STAND SAFETY MONITORING OF A LOADING CRANE MOUNTED ON A VEHICLE

专利摘要:
Method for monitoring at least one stability parameter of a loading crane (2) mounted on a vehicle (1), the vehicle (1) being in crane operation via wheels (3a, 3b) and by means of separate support elements (4) from the wheels (3a, 3b) on the ground is supported, both contributions of the wheels (3a, 3b) and contributions of the support elements (4) are detected to a size of the stability parameter and this size is compared with at least one predetermined limit.
公开号:AT511234A1
申请号:T5002011
申请日:2011-04-08
公开日:2012-10-15
发明作者:
申请人:Palfinger Ag；
IPC主号:

专利说明:

1
The invention relates to a method and a device for monitoring at least one stability parameter of a loading crane mounted on a vehicle, wherein the vehicle is supported or can be supported on the ground in cranes via wheels and support elements separate from the wheels. Usually, the support elements are extendable in the vertical direction support legs, which are mounted on a laterally extendable in the horizontal direction Abstützverbreiterung. The property of the extensibility of the support legs and the Abstützverbreiterung is made possible by a telescopic construction. The relevant in the context of the invention vehicles usually have either one or two such Abstützverbreiterungen with two support legs.
According to EN 12999 an overload protection is required for loader cranes with capacities over 1000 kg. According to this standard, the corresponding stability test is carried out with a test load equivalent to 125% of the stated load capacity. It is important that at least one wheel braked by a (usually manually operated) parking brake must remain on the ground. In this case, the loading crane is in a so-called partially raised state. The at least one braked by means of a parking brake wheel, which must remain on the ground, acts as an additional friction point and serves to absorb horizontal forces.
It is known that the load moment limitation for the overload protection according to EN 12999 is solved by adjusting the lifting capacity in the crane hydraulics. For crane work with laterally not fully extended support elements and / or boom positions above the cab additional Hubkraftbegrenzungen be made. Map-based lifting capacity adjustments are state of the art.
In such system solutions, however, the high adjustment and testing costs are assessed as disadvantageous. The risk of incorrect settings exists. In addition, no payloads are considered. In order to avoid these disadvantages, preferably effects of the crane work on the entire machine are to be sensed. For truck-mounted concrete pumps, there are solution approaches that are aimed in this direction. By way of example, patent specification DE 103 49 234 A1 may be mentioned in this connection. Here, the support forces in the support legs are determined to monitor the stability and charged to a stability number. However, truck-mounted concrete pumps are in a fully raised condition during their operation, i. that none of the wheels touches the ground. The solutions used for truck-mounted concrete pumps are thus not suitable for the relevant in the context of the present invention loading cranes, which must comply with EN 12999.
Therefore, the object of the invention is to avoid the disadvantages described above and to provide a comparison with the prior art improved solution for stability control of a vehicle mounted on a loading crane.
This object is achieved by the features of the two independent claims 1 and 18.
One of the basic ideas of the invention is thus that not only the contributions of the supporting elements, but also the contributions of the wheels to the size of at least one stability parameter are detected and this quantity is compared with at least one predetermined limit value.
Advantageously, depending on whether the at least one predetermined limit value is an upper or lower critical limit, at least one warning signal (to the operator of the crane) is output and / or at least if the limit value is exceeded or undershot a measure to restore the limit is carried out. These include in particular correction movements of the boom system.
Since the stability that can be achieved by the commonly used supporting elements is not the same in every subarea of the theoretically conceivable working space of the cantilever system and the supporting elements under certain working conditions, e.g. On cramped construction sites, can not be fully extended, it is also advantageous if a rotation angle ordes loading crane is detected about a vertical axis and / or an extended state of the support elements. In this case, it is possible to monitor the at least one stability parameter depending on the angle of rotation a and / or the extension state of the support elements. By detecting the extended state of the support elements, the relative position of the support elements with respect to the vehicle is known. When the support elements are - as described above - vertically extendable support legs, which are mounted on a laterally extendable Ausstützverbreiterung in the horizontal direction acts, to the detection of the extended state of the support elements both the detection of the distance by which the Abstützverbreiterung is extended, as well as the detection of the distances by which the support legs are extended.
In preferred embodiments, as a stability parameter, the number a of the wheels and support elements, via which the vehicle is supported on the ground, and / or the force-stability coefficient Sf is monitored, Sf being calculated from the support forces F, provided via the wheels and the support elements. The calculation of Sf preferably takes place according to the following formula:
where, the total number of wheels and support members, n, n is a predetermined minimum number of wheels and support elements over which the vehicle must be supported at least on the ground, and F, rmax indicate the (am / r, -1) largest support forces. Sp is a dimensionless variable that has the following effect: Assuming that the vehicle can be supported by two front and two flywheels and a laterally extended support widening with two support elements on the ground, i. it would apply = 6. Furthermore, suppose that a lazy condition in which the vehicle threatens to tip over exists when the vehicle is only on a front and a rear wheel and a support element, wherein the front and the rear wheel and the support member on the same Vehicle side, it would have to demand that in the operating state at any time the limit value,> 4, is not reached, so as not to reach this unstable state. The advantage of the force-stability coefficient Sf is that with its help it is very easy to monitor compliance with this preset limit value by making sure that the value of SF - calculated according to the above formula - is always greater than one. In the case of the labile state, i. in the case of only three support points, namely the force sum in the denominator would take the same value as the force sum in the counter, since it is the three only three support forces then different from zero support forces.
In the event that the vehicle via two front wheels and two, in particular designed as twin wheels, rear wheels and two laterally extendable Abstützverbreiterungen with two support elements on the ground is supported and the angle of rotation a of the loading crane is detected about a vertical axis and the extended state of the support elements, It is advantageous if, in laterally fully extended Abstützverbreiterungen depending on the angle of rotation a of the loading crane ami "-6 or am / n = 5 and is selected at the side not fully extended Abstützverbreiterungen 3min-Q.
In the event that the vehicle via two front wheels and two, in particular designed as twin wheels, rear wheels and a laterally extendable Abstützverbreiterung with two support elements on the ground is supported and the angle of rotation «of the loading crane is detected about a vertical axis and the extended state of the support elements, is It is advantageous if, with laterally fully extended outrigger broadening depending on the angle of rotation a of the loading crane am / n = 6 or amin = 4 and at laterally not fully extended Abstützverbreiterung am / n = 6 is selected.
It should be noted that by adhering to the limit values for amine mentioned in the last two sections, the standard mentioned in the introduction, which is mentioned in the introduction, is automatically met, provided that all wheels can be braked by a parking brake.
If the support forces F, provided via the wheels, are detected, then it is also advisable to additionally monitor the axle loads in the course of the stability monitoring, since they are very easily generated from the corresponding support forces F; can be calculated (by summation). The axle load is the proportion of the total mass (net mass and mass of the load of a vehicle) that is allocated to an axle (a wheel set) of that vehicle.
It is particularly advantageous to determine the supporting forces F, provided via the wheels, via a measurement of rebound distances (of the wheel suspensions). For this purpose, it is advantageous to determine for each of the wheels once a Entfederungskennlinie (Entfederungsweg as a function of the supporting force). Subsequently, these characteristics can be used at any time for a conversion of the measured Entfederungswege in supporting forces. The maximum possible Entfederungsweg corresponds to the way in which a wheel lifts off the ground and the support provided by this wheel assumes the value zero. This approach is particularly suitable for vehicles that have leaf springs with a linear spring characteristic. In other types of suspensions one could e.g. For the sake of simplicity, also the measured lengths L, · convert the vibration damper of the wheels directly into a length stability coefficient SL, and monitor the value of SL. The calculation of Sz. Preferably takes place according to the following formula:. M1. | , ^ border, i ~ " V i jnax i = l where rges is the total number of wheels, rmm a predetermined minimum number of wheels over which the vehicle must be supported at least on the ground, Lresf, the residual lengths of the vibration damper until the wheels lift off, Lgremj the limit lengths of the vibration damper, where the wheels lift off the ground, and Lresu.max specify the (rmin-1) largest residual lengths of the vibration dampers. As in the case of the force-stability coefficient Sf, it would then be possible during the stability monitoring to make sure that the value of Sl is always greater than one.
A further advantageous embodiment is that the extended state of the support elements is detected, and based on that, the possible tilting edges Ky of the vehicle are calculated in crane operation.
If, in addition, one calculates the distances / / wheels and supporting elements to the tilting edges K, and at the same time detects the angle of rotation a of the loading crane about a vertical axis and the supporting forces F provided by the wheels and the supporting elements, then it is possible to Depending on the angle of rotation a of the loading crane with respect to the currently relevant tilting edge Ka as a stability parameter to monitor the residual state moment Mrest.Ka, whereby Mrest.Ka can be calculated according to the following formula:
which in turn indicates the total number of wheels and support elements.
Protection is also desired for a device for monitoring at least one stability parameter of a loading crane mounted on a vehicle, whereby the vehicle can be supported on the ground by wheels and by supporting elements separate from the wheels, characterized in that the device comprises: wheel and Abstützefement-measuring devices by which both contributions of the wheels and contributions of the support elements to the size of the at least one stability parameter can be detected, and - a control and regulation unit, which measurement signals of the wheel and support element measuring devices can be supplied, wherein by the control and Control unit determines a size of the at least one stability parameter and is comparable to at least one predetermined limit.
The at least one stability parameter may in turn-just as described in connection with the method according to the invention-be the number a of wheels and support elements, over which the
Vehicle is supported on the ground and / or the force-stability coefficient Sf and / or the residual state moment MrestKa act as a function of the angle of rotation a of the loading crane with respect to the currently relevant tilting edge Ka.
Advantageously, at least one warning signal can be generated by the control and regulation unit when the at least one predetermined limit value is exceeded or fallen short of, and / or at least one measure for restraining the at least one predetermined limit value can be controlled. The warning signal may be transmitted by the control unit e.g. generated in the form of an electrical pulse sequence and then converted by means of warning lights and / or speakers in an optical and / or acoustic signal. The at least one measure for restoring the at least one predetermined limit value can be stored, for example, as a programmed course of action in the control and regulation unit. In the simplest case, the course of action is a stop process by which crane operation is stopped.
It is also advantageous if the device has a rotation angle measuring device for detecting a rotation angle of the loading crane about a vertical axis and / or an extended state measuring device for detecting an extended state of the supporting elements, wherein the measurement signals of the rotational angle and / or the extended state Measuring device (eg via corresponding signal lines or by wireless transmission) of the control unit can be fed. In the event that the support elements are support legs mounted on a laterally extendable support widening and that all non-variable parameters (such as the mounting position of the support extension on the vehicle frame) are known and stored in the control unit to determine the position of the support elements relative to the vehicle, it is only necessary to detect the extension lengths of the support widening and the support legs with the aid of the extended state measuring device. In the event that the support elements are arranged on at least one laterally extendable Abstützverbreiterung and the loading crane resting on a crane base, which is connected to the at least one Abstützverbreiterung, rests, it is advantageous, the Abstützelement-measuring devices in the support elements and / or «« TM · · ·
»T» »A m« »· 8 * at the connection of the supporting elements to the supporting widening and / or to the connection of the supporting widening with the crane base.
In a preferred embodiment, the support forces F, which are provided via the wheels and the support elements, can be detected by the wheel and support element measuring devices. This is in the case of the supporting forces F, e.g. possible because the support element measuring devices are designed as load cells. In the case of the wheels, the measurement of the supporting forces F can be carried out, for example, by measuring deflection distances (of the wheel suspensions) or lengths Li of the vibration absorbers (for example by means of cable length sensors) or by measuring the tire internal pressures. Furthermore, it is conceivable to realize a Radkraftmessung by means of strain gauges near the axis ends. If the supporting forces F-detected via the wheels are detected, then it is advisable (as already described above) to monitor the axle loads in the course of stability monitoring - with the aid of the control and regulation unit - since they are very stable Simply calculate from the corresponding support forces (by summation).
Further exemplary embodiments are characterized in that (in the case of a known position of the position of the support elements relative to the vehicle) the tilting edges of the vehicle in crane operation and, in addition, the distances of the wheels and support elements to the tilting edges Kj can be calculated by the control and regulation unit. Under this condition, it is then possible (as described above) to monitor the remaining stall torque Mrest, Ka as the stability parameter.
Further details and advantages of the present invention will be explained with reference to the figure description with reference to the embodiments illustrated in the drawings. Showing:
1 is a schematic representation of an embodiment of a vehicle on which a loading crane is mounted and which is relevant to the present invention,
2 shows a model of the vehicle shown in FIG. 1, in which some of the parameters relevant to the stability monitoring are shown,
Fig. 3a, 3b, 4a, 4b limit value representations for the minimum number of wheels and
Supporting elements, via which the vehicle must be supported in different embodiments at least on the ground, in dependence on the angle of rotation α of the loading crane and the extended state of the supporting elements,
5 shows an exemplary course of the force
Stability coefficient SF as a function of the angle of rotation α of the loading crane and
Fig. 6 is a schematic representation of a possible
Vibration damper of a wheel.
1 shows schematically one of the examples of a vehicle 1 on which a loading crane 2 is mounted and whose stability can be monitored by means of the method according to the invention or the device according to the invention. In this case, the vehicle 1 via two front wheels 3a and four formed as a twin wheels rear wheels 3b and a laterally extendable Abstützverbreiterung 5 with two support elements 4 can be supported on the ground. Also visible are one of the axles 6 of the vehicle 1, a part of the vehicle frame 9, a control and regulation unit 7 and the crane base 8 of the loading crane 2. Not visible are the wheel, support element, rotation angle and extension state measuring devices. as these partially in certain vehicle components - such as in the case of the support element measuring devices in the support legs 4 - are integrated or hidden by other vehicle components.
FIG. 2 shows a model of the vehicle 1 shown in FIG. 1 in plan view.
In this model, the support points on the ground (black and white circles), the position of the crane base 8, which at the same time defines the intersection of the vertical axis about which the loading crane 2 can be rotated, with the horizontal vehicle level, one of the in this state possible tilting edges Ka and the distances / "*" of the support points (wheels 3a and 3b and support elements 4) to the tilting edge Ka drawn. The model further includes a definition of the angle of rotation α of the loading crane 2 about the vertical axis. It should be noted that the wheels 3a and 3b are in reality not support points, but support surfaces. In the first food was here but assumed from support points.
FIGS. 3 a, 3 b, 4 a and 4 b show preferred limit values for the minimum number of wheels 3 a and 3 b and support elements 4 over which the vehicle 1 must be supported in different embodiments at least on the ground, depending on the angle of rotation α of the loading crane 2 and the Extended state of the support elements 4 shown. The reference numerals are representative of this group of figures only in the Fig, 3a given, Figures 3a and 3b refer to the case that the vehicle 1 maximum two front wheels 3a and two formed as a twin wheels rear wheels 3b and two laterally extendable Abstützverbreiterungen 5 respectively two support elements 4 can be supported on the ground. In this case, it is advantageous if at laterally fully extended Abstützverbreiterungen 5 (Fig. 3b) at a rotation angle a of the loading crane 2 between about 225 ° and 315 ° amin-6 or amin = 5 and laterally not fully extended Abstützverbreiterungen 5 (Fig. Fig. 3a) is always am / n = 6 is selected to ensure the stability of the vehicle 1 in crane operation. If, however, the vehicle has only one laterally extendable support widening 5 with two support elements 4, then it is advantageous for laterally fully extended support widenings 5 (FIG. 4b) for a rotation angle of the loading crane 2 between approximately 225 ° and 315 °, -6 or amm = 4 and in the case of laterally not fully extended support spacers 5 (FIG. 4a), select "6".
FIG. 5 shows an exemplary profile of the force stability coefficient Sf as a function of the rotational angle α of the loading crane 2. This course results approximately in the situation illustrated in FIG. 3b. It is very clear that the value of SF between approximately 225 ° and 315 ° assumes an absolute minimum. Here is the loading crane 2 or the boom system above the driver's cab. To ensure stability, it is therefore advantageous to require am / n = 6 for this angular range. · * · · »* · ·» ♦ t * * * * * * * * «« «» «« t · · · • * w «4« * · «·» ··
6 shows a schematic representation of a possible vibration damper 10 of one of the wheels 3a and 3b. Dashed lines the position of the vibration damper 10 is located, in which the wheel would lift off the ground. Furthermore, the relevant for the calculation of the longitudinal stability coefficient SL sizes and Lgrenzj are drawn.
Innsbruck, on April 7, 2011

权利要求:
Claims (27)
[1]
1. A method for monitoring at least one stability parameter of a loading crane (2) mounted on a vehicle (1), wherein the vehicle (1) is in crane operation via wheels (3a, 3b) and via the wheels (3a, 3b) separate supporting elements (4) is supported on the ground, characterized in that both contributions of the wheels (3a, 3b) and contributions of the supporting elements (4) to a Size of the stability parameter can be detected and this size is compared with at least one predetermined limit.
[2]
2. The method according to claim 1, characterized in that at overshoot or undershooting of the at least one predetermined limit value issued at least one warning signal and / or at least one measure for restoring the at least one predetermined limit value is performed.
[3]
3. The method according to claim 1 or 2, characterized in that a rotation angle {a) of the loading crane (2) about a vertical axis and / or an extended state of the supporting elements (4) is detected.
[4]
4. The method according to claim 3, characterized in that the at least one stability parameter depending on the angle of rotation {a) of the loading crane (2) and / or the extended state of the supporting elements (4) is monitored.
[5]
5. The method according to any one of claims 1 to 4, characterized in that as a stability parameter, a number (a) of the wheels (3a, 3b) and supporting elements (4), via which the vehicle (1) is supported on the ground, is monitored.
[6]
6. The method according to any one of claims 1 to 5, characterized in that as a stability parameter, a force-stability coefficient ($ F) is monitored, wherein the force-stability coefficient (SF) from the wheels (3a, 3b) and the support elements (4 ) provided supporting forces (Fl) is calculated.
[7]
7. The method according to claim 6, characterized in that the force-stability coefficient (S / =) is calculated according to the following formula:

wherein (e) indicates a total number of wheels (3a, 3b) and supporting elements (4), (a, ") a predetermined minimum number of wheels (3a, 3b) and supporting elements (4) over which the vehicle (1) at least on Must be supported and indicates (F /, max) the (amin ~ 1) largest support forces.
[8]
8. The method of claim 7, wherein the vehicle (1) via two front wheels (3a) and two, in particular designed as twin wheels, rear wheels (3b) and two laterally extendable Abstützverbreiterungen (5), each with two support elements (4) is supportable on the ground and the angle of rotation (a) of the loading crane (2) about a vertical axis and the extended state of the supporting elements (4) is detected, characterized in that at laterally fully extended Abstützverbreiterungen (5) depending on the angle of rotation (a) of the loading crane (2) , n = 6 or am, n = 5 and amjn = Q is selected for laterally not fully extended support extensions (5).
[9]
9. The method of claim 7, wherein the vehicle (1) via two front wheels (3a) and two, in particular designed as a twin wheels, rear wheels (3b) and a laterally extendable Abstützverbreiterung (5) with two support elements (4) is supported on the ground and the rotation angle («) of the loading crane (2) about a vertical axis and the extended state of the supporting elements (4) is detected, characterized in that at laterally fully extended support widening (5) depending on the angle of rotation (a) of the loading crane (2) 6 or am-m-4 and with side support not fully extended (5) amin = 6 is selected.
[10]
10. The method according to any one of claims 1 to 9, wherein the wheels (3a, 3b) of the vehicle (1) on axes (6) are arranged, characterized in that axle loads are monitored, the axle loads from the on the wheels (3a , 3b) provided supporting forces {Fi) are calculated.
[11]
11 Method according to one of claims 6 to 10, characterized in that the support forces (Fi) provided via the wheels (3a, 3b) are determined via a measurement of rebound distances.
[12]
12. The method according to any one of claims 1 to 11, characterized in that lengths (Li) of vibration dampers (10) of the wheels (3a, 3b) are detected and that a length-stability coefficient (SO is monitored, wherein the length stability coefficient ( SO is calculated from the measured lengths (L,).
[13]
13. The method according to claim 12, characterized in that the length stability coefficient (SO is calculated according to the following formula: C - '=! _ • mm * 1-1 with Lr £ n, ^ gren:,:' where () a Total number of wheels (3a, 3b) indicates (rm / 0 indicates a predetermined minimum number of wheels (3a, 3b), over which the vehicle (1) must be supported at least on the ground, (Lresii) remaining lengths of the vibration damper (10) indicate (Lgren2ii) limit lengths of the vibration dampers (10) at which the wheels (3a, 3b) lift off the ground, and (Lresf, /, max) the (w1) largest Specify residual lengths of the vibration dampers (10).
[14]
14. The method according to claim 7 to 13, characterized in that in crane operation, a condition SF> 1 and / or a condition Si> 1 is maintained.
[15]
15. The method according to any one of claims 1 to 14, characterized in that tilting edges (K}) of the vehicle (1) are calculated in crane operation.
[16]
16. The method according to claim 15, characterized in that distances (// _ *,) of the wheels (3a, 3b) and supporting elements (4) to the tilting edges (K;) are calculated.
[17]
17. The method according to claim 16, wherein the angle of rotation (a) of the loading crane (2) is detected about a vertical axis and on the wheels (3a, 3b) and the supporting elements (4) provided supporting forces (F,) are determined by in that, depending on the angle of rotation (or) of the loading crane (2) with respect to a current tilting edge (Ka), a residual stability torque (MKSt, Ka) is monitored as a stability parameter, the residual moment of inertia (Μ "& κα) being Formula is calculated:

where (total) indicates the total number of wheels (3a, 3b) and supporting elements (4).
[18]
18. Device for monitoring at least one stability parameter of a loading crane (2) mounted on a vehicle (1), wherein the vehicle (1) in crane operation via wheels (3a, 3b) and via the support elements (4, 4) separated from the wheels (3a, 3b) ) is supportable on the ground, characterized in that the device comprises: - Rad- and support element measuring devices, by which both contributions of the wheels (3a, 3b) and contributions of the support elements (4) to the size of the at least one stability parameter can be detected and - a control and regulating unit (7) to which measurement signals of the wheel and support element measuring devices can be supplied, wherein a size of the at least one stability parameter can be determined by the control and regulation unit (7) and compared to at least one predetermined limit value.
[19]
19. The apparatus according to claim 18, characterized in that at least one warning signal can be generated by the control and regulation unit (7) in case of exceeding or falling below the at least one predetermined limit and / or at least one measure for restoring the at least one predetermined limit is controllable ,
[20]
20. The apparatus of claim 18 or 19, characterized in that the device comprises a rotation angle measuring device for detecting a rotation angle (a) of the loading crane (2) about a vertical axis and / or an extended state measuring device for detecting an extended state of the supporting elements (4 ), wherein measurement signals of the rotational angle and / or the extended state measuring device of the control and regulating unit (7) can be fed.
[21]
21. Device according to one of claims 18 to 20, wherein the support elements (4) are arranged on at least one laterally extendable Abstützverbreiterung (5) and the loading crane (2) on a crane base (8), which with the at least one Abstützverbreiterung (5). is connected, rests, characterized in that the support element measuring means in the support elements (4) and / or at a compound of the support elements (4) with the Abstützverbreiterung (5) and / or at a compound of Abstützverbreiterung (5) with the crane base (8) are arranged.
[22]
22. Device according to one of claims 18 to 21, characterized in that on the wheels (3a, 3b) and the supporting elements (4) provided supporting forces (F,) can be detected by the wheel and support element measuring devices.
[23]
23. The device according to claim 22, characterized in that the over the wheels (3a, 3b) provided supporting forces (F,) are detectable via a measurement of Entfederungswegen. * * * * * * * * * * * * * * * * * * * * * * * * * * T * «$ * Ψ * * MO *
[24]
24. Device according to one of claims 18 to 23, characterized in that by the wheel-measuring devices lengths (Lj) of vibration dampers (10) of the wheels (3a, 3b) are detectable.
[25]
25. Device according to one of claims 18 to 24, characterized in that by the control and regulating unit (7) tilting edges (Ky) of the vehicle (1) are calculable in crane operation.
[26]
26. The apparatus according to claim 25, characterized in that by the control and regulating unit (7) distances (Α, κ;) of the wheels (3a, 3b) and supporting elements (4) to the tilting edges (Kj) are computable.
[27]
27 vehicle (1) on which a loading crane (2) is mounted and the wheels (3a, 3b) and extendable support elements (4), characterized in that the vehicle (1) comprises a device according to one of claims 18 to 26 having. Innsbruck, on April 7, 2011

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EP3470362A1|2019-04-17|

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RU2013149870A|2015-05-20|

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BR112013025008A8|2018-03-13|

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RU2597043C2|2016-09-10|

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法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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AT5002011A|AT511234B1|2011-04-08|2011-04-08|STAND SAFETY MONITORING OF A LOADING CRANE MOUNTED ON A VEHICLE|AT5002011A| AT511234B1|2011-04-08|2011-04-08|STAND SAFETY MONITORING OF A LOADING CRANE MOUNTED ON A VEHICLE|

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EP18207557.2A| EP3470362A1|2011-04-08|2012-04-05|Method and device for monitoring the stability of a loading crane mounted on a vehicle|

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RU2013149870/11A| RU2597043C2|2011-04-08|2012-04-05|Method and device for monitoring stability of loading crane installed on vehicle|

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AU2012239830A| AU2012239830B2|2011-04-08|2012-04-05|Method and device for monitoring the stability of a loading crane mounted on a vehicle|

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BR112013025008A| BR112013025008A8|2011-04-08|2012-04-05|method and device for the stability monitoring of a cargo crane mounted on a vehicle|

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CN201280015623.5A| CN103476699B|2011-04-08|2012-04-05|Monitoring is arranged on the method and apparatus of the stability of the stevedoring crane on vehicle|

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EP12721693.5A| EP2694426A1|2011-04-08|2012-04-05|Method and device for monitoring the stability of a loading crane mounted on a vehicle|

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PCT/AT2012/000092| WO2012135882A1|2011-04-08|2012-04-05|Method and device for monitoring the stability of a loading crane mounted on a vehicle|

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US14/047,388| US8874329B2|2011-04-08|2013-10-07|Method and device for monitoring the stability of a loading crane mounted on a vehicle|