ES2494741T3 - Lifting vehicle - Google Patents

Abstract

Lifting vehicle, comprising - a self-propelled chassis (12) having a front axle (14) and a rear axle (16), - a telescopic boom (18) articulated to the chassis (12) and provided with a fixing (22) for assemble equipment (60), - at least one lifting / lowering cylinder (24) arranged between the telescopic boom (18) and the chassis (12), - a hydraulic control circuit (30) that includes a hydraulic distributor (36) connected to said lifting / lowering cylinder (24), - a control system (48) associated with said hydraulic control circuit (30), - a load sensor (52) adapted to detect the load applied to said boom (18 ), - a length sensor (56) adapted to detect the extension length (L) of said telescopic boom (18), - an angle sensor (54) adapted to detect the elevation angle (α) of said telescopic boom (18), - means (56, 64) for providing information on the type of equipment (60) applied to said p luma (18), and - an electronic control unit (50) that receives information provided by the load sensor (52), the length sensor (56), the angle sensor (54) and information on the type of equipment (60) applied to the boom (18), in which the electronic control unit (50) is programmed to define a load diagram that defines a real work area (AEFF) of the boom (18), characterized in that the Electronic control unit (50) is programmed to divide said load diagram into a plurality of real work sub-zones (AEFF1, AEFF2, AEFF3, AEFF4, AEFF5) depending on the type of equipment (60), the load (P) applied to the boom (18), having the length (L) and angle (α) of the boom (18), said real working subzones (AEFF1, AEFF2, AEFF3, AEFF4, AEFF5) different maximum boom descent speeds (18). Being the electronic control unit (50) also programmed to act on a discharge valve (46) to thereby limit the maximum boom descent speed (18) depending on the actual working sub-zones (AEFF1, AEFF2, AEFF3, AEFF4, AEFF5) in which the pen (18) works.

Description

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DESCRIPTION

Lifting vehicle

Field of the Invention

The present invention relates to a lift vehicle, comprising:

 a self-propelled chassis  a telescopic boom articulated to the self-propelled chassis and equipped with a connection for mounting equipment, and  at least one lifting / lowering cylinder arranged between the telescopic boom and the chassis.

Description of the prior art

Lift vehicles of this type may be equipped with different types of equipment, such as forks, shovels, aerial platforms, etc. During operation, the load applied to the equipment located at the end of the telescopic boom may vary within very wide intervals.

One of the fundamental safety elements of a lift vehicle is its stability with respect to longitudinal overturning.

Normally, the vehicle is equipped with a load diagram that indicates the maximum load that can be applied at the end of the lifting boom depending on the position of the equipment.

EP-A-1312579 discloses a lift vehicle according to the preamble of claim 1, wherein an electronic control system generates an electronic load diagram and shows in the electronic load diagram a cursor located in the working position of the pen. However, compliance with the load diagram is left to the operator.

Typically, vehicles with a telescopic boom are equipped with a roll-over safety system that blocks or reduces the speed of movement of the boom when the rear axle load falls below a predetermined reference threshold. In fact, reducing the load on the rear axle below a critical threshold indicates that the vehicle is near a rollover condition. An example of such a rollover system is disclosed in EP-A-1897847.

A problem with known solutions is that the roll-over safety system of the known type is not a sufficient guarantee of safety under dynamic conditions. The anti-tip system of vehicles of known type is essentially intended for safety against longitudinal overturning in static conditions. If the roll-over safety system locks the boom during lowering of the boom at high speed, inertial force can cause the vehicle to tip over.

The situation is even more complex because the risk conditions vary considerably depending on the type of equipment used by the vehicle.

Object and summary of the invention

The present invention is directed to provide an elevator vehicle with increased safety against longitudinal tipping in dynamic conditions.

According to the present invention, this object is carried out by a vehicle having the characteristics that constitute the object of the claims.

The claims form an integral part of the teachings provided with respect to the invention.

Brief description of the drawings

The present invention will now be described in detail with reference to the accompanying drawings, provided merely by way of non-limiting example, in which:

-Figure 1 is a perspective view of a telescopic boom lift vehicle,

- Figure 2 is a schematic diagram of the control circuit of the vehicle boom of Figure 1; Y

- Figures 3 and 4 show two load diagrams of the lift vehicle with different loads and that indicate

intervals with different maximum speeds of descent of the telescopic boom.

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Detailed description of the embodiments of the invention

With reference to Figure 1, the number 10 designates a lifting vehicle comprising a self-propelled chassis 12 having a front axle 15 and a rear axle 16. The vehicle 10 comprises a telescopic boom 18 articulated in the rear section of the chassis 12 around a transverse axis 20. The telescopic boom 18 is equipped at one end with a fixing 22 for the connection of different types of equipment.

The vehicle 10 comprises at least one lifting / lowering cylinder 24 with ends articulated to the chassis 12 and the boom 18 around respective axes 26, 28. The boom 18 is also equipped with a cylinder (not shown) that controls the telescopic movements of extension and retraction of the pen.

With reference to Figure 2, the vehicle 10 has a hydraulic control circuit 30 that includes a main pump 32 driven by the thermal engine 34 of the vehicle. The hydraulic circuit 30 comprises a hydraulic distributor 36 that receives pressurized fluid from the pump 32 and controls the hydraulic cylinder 24 via a hydraulic feed line 38. The distributor 38 is connected to a reservoir 40 through the discharge line 42.

The hydraulic control circuit 30 comprises an electrically controlled blocking valve 44, arranged in the supply line 38. When the blocking valve 44 is activated, it blocks the movements of the boom 18 that increase the risk of return (descent and extension).

The hydraulic control circuit 30 also includes an electrically controlled discharge valve 46. The discharge valve 46 is adapted to limit the maximum boom descent speed 18. The boom descent speed 18 is controlled by the operator through the distributor 36. The discharge valve 46 limits the maximum fluid flow rate in the command line 38 and consequently limits the maximum descent speed of the pen 18 depending on the electrical control signal it receives.

Again with reference to Figure 2, the vehicle 10 includes a control system 48 that controls, among other things, the blocking valve 44 and the discharge valve 46. The control system 48 comprises a programmed electronic control unit 50 to control the discharge valve 46 depending on the position of the boom 18, the load applied to it and the type of equipment applied to it.

The control system 48 includes a load sensor 52 that provides an indication of the intensity of the load applied to the boom 18. The load sensor 52 can be, for example, a load cell applied to the lift / lower cylinder 24 The control system 48 comprises sensors 54, 56 that detect, respectively, the angle of inclination of the boom 18 and the extension length L of the telescopic portion of the blade 18 (boom extension). The control system 48 also comprises a recognition unit 58 adapted to recognize the type of equipment 60 applied to the pen 18. The recognition unit 58 may, for example, be based on RFID technology.

The control system 48 further comprises one or more sensors 62 to detect the load on the rear axle 16 of the vehicle. Also, a plurality of selectors 64, 66 can be provided which can be manually adjusted by the operator.

For example, a selector 64 can be provided, for the selection of the type of equipment 60 in the case where the recognition unit 58 does not automatically recognize the type of equipment 60 applied to the pen 18. A selector 66 can be provided which allows temporarily disable the operation of the blocking valve 44.

The electronic control unit 50 receives signals from the sensors 52, 54, 56, 62 of the recognition unit 58 and the selectors 64, 66, in addition to any information from other sensors or other selectors that may be present in the vehicle .

The electronic control unit 50 is programmed to control the discharge valve 46 to thereby limit the maximum descent speed of the boom 18 according to the type of equipment 60, the load on the boom 18, the length L and the angle α of the pen 18.

The electronic control unit 50 limits the maximum boom descent speed with respect to the absolute maximum speed, to ensure that the vehicle operates in stable conditions with respect to the risk of longitudinal turning even in dynamic conditions. In particular, the limitation on the maximum speed of descent of the boom 18 allows to keep the vehicle in safe conditions during the maneuver of descent of the boom 18, which is the most critical condition from the point of view of the risk of longitudinal tipping.

Figures 3 and 4 show as an example two load diagrams of the vehicle 10 with a different load P applied to the boom 18. The load diagram of Figure 3 shows the working range of the vehicle 10 with a

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P1 load of 1,500 kg and the diagram in Figure 4 shows the working range of the same vehicle with a P2 load of 3,400 kg. In Figures 3 and 4, the diagrams referring to a vehicle operating with the forks 68 are shown. The load diagrams of the vehicle 10 vary depending on the type of equipment applied to the boom and depending on the load applied to the pen.

In Figures 3 and 4, AMAX indicates the maximum working area of the pen 18, which represents the geometric coverage area of the pen 18. In the same AEFF diagrams it indicates the actual working area with the load P1 or P2. The actual work zone is reduced compared to the maximum work zone with the increase in the P load. The maximum AMAX work zone corresponds to the conditions under which the load P applied to the boom is zero.

The real AEFF work zone is divided into work sub-zones with different maximum descent speeds, indicated with AEFF1, AEFF2, AEFF3, AEFF4 and AEFF5. The electronic control unit 50 limits the maximum descent speed of the boom 18 in different ways according to the different subzones. In the example illustrated in Figures 3 and 4 in the working sub-area AEFF1 the maximum boom descent speed is 100%, this means that in this subzone there is no limitation of the maximum boom descent speed and that the descent speed is equal to the maximum possible speed. In the graph of Figure 3, the AEFF1 subzone defines a working interval in which the maximum speed of descent of the boom 18 is equal to 75% of the maximum speed. In the sub-areas AEFF3, AEFF4 and AEFF5 the maximum boom descent speed 18 is, respectively, 50%, 25% and 10% with respect to the maximum speed.

In the graph in Figure 4, the AEFF2 work zone has a maximum boom down speed of 50% with respect to the maximum speed it has in the AEFF1 zone. The working sub-areas AEFF3 and AEFF4 respectively have maximum boom down speeds of 25% and 10%. Outside the AEFF work zone the boom descent speed is zero. If the vehicle is operating outside the real AEFF work area for loading conditions and for the type of equipment installed, the operator should reduce the length of the boom to return to the conditions in which a maneuver speed is possible of the pen.

As stated above, the diagrams in Figures 3 and 4 vary depending on the load P and depending on the type of equipment installed in the vehicle. These diagrams also vary depending on the type of vehicle. The diagrams of Figures 3 and 4 have been provided simply for guidance to understand, at a qualitative level, the operation of the system according to the invention. The actual work areas for the type of vehicle, for the type of equipment installed and for the different loads P are determined experimentally in order to keep the vehicle 10 in conditions of dynamic stability with respect to the risk of longitudinal turning during the maneuver lowering the boom 18.

Obviously, without prejudice to the principle of the invention, construction details and embodiments can vary greatly from what has been described and illustrated without departing from the scope of the invention defined in the following claims.

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Claims (3)

5 10 fifteen twenty 25 30 E12166815 08-20-2014 1.-Lifting vehicle, which includes  a self-propelled chassis (12) that has a front axle (14) and a rear axle (16),  a telescopic boom (18) articulated to the chassis (12) and provided with a mounting bracket (22) for mounting equipment (60),  at least one lifting / lowering cylinder (24) arranged between the telescopic boom (18) and the chassis (12),  a hydraulic control circuit (30) that includes a hydraulic distributor (36) connected to said cylinder of raise / lower (24),  a control system (48) associated with said hydraulic control circuit (30),  a load sensor (52) adapted to detect the load applied to said pen (18),  a length sensor (56) adapted to detect the extension length (L) of said telescopic boom (18),  an angle sensor (54) adapted to detect the elevation angle (α) of said telescopic boom (18),  means (56, 64) to provide information on the type of equipment (60) applied to said pen (18), and  an electronic control unit (50) that receives information provided by the load sensor (52), the length sensor (56), angle sensor (54) and information on the type of equipment (60) applied to the boom (18), in which the electronic control unit (50) is programmed to define a load diagram defining a real work area (AEFF) of the boom (18), characterized in that the electronic control unit (50) is programmed to divide said load diagram into a plurality of real work sub-zones (AEFF1, AEFF2, AEFF3, AEFF4, AEFF5) depending on the type of equipment (60), the load ( P) applied to the boom (18), the length (L) and the angle (α) of the boom (18) having said real working subzones (AEFF1, AEFF2, AEFF3, AEFF4, AEFF5) different maximum descent speeds of the pen (18). Being the electronic control unit (50) also programmed to act on a discharge valve (46) to thereby limit the maximum boom descent speed (18) depending on the actual working sub-zones (AEFF1, AEFF2, AEFF3, AEFF4, AEFF5) in which the pen (18) works. 2.-Lift vehicle according to claim 1, characterized in that it comprises a recognition unit (58) adapted to detect the type of equipment (60) applied to the pen (18). 3. Lift vehicle according to claim 1, characterized in that it includes a selector (64) that can be manually adjusted to select the type of equipment (60) applied to the boom (18). 5