ).
公开号:AT513813A1
申请号:T50015/2013
申请日:2013-01-14
公开日:2014-07-15
发明作者:
申请人:Knorr Bremse Ges Mit Beschränkter Haftung；
IPC主号:

专利说明:

1
The invention relates to a boarding aid for a rail vehicle or a motor vehicle, comprising a running board, which is mounted displaceably on rolling elements and / or sliding surfaces, and coupled to the running board drive, which is set up for extending and retracting the running board.
Such a boarding aid is basically known from the prior art. For example, such boarding aids are used in (public) passenger vehicles to facilitate boarding and exiting the vehicle or to avoid endangering people. For example, the footboard of a rail vehicle serves to bridge the gap between the rail vehicle and a platform when the rail vehicle is stopped at a station. In this way, passengers are prevented from slipping and injuring themselves in the gap in question. Similarly, the footboard on buses can serve to cover the gap between the vehicle and curb. In general, however, the footboard can also serve to bridge the difference in height between the interior of the vehicle and the railway or sidewalk in order to facilitate the entry and exit with wheelchairs and pushchairs. For this purpose, some buses can also be tilted to the side, whereby the footboard is also placed obliquely down.
In general, the running board, which can be moved by means of a drive between a rest position and a use position, guided on two mutually parallel rails. Typically, each rail two spaced apart in the sliding direction rollers are provided so that a tilting of the footboard is prevented. 2/28 N2012 / 25800 2
This system has some disadvantages. For example, the footboard can easily tilt, especially if it is unbalanced load. Furthermore, the rolling elements / sliding surfaces or the running surface of the rail can be damaged under excessive load.
An object of the invention is therefore to provide an improved boarding aid for a rail vehicle or a motor vehicle. In particular, the above-mentioned disadvantages should be avoided or at least mitigated.
The object of the invention is achieved with a boarding aid of the type mentioned, in which the rolling elements and / or sliding surfaces a) are positioned in exactly three spaced apart and arranged in a triangular support areas or b) are arranged on multiple rockers and bearing points of the rockers in exactly three spaced apart and arranged in a triangle supporting areas are positioned.
As a result, the storage of the footboard is statically determined substantially. Unlike with more support areas, as they result, for example, by the four spaced rollers in the prior art, the forces on the support areas are therefore better predictable. Unintentional lifting of a support area from its bearing or rolling surface, which leads to an unplanned excessive loading of the remaining support areas in the prior art, is excluded in the procedure presented. Furthermore, this ensures that the support areas are exposed only to an advantageous swelling load, but not a disadvantageous alternating load, as is possible for example in a running board with four rollers. The fact that a lifting of a support area is prevented, damage is also avoided, which can result from the impact of a support area on its support or rolling surface. In particular, hardened surfaces can otherwise be destroyed even at a relatively low load or even after only a short time. 3/28 N2012 / 25800 3
In addition, the risk of tilting the leadership of the running board is significantly reduced. Therefore, the necessary for safe retraction and extension of the footboard force is better planable. Unscheduled stays, which are due to a jammed footboard, as well as work to repair them can be avoided. In the context of the invention, "spaced-apart support areas" each having a plurality of rolling bodies / sliding surfaces are characterized in that the rolling bodies / sliding surfaces of a support area form a clearly recognizable group or a clearly recognizable "cluster". That is, the distance between the individual rolling elements / sliding surfaces of a support area to each other is small compared to the distance between the rolling elements / sliding surfaces of two different support areas.
The spaced-apart support areas or clusters can also be related to (momentless) force introduction points of a plurality of rolling elements / sliding surfaces. For example, two rolling elements / sliding surfaces can be connected via a rocker, on the one hand to divide a load on several rolling elements / sliding surfaces, on the other hand, but also to ensure that the rolling elements / sliding surfaces wear in any case. About the pivot bearing of the rocker essentially only a bearing force, but no torque can be transmitted. Such force introduction or bearing points can also be arranged in a triangle or form clusters. In this case, the bearing of the footboard is still statically determined essentially when the rolling elements / sliding surfaces and / or sliding surfaces themselves do not form clusters, but the force application or bearing points have this property.
Further advantageous embodiments and modifications of the invention will become apparent from the dependent claims and from the description in conjunction with the figures. It is favorable if the distance between two support areas is at least five times as great as their maximum extent. As a result, the storage of the footboard is determined essentially static, since the support areas are small compared to the distance. For example, the distance between two supporting areas may be based on their center distance or on the distance between their centroids and on their (smallest) edge distance.
It is advantageous if exactly one rolling body or a sliding surface or a bearing point is provided per support area. That is, the number of Wälzkör- per / sliding surfaces / bearing points is exactly three. The static certainty of the footboard storage is therefore particularly good.
It is furthermore particularly advantageous if all supporting regions are spaced apart from each other with respect to a direction transverse to a direction of movement of the running board. Each support area is thus assigned to a separate rail. The security against tilting is therefore particularly great in this variant.
A further advantageous variant of the boarding aid is given when a first and a second support area seen in a direction of movement of the running board are closer to the running board than the third support area, wherein the first and the second support area seen in a direction of movement of the footboard are equidistant from the footboard , In this variant of the invention, therefore, there are two support areas close to the footboard, in particular close to its side edges. A third support area is located somewhat further away from the running board and is preferably arranged in the middle of the width of the running board. This results in largely symmetrical conditions. Assuming that the footboard is centrally loaded, which is the standard case, and provided that the third support area is equidistant from the first / second support area with respect to a moving direction of the footboard, the first acts in the first to the third support area equal forces which correspond to the load on the footboard. In the first and second support areas, the forces mentioned act upwards, whereas the force in the third support area acts downward. As a result, three identical Wälzkör- per / sliding surfaces are used, which also have substantially the same life due to their symmetrical load. Depending on how strongly the construction deviates from this symmetry, correspondingly different balance of power results. If necessary, then different numbers or 5/28 N2012 / 25800 5 can be used in different rolling elements / sliding surfaces in the individual support areas. It is advantageous if one or more of the group ball, roller, needle and / or barrel is / are provided as the rolling element. Depending on the application, different rolling elements can be used. For example, rollers and tons can absorb relatively high forces. A barrel bearing can also compensate for angular errors well. A compensation of angular errors also succeeds well when balls are used as rolling elements. In particular, balls are also suitable if the running surface is not configured horizontally but is set somewhat obliquely in order to improve the lateral guidance of the running board. The resulting contact force is then not vertically but just obliquely aligned. Finally, needles are particularly suitable for installation situations in which a low overall height is important. It is favorable if the access aid comprises a force sensor which is set up to measure the bearing force acting in a support area. In this way, the load acting on the footboard can be determined. For example, conclusions can be drawn with the data thus obtained as to who or what is currently on the running board. For example, if the magnitude of the force is over 500N, it is highly likely that an adult will be on the running board. If the load is variable, it is most likely a living thing (human or animal) on the running board, it is static for a long time, so it may be with a certain probability, just a parked on the footboard baggage item. It is favorable if the access aid comprises three force sensors which are set up to measure the bearing forces acting in all three support areas. In this way, on the one hand, the size of the force acting on the footboard (vertical) force and their point of attack can be calculated on the running board.
It is also advantageous if the boarding aid comprises two force sensors which are arranged to measure the bearing forces acting in two support areas, in particular for measuring the bearing forces acting in the first support area and in the second support area. In this way, on the one hand, the size of the force acting on the footboard (vertical) force and their point of application can be calculated on the running board, provided that a coordinate of the same is assumed or assumed to be known. For example, the said point of application can be assumed in good approximation with respect to the depth of the running board in the middle.
Moreover, it is particularly advantageous if the boarding aid comprises exactly one force sensor which is set up to measure the bearing force acting in exactly one bearing area, in particular for measuring the bearing force acting in the third bearing area. In this way, the magnitude of the force acting on the footboard can be calculated if its point of attack is assumed or assumed to be known. For example, the said point can be assumed in good approximation in the center of the footboard. If the force sensor is provided in the third support area, the knowledge of the coordinate of the point of application of the force in the direction of movement of the running board is sufficient. For example, the said point can be assumed in a good approximation based on the depth of the running board in the middle. Of course, other points of attack can be assumed based on the depth of the running board, for example, the front edge or trailing edge.
It is advantageous if the rolling bodies per / sliding surfaces provided in a support region are mounted so as to be movable relative to one another transversely to their support surface, in particular resiliently. In this way tolerances of the boarding aid can be compensated in the sense that the Wälzkör- / / sliding surfaces of a support area also have (all) contact to a support or rolling surface and not "hang in the air". This avoids that the force acting in a support area force is not inadvertently taken up only by a part of the rolling elements / sliding surfaces located in the support area and therefore they are excessively loaded. 7/28 N2012 / 25800 7
But it is also advantageous if the rolling body / sliding surfaces provided in a support area are mounted rigidly relative to one another in relation to a direction transverse to their support surface. This results in a simple and less error-prone construction of the boarding aid. In addition, it is favorable if the support areas are mounted with respect to a direction transverse to their support surface to one another in a movable, in particular resilient, manner. In this way it is achieved, for example, that the footboard can be aligned horizontally despite tolerances which lead to unwanted height deviations of the support areas. It is also favorable if the support areas are mounted rigidly relative to one another in relation to a direction transverse to their support surface. This in turn results in a simple and less error-prone construction of boarding assistance.
It is also particularly advantageous if at least one rolling element / at least one sliding surface is resiliently mounted by means of a spring and the boarding aid comprises a stop, which after a predetermined spring travel of the spring away from the at least one rolling element / the at least one sliding surface and the spring effectively is. Characterized the load of the rolling body / the sliding surface is limited to that force, which is defined by the spring constant of the spring and the spring travel, in which the stopper is effective. An additional load of the rolling element / the sliding surface is avoided, however, since it is absorbed by the aforementioned stop. The "off the rolling element / the sliding surface and the spring" arranged stop is therefore different from a stop which acts on the rolling body / the sliding surface or the spring mechanism. Although further compression of the rolling element / the sliding surface is prevented, an additionally acting force is however carried by the rolling element / of the sliding surface itself. It is favorable if the force sensor is arranged to measure the bearing force acting on at least one rolling element / at least one sliding surface. In this variant, the on the at least one rolling element / the at least one 8/28 N2012 / 25800 8
Direct acting sliding surface force, for example, with a piezo-pressure sensor. The results obtained are therefore particularly accurate. It is also favorable if the force sensor is arranged to measure the deformation of the spring and / or to measure the spring travel. In this variant, the force acting on the at least one rolling element / the at least one sliding surface is determined via the detour of the deformation measurement. Under certain circumstances, such an arrangement is structurally easier to solve than the direct measurement of said force. For example, the force sensor may be formed as an area sensor, which measures the said deformation of the spring and / or said spring travel. In principle, the use of such a field sensor may also be advantageous independently of the features of patent claim 1, that is to say also in the case of a footboard which is mounted with more than three support areas / sliding areas.
It when the stop above the allowable load of the at least one rolling element / the at least one sliding surface is effective is particularly advantageous. In this way it is avoided that the at least one rolling element / the at least one sliding surface is damaged at high load, since a force on the allowable load of the at least one rolling element / the at least one sliding force is absorbed by the stop.
It is furthermore particularly advantageous if the stop is effective over the measuring range of the force sensor. As a result, the measuring range of the force sensor can be well utilized. In order to avoid damage to the same, an additional force is absorbed by the stop.
In addition, it is also advantageous if the stop is inoperative with unloaded footboard. As a result, an easy retraction and extension of the running board is made possible, since essentially only rolling friction occurs in the guide, but a frictional force caused by the stop is avoided.
Another particularly advantageous variant of the boarding aid is given when the stop is effective at a more than 100 N on the weight of the footboard outgoing on the running board and rectified with the force of gravity outgoing 9/28 N2012 / 25800. In this way, a certain safety reserve approach, so that the stop is due to tolerances and aging or setting already at unloaded footboard and thus always effective. Preferably, the stop is effective for a more than 700 N beyond the weight of the footboard on the running board acting and rectified with the weight force. Thus, the most common load case of an average person with 70 kg body weight is still supported by Wälzkör- / sliding surfaces, or an adult average person and lighter persons and objects on the running board with the help of the force sensors can be detected safely.
It is furthermore advantageous if the abutment has a static friction coefficient of μ> 0.5 at or with a bearing surface, or a releasable positive-locking connection is provided between them. This tends to inhibit or even prevent the tread movement when under (excessive) load. For example, dangerous situations can be prevented in this way. For example, with proper matching of driving force of the drive, spring constant, spring travel to stop effectiveness and coefficient of friction, movement of a tread loaded by a person can be prevented solely by the drive being too weak. Even with a failure of any existing person detection, which controls the drive, then the footboard does not move. It moves only when it is unloaded or only slightly loaded. The same applies if between the stop and its support surface in the rail a releasable positive connection is provided, for example by the stop and the rail are provided with a toothing. The height of the toothing is preferably chosen so that the toothing is released by a spring when the load falls below a certain threshold.
Finally, it is advantageous if the stop has a static friction coefficient of μ <0.5 (preferably μ <0.2) at or with a bearing surface. As a result, the movement of the tread under load is more favored. 10/28 N2012 / 25800 10
For example, with appropriate coordination of drive force of the drive, spring constant, spring travel to the effectiveness of the stop and friction coefficient, the tread can be retracted even if it is loaded. In this way, the transport can continue its journey even if the footboard is loaded, for example, by a forgotten piece of luggage.
For a better understanding of the invention, this will be explained in more detail with reference to the following figures. Show it:
Fig. 1 is a schematically illustrated boarding aid;
Fig. 2 is an inserted in the inserted in Figure 1 sliding element in an oblique view.
Fig. 3 shows the sliding element of Figure 2 in side view.
Fig. 4 shows a sliding element with a spring-mounted sliding body and
Fig. 5 shows an arrangement in which two rolling elements are arranged on a rocker.
By way of introduction, it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals or the same component names, wherein the disclosures contained in the entire description can be mutatis mutandis to the same parts with the same reference numerals or component names. Also, the location information chosen in the description, such as top, bottom, side, etc. related to the immediately described and illustrated figure and are to be transferred to the new situation mutatis mutandis when a change in position. Furthermore, individual features or combinations of features from the illustrated and described different embodiments may represent for themselves, inventive or inventive solutions. All statements on ranges of values in the description of the present invention should be understood to include any and all sub-ranges thereof, e.g. the indication 1 to 10 should be understood to mean that all subregions excluded from the lower limit 1 and the upper limit 10 are included, i. e. all sub-ranges begin with a lower limit of 1 or greater and end at an upper limit of 10 or less, e.g. 1 to 1.7, or 3.2 to 8.1 or 5.5 to 10.
Fig. 1 shows an entry aid 1 for a rail vehicle or a motor vehicle, comprising a footboard 2, which is mounted on rolling elements 31..33 slidably. The rolling elements 31.33 are positioned in this example in spaced support portions 41 ..43 and run in indicated rails 51.53. Furthermore, the boarding aid 1 comprises a coupled to the running board 2 drive 6, which is shown only schematically in FIG. 1 and which is set up for extending and retracting the running board 2. In the example shown in FIG. 1, the rolling bodies 31.33 are arranged in special sliding elements 71.73.
FIGS. 2 and 3 now show such a sliding element 70 in detail. Specifically, Fig. 2 shows the sliding member 70 in an oblique view, Fig. 3 in side view. The sliding element 70 comprises a base body 8, on which sliding blocks 9 are fastened with screws 10. With these Nutsteinen 9 or screws 10, the sliding element 70 can be attached to the footboard 2. The roller 30 is arranged in a roller holder 11, which is mounted on the main body 8 via a spring assembly 12 and a screw 13. Furthermore, the sliding element 70 comprises an adjusting screw 14, an optional Kraftmeßsensor 15 and a stop 16. Thus, the sliding element 70 and the boarding aid 1 in this example comprises a rolling element 30 respectively a support portion 40 which is resiliently mounted by means of a spring 12, and a Stop 16, which is effective after a predetermined spring travel of the spring 12 away from the at least one rolling element 30 and the spring 12.
The function of Getting Started 1 is now as follows:
In the basic position of the rolling element 30, which is designed here as a role, projects beyond the underside of the base body 8 and the stopper 16 addition. In the basic position, the sliding element 70 and thus the footboard 2 on the 12/28 N2012 / 25800 12 rolling elements 30..33 and can be moved alone by overcoming the rolling friction.
By the spring 12, the load of the rolling element 30 is limited to that force, which is defined by the spring constant of the spring 12 and the spring travel, in which the stopper 16 is effective. A further burden of the rolling element 30 is, however, avoided, since with increasing load, the roller 30 in Figs. 2 and 3 is pushed upward noticeably and comes to lie in consequence of the stop 16 on the arranged in the rail 51.53 tread. Another load is added as a result of the stop 16. The load on the roller 30 is constant from this point on. It is advantageous in this context when the stop 16 is effective over the allowable load of the rolling element 30 to protect the rolling elements 30 from damage. The force from which the stop 16 is effective, can be adjusted with the adjusting screw 14.
With the force sensor 15, which is formed in this example for measuring the spring travel of the spring 12, the bearing force acting on the roller 30 can be measured. Alternatively, the force sensor 15 can also be designed to measure the deformation of the spring 12 and be realized for example by means of strain gauges. But even the direct measurement of the aforementioned contact force is possible in principle. For example, a force sensor 15 embodied as a piezo pressure sensor may be arranged in the region of the bearing of the roller 30 in the roll holder 11. When using a force sensor 15, it is advantageous if the stop 16 is effective over the measuring range of the force sensor 15, because in this way the measuring range of the force sensor 15 can be well utilized without having to risk damaging it due to excessive load. A force beyond the measuring range is then picked up by the stop 16.
With the help of the force sensor 15, the load acting on the footboard 2 can be determined. For example, with the data thus obtained conclusions can be drawn who or what is currently on the footboard 2. For example, if the magnitude of the force F is greater than 500N, it can be assumed that there is a high probability that an adult person is on the footboard 2. If the load is variable, it is most likely a living being (human or animal) on the footboard 2, it is static for a long time, so it may be with a certain probability, only a parked on the footboard 2 baggage item.
In general, several options are available for the arrangement of the force sensor 15 or several force sensors 15. For example, all sliding elements 71.73 in FIG. 1 can be equipped with force sensors 15 so that the bearing forces acting in all three support areas 41.43 can be measured. In this way, on the one hand, the size of the force F acting on the footboard 2 and its point of application on the footboard 2 can be calculated.
It is also conceivable that the boarding aid 1 comprises only two force sensors 15, which are set up to measure the bearing forces acting in two support areas 41.43. It is particularly advantageous if the first and second sliding elements 71 and 72 are equipped with force sensors 15 and thus the bearing forces acting in the first support region 41 and in the second support region 42 can be measured. In this way, on the one hand, the size of the force F acting on the footboard 2 and its point of application on the footboard 2 can be calculated, provided that a coordinate thereof is assumed or assumed to be known. For example, the said point of attack can be assumed in good approximation with respect to the depth of the footboard 2 in the middle.
It is also conceivable that the boarding aid 1 comprises only one force sensor 15. In this way, the magnitude of the force F acting on the footboard 2 can be calculated if its point of application is assumed or assumed to be known. For example, the said point of application can be assumed to a good approximation in the center of the footboard 2. If the force sensor 15 is provided in the third sliding element 73, so that the bearing force acting in the third support region 43 can be measured, the knowledge of the coordinate of the point of application of the force F in the direction of movement B of the footboard 2 is sufficient. 14/28 N2012 / 25800 14
For example, the said attack point can be assumed in a good approximation based on the depth of the footboard 2 in its center. Of course, other points of attack can be assumed based on the depth of the footboard 2, for example, the front edge or trailing edge.
The rolling elements 31 ..33 are in this example in exactly three spaced-apart and arranged in a triangular support portions 41.43 positioned.
As a result, the storage of the footboard 2 is determined statically. Thus, the forces on the rollers 31 ..33 well predictable, since a lifting of the rolling elements 31.33 and the stops 16 is impossible, as it may occur in a leadership, which has more than three support portions 31.33. In addition, the risk of tilting of the sliding elements 71.73 in the rails 51.53 is significantly reduced.
In the example shown in FIG. 1, exactly one rolling element 31.33 is provided per support region 41.43, that is, the number of rolling elements 31.33 is exactly three. But it is also possible that a support portion 41.43 has more than one roller 31.33. For example, juxtaposed or successively arranged rollers 31 ..33 may be provided. It is advantageous if the distance between two support areas 41.43 from each other at least five times as large as their maximum extent. As a result, the storage of the footboard 2 is then determined essentially static.
When using a plurality of rolling elements 30..33 per support area 40..43, it is also advantageous if the rolling elements 30..33 provided in a support area 40..43 are movable relative to one another transversely to their support surface, in particular resiliently, are stored. In this way tolerances of the boarding aid can be compensated in the respect that all rolling elements 30..33 a support portion 40..43 have contact with a support or rolling surface and not "hang in the air". This avoids that the force acting in a support area 40..43 force is not inadvertently taken up only by a part of the rolling elements 30..33 located in the Wälzbereich40..43 and they are therefore excessively burdened. 15/28 N2012 / 25800 15
Of course, the rolling elements 30... 33 provided in a support region 40... 43 can be rigidly mounted relative to one another in relation to a direction transverse to their support surface, resulting in a simple and less error-prone design of the access aid 1.
In the example shown in FIG. 1, all supporting areas 41..43 are spaced apart from each other with respect to a direction transverse to a direction of movement of the running board 2 (see also the double arrow B in FIG. 1). Thus, each supporting area 41..43 is assigned its own running surface or rail 51.53. The security against tilting is therefore particularly great in this variant.
Furthermore, the first and the second support portion 41, 42 seen in a direction of movement of the footboard 2 closer to the footboard 2 as the third support portion 43, the first and the second support portion 41, 42 viewed in a direction of movement of the footboard 2 equidistant from the footboard. 2 are removed. This results in largely symmetrical conditions. Provided that the third support region 43 is equidistant from the first / second support region 41, 42 with respect to the direction of movement of the footboard 2, equally large forces acting on the load F in the first to third support regions 41, 43 act correspond to the footboard 2. In the first and second support region 41, 42, the said forces act upward, whereas the force in the third support region 43 acts downward. This allows three identical rolling elements 31.33 are used, which also have substantially the same life due to their symmetrical load. Of course, this symmetry for the boarding aid 1 is not mandatory. Deviating geometric conditions are of course possible without restriction.
In the example shown, the support portions 40..43 and the rolling elements 30..33 are mutually movable with respect to a direction transverse to the bearing surface, in this case even resiliently mounted. In principle, however, it is also conceivable that the support regions 40..43 and the rolling elements 30..33 are mounted rigidly relative to one another in relation to a direction transverse to their bearing surface. This results in a simple and less error-prone construction of the access aid 1. 16/28 N2012 / 25800 16
Generally, the rolling element 30..33 also have a different shape than a roller. For example, these can be designed as a ball, needle and / or barrel. For example, rollers and tons can absorb relatively high forces. A barrel bearing can also compensate for angular errors well. A compensation of angular errors also succeeds well when balls are used as rolling elements. In particular, balls are also suitable if the running surface is not designed horizontally but is set somewhat obliquely in order to improve the lateral guidance of the running board 2. The resulting contact force is then not vertically but just obliquely aligned. Finally, needles are particularly suitable for installation situations in which a low overall height is important. Optionally, different numbers of rolling elements or different types of rolling elements can then be used in the individual support areas.
As mentioned, in the examples shown in the figures, the stop 16 is ineffective in unloaded footboard 2. This makes it possible to easily slide in and out of the running board 2, since essentially only rolling friction occurs between the rollers 30... 33 and the rails 51. 53, but a frictional force caused by the stop 16 is avoided.
It is advantageous if the stop 16 is effective at more than 100 N beyond the weight of the footboard 2, acting on the footboard 2 and rectified with the weight force. In this way, a certain safety reserve procedure, so that the stopper 16 is not already effective in unloaded footboard 2 and thus always due to tolerances and aging or setting. Preferably, the stopper 16 is effective at more than 700 N beyond the weight of the footboard 2 force. As a result, the most frequent load case of an average person weighing 70 kg is still borne by the rolling bodies 30... 33, or an adult average person as well as lighter persons and objects on the running board 2 can be reliably detected with the aid of the force measuring sensors 15.
For example, a coefficient of static friction of μ> 0.5 or a releasable form-fitting connection can be provided between the stop 16 and its bearing surface in the rail 51... 53. As a result, the movement of the footboard 2 is rather inhibited or even prevented under (excessive) load. For example, dangerous situations can be prevented in this way. With proper coordination of driving force of the drive 6, spring constant, spring travel to the effectiveness of the stop 16 and coefficient of friction, for example, a movement of the footboard 2, which is loaded by a person, be prevented solely by the fact that the drive is too weak for it. Even if there is a failure of any existing person detection, which controls the drive 6, then the footboard 2 does not move, but only when it is unloaded or only slightly loaded. The same applies if between the stop 16 and its bearing surface in the rail 51.53 a releasable positive connection is provided, for example by the stop 16 and the rail 51.53 are provided with a toothing. The height of the toothing is preferably chosen so that the toothing is released by the spring 12 when the load falls below a certain threshold. Of course, the footboard 2 can also be locked differently, for example by a latching bolt, which prevents a displacement of the displacement element 70..53 in the rail 51.53.
But between the stop 16 and its bearing surface in the rail 51.53, for example, a static friction coefficient of μ <0.5 (preferably μ <0.2) may be provided. As a result, the movement of the footboard 2 is more favored under load. For example, with appropriate coordination of driving force of the drive 6, spring constant, spring travel to the effectiveness of the stop 16 and coefficient of friction, the footboard 2 are retracted even if it is loaded.
4 shows an embodiment of a sliding element 74 in which a spring-mounted sliding body 17 with a sliding surface 18 is arranged in a base body 8. Increases the force acting on the sliding surface 18, the slider 17 is visibly pushed against the force of the coil spring 19 in the base body 8 until it protrudes the same distance from the base body 8 as the stop 16. 18/28 N2012 / 25800 18th
From this point, any further load - similar to the one shown in Figures 1 to 3 sliding elements 70..73 - taken from the stop 16.
The doctrine disclosed with reference to FIGS. 1 to 3 can also be transferred analogously to the embodiment shown in FIG. 4, in particular also with regard to the use of force sensors and the provision of specific coefficients of friction or a detachable form-fitting connection for the stop 16 It is advantageous if the coefficient of friction between the sliding surface 18 and its support surface in the rail 51.53 is smaller than the coefficient of friction between the stop 16 and its support surface in the rail 51.53, if the stop 16 is not at all a releasable positive connection with the rail 51.53 forms.
Fig. 5 shows an arrangement in which two rolling elements 30 are arranged on a rocker 20. As a result, on the one hand, a load can be divided among a plurality of rolling elements 30, but on the other hand, it can also be ensured that the rolling elements 30 are in each case supported. About the pivot bearing or the bearing point 21 of the rocker 20 can essentially only a bearing force, but no torque can be transmitted. The bearing points 21 of the rockers 20 are - as shown in Fig. 1 for the rolling elements 31.33 - positioned in exactly three spaced-apart and arranged in a triangle support areas 40..43. The mounting of the footboard 2 is then even statically substantially determined when the rolling elements 30 themselves do not form clusters, but said force introduction or bearing points 21 have this property. The embodiment shown in FIG. 5 is shown in connection with rolling elements 30, of course, the rocker 20 shown can also be used in conjunction with sliding bodies 18.
The embodiments show possible embodiments of a boarding aid according to the invention 1 and a sliding element according to the invention 70..74, which should be noted at this point that the invention is not limited to the specific embodiments illustrated thereof, but rather various combinations of the individual embodiments are possible with each other and this possibility of variation due to the teaching 19/28 N2012 / 25800 19 for technical action by representational invention in the skill of those working in this technical field is the expert. So are all conceivable embodiments, which are possible by combinations of individual details of the illustrated and described embodiment variant, includes the scope of protection.
In particular, it is stated that the illustrated access aid 1 or the illustrated sliding element 70..74 can in reality also comprise more or fewer components than shown. In particular, the footboard 2, unlike shown in the figures, can also be mounted on fixed rolling elements 30, 33 and / or sliding surfaces 18 (that is, not spring-mounted). A stop 16 can be omitted in this case. Also conceivable are hybrid forms of the illustrated embodiments. Thus, for example, a rolling element 30... 33 and a sliding element 17 can be used mixed for the storage of a running board 2. The same applies to rockers 20. In addition, spring-mounted rolling elements 30..33 or sliding body 17 with fixed rolling elements 30..33 or sliding bodies 17 can be used together.
For the sake of order, it should finally be pointed out that the access aid 1 and the sliding element 70..74, as well as their components for a better understanding of their structure were shown partially uneven and / or enlarged and / or reduced.
The task underlying the independent inventive solutions can be taken from the description. 20/28 N2012 / 25800
LIST OF REFERENCE NUMERALS 1 Accessory 2 T rittbrett 30..33 Rolling element (roller) 40..43 Supporting area 50..53 Rail 6 Drive 71..74 Sliding element 8 Base 9 Sliding block 10 Fixing screw 11 Roller holder 12 Spring pack 13 Screw 14 Adjusting screw 15 Force measuring sensor 16 Stop 17 Sliding element 18 Sliding surface 19 Spiral spring 20 Rocker 21 Bearing point Rocker B Movement direction F Force 21/28 N2012 / 25800

权利要求:
Claims (10)
[1]
1 access aid (1) for a rail vehicle or a motor vehicle, comprising a footboard (2) which is mounted on rolling elements (30..33) and / or sliding surfaces (18) slidably, and one with the running board (2) coupled drive (6), which is arranged for extending and retracting the running board (2), characterized in that the rolling elements (30..33) / sliding surfaces (18) a) in exactly three spaced apart and arranged in a triangular support areas ( 40..43) are positioned or b) are arranged on a plurality of rockers (20) and bearing points (21) of the rockers (20) in exactly three spaced-apart and arranged in a triangle support areas (40..43) are positioned.
[2]
2. boarding aid (1) according to claim 1, characterized in that the distance between two support areas (40..43) from each other at least five times as large as their maximum extent.
[3]
3. boarding aid (1) according to claim 1 or 2, characterized in that per support area (40..43) exactly one rolling element (30..33) or a sliding surface (18) or a bearing point (21) is provided.
[4]
4. boarding aid (1) according to one of claims 1 to 3, characterized in that all supporting areas (40..43) with respect to a direction transverse to a direction of movement of the running board (2) are spaced from each other.
[5]
5. boarding aid (1) according to one of claims 1 to 4, characterized in that a first and a second support portion (41,42) seen in a direction of movement of the running board (2) closer to the running board (2) than the third 22 / 28 N2012 / 25800 2 bearing area (43), wherein the first and the second support area (41, 42) are located equidistant from the footboard (2) in a movement direction of the running board (2).
[6]
6. boarding aid (1) according to one of claims 1 to 5, characterized by a force sensor (15) which is adapted to measure in a support area (40..43) acting bearing force
[7]
7. boarding aid (1) according to claim 6, characterized by three force sensors (15) which are adapted to measure in all three support areas (40..43) acting bearing forces.
[8]
8. boarding aid (1) according to claim 6, characterized by two force sensors (15) which are adapted to measure the in two support area (40..43) acting bearing forces.
[9]
9. boarding aid (1) according to claim 6, characterized by exactly one force sensor (15) which is adapted to measure in exactly one support area (40..43) acting bearing force.
[10]
10. boarding aid (1) according to one of claims 1 to 9, characterized in that the support portions (40..43) are movable relative to a direction transverse to the support surface to each other. 23/28 N2012 / 25800

类似技术:

公开号 | 公开日 | 专利标题

AT513813B1|2014-10-15|Sliding step for a rail vehicle or a motor vehicle

EP3094534B1|2019-11-27|Height-adjustable step platform for a rail vehicle

DE102013014094B4|2018-10-18|Industrial truck

DE202012104800U1|2013-01-14|Battery replacement device for electric vehicles

EP3077321A1|2016-10-12|Support for supporting a person conveying device on a structure

EP2033870B1|2011-10-26|Retractable step for railway vehicles

DE202017107136U1|2019-03-01|Anti-slip device for crawler carriers

DE3439616A1|1986-04-30|BOGIE FOR RAIL VEHICLES

EP3365218B1|2021-09-22|Height control mechanism

DE202008008063U1|2008-09-04|Mine jack roller, pit jack and pit

DE102016124450A1|2018-06-21|Storage and retrieval unit

DE202011051598U1|2011-11-07|Rolling device of a trailer for a vehicle body

DE202015101275U1|2016-06-15|Niveauerzwingungseinrichtung

EP0047222B1|1984-09-26|Locking device for securing a wheeled and/or tracked vehicle on a railroad car

EP2243679B1|2016-01-13|Roller system with support function for a retractable sliding step

DE102017009094A1|2019-03-28|Floor conveyor and method of transport on a floor conveyor

EP3057902B1|2020-03-25|Progressive safety gear and method for conveying means

EP3197721B1|2018-08-15|Step plate having expansion element

DE102012111320B3|2013-11-14|Device for tracking apparatuses and/or machines movable on rails, has attenuation mat pre-tensioned by assembling attenuation mat between head part and roller carriages such that force to roller carriages exerts away from head part

DE102019218915A1|2021-06-10|Escalator with safety system

DE102014113624A1|2016-03-24|Tread plate with expansion element

DE102021115805A1|2022-01-13|Device for translational transverse movement for forklifts, in particular forklifts with forks or the like

DE102007001626B4|2010-07-29|Mobile measuring device for detecting wheel loads of rail vehicles

AT519530B1|2018-12-15|DEVICE FOR MOVING A SHIFTER OF A SOFT

DE202008004206U1|2009-10-15|Handrail for moving walks, escalators and the like.

同族专利:

公开号 | 公开日

WO2014107756A1|2014-07-17|

RU2015134100A|2017-02-16|

RU2647110C2|2018-03-13|

BR112015016094A2|2017-07-11|

AT513813B1|2014-10-15|

JP2016504237A|2016-02-12|

JP6275164B2|2018-02-07|

CN104936847B|2017-11-14|

US20150352992A1|2015-12-10|

CN104936847A|2015-09-23|

US9505330B2|2016-11-29|

ES2625822T3|2017-07-20|

PL2943387T3|2017-10-31|

EP2943387B1|2017-03-01|

PL2943387T4|2017-10-31|

EP2943387A1|2015-11-18|

TR201708038T4|2018-11-21|

BR112015016094A8|2019-10-22|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

DE19928571A1|1999-06-22|2001-01-04|Siemens Ag|Motor vehicle entrance door access ramp|

DE202009004004U1|2009-03-25|2010-08-12|Gebr. Bode Gmbh & Co. Kg|Roller system for a boarding aid|DE102014203049A1|2014-02-20|2015-08-20|Robert Bosch Gmbh|Sliding step arrangement|US3341223A|1965-09-01|1967-09-12|Wampfler Jacob|Retractible safety steps|

FR2693421B1|1992-07-10|1994-08-19|Alsthom Gec|Device facilitating access to a rail vehicle.|

US5775232A|1997-02-14|1998-07-07|Vapor Corporation|Bridge plate for a mass transit vehicle|

US6010298A|1998-04-15|2000-01-04|Lift-U Division Of Hogan Mfg., Inc.|Low floor vehicle ramp assembly|

US6167816B1|1998-06-05|2001-01-02|Westinghouse Air Brake Company|Single screw bridgeplate|

US7052227B2|2001-01-26|2006-05-30|The Braun Corporation|Drive mechanism for a vehicle access system|

WO2003018355A1|2001-08-22|2003-03-06|The Braun Corporation|Wheelchair ramp with side barriers|

JP2004148941A|2002-10-30|2004-05-27|Nabco Ltd|Step device for platform|

AT412394B|2003-03-25|2005-02-25|Knorr Bremse Gmbh|SLIDING KICK|

JP4527569B2|2005-03-07|2010-08-18|東急車輛製造株式会社|Railway vehicle stepping device|

JP4846485B2|2006-08-18|2011-12-28|ナブテスコ株式会社|Platform step device|

CN101522502A|2006-10-03|2009-09-02|卡巴吉尔根股份公司|Gap-bridging device for train platforms|

US7971891B2|2007-01-18|2011-07-05|Werner Kircher|Boarding and/or access aid for passenger vehicles|

CA2630570A1|2007-05-04|2008-11-04|Lift-U, Division Of Hogan Mfg., Inc.|Fold out ramp|

JP5054494B2|2007-11-28|2012-10-24|ナブテスコ株式会社|Fall prevention device|

US8020496B1|2008-03-17|2011-09-20|Ignacio Maysonet|Retractable platform device for use with subway trains and associated method|

DE202008004517U1|2008-04-01|2009-08-13|Gebr. Bode Gmbh & Co. Kg|Approach aid with improved spindle drive|

DE202008004592U1|2008-04-02|2009-08-13|Gebr. Bode Gmbh & Co. Kg|Door system with piezo-sensors|

CN101722961A|2008-11-03|2010-06-09|刘峰|Extension reverse turning plate of passenger train foot treadle|

FR2939735A1|2008-12-12|2010-06-18|Faiveley Transp Tours|DEPLOYABLE DEVICE FOR ACCESSING A VEHICLE|

DE202009005045U1|2009-04-20|2010-09-09|Gebr. Bode Gmbh & Co. Kg|Roller system with support function|

KR200454982Y1|2009-05-13|2011-08-09|현대로템 주식회사|Sliding scaffolding cover device for railway vehicles|US9902326B2|2010-03-06|2018-02-27|Jeffrey Carr|Auxiliary step for vehicles|

DE102014206184A1|2014-04-01|2015-10-15|Siemens Aktiengesellschaft|Height-adjustable tread platform for a rail vehicle|

CN107107830A|2014-09-22|2017-08-29|盖伯.伯德有限两合公司|Pedal with strain gauge element|

US10507848B2|2014-11-19|2019-12-17|Alstom Transport Technologies|Railway vehicle with a movable, vertical gap bridging entry threshold|

CL2014003523A1|2014-11-24|2015-07-31|Bode Gmbh & Co Kg|A sliding step for a public transport vehicle comprising, a step plate with at least two rollers arranged on its side faces, a centering means comprising two centering elements, which cooperate with each other so that when the plate of the step retracts in the frame, the plate is placed in a predefined position.|

DE102015100702A1|2015-01-19|2016-07-21|Gebr. Bode Gmbh & Co. Kg|Double push step with strain gauge|

CN105818824A|2015-09-17|2016-08-03|成都明日星辰科技有限公司|Mechanical intelligent linkage device for rail traffic safety pedal|

CN105711608A|2015-09-17|2016-06-29|成都明日星辰科技有限公司|Mechanical and durable smart pedal with support device|

CN105035104A|2015-09-18|2015-11-11|成都明日星辰科技有限公司|Mechanical durable intelligent footboard for railway traffic|

CN105196921A|2015-10-16|2015-12-30|李怡然|Automobile with supporting plates|

DE102016103265A1|2016-02-24|2017-08-24|Bombardier Transportation Gmbh|Vehicle treadle and method of operation therefor|

CN105599687A|2016-03-31|2016-05-25|桂林理工大学|Ramp pneumatic drawing type barrier-free bus door|

US20200307650A1|2019-03-31|2020-10-01|Universal City Studios Llc|Gap blocking systems and methods for amusement park attractions|

CN111238616B|2020-01-21|2021-11-12|中车齐齐哈尔车辆有限公司|Weighing device and weighing system with same|

CN111497878B|2020-04-27|2021-05-11|中车青岛四方机车车辆股份有限公司|Door clearance compensator footboard section bar structure, door clearance compensator and rail vehicle|

法律状态:

优先权:

申请号 | 申请日 | 专利标题

ATA50015/2013A|AT513813B1|2013-01-14|2013-01-14|Sliding step for a rail vehicle or a motor vehicle|ATA50015/2013A| AT513813B1|2013-01-14|2013-01-14|Sliding step for a rail vehicle or a motor vehicle|

RU2015134100A| RU2647110C2|2013-01-14|2014-01-13|Entry aid with three-point bearing for a rail vehicle or a motor vehicle|

JP2015551934A| JP6275164B2|2013-01-14|2014-01-13|Entry / exit assistance means for rail vehicles or automobiles with three-point support|

TR2017/08038T| TR201708038T4|2013-01-14|2014-01-13|Riding aid with three-point bearing for a railway vehicle or a motor vehicle.|

CN201480004761.2A| CN104936847B|2013-01-14|2014-01-13|The servicing unit of getting on the bus for being used for rail vehicle or motor vehicle including bikini support meanss|

US14/760,318| US9505330B2|2013-01-14|2014-01-13|Entry aid with three-point bearing for a rail vehicle or a motor vehicle|

ES14712185.9T| ES2625822T3|2013-01-14|2014-01-13|Access aid for a rail vehicle or a motor vehicle with three support points|

BR112015016094A| BR112015016094A8|2013-01-14|2014-01-13|input assistance for a rail vehicle or a three-point self-propelled motor vehicle|

PL14712185T| PL2943387T3|2013-01-14|2014-01-13|Entry aid with three-point bearing for a rail vehicle or a motor vehicle|

EP14712185.9A| EP2943387B1|2013-01-14|2014-01-13|Entry aid with three-point bearing for a rail vehicle or a motor vehicle|

PCT/AT2014/050007| WO2014107756A1|2013-01-14|2014-01-13|Entry aid with three-point bearing for a rail vehicle or a motor vehicle|

[返回顶部]