The present disclosure relates to a pressurized medium assembly and to a method for controlling a pressurized medium assembly.
A pressurized medium assembly generally includes at least two working chambers each one of which being adapted to be pressurized in order to produce a load. The load produced may for instance be a resultant force and/or a resultant torque at a common point.
The magnitude of the load produced by the pressurized medium assembly is dependent on inter alia the pressure levels in the working chambers. To this end, the pressurized medium assembly generally includes control means, such as valve assemblies, adapted to control the pressure level in each one of the working chambers.
In order to reduce possible power losses in the pressure level control, WO 2010/040890 proposes that the pressure level in each one of the working chambers be controlled by shut-off valves, such as electrically and/or hydraulically controlled on/off valves. As such, WO 2010/040890 proposes a pressurized medium system in which each one of the working chambers can be pressurized to a finite number of pressure levels. The finite number of pressure levels in each one of the working chambers can be combined such that a finite number of load levels are produced by the pressurized medium system. A pressurized medium system such as the one presented in WO 2010/040890 may be referred to as a digital pressurized medium system.
Although a digital pressurized medium system may have the advantage of having relatively low power losses in the pressure level control portion thereof, the digital pressurized system may have the disadvantage that it is not always capable of producing a requested load. For instance, if a load is requested which is located between a lower one and a higher one, relative to the requested load, of the finite number of load levels that the digital pressurized system is capable of producing, there is a risk that the digital pressurized medium system will be oscillating between the lower and higher load level. Such an oscillation may impair the digital pressurized medium system as such and it may also have a negative effect on the member that is adapted to receive the load produced by the system.
It is desirable to provide a pressurized medium assembly that has reasonable power losses but wherein the risk of obtaining an oscillating load is reasonably low.
An aspect of the present disclosure relates to a pressurized medium assembly comprising a first working chamber and a second working chamber. The first and second working chambers are adapted to together produce a load. The pressurized medium assembly comprises a first control means being adapted to provide a fluid communication between the first working chamber and a pressure line in an on/off manner. The pressurized medium assembly further comprises a second control means adapted to provide a fluid communication between the second working chamber and a pressure line.
Moreover, the second control means is adapted to proportionally regulate the pressure in the second working chamber.
As used herein, the expression “load” is intended to encompass a resultant force and/or a resultant torque at a common point.
The pressurized medium assembly as presented hereinabove combines the possibility of obtaining reduced power losses, by virtue of the on/off control of the first working chamber, with the possibility to provide at least a load sub-range, by virtue of the proportional regulation of the pressure in the second working chamber, within which the load produced by the pressurized medium assembly can be infinitely varied. The infinite variation within the load range in turn implies that the risk of obtaining an oscillating load may be reduced.
Optionally, the effective area of the first working chamber is larger than the effective area of the second working chamber. In other words, the effective area of the second working chamber is smaller than the effective area of the first working chamber. This implies that possible power losses due to the proportional regulation of the pressure in the second working chamber may be reduced, as compared to a pressurized medium assembly in which the working chamber with the largest effective area is proportionally regulated.
As used herein, the expression “effective area” relates to the area of the working chamber upon which fluid pressure acts to provide a mechanical force.
Optionally, the second control means comprises a proportional pressure control valve. The use of a proportional pressure control valve may result in an improved accuracy of the proportional control of the pressure in the second working chamber.
Optionally, the pressurized medium assembly comprises, in addition to the first working chamber, at least one more working chamber adapted to be in fluid communication with a pressure line in an on/off manner. Optionally, the pressurized medium assembly comprises, in addition to the first working chamber, a plurality of additional working chambers each one of which being adapted to be in fluid communication with a pressure line in an on/off manner. To this end, the pressurized medium assembly may optionally comprise additional control means adapted to provide a fluid communication between the at least one more working chamber, or between each one of the plurality of additional working chambers, and a pressure line in an on/off manner. As such, a plurality of discrete load levels may be obtained with low power losses, since a plurality of working chambers are controlled in an on/off manner, and a proportional control of at least a subrange between at least two of the discrete load levels may be obtained by regulating the second working chamber.
Optionally, the pressurized medium assembly further comprises a third working chamber. The pressurized medium assembly further comprises a third control means adapted to provide a fluid communication between the third working chamber and a pressure line. The third control means is adapted to proportionally regulate the pressure in the third working chamber.
Optionally, the pressurized medium assembly comprises a single spool valve adapted to form a part of the second control means as well as the third control means. The fact that the assembly may comprise a single spool valve for regulating the pressure in the second working chamber as well as in the third working chamber implies that a relative compact and cost efficient control of both the chambers may be obtained.
A second aspect of the present disclosure relates to a pressurized medium steering system for an articulated vehicle, the pressurized medium steering system comprising a pressurized medium assembly according to the first aspect of the present disclosure.
A third aspect of the present disclosure relates to a vehicle comprising a pressurized medium assembly according to the first aspect of the present disclosure and/or a pressurized medium steering system according to the second aspect of the present disclosure.
A fourth aspect of the present disclosure relates to a method for controlling a pressurized medium assembly comprising a first working chamber and a second working chamber in order to produce a load, the method comprising:
Optionally, the pressurized medium assembly further comprises a third working chamber the method further comprising,
Optionally, the second working chamber is an extending chamber and the third chamber is a retracting chamber, the method further comprising:
The above discussed alteration may imply that a relatively smooth load control may be obtained.
With reference to the appended drawings, below follows a more detailed description of embodiments of the invention cited as examples.
In the drawings:
It should be noted that the appended drawings are not necessarily drawn to scale and that the dimensions of some features of the present invention may have been exaggerated for the sake of clarity.
The invention will below be described for a vehicle in the form of a wheel loader 1 such as the one illustrated in
Moreover, the digital pressurized medium assembly 10 illustrated in
In a similar vein, the digital pressurized medium assembly 10 comprises a second control means 24, or second controller, adapted to provide a fluid communication between the second working chamber 16 and the first fluid line 18 in an on/off manner. To this end, the a second control means 24 may comprise a first shut-off valve 24′, such as an electrically and/or hydraulically controlled on/off valve, located between the first second chamber 16 and the first fluid line 18.
When a fluid communication between one of the working chambers 14, 16 and the second fluid line 26 is established, that working chamber assumes an atmospheric pressure state, i.e. a zero positive pressure state.
The control means of the digital pressurized medium assembly 10 can be controlled such that each one of the working chambers either assumes the zero positive pressure state (hereinafter denoted by 0) or the predetermined non-zero positive pressure P state (hereinafter denoted by 1). As such, the digital pressurized medium assembly 10 can assume the four load states that are presented in Table 1.
Since the second working chamber 16 is a retracting chamber, the A load state results in that the digital pressurized medium assembly 10 produces a negative load 1_i in the first direction X. The A2 load state results in a zero load 1_2 whereas the A3 and A4 load states results in positive loads L3, L4.
The invention will, in the following, be exemplified by embodiments. It is to be understood, however, that the embodiments are included in order to explain principles of the invention and not to limit the scope of the invention defined by the appended claims.
Moreover, the pressurized medium assembly 10 illustrated in
Purely by way of example, the fluid used in the first fluid line 18 may be a gas, such as air, or a liquid, such as oil.
Moreover, the pressurized medium assembly 10 comprises a first control means 22, or first controller, adapted to provide a fluid communication between the first working chamber 14 and the first fluid line 18 in an on/off manner. To this end, although purely by way of example, the first control means 22 may comprise a first shut-off valve 22′, such as an electrically and/or hydraulically controlled on/off valve, located between the first working chamber 14 and the first fluid line 18. In a similar vein, the digital pressurized medium assembly 10 comprises a second control means 24, or a second controller, adapted to provide a fluid communication between the second working chamber 16 and the first fluid line 18. However, in contrast to the
Preferably, the fluid used in the second fluid line 26 may be the same as the fluid used in the first fluid line.
Each one of the first 22 and second 24 control means are adapted to provide on/off fluid communication between each one of the first and second chambers 14, 16 and the second fluid line 26. To this end, the first control means 22 may comprise a second shut-off valve 22″, such as an electrically and/or hydraulically controlled on/off valve, located between the first working chamber 14 and the second fluid line 26. Moreover, the second control means 24 may comprise a second shut-off valve 24″, such as an electrically and/or hydraulically controlled on/off valve, located between the second working chamber 16 and the second fluid line 26.
The first control means 22 of the pressurized medium assembly 10 illustrated in
Moreover, the second control means 24 pressurized medium assembly 10 illustrated in
As such, the embodiment of the pressurized medium assembly 10 illustrated in
The pressure in each one of the working chambers 14, 16 for each one of the four load states A1, A2, A3, A4 of Table 2, as well as the loads L obtainable therefrom, are illustrated in
As may be gleaned from
As such, by the embodiment of the pressurized medium assembly 10 as illustrated in
Another embodiment of the pressurized medium assembly 10 may be obtained by arranging the second control means 24 such that it is adapted to proportionally decrease the pressure in the second working chamber 16 from the first pressure level of the first fluid line 18 to the second pressure level P2 of the second fluid line 26. Moreover, the second control means 24 of the present embodiment may comprise a second shut-off valve 24″, such as an electrically and/or hydraulically controlled on/off valve, located between the second working chamber 16 and the first fluid line 18. The present embodiment may be used for obtaining a stepless load increase, e.g. from the third load level 1_3 to the fourth load level L4.
As such, the embodiment of the pressurized medium assembly 10 illustrated in
The pressure in each one of the working chambers 14, 16 for each one of the four load states A1, A2, A3, A4 of Table 3, as well as the loads L obtainable therefrom, are illustrated in
As may be gleaned from
Moreover, the
The second working chamber 16 of the
However, in order to reduce the amount of power losses that may occur due to the proportional regulation of the second working chamber 16, it may be preferred that the second working chamber 16 is not the largest one of the working chambers of the pressurized medium assembly 10. In other words, it may be preferred that the effective area of at least the first working chamber 14 is larger than the effective area of the second working chamber 16.
An example of such an embodiment is illustrated in
Purely by way of example, the working chambers 14, 16, 34, 36, 38 of the
As such, according to the above non-limiting example, the working chambers 14, 16, 34, 36, 38 may have effective areas according to the following ratios: 1:2:4:8:16.
Moreover, a pressurized medium assembly could preferably comprise a third working chamber and the third control means adapted to proportionally regulate the pressure in the third working chamber.
An example of an embodiment comprising two working chambers wherein the pressure in each one of the working chambers is proportionally regulated is illustrated in
As such,
In the above discussed embodiments of the pressurized medium assembly 10, the proportional control means have been exemplified as 2/2-way proportional valves.
However,
Furthermore,
As may be gleaned from
Preferably, one of the proportionally controlled working chambers is firstly controlled proportionally over its entire pressure range (i.e. between P-i and P2) before the other proportionally controlled working chambers is proportionally controlled, preferably also over its entire pressure range, before the first proportionally chamber is proportionally controlled again.
It should be noted that although the embodiments of the invention which have been described hereinabove comprises two fluid lines 18, 26, it is envisaged that embodiments of the pressurized medium assembly 10 may comprise more than two fluid lines.
For instance,
Moreover, in a similar vein as has been discussed hereinabove, the pressurized medium assembly 10 illustrated in
Furthermore, the
Moreover, the above discussed embodiments of the pressurized medium assemblies 10 comprise an actuator which in turn comprises the working chambers. However, it should be noted that pressurized medium assemblies 10 could instead, or in addition, comprise at least two actuators 52, 54 each one of which comprising at least one, though preferably at least two, working chambers.
For instance,
Purely by way of example, the working chambers 14, 16, 34, 36, 38 of the
Furthermore, the effective area of the third working chamber 34 may be at least approximately twice as large as the effective area of the fourth working chamber 36. As such, according to the above non-limiting example, the working chambers 14, 16, 34, 36 may have effective areas according to the following ratios: 1:2:4:8.
Moreover, the pressurized medium steering system 56 comprises a first control assembly 62 for selectively providing a fluid communication between one a first and second fluid lines 18, 26 and at least one of the first, third and fourth working chambers 14, 36, 38 in an on-off manner. Furthermore, the
Finally, it should be recognized that structures and/or elements and/or method steps shown and/or described in connection with any disclosed form or embodiment of the invention may be incorporated in any other disclosed or described or suggested form or embodiment as a general matter of design choice. It is the intention, therefore, to be limited only as indicated by the scope of the claims appended hereto.
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PCT/SE2012/000192 | 11/20/2012 | WO | 00 |
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WO2014/081353 | 5/30/2014 | WO | A |
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