IT202100014852A1 - IMPROVED HYDRAULIC ASSEMBLY FOR HYDRAULIC ENERGY RECOVERY SYSTEMS IN WORK VEHICLES - Google Patents

Description

DESCRIPTION

of the patent for industrial invention entitled:

?IMPROVED HYDRAULIC ASSEMBLY FOR HYDRAULIC ENERGY RECOVERY SYSTEMS IN WORK VEHICLES?

TECHNICAL FIELD

The present invention ? relating to a hydraulic assembly, in particular to provide a functionality? of energy recovery in a work vehicle.

The present invention finds its preferred, though not exclusive, application in vehicles equipped with a hydraulically actuated arm.

BACKGROUND OF THE INVENTION

Work vehicles such as excavators, i.e. vehicles equipped with a hydraulically operated boom, can be equipped with so-called energy recovery systems.

Energy recovery systems are configured to reduce energy consumption during the movement of a boom controlled by a hydraulic actuator.

Indeed, when the boom is commanded to lower, the fluid discharged from the hydraulic actuator is retained for use when the boom is commanded to be raised.

Such systems include accumulators to allow storage of the fluid discharged from the actuator and a control block configured to manage the fluid flow between the accumulators and the actuator.

However, the accumulators and the control block require placement space that is not? negligible on working machines.

Consequentially, ? notes from US10167612B2 or CN102943496 the placement of the accumulators together with or in place of counterweights of the working vehicle.

However, this solution requires long high-pressure lines between the counterweights, which are usually arranged on the side opposite the arm, and the arm itself.

Furthermore, in the case of work vehicles more? light, the presence of the accumulators increases the weight of the work vehicle, thus increasing its fuel consumption and partially wastes the results that can be achieved thanks to the energy recovery system.

Therefore, there is a need to allow the use of an energy recovery system on a work vehicle without using additional space and without increasing weights on work vehicles.

An objective of the present invention ? meet the needs? above in an optimized and cost-effective manner.

SUMMARY OF THE INVENTION

The aforementioned object is achieved with a hydraulic assembly and work vehicle as claimed in the appended set of claims.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the present invention, a preferred embodiment is described below, by way of non-limiting example, with reference to the attached drawings in which:

? figure 1 ? a schematic perspective view of a work vehicle including a hydraulic assembly according to the present invention;

? figures 2A to 2D are schematic perspective views of respective alternative embodiments of the hydraulic assembly according to the invention; And ? figure 3 ? a hydraulic diagram of a hydraulic circuit of the working vehicle equipped with the hydraulic unit of the invention.

DETAILED DESCRIPTION OF THE INVENTION

Figure 1 depicts a work vehicle 1, for example an excavator, equipped with a body 2 carried by a frame 3 which ? mobile on the ground thanks to traction means 4, for example tracks.

The work vehicle 1 advantageously comprises an arm 5 configured to be operated via hydraulic actuators 6 controlled by a related hydraulic circuit (not shown for clarity) based on a control provided by a user of the vehicle 1.

Vehicle 1? equipped with an energy recovery system that ? hydraulically coupled to the 6 hydraulic actuators to provide functionality? of energy recovery.

The work vehicle 1 further comprises a hydraulic assembly 7 configured to be carried by the body 2.

The hydraulic unit 7 can? be advantageously arranged inside a housing 8 having a parallelepiped shape and configured to define a space in which to house the elements described below.

In particular, the hydraulic unit 7 has a compact size, suitable for replacing tanks already in use. existing on work vehicles to conserve hydraulic oil to allow the operation of all the vehicle's hydraulic circuits.

In particular, the hydraulic unit 7 has a width, X, a height, Y, and a thickness, Z which are sized in such a way that approximately 30-40% of the total oil volume of the working vehicle 1 can be stored in the tank and 70-60% of the oil volume is contained in the hydraulic circuits of the work vehicle 1.

For the purposes of the example, the following values can be determined for the following vehicle weights:

? 1800 kg vehicle X= 500 mm, Y=400 mm, Z=160 mm; ? vehicle of 13000 kg X= 525 mm, Y=870 mm, Z=380 mm; ? 20000 kg vehicle X= 790 mm, Y=900 mm, Z=513 mm; ? vehicle of 35000 kg X= 800 mm, Y=830 mm, Z=575 mm. Clearly, with the aforementioned width X, height Y and thickness Z reference is made to three mutually perpendicular axes, ie according to a Cartesian reference.

The hydraulic unit 7 comprises part of the energy recovery system, i.e. at least one accumulator 10, and a controller 12, and a tank 11 which are all connected at fluid level to each other and preferably arranged inside the housing 8.

Tank 11? configured to allow retention of purge oil for all hydraulic circuits of the work vehicle 1.

In Figures 2A to 2D four different exemplary embodiments are described.

In all exemplary embodiments, the tank 11 has a height and weight which occupy the entire respective space of the hydraulic assembly 7 while the thickness of the tank ? a part, half in the specific examples described, of the available thickness of the hydraulic unit 7.

According to a first embodiment, shown in figure 2A, the hydraulic unit 7 comprises a tank 11, a controller and three accumulators 10. In particular, the tank 11 extends over the entire height and width of the hydraulic unit 7 and half of the thickness of the hydraulic assembly 7. According to this embodiment, the controller 12 extends along the entire width of the hydraulic assembly 7 and occupies the remaining part of the thickness of the latter. The three accumulators 10 are housed vertically above the controller 12 and each extend the remaining part of the height of the hydraulic assembly 7. The three accumulators 10 are housed adjacent to each other in the width direction and are preferably designed as cylinders. On the direction of thickness are in contact with the tank 11.

According to a second embodiment, shown in Figure 2B, the hydraulic unit 7 comprises a tank 11, a controller 12 and three accumulators 10. In particular, the tank 11 extends over the entire height and width of the hydraulic unit 7 and half of the thickness of the hydraulic assembly 7. According to this embodiment, the controller 12 extends along only part of the width of the hydraulic assembly 7 and occupies the remaining part of the thickness of the latter. The three accumulators 10 are accommodated adjacent to each other in the width direction and are preferably designed as cylinders. On the thickness direction they are in contact with the tank 11. On the vertical direction, two of the accumulators 10 extend above the controller 12 occupying the remaining possible vertical extension while a third accumulator extends over the entire vertical extension of the hydraulic assembly 7 and ? adjacent to the controller 12. In particular, this third accumulator occupies, in width, the space not occupied by the controller 12.

According to a third embodiment, shown in Figure 2C, the hydraulic unit 7 comprises a tank 11, a controller 12 and two accumulators 10. In particular, the tank 11 extends over the entire height and width of the hydraulic unit 7 and half of the thickness of the hydraulic assembly 7. According to this embodiment, the controller 12 extends along only part of the width of the hydraulic assembly 7 and occupies the entire vertical extension of the latter. The three accumulators 10 are accommodated adjacent to each other in the width direction and are preferably designed as cylinders. Both accumulators 12 extend vertically along the entire vertical extension of the hydraulic assembly 7. According to the foregoing, one of the two accumulators 10 is adjacent to the controller 12 and in the width direction the two accumulators 10 occupy all the space remaining from the controller 12.

According to a fourth embodiment, shown in Figure 2D, the hydraulic unit 7 comprises a tank 11, a controller 12 and two accumulators 10. In particular, the tank 11 extends over the entire height and width of the hydraulic unit 7 and half of the thickness of the hydraulic assembly 7. According to this embodiment, the controller 12 extends along the entire width of the hydraulic assembly 7 and occupies the remaining part of the thickness of the latter. The two accumulators 10 are housed vertically above the controller 12 and each extend over the entire width of the hydraulic assembly 7 and vertically adjacent to each other. The two accumulators 10 are preferably designed as cylinders and in the thickness direction are in contact with the reservoir 11.

As shown schematically in Figure 3, the at least one accumulator 10 (three accumulators 10 are described by way of example) ? fluid level connected to the controller 12, reservoir 11 and hydraulic actuator 6.

In particular, the controller 12 comprises a loading module 12a and a balancing module 12b connected at a fluid level between the loading module 12a, the hydraulic actuator 6, the tank 11 and the accumulators 10. The loading module 12a and the balancing module 12b are configured to regulate the passage of fluid between accumulators 10, tank 11 and actuator 6 and can be made according to different hydraulic schemes according to the dimensions of the work vehicle 1.

In all possible embodiments, the hydraulic assembly 7 can also include a unit? control electronics, ECU, of the vehicle housed together with the controller 12.

The operation of the above hydraulic unit 7 according to the invention ? the following.

When the user gives a control to lower the arm 5, the actuators 6 are discharged to allow this lowering and the fluid flows to the accumulators 10 thanks to the action of the controller 12. Conversely, when the user gives a control to raise the arm 5, the actuators 6 are also recharged thanks to the accumulators 10 which are emptied thus saving energy.

During use of the vehicle 1, the tank 11 performs its reserve function of a quantity enough oil to allow the operation of all the hydraulic circuits of the vehicle 1.

In the light of the above, the advantages of a hydraulic assembly 7 according to the invention are evident.

The proposed hydraulic assembly 7 provides in a single compact space both the tank 11 of the vehicle and the energy recovery systems, i.e. the accumulators 10 and the controller 12.

In particular, the dimensions of the tank 11 have been optimized to minimize the quantity? of oil stored to guarantee the operation, in any condition, of the work vehicle and this reduction of space? was used to house the batteries and the energy recovery system controller.

In this way, the hydraulic connections between accumulators 10, controller 12 and tank 11 require short pipes thus reducing costs, weight and probability of of breakdowns.

In particular, the reduced space of the tank 11 with respect to the existing one allows the entire hydraulic unit 7 to be positioned in the space occupied by the known tank. In fact, the tank 11 has a volume that is approximately 50% smaller than existing tanks.

However, given that the oil is usually contained at 50% in the tank and 50% in the hydraulic circuits, in known work vehicles, the reduction of 50% and the new distribution of the oil between the tank and the hydraulic circuits does not affect the operation of the hydraulic circuits. In fact, the remaining volume of the tank ? sufficient to enable its storage function.

Consequently, isn't it? is it necessary that the hydraulic assembly 7 takes up more space in the vehicle and it can? also be supplied in existing vehicles as a kit.

Furthermore, the hydraulic unit 7 can? be easily mounted, thus reducing the cost of industrialization, and allows easy maintenance in the field since all components are easily accessible.

As mentioned, given that the hydraulic unit 7 pu? be housed in place of existing tanks, not ? no changes to the configuration or overall design of existing machines are required.

Furthermore, given that the accumulators 11 are arranged between the tank and the vehicle hoods and can be covered by a housing 8, the driver protected by the latter.

? clear what? It is possible to make modifications to the hydraulic assembly 7 described which do not extend beyond the scope of protection defined by the claims.

For example, as demonstrated, the accumulators 10 may be arranged in a different orientation with respect to the reservoir 11. It is possible to apply a similar consideration to controller 12.

Claims (13)

1. Hydraulic assembly (7) for a working vehicle (1) equipped with an energy recovery system, said hydraulic assembly (7) comprising a tank (11) configured to store hydraulic oil to be used by the hydraulic circuits of said work vehicle (1), at least one accumulator (10) and a controller (12), the accumulator (10) and controller (12) being part of the energy recovery system of said work vehicle (1) , said hydraulic assembly (7) extending over a width direction (X), a vertical direction (Y) and a thickness direction (Z), said tank (11) extending entirely on said width direction and said vertical direction (X, Y) and part of said thickness direction (Z), said at least one accumulator (10) and said controller (12) extending at least on the remaining part of said thickness adjacent to said tank (11) and at least on part of the space available on said width direction and said vertical direction (X, Y). The hydraulic assembly according to claim 1, further comprising a housing (8) defining a space for arranging said reservoir (11), said at least one accumulator (10) and said controller (12). The hydraulic assembly according to claim 1 or 2, wherein the width direction (X), the vertical direction (Y) and the thickness direction (Z) are dimensioned such that, for a specific vehicle weight, the 30%-40% of the total volume of oil of the work vehicle (1) can be contained in the tank (11) and the remaining 60%-70% of the volume of oil can be contained in the hydraulic circuits of said work vehicle (1 ). 4. Hydraulic assembly according to any one of claims 1 to 3, wherein: if the weight of said vehicle ? about 1800 kg, said extension in the width direction (X) ? 500 mm, said extension in the vertical direction (Y) ? 400 mm and said extension in the thickness direction (Z) ? 160mm; if the weight of said vehicle ? about 13,000 kg, said extension in the width direction (X) ? 525 mm, said extension in the vertical direction (Y) ? 870 mm and said extension in the thickness direction (Z) ? 513mm; if the weight of said vehicle ? about 20000 kg, said extension in the direction of width (X) ? 790 mm, said extension in the vertical direction (Y) ? 900 mm and said extension in the thickness direction (Z) ? 513mm; And if the weight of said vehicle ? about 35,000 kg, said extension in the width direction (X) ? 800 mm, said extension in the vertical direction (Y) ? 830 mm and said extension in the thickness direction (Z) ? 575mm. 5. Hydraulic assembly according to any one of the preceding claims, wherein said controller (12) extends throughout said vertical direction. 6. Hydraulic assembly according to any one of the preceding claims, wherein said at least one accumulator (10) extends over the whole of said vertical direction. The hydraulic assembly according to any one of the preceding claims, wherein said controller (12) extends across said width direction. The hydraulic assembly according to any one of the preceding claims, wherein said at least one accumulator (10) extends over the whole of said width direction. 9. Hydraulic assembly according to any one of the preceding claims, wherein said at least one accumulator (10) is laterally or vertically adjacent to said controller (12). 10. Hydraulic assembly according to any one of the preceding claims, wherein said at least one accumulator (10) is arranged above with respect to said controller (12). 11. Hydraulic assembly according to any one of the preceding claims, wherein said controller (12) integrates a unit? control electronics, ECU, of said work vehicle (1). 12. Work vehicle (1) comprising a body (2) movable on the ground and an arm (5) operated by a hydraulic actuator (6) and an energy recovery system comprising at least an accumulator (10) and a controller (12 ), said at least one accumulator (10) and said controller (12) being arranged in a hydraulic assembly (7) made according to any one of the preceding claims. 13. Work vehicle according to claim 12, wherein said hydraulic assembly (1) is integrated in said body (2).