The present invention relates to work machines and particularly to a work machine in which the operator can specify an engine speed using an engine speed instructing device such as an engine control dial (hereinafter referred to as the EC dial) or the like.
A work machine, such as a hydraulic excavator, is known in which a hydraulic pump is driven by the power of an engine and the hydraulic fluid discharged from the hydraulic pump is used to drive hydraulic actuators. Generally, in such work machines, the operator operates the EC dial to determine an engine speed and operates operation levers to determine the speed and power of each hydraulic actuator.
For example, there is a work machine with a heavy load work mode, a normal work mode, and an economy mode for saving fuel (see
There is also a work machine in which the EC dial is used to determine a target engine speed, the engine is controlled such that its speed reaches the target engine speed, and the hydraulic pump is controlled such that the pump absorption torque corresponding to the engine speed is achieved. This EC dial can instruct any target speed, and the pump absorption torque is adjusted accordingly to any value desired (see, for example,
There is another work machine that determines the target engine speed to any speed excluding a preset speed range for the purpose of preventing resonance resulting from particular engine speeds (see
Patent Document 1: JP-2011-157751-A
Patent Document 2: Japanese Patent No. 4136041
Patent Document 3: JP-2008-169796-A
In the method of using the EC dial to set the engine speed to any speed between the minimum speed and the maximum speed as in the methods of Patent Documents 1 and 2, if there is a mechanical resonance-inducing speed range in the range in which the engine speed can be set, setting the engine speed in the vicinity of mechanical resonance frequencies may cause resonance, and generate large oscillation.
By contrast, according to the method of Patent Document 3, resonance resulting from particular engine speeds can be prevented. However, while a typical work machine is often required to perform fine adjustments of the engine speed in a high speed range in which output power is also high, the method of Patent Document 3 is such that the slope in the range from the upper limit (Rhmin in
Further, some engines have a speed-torque characteristics that a speed decrease results in a drastic torque decrease in a particular speed range such as the one illustrated in
The invention has been contrived in view of the above, and its object is to provide a work machine including an engine speed control device that makes resonance and engine lug down less likely to occur even if the speed-torque characteristics of the engine are such that there is a speed range where an engine speed decrease results in a drastic torque decrease or a mechanical resonance-inducing speed range between a minimum speed and a maximum speed and also allows fine adjustments of the engine speed in a high speed range.
To achieve the above object, a first aspect of the invention is a work machine including: an engine; a hydraulic pump driven by the engine; a hydraulic actuator driven by hydraulic fluid discharged from the hydraulic pump; an engine speed instructing device for an operator to instruct a target engine speed for the engine; and a control device for controlling an engine speed of the engine. The control device includes a target engine speed computing section for detecting an operation amount of the engine speed instructing device and computing the target engine speed based on target engine speed characteristics preset from the detected operation amount of the engine speed instructing device. The target engine speed characteristics are such that the target engine speed can be set excluding a range between a first engine speed and a second engine speed, the first engine speed being higher than a minimum speed of the engine and lower than a maximum speed of the engine, the second engine speed being higher than the first engine speed and lower than the maximum speed of the engine. A ratio of a change in the target engine speed to a change in the operation amount of the engine speed instructing device when the operation amount of the engine speed instructing device is changed from an operation amount for instructing the minimum speed to an operation amount for instructing the first engine speed is larger than a ratio of a change in the target engine speed to a change in the operation amount of the engine speed instructing device when the operation amount of the engine speed instructing device is changed from an operation amount for instructing the second engine speed to an operation amount for instructing the maximum speed.
In accordance with the invention, resonance and engine lug down are less likely to occur even if there is a mechanical resonance-inducing speed range or a speed range where an engine speed decrease results in a drastic torque decrease between a minimum speed and a maximum speed of the engine speed. Further, because the engine speed can be finely adjusted in a speed range higher than a particular engine speed, it is possible to improve work efficiency in the speed range frequently used in the work machine.
A work machine according to an embodiment of the present invention will now be described with reference to the accompanying drawings. A hydraulic excavator is used as an example of the work machine. It should be noted that the invention is not limited to hydraulic excavators but is applicable to any work machine as long as the operator can specify an engine speed using an engine speed instructing device such as an EC dial or the like.
The lower travel structure 10 includes a pair of crawlers 11a and 11b, a pair of crawler frames 12a and 12b (only one side is illustrated in
The upper swing structure 20 includes a swing frame 21; an engine 22 as a prime mover, provided on the swing frame 21; a hydraulic swing motor 27; a decelerating mechanism 26 for decelerating the rotation of the hydraulic swing motor 27; and the like. The drive power of the hydraulic swing motor 27 is transmitted via the decelerating mechanism 26, and the transmitted power is used to swing the upper swing structure 20 (swing frame 21) relative to the lower travel structure 10.
The excavating mechanism (front device) 30 is installed on the upper swing structure 20. The excavating mechanism 30 includes a boom 31; a boom cylinder 32 for driving the boom 31; an arm 33 supported pivotably near the distal end of the boom 31; an arm cylinder 34 for driving the arm 33; a bucket 35 supported pivotably at the distal end of the arm 33; a bucket cylinder 36 for driving the bucket 35; and the like.
Also, a hydraulic system 40 is installed on the swing frame 21 of the upper swing structure 20. The hydraulic system 40 is used to drive hydraulic actuators including the above-described hydraulic travel motors 13a and 13b, hydraulic swing motor 27, boom cylinder 32, arm cylinder 34, and bucket cylinder 36.
The hydraulic system 40 includes hydraulic pumps, regulators, a control valve, and the like, the details of which are described below with reference to
The overall system of the hydraulic excavator includes the above-described hydraulic system 40; the engine 22 that drives the first and second hydraulic pumps 41a and 41b; an engine controller 23; an EC dial 91, and a controller 100.
Rotationally driven by the engine 22, the first hydraulic pump 41a and the second hydraulic pump 41b discharge the hydraulic fluid at an amount proportional to the product of its rotational speed and volume. The discharge pipe of the first hydraulic pump 41a is connected with the boom cylinder 32, the arm cylinder 34, the bucket cylinder 36, the right hydraulic travel motor 13a, and the hydraulic swing motor 27. The discharge pipe of the second hydraulic pump 41b is connected with the boom cylinder 32, the arm cylinder 34, the left hydraulic travel motor 13a, and the hydraulic swing motor 27.
A pressure sensor 44 is provided in the discharge pipe of the first hydraulic pump 41a to detect the discharge pressure Pa of the first hydraulic pump 41a while a pressure sensor 45 is provided in the discharge pipe of the second hydraulic pump 41b to detect the discharge pressure Pb of the second hydraulic pump 41b. Signals detected by these pressure sensors 44 and 45 are input to the controller 100.
The first hydraulic pump 41a and the second hydraulic pump 41b include the regulators 42a and 42b, respectively. The regulators 42a and 42b are driven by commands from the controller 100 to change the volumes of the first hydraulic pump 41a and the second hydraulic pump 41b.
The control valve 43 is driven by the operation levers, not illustrated, provided for the hydraulic actuators including the hydraulic travel motors 13a and 13b, the hydraulic swing motor 27, the boom cylinder 32, the arm cylinder 34, and the bucket cylinder 36. The control valve 43 adjusts the flow rates at which the hydraulic fluid flows from the first hydraulic pump 41a and the second hydraulic pump 41b to the hydraulic actuators and the flow rates at which the hydraulic fluid flows from the hydraulic actuators to a hydraulic fluid tank (not illustrated).
The engine controller 23 receives a target engine speed from the controller 100 and adjusts an amount and a timing of fuel injection to the engine 22 such that the actual engine speed matches the target engine speed.
The EC dial 91 is the device with which the operator instructs an engine speed, and its output voltage changes according to dial angles set by the operator. The output voltage is input to the controller 100.
The controller 100 receives the output voltage of the EC dial 91, the operation amounts of the operation levers, not illustrated, provided for the hydraulic actuators, the discharge pressure Pa of the first hydraulic pump 41a detected by the pressure sensor 44, and the discharge pressure Pb of the second hydraulic pump 41b detected by the pressure sensor 45. Based on these input signals, the controller 100 computes command signals for the engine controller 23 and the regulators 42a and 42b and outputs the obtained signals thereto, thereby controlling the speed of the engine 22 and the discharge flow rates of the first hydraulic pump 41a and the second hydraulic pump 41b.
The control performed by the controller 100 will next be described with reference to the drawings.
As illustrated in
The target pump flow rate computing section 200 receives the following signals: a signal Sa indicative of the maximum operation amount among the operation amounts of the operation levers for operating the hydraulic actuators (the boom cylinder 32, the arm cylinder 34, the bucket cylinder 36, the right hydraulic travel motor 13a, and the hydraulic swing motor 27) connected with the discharge pipe of the first hydraulic pump 41a; a signal Sb indicative of the maximum operation amount among the operation amounts of the operation levers for operating the hydraulic actuators (the boom cylinder 32, the arm cylinder 34, the left hydraulic travel motor 13a, and the hydraulic swing motor 27) connected with the discharge pipe of the second hydraulic pump 41b; the discharge pressure Pa of the first hydraulic pump 41a; the discharge pressure Pb of the second hydraulic pump 41b; and the output voltage of the EC dial. Based on these signals, the target pump flow rate computing section 200 computes a target flow rate Q4a of the first hydraulic pump 41a and a target flow rate Q4b of the second hydraulic pump 41b. The target flow rate Q4a of the first hydraulic pump 41a is output to the first divider 400 while the target flow rate Q4b of the second hydraulic pump 41b is output to the second divider 500. The computations performed by the target pump flow rate computing section 200 will later be described in detail.
The target engine speed computing section 300 receives the output voltage of the EC dial, determines a target engine speed based on a preset table, and outputs the target engine speed to the first divider 400, the second divider 500, and the engine controller 23.
As illustrated in
If mechanical resonance frequencies exist between the minimum speed N1 and maximum speed N2 of the engine 22, N3 and N4 are set such that the resonance frequencies lie between N3 and N4. By doing so, the target engine speed does not stay between N3 and N4, and resonance is less likely to occur.
Similar to the speed-torque characteristics shown in
Referring back to
Referring again to
The second divider 500 receives the target flow rate Q4b of the second hydraulic pump 41b computed by the target pump flow rate computing section 200 and the target engine speed computed by the target engine speed computing section 300. The second divider 500 divides the target flow rate Q4b by the target engine speed to calculate a target volume q1b for the second hydraulic pump 41b. Based on the target volume q1b, the second divider 500 outputs a command signal to the regulator 42b to control the second hydraulic pump 41b . As a result, the discharge flow rate of the second hydraulic pump 41b is made substantially equal to Q4b.
With reference to
The first function generator 201 receives the signal Sa indicative of the maximum operation amount among the operation amounts of the operation levers for operating the hydraulic actuators connected with the discharge pipe of the first hydraulic pump 41a. The first function generator 201 computes a flow rate signal Q1a based on a preset table and outputs it to the first multiplier 204. The table is determined by using as a reference the target flow rate of the first hydraulic pump 41a versus the operation amount signal Sa when the engine 22 is operated at the maximum speed and the discharge pressure of the first hydraulic pump 41a is low. The table is set such that as the operation amount signal Sa increases, the target flow rate signal Q1a increases accordingly.
The second function generator 202 receives the signal Sb indicative of the maximum operation amount among the operation amounts of the operation levers for operating the hydraulic actuators connected with the discharge pipe of the second hydraulic pump 41b. By performing a computation similar to that performed by the first function generator 201, the second function generator 202 computes a target flow rate signal Q1b for the second hydraulic pump 41b and outputs it to the second multiplier 205.
The third function generator 203 receives the EC dial output voltage, computes a gain signal K1 based on a preset table, and outputs it to the first multiplier 204 and the second multiplier 205.
Referring again to
Referring back to
The fourth function generator 206 receives the signal Sa indicative of the maximum operation amount among the operation amounts of the operation levers for operating the hydraulic actuators connected with the discharge pipe of the first hydraulic pump 41a. The fourth function generator 206 computes a target output power signal Pow1a based on a preset table and outputs it to the third multiplier 209. The table is determined by using as a reference the target output power of the first hydraulic pump 41a versus the operation amount signal Sa when the engine 22 is operated at the maximum speed. The table is set such that as the operation amount signal Sa increases, the target output power signal Pow1a increases accordingly.
The fifth function generator 207 receives the operation amount signal Sb, performs a computation similar to that performed by the fourth function generator 206 to calculate a target output power signal Pow1b for the second hydraulic pump 41b, and outputs it to the fourth multiplier 210.
The sixth function generator 208 receives the EC dial output voltage, computes a gain signal K2 based on a preset table, and outputs it to the third multiplier 209 and the fourth multiplier 210.
Referring again to
Referring again to
The first flow rate calculator 211 receives the target output power signal Pow2a and the discharge pressure signal Pa of the first hydraulic pump 41a, divides the target output power signal Pow2a by the discharge pressure signal Pa to calculate a target flow rate signal Q3a for the first hydraulic pump 41a, and outputs it to the first minimum selector 213.
The second flow rate calculator 212 receives the target output power signal Pow2b and the discharge pressure signal Pb of the second hydraulic pump 41b, divides the target output power signal Pow2b by the discharge pressure signal Pb to calculate a target flow rate signal Q3b for the second hydraulic pump 41b, and outputs it to the second minimum selector 214.
The first minimum selector 213 receives the target flow rate signal Q2a computed by the first multiplier 204 and the target flow rate signal Q3a computed by the first flow rate calculator 211, selects the smaller of the two as a target flow rate Q4a for the first hydraulic pump 41a, and outputs it to the first divider 400 shown in
The second minimum selector 214 receives the target flow rate signal Q2b computed by the second multiplier 205 and the target flow rate signal Q3b computed by the second flow rate calculator 212, selects the smaller of the two as a target flow rate Q4b for the second hydraulic pump 41b, and outputs it to the second divider 500 shown in
In
When the target flow rate signal Q2a exhibits the characteristics shown in
In the present embodiment, the output characteristics illustrated in
Further, in
According to the work machine according to the embodiment of the present invention described above, resonance and engine lug down are less likely to occur even if there is a mechanical resonance-inducing speed range or a speed range where an engine speed decrease results in a drastic torque decrease between a minimum speed and a maximum speed of the engine speed. Further, since the engine speed can be finely adjusted in a speed range higher than a particular engine speed, it is possible to improve work efficiency in the speed range frequently used in the work machine.
When the table of the target engine speed computing section illustrated in
The characteristics in
Conversely, when the EC dial output voltage decreases from V2 to V4, the output value indicative of the target engine speed decreases from N2 to N4. Even when the EC dial output voltage falls below V4, the output value indicative of the target engine speed stays at N4 until the EC dial output voltage reaches V3. After the EC dial output voltage falls below V3 by any amount, the output value becomes N3. As the EC dial output voltage decreases from V3 to V1, the output value decreases from N3 to N1.
As described above, when hysteresis characteristics are added to the table used by the target engine speed computing section of the controller, the characteristics of the computing sections of the controller illustrated in
As illustrated in
While we have described a case where the invention is applied to a hydraulic excavator, the invention is not limited thereto. The invention is applicable to any work machine as long as the operator can specify an engine speed using an engine speed instructing device such as an EC dial or the like.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2016/057681 | 3/10/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/154187 | 9/14/2017 | WO | A |
Number | Name | Date | Kind |
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20080299847 | Kaji | Dec 2008 | A1 |
Number | Date | Country |
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11-166482 | Jun 1999 | JP |
2008-169796 | Jul 2008 | JP |
4136041 | Aug 2008 | JP |
2009-008072 | Jan 2009 | JP |
2011-157751 | Aug 2011 | JP |
Entry |
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International Search Report of PCT/JP2016/057681 dated Apr. 5, 2016. |
International Preliminary Report on Patentability received in corresponding International Application No. PCT/JP2016/057681 dated Sep. 20, 2018. |
Number | Date | Country | |
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20180163374 A1 | Jun 2018 | US |