CN115233758A - Slot milling machine - Google Patents
Slot milling machine Download PDFInfo
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- CN115233758A CN115233758A CN202211052898.8A CN202211052898A CN115233758A CN 115233758 A CN115233758 A CN 115233758A CN 202211052898 A CN202211052898 A CN 202211052898A CN 115233758 A CN115233758 A CN 115233758A
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- 238000003801 milling Methods 0.000 title claims abstract description 241
- 229910000831 Steel Inorganic materials 0.000 claims abstract description 69
- 239000010959 steel Substances 0.000 claims abstract description 69
- 238000001514 detection method Methods 0.000 claims description 61
- 238000004804 winding Methods 0.000 claims description 14
- 230000007246 mechanism Effects 0.000 claims description 8
- 238000004891 communication Methods 0.000 claims description 5
- 239000000725 suspension Substances 0.000 claims description 5
- 238000000034 method Methods 0.000 abstract description 31
- 230000008569 process Effects 0.000 abstract description 6
- YZCKVEUIGOORGS-IGMARMGPSA-N Protium Chemical compound [1H] YZCKVEUIGOORGS-IGMARMGPSA-N 0.000 abstract 1
- 239000011435 rock Substances 0.000 description 11
- 239000002002 slurry Substances 0.000 description 11
- 239000002689 soil Substances 0.000 description 6
- 238000010586 diagram Methods 0.000 description 4
- 230000009467 reduction Effects 0.000 description 4
- 230000003578 releasing effect Effects 0.000 description 4
- 230000009286 beneficial effect Effects 0.000 description 3
- 230000002035 prolonged effect Effects 0.000 description 3
- 230000009471 action Effects 0.000 description 2
- 230000008859 change Effects 0.000 description 2
- 238000010276 construction Methods 0.000 description 2
- 230000004048 modification Effects 0.000 description 2
- 238000012986 modification Methods 0.000 description 2
- 230000008054 signal transmission Effects 0.000 description 2
- YZCKVEUIGOORGS-OUBTZVSYSA-N Deuterium Chemical compound [2H] YZCKVEUIGOORGS-OUBTZVSYSA-N 0.000 description 1
- UFHFLCQGNIYNRP-UHFFFAOYSA-N Hydrogen Chemical compound [H][H] UFHFLCQGNIYNRP-UHFFFAOYSA-N 0.000 description 1
- 230000000712 assembly Effects 0.000 description 1
- 238000000429 assembly Methods 0.000 description 1
- 230000005540 biological transmission Effects 0.000 description 1
- 230000000903 blocking effect Effects 0.000 description 1
- 238000006073 displacement reaction Methods 0.000 description 1
- 230000005484 gravity Effects 0.000 description 1
- 229910052739 hydrogen Inorganic materials 0.000 description 1
- 239000001257 hydrogen Substances 0.000 description 1
- 238000006467 substitution reaction Methods 0.000 description 1
- 230000007704 transition Effects 0.000 description 1
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Classifications
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- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F5/00—Dredgers or soil-shifting machines for special purposes
- E02F5/02—Dredgers or soil-shifting machines for special purposes for digging trenches or ditches
- E02F5/08—Dredgers or soil-shifting machines for special purposes for digging trenches or ditches with digging wheels turning round an axis
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- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F3/00—Dredgers; Soil-shifting machines
- E02F3/04—Dredgers; Soil-shifting machines mechanically-driven
- E02F3/18—Dredgers; Soil-shifting machines mechanically-driven with digging wheels turning round an axis, e.g. bucket-type wheels
- E02F3/20—Dredgers; Soil-shifting machines mechanically-driven with digging wheels turning round an axis, e.g. bucket-type wheels with tools that only loosen the material, i.e. mill-type wheels
- E02F3/205—Dredgers; Soil-shifting machines mechanically-driven with digging wheels turning round an axis, e.g. bucket-type wheels with tools that only loosen the material, i.e. mill-type wheels with a pair of digging wheels, e.g. slotting machines
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- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F3/00—Dredgers; Soil-shifting machines
- E02F3/04—Dredgers; Soil-shifting machines mechanically-driven
- E02F3/18—Dredgers; Soil-shifting machines mechanically-driven with digging wheels turning round an axis, e.g. bucket-type wheels
- E02F3/22—Component parts
- E02F3/24—Digging wheels; Digging elements of wheels; Drives for wheels
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F3/00—Dredgers; Soil-shifting machines
- E02F3/04—Dredgers; Soil-shifting machines mechanically-driven
- E02F3/18—Dredgers; Soil-shifting machines mechanically-driven with digging wheels turning round an axis, e.g. bucket-type wheels
- E02F3/22—Component parts
- E02F3/24—Digging wheels; Digging elements of wheels; Drives for wheels
- E02F3/246—Digging wheels; Digging elements of wheels; Drives for wheels drives
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F3/00—Dredgers; Soil-shifting machines
- E02F3/04—Dredgers; Soil-shifting machines mechanically-driven
- E02F3/18—Dredgers; Soil-shifting machines mechanically-driven with digging wheels turning round an axis, e.g. bucket-type wheels
- E02F3/22—Component parts
- E02F3/26—Safety or control devices
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- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F5/00—Dredgers or soil-shifting machines for special purposes
- E02F5/02—Dredgers or soil-shifting machines for special purposes for digging trenches or ditches
- E02F5/14—Component parts for trench excavators, e.g. indicating devices travelling gear chassis, supports, skids
- E02F5/145—Component parts for trench excavators, e.g. indicating devices travelling gear chassis, supports, skids control and indicating devices
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Mining & Mineral Resources (AREA)
- Civil Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Structural Engineering (AREA)
- Constituent Portions Of Griding Lathes, Driving, Sensing And Control (AREA)
Abstract
The invention discloses a slot milling machine, relates to the field of engineering machinery, and aims to realize accurate control of a tool rest of the slot milling machine and prevent an unbalance loading phenomenon. The method comprises the following steps: in the working process of the slot milling machine, the loads of all milling wheels of the slot milling machine are adopted in real time; taking the loads of all milling wheels as parameters, and taking the maximum load of the loads of all milling wheels as the real-time load N of the slot milling machine; judging whether the real-time load of the slot milling machine meets a first set formula (S1): n is a radical of hydrogen 1 ≤N≤N 2 (ii) a If the real-time load N does not satisfy the first set formula (S1), judging whether the real-time load N of the slot milling machine satisfies a second set formula (S2): n is a radical of<N 1 (ii) a If the second set formula (S2) is met, continuously judging whether the tensile force F of the steel wire rope of the slot milling machine meets the following third set formula (S3): f 1 <F; and if the third set formula (S3) is not met, tightening the steel wire rope to lift a milling cutter frame of the slot milling machine.
Description
Technical Field
The invention relates to the field of engineering machinery, in particular to a slot milling machine.
Background
The double-wheel milling is a grooving operation device for an underground diaphragm wall, and a working device is hung through a steel wire rope and is excavated downwards and vertically in a slotted hole filled with slurry. During operation, the working device can apply downward pressure on a rock stratum at the bottom of the tank under the actions of the pulling force of the steel wire rope, the self weight of the working device, buoyancy and the like. Under the pressure, the milling wheel at the lower part of the working device is driven by the motor to mill rock soil at the bottom of the groove and remove the rock soil from the groove hole. When the rock soil on the lower part of the milling wheel is milled to be empty, the steel wire rope is released, the working device feeds downwards, and the rock soil is continuously milled.
In the related art, there is an automatic feeding control method for a double-wheel milling and milling tool rest, which controls the feeding state of a steel wire rope according to the tension of the steel wire rope and a set value.
The inventor finds that at least the following problems exist in the prior art: in the prior art, the feeding and the lowering of the tool rest are controlled by the tension of a steel wire rope, so that the overload of a working device is easily caused, a reduction gearbox or a milling wheel driving device is damaged, or the light load of the working device is not beneficial to achieving the optimal efficiency of the working device. In addition, when the construction of a slope rock stratum or the deflection of a tool rest occurs, the ground pressure which is supposed to be commonly born by the two milling wheels is changed into the load bearing of the single milling wheel, and under the condition of the deflection load, the tension of the original steel wire rope is still used for controlling, so that the single overload damage is easily caused, and the control fault is generated.
Disclosure of Invention
The invention provides a slot milling machine, which is used for realizing the accurate control of a tool rest of the slot milling machine and preventing unbalance loading.
The embodiment of the invention provides a slot milling machine control method, which comprises the following steps:
in the working process of the slot milling machine, the loads of all milling wheels of the slot milling machine are adopted in real time;
taking the loads of all milling wheels as parameters, and taking the maximum load in the loads of all milling wheels as the real-time load N of the slot milling machine;
judging whether the real-time load of the slot milling machine meets a first set formula (S1): n is a radical of 1 ≤N≤N 2 (ii) a Wherein, N 1 Setting a lower limit value for the load; n is a radical of hydrogen 2 Setting an upper limit value for the first load;
if the first set formula (S1) is not satisfied, judging whether the real-time load N of the slot milling machine satisfies the following second set formula (S2) or not: n is a radical of hydrogen<N 1 ;
If the second set formula (S2) is met, continuously judging whether the tensile force F of the steel wire rope of the slot milling machine meets the following third set formula (S3): f 1 <F, wherein F 1 Setting tension for a steel wire rope of the slot milling machine;
and if the third set formula (S3) is not met, tightening the steel wire rope to lift a milling cutter frame of the slot milling machine.
In some embodiments, the slot milling machine control method further comprises the steps of:
if the third set formula (S3) is met, the steel wire rope is put down in an accelerated manner, and then a milling cutter frame of the slot milling machine is put down.
In some embodiments, the slotter control method further comprises the steps of:
if the real-time load N does not meet the second set formula (S2), continuously judging whether the real-time load N of the slot milling machine meets the following fourth set formula (S4) or not: n is a radical of 2 <N≤N 3 (ii) a Wherein, N 3 Setting an upper limit value for the second load;
and if the fourth set formula (S4) is satisfied, slowing down the descending speed of the steel wire rope.
In some embodiments, the slotter control method further comprises the steps of:
and if the fourth set formula (S4) is not met, tightening the steel wire rope to lift a milling cutter frame of the slot milling machine.
In some embodiments, the slot milling machine control method further comprises the steps of:
and if the first set formula (S1) is met, keeping the working state of the steel wire rope of the slot milling machine unchanged.
In some embodiments, the load of the cutterhead is the pressure of the cutterhead, then: the first setting formula (S1) is specifically: p 1 ≤P≤P 2 (ii) a Wherein P is the real-time pressure of the slot milling machine, P 1 Setting a lower limit value for the pressure; p 2 Setting a first upper limit value for the pressure; and/or the second set formula (S2) is specifically: p is<P 1 (ii) a And/or the fourth setting formula (S4) is specifically: p 2 <P≤P 3 (ii) a Wherein, P 3 An upper limit value is set for the second pressure.
In some embodiments, the load of the cutterhead is the torque of the cutterhead, then: the first setting formula (S1) is specifically: t is 1 ≤T≤T 2 (ii) a Wherein T is the real-time torque of the slot milling machine 1 Setting a lower limit value for the torque; t is a unit of 2 Setting an upper limit value for the first torque; and/or the second set formula (S2) is specifically: t is<T 1 (ii) a And/or the fourth setting formula (S4) is specifically: t is 2 <T≤T 3 (ii) a Wherein, T 3 An upper limit value is set for the second torque.
In some embodiments, the number of cutterheads is more than two.
An embodiment of the present invention further provides a slot milling machine, including:
a host;
the suspension arm can be arranged on the main machine in a variable amplitude manner;
the driving mechanism comprises a driving piece and a steel wire rope; the driving part is installed on the host, one end of the steel wire rope is in driving connection with the driving part, and the other end of the steel wire rope bypasses the suspension arm;
the tool rest is hung at the other end of the steel wire rope;
the milling wheel driving device assembly is arranged on the tool rest;
the milling device is in driving connection with the milling wheel driving device assembly;
the load detection element is connected with the milling wheel driving device assembly so as to detect the load of the milling wheel driving device assembly;
a tension detecting element installed at the boom or the wire rope and configured to detect a tension of the wire rope; and
and the speed detection element is arranged on the driving piece so as to detect the winding and unwinding speeds of the steel wire rope.
In some embodiments, the cutterhead drive assembly includes first and second cutterhead drives each mounted to the tool post, the milling device including first and second cutterheads; the first milling wheel driving device is in driving connection with the first milling wheel, and the second milling wheel driving device is in driving connection with the second milling wheel.
In some embodiments, the load detection element comprises:
a first pressure detecting element mounted to the first mill wheel driving unit to detect a pressure of the first mill wheel driving unit; and
and the second pressure detection element is arranged on the second milling wheel driving device so as to detect the pressure of the second milling wheel driving device.
In some embodiments, the load detection element comprises:
a first torque detecting element mounted to the first mill wheel driving means to detect a torque of the first mill wheel driving means; and
and the second torque detection element is arranged on the second milling wheel driving device so as to detect the torque of the second milling wheel driving device.
In some embodiments, the slot milling machine further comprises:
the controller is in communication connection with the load detection element, the tension detection element and the speed detection element; the controller is configured to control the winding and unwinding of the steel wire rope according to data transmitted by the load detection element, the tension detection element and the speed detection element.
In some embodiments, the slot milling machine further comprises:
a display communicatively coupled to the controller; the display is configured to display a feed speed of the milling device.
In some embodiments, the tension detection element is mounted at the boom tip.
In some embodiments, the driver comprises one of: hoisting and oil cylinder.
The working device of the slot milling machine works in the slurry, the density of the slurry changes with the depth, and therefore, the buoyancy force applied to the tool rest of the working device of the slot milling machine in the slurry is changed. The uncertainty of the buoyancy can affect the precise control of the tool holder feed. By adopting the scheme provided by the embodiment of the invention, the accurate control of the feeding of the tool rest can be realized, and particularly, the control method of the slot milling machine provided by the technical scheme can be used for acquiring the pressure of the first milling wheel driving device and the load of the second milling wheel driving device of the slot milling machine in real time in the working process of the slot milling machine; and the largest load in the loads of all milling wheels of the slot milling machine is used as a real-time load, and then the slot milling machine is controlled according to the real-time load N of the slot milling machine and the tension F of the steel wire rope, so that the retracting and releasing actions of the steel wire rope of the slot milling machine are accurately controlled, and further the slot milling machine is controlled to feed or not. According to the technical scheme, the load of the slot milling machine is judged in real time through the specific judging step, and the real-time load of the slot milling machine can be accurately calculated no matter whether the working depth of the slot milling machine is changed. The method realizes that whether the tool rest connected with the steel wire rope is blocked or not is judged in advance in real time through the load of all milling wheels of the slot milling machine and the tension of the steel wire rope, so that the action direction of the tool rest is accurately controlled, the phenomenon of blocking is eliminated, and the automatic feeding is realized when the conditions are met, so that the slot milling machine normally and stably works; the cutter driving device directly controls the feeding and the lowering of the cutter frame through real-time load, reduces or even avoids the overload or no-load phenomenon of the milling device, is beneficial to prolonging the service life of a reduction gearbox and a motor, and is also beneficial to exerting the best efficiency of work.
Drawings
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention. In the drawings:
fig. 1 is a schematic structural view of a slot milling machine according to some embodiments of the present invention.
Fig. 2 is a schematic diagram of a principle of a control portion of a slot milling machine according to some embodiments of the present invention.
Fig. 3 is a logic diagram of a slot milling machine control method according to some embodiments of the present invention.
Fig. 4 is a schematic flow chart of a slot milling machine control method according to some embodiments of the present invention.
Fig. 5 is a schematic structural view of a slot milling machine according to another embodiment of the present invention.
Fig. 6 is a schematic diagram illustrating a principle of a control portion of a slot milling machine according to another embodiment of the present invention.
Fig. 7 is a logic diagram of a slot milling machine control method according to another embodiment of the present invention.
Fig. 8 is a schematic flow chart of a slot milling machine control method according to another embodiment of the present invention.
Detailed Description
The technical solution provided by the present invention is explained in more detail with reference to fig. 1 to 8.
Referring to fig. 1 and 2, a slot milling machine according to an embodiment of the present invention includes a main machine 1, a boom 2, a driving mechanism 3, a tool post 4, a mill wheel driving device assembly 5, a milling device 6, a load detection element 7, a tension detection element 8, and a speed detection element 9.
The main machine 1 is a main body part of the slot milling machine, and the main machine 1 runs on the ground so as to realize transition transportation of the slot milling machine. The main body 1 also serves as a bearing base for other components, and the boom 2 is mounted to the main body 1 in a variable-width manner. The driving mechanism 3 includes a driving member 31 and a wire rope 32; the driving part 31 is installed on the main machine 1, one end of the wire rope 32 is in driving connection with the driving part 31, and the other end of the wire rope 32 bypasses the top end of the boom 2. The tool holder 4 is suspended from the other end of the wire rope 32. The speed detecting element 9 is mounted on the driving member 31 to detect the winding and unwinding speed of the wire rope 32. The tension detecting element 8 is mounted to the boom 2, and is configured to detect the tension of the wire rope 32.
The suspension arm 2 can change the amplitude relative to the main machine 1, and the angle of the suspension arm 2 relative to the ground is changed to lift a tool rest 4, a milling wheel driving device assembly 5, a milling device 6 and other working devices. Specifically, the drive mechanism 3 includes a drive member 31, a wire rope 32, and a sheave assembly 33. The driving member 31 is a winding mechanism. One end of a wire rope 32 is mounted on the hoisting mechanism, the tool rest 4 is suspended at the other end of the wire rope 32, and the middle part of the wire rope 32 is wound around a pulley assembly 33 mounted at the top of the boom 2. The hoisting height of the tool rest 4, namely the working position of the tool rest 4, is changed by winding and unwinding the steel wire rope 32 through the winding mechanism. The steel wire rope 32 is hoisted and released, the tool rest 4 descends, and the working depth of the slot milling machine becomes deep. The steel wire rope 32 is wound in a winding way, the tool rest 4 rises, and the working depth of the slot milling machine becomes shallow.
The speed of winding and unwinding the steel wire rope 32 is measured by the speed detection element 9, the winding and unwinding length of the steel wire rope 32 can be obtained through calculation according to the speed value measured by the speed detection element 9, and the height position of the tool rest 4 is further obtained through calculation.
The tensile force to which the wire rope 32 is subjected is measured by the tension detecting member 8. The tension detection element 8 is, for example, a pin sensor. Since the working device of the slot milling machine works in the slurry, the density of the slurry is not constant but varies with the depth, and therefore the buoyancy force to which the tool holder 4 of the working device of the slot milling machine is subjected in the slurry varies. The tensile force applied to the wire rope 32 is detected by the tension detecting member 8. According to the technical scheme, the tension of the steel wire rope 32 is measured by the tension detection element 8, the controller 10 performs safety overload prejudgment according to the tension value, and controls the feeding state of the tool rest 4 according to the judgment result; and, judge whether milling equipment 6 is in idle load or overload according to the tensile set value of wire rope 32, assist and participate in the feed control.
With continued reference to fig. 1 and 2, a mill wheel drive assembly 5 is mounted to the tool holder 4. The milling device 6 is in driving connection with the mill wheel drive assembly 5. The milling device 6 comprises at least two milling wheels, such as two milling wheels or more than three milling wheels. The parameter of the cutterhead with the highest real-time load in each cutterhead is taken as the real-time load of the slot milling machine. The number of the milling wheel driving device assemblies 5 and the number of the load detection elements are in one-to-one correspondence with the milling devices 6, and a plurality of milling wheels are correspondingly provided with a plurality of milling wheel driving devices. For convenience of description, in the following embodiments, two cutterheads, two cutterhead driving devices, and two load detecting elements are provided as examples for detailed description.
In particular, the mill wheel drive assembly 5 comprises a first mill wheel drive 51 and a second mill wheel drive 52, both mounted to the tool holder 4. The milling device 6 comprises a first cutterhead 61 and a second cutterhead 62. The first cutterhead drive 51 is in driving connection with a first cutterhead 61 and the second cutterhead drive 52 is in driving connection with a second cutterhead 62.
A load sensing element 7 is connected to the cutterhead drive assembly 5 to sense the load of the cutterhead drive assembly 5. The load is divided into pressure and torque. The following description will be made in detail with respect to two load parameters, pressure and torque.
An implementation using pressure as a load parameter is described.
The load detection element 7 includes a first pressure detection element 71 and a second pressure detection element 72; the first pressure detecting element 71 is mounted to the first mill wheel driving means 51 to detect the pressure of the first mill wheel driving means 51. The second pressure detecting element 72 is installed to the second mill wheel driving means 52 to detect the pressure of the second mill wheel driving means 52.
The first cutterhead drive 51 is used to drive the operation of the first cutterhead 61. The second cutterhead drive 52 is used to drive the operation of the second cutterhead 62.
In some embodiments, the slot milling machine further comprises a controller 10, wherein the controller 10 is in communication connection with the load detection element 7, the tension detection element 8 and the speed detection element 9; the controller 10 is configured to control the winding and unwinding of the wire rope 32 based on data transmitted from the load detection element 7, the tension detection element 8, and the speed detection element 9.
The controller 10 is mounted to the tool post 4 at a location, such as at the top or upper portion of the tool post 4. Since the load sensing member 7 is provided to the cutterhead drive assembly 5, specifically, the first cutterhead 61 is provided with a first pressure sensing member 71 and the second cutterhead 62 is provided with a second pressure sensing member 72. The first pressure detection element 71 and the second pressure detection element 72 are in communication connection with the controller 10, and the first pressure detection element 71 and the second pressure detection element 72 are short in distance from the controller 10 and are located in mud, so that the first pressure detection element 71 and the second pressure detection element 72 are short in connection with the controller 10, and the reliability of information transmission between the controller 10 and the first pressure detection element 71 and the second pressure detection element 72 cannot be affected due to the fact that the working environment is severe.
The tension detecting element 8 is attached to the tip end of the boom 2, and the speed detecting element 9 is attached near the driver 31, but the tension detecting element 8 and the speed detecting element 9 are relatively distant from the controller 10, but since neither the tension detecting element 8 nor the speed detecting element 9 is located in the slurry, the signal lines between the tension detecting element 8, the speed detecting element 9, and the controller 10 do not affect the reliability of signal transmission even if they are long. Moreover, the controller 10 is located at the top or upper region of the tool rest 4, so that the length of the signal wire between the tension detection element 8, the speed detection element 9 and the controller 10 is shortened as much as possible, and the signal transmission is more efficient and reliable.
According to the technical scheme, the load detection element 7 is used for collecting the working pressure of the milling wheel driving device assembly 5 and transmitting the pressure value to the controller 10. The controller 10 controls the winding and unwinding steel wire rope 32 according to the pressure value, thereby realizing the feeding control of the tool rest 4.
In some embodiments, the slot milling machine further comprises a display 11, the display 11 being in communication with the controller 10. The display 11 is configured to display the feed speed of the milling device 6. The speed detecting element 9 acquires the feeding speed of the wire rope 32 and transmits the speed value to the controller 10. The controller 10 calculates the feeding speed of the tool rest 4 and sends the feeding speed to the display 11 for displaying, so that the manipulator can know the feeding state in time.
Referring to fig. 3 and 4, the embodiment of the invention further provides a slot milling machine control method, and the method is implemented by using the slot milling machine provided by any one of the embodiments. The slot milling machine control method comprises the following steps:
and S100, acquiring the load of all milling wheels of the slot milling machine in real time in the working process of the slot milling machine. Specifically, during the operation of the slot milling machine, the pressure of the first wheel driving device 51 and the pressure of the second wheel driving device 52 of the slot milling machine are collected in real time.
As described above, the pressure of the first mill wheel drive 51 and the pressure of the second mill wheel drive 52 are detected using the load detection element 7. Specifically, two load detecting elements 7 may be used to measure the pressure of the first mill wheel drive 51 and the pressure of the second mill wheel drive 52, respectively. The measured data is directly the pressure of the corresponding milling wheel driving device, and subsequent analysis and calculation are facilitated. The load detection element 7 includes a first pressure detection element 71 and a second pressure detection element 72. The first pressure detecting element 71 is mounted to the first mill wheel driving means 51 to detect the pressure of the first mill wheel driving means 51; the second pressure detecting element 72 is mounted to the second mill wheel driving means 52 to detect the pressure of the second mill wheel driving means 52.
And S200, taking the loads of all milling wheels as parameters, and taking the maximum load of the loads of all milling wheels as the real-time load N of the slot milling machine. Specifically, the real-time pressure P of the slot milling machine is calculated according to a set formula by taking the pressure of the first cutter wheel driving device 51 and the pressure of the second cutter wheel driving device 52 as parameters.
In some embodiments, the formula is set as: the real-time pressure P of the slot milling machine is determined as the pressure having a large value of the pressure of the first cutter wheel driving unit 51 and the pressure of the second cutter wheel driving unit 52. After the milling device 6 has been jammed, the jammed milling device 6 is subjected to a relatively large pressure. The real-time pressure P of the slot milling machine is taken as the pressure with larger pressure in the pressure of the first milling wheel driving device 51 and the pressure of the second milling wheel driving device 52, so that the overload of the milling device 6 can be prevented; and the clamping stagnation phenomenon can be eliminated by subsequently controlling the winding and unwinding operations of the steel wire rope 32 under the condition of not needing complex identification. In addition, if the tool rest 4 has a certain inclination, the working depths of the first milling wheel 61 and the second milling wheel 62 are different, and the real-time pressure P of the slot milling machine is determined as the pressure with the larger pressure in the pressure of the first milling wheel driving device 51 and the pressure of the second milling wheel driving device 52, so that the milling wheel driving device with the worse working condition is used as a factor for subsequent control, and the control is more accurate.
Step S300, judging whether the real-time load of the slot milling machine meets a first set formula (S1): n is a radical of 1 ≤N≤N 2 (ii) a Wherein N is 1 Setting a lower limit value; n is a radical of 2 The first upper limit value is set. Specifically, whether the real-time pressure P of the slot milling machine meets the following first set formula (S1) is judged: p 1 ≤P≤P 2 (ii) a Wherein, P 1 Setting a lower limit value; p is 2 The first upper limit value is set. P is 1 、P 2 Are preset and stored in the controller 10 described above. Under different working conditions, for different milling difficulties, landforms and types of the milling device 6, P can be changed 1 、P 2 The set value of (2). Likewise, P is introduced later 3 、F 1 And also set values, a plurality of groups of values can be set and stored in the controller 10 according to working conditions, different milling difficulties, different landforms and different types of the milling device 6, or the values can be set in advance in practical situations, and the control requirements can also be met.
Step S400, if the first set formula (S1) is not satisfied, judging whether the real-time load N of the slot milling machine satisfies the following second set formula (S2) or not: n is a radical of<N 1 . Specifically, whether the real-time pressure P of the slot milling machine meets the following second set formula (S2) is judged: p is<P 1 。
Step S500, if the second set formula (S2) is satisfied, continuously determining whether the tensile force F of the wire rope 32 of the slot milling machine satisfies the following third set formula (S3): f 1 <F, wherein F 1 A tension is set for the wire rope 32 of the slot milling machine. F 1 To set upThe value may be set in advance and stored in the controller 10.
In step S500, if the second set formula (S2) is satisfied, it indicates that the current mill wheel driving device has a low working pressure, a slow milling speed, and a low efficiency. At this time, the real-time tension value F of the steel wire rope 32 needs to be further compared with the set tension F of the steel wire rope 32 of the slot milling machine 1 Of (c) is used.
a) When the tension F of the steel wire rope 32 is smaller than the set tension F of the steel wire rope 32 1 When the tool rest 4 is in a state of being stuck by rock soil remaining in a slotted hole, the controller 10 needs to control the winch to withdraw the steel wire rope 32, lift the tool rest 4 by a certain height, and then perform milling. In the above step, i.e., step S600, if the third set formula is not satisfied (S3), the wire rope 32 is tightened to lift the tool holder 4 of the slot milling machine.
b) When the tension value F of the steel wire rope 32 is larger than or equal to the set tension F of the steel wire rope 32 1 And the cutter frame 4 is not clamped, so that the milling speed is low and the efficiency is low. The controller 10 needs to control the winch to increase the releasing speed of the steel wire rope 32, increase the lowering speed of the tool rest 4 and improve the working efficiency. The above step is step S700: if the third set formula (S3) is met, the steel wire rope 32 is put down in an accelerated manner, and the cutter frame 4 of the slot milling machine is put down, namely, the working depth of the cutter frame 4 of the slot milling machine is increased.
In some embodiments, the slot milling machine control method further comprises the steps of:
step S800, if the second set formula (S2) is not satisfied, continuously judging whether the real-time load N of the slot milling machine satisfies the following fourth set formula (S4): n is a radical of 2 <N≤N 3 (ii) a Wherein N is 3 An upper limit value is set for the second load. Specifically, if the second set formula (S2) is not satisfied, it is continuously determined whether the real-time pressure P of the slot milling machine satisfies the following fourth set formula (S4): p 2 <P≤P 3 (ii) a Wherein, P 3 Setting an upper limit value for the second;
step S900, if the fourth setting formula (S4) is satisfied, the lowering speed of the wire rope 32 is slowed down.
Specifically, if the fourth setting formula is satisfied(S4), the fourth setting formula (S4) is: p is 2 ≤P≤P 3 It is stated that the mill wheel drive is in high-load operation at this point, which is more efficient, but there is a risk of damage to the mill 6 and the mill wheel drive. In order to avoid unnecessary damage, the controller 10 controls the winch to reduce the release speed of the wire rope 32, and reduces the lowering speed of the tool rest 4.
In some embodiments, the slot milling machine control method further comprises the steps of:
and step S1000, if the fourth set formula (S4) is not met, tightening the steel wire rope 32 to lift the tool rest 4 of the slot milling machine.
Specifically, if the real-time pressure P of the slot milling machine does not satisfy the fourth set formula (S4), it indicates that the real-time pressure P of the slot milling machine is equal to or higher than the real-time pressure P of the slot milling machine>P 2 At this time, it is described that the milling wheel driving device is in a severe overload state, the possibility of damage to the milling device 6 and the milling wheel driving device is significantly increased, and the controller 10 needs to immediately control the hoisting and recovering steel wire rope 32 to lift the tool rest 4 to a certain height, and then to lower the tool rest for milling.
In some embodiments, the slotter control method further comprises the steps of:
step S1100, if the first set formula (S1) is satisfied, the working state of the wire rope 32 of the slot milling machine is kept unchanged. Specifically, if the first set formula (S1) is satisfied, it indicates that the mill wheel driving device is in a better working state, which can ensure the working efficiency and has no overload risk. At this time, the controller 10 controls the winch to keep the current motion state, and the steel wire rope 32 lifts the tool rest 4 to keep the current speed for feeding and milling.
According to the technical scheme, the feeding and the lowering of the cutter rest 4 are directly controlled through the pressure value of the motor of the milling wheel, so that the changes of the slurry density, the specification of the cutter rest 4 and the like can be avoided, and the control precision is improved; the idle running of the milling wheel during bucket clamping is avoided, the efficiency is improved, the service lives of the reduction gearbox and the motor are prolonged, and the best working efficiency is brought into play.
For a double-wheel slot milling machine, the pressure of a milling wheel to the ground is judged through the tension of a steel wire rope in the prior art. When the plane rock stratum is normal, the two milling wheels bear the pressure to the ground together; when sloping rocks, the one-sided cutterhead is loaded with almost all ground pressure, while the other-sided cutterhead bears little ground pressure. Therefore, in the prior art, the tensile force of the steel wire rope is used as a control parameter, and whether the steel wire rope is overloaded on one side or not cannot be judged. However, the technical scheme provided by the application can effectively identify the unbalance loading phenomenon, because the pressure of the overload side milling wheel is obviously increased when the unbalance loading occurs, the technical scheme controls the speed of slowing down the tool rest or lifting the tool rest according to the pressure values at two sides, so that the phenomenon of single-side overload is effectively avoided, further the control misjudgment caused by the deflection or the inclined rock of the tool rest 4 is avoided, the overload of the single-side milling wheel is avoided, the service life of the working device is prolonged, the groove hole deviation milling is also avoided, the overload work of the single wheel is avoided, and the reliability is improved; the influence of buoyancy and the weight of the tool rests 4 with different specifications is avoided, and the precision is improved.
The following describes a specific implementation using torque as a load parameter.
Referring to fig. 5 and 6, this embodiment is substantially the same as the above described implementation with pressure as the load parameter, but with the following differences: the load detection member 7 includes a first torque detection member 71 'and a second torque detection member 72', both of which employ a torque sensor, for example. Or a pressure sensor is adopted, and a torque value is obtained through calculation. The following functional relationship exists between torque T and pressure P:where q is the motor displacement and η is the efficiency. A first torque detecting element 71' is mounted to the first mill wheel drive 51 to detect a torque of the first mill wheel drive 51. A second torque detecting element 72' is mounted to the second mill wheel drive 52 to detect the torque of the second mill wheel drive 52.
For other similar matters, please refer to the above description, and further description is omitted here.
Accordingly, the control method using torque as a load parameter is also substantially the same as the above-described control method using pressure as a control parameter, except that the parameter to be compared is torque.
Referring to fig. 7 and 8, when torque is used as a load parameter, a slot milling machine control method provided by the embodiment of the invention is as follows.
Step S100', in the working process of the slot milling machine, the torque of the first cutter wheel driving device 51 and the torque of the second cutter wheel driving device 52 of the slot milling machine are collected in real time.
As described above, the torque of the first mill wheel drive 51 and the torque of the second mill wheel drive 52 are detected using the load detection member 7. Specifically, two load detecting elements 7 may be used to measure the pressure of the first mill wheel drive 51 and the pressure of the second mill wheel drive 52, respectively. The measured data is directly the pressure of the corresponding milling wheel driving device, and subsequent analysis and calculation are facilitated. The load detection member 7 includes a first torque detection member 71 'and a second torque detection member 72'. A first torque detecting element 71' is installed to the first cutter wheel driving means 51 to detect a pressing force of the first cutter wheel driving means 51; a second torque detecting element 72' is mounted to the second mill wheel drive 52 to detect the pressure of the second mill wheel drive 52.
And step S200', calculating the real-time torque T of the slot milling machine according to a set formula by taking the torque of the first milling wheel driving device 51 and the torque of the second milling wheel driving device 52 as parameters.
In some embodiments, the formula is set as: the torque with a large value of the torque of the first cutter wheel driving device 51 and the torque of the second cutter wheel driving device 52 is used as the real-time torque T of the slot milling machine. After one of the cutterheads of the milling device 6 is stuck, the torque of the stuck cutterhead is large. The larger torque of the first mill wheel driving device 51 and the torque of the second mill wheel driving device 52 is used as the real-time torque T of the slot milling machine, so that the overload of the milling device 6 can be prevented; and the clamping stagnation phenomenon can be eliminated by subsequently controlling the operation of retracting and releasing the steel wire rope 32 under the condition of not needing complex identification; in addition, if the tool post 4 has a certain inclination, the working depths of the first cutterhead 61 and the second cutterhead 62 are different, and the torque with the larger torque in the torque of the first cutterhead driving device 51 and the torque of the second cutterhead driving device 52 is used as the real-time torque T of the slot milling machine, so that the cutterhead driving device with the worse working condition is used as a factor for subsequent control, and the control is more accurate.
Step S300', judging whether the real-time torque T of the slot milling machine meets the following first set formula (S1): t is 1 ≤T≤T 2 (ii) a Wherein, T 1 Setting a lower limit value; t is 2 The first upper limit value is set. T is 1 、T 2 Are preset and stored in the controller 10 described above. Under different working conditions, for different milling difficulties, landforms and types of the milling device 6, T can be changed 1 、T 2 The set value of (2). Also, T is described hereinafter 3 、F 1 And also set values, a plurality of groups of values can be set and stored in the controller 10 according to working conditions, different milling difficulties, different landforms and different types of the milling device 6, or the values can be set in advance in practical situations, and the control requirements can also be met.
Step S400', if the first set formula (S1) is not satisfied, determining whether the immediate torque T of the slot milling machine satisfies the following second set formula (S2): t < T1.
Step S500', if the second set formula (S2) is satisfied, continuously determining whether the tension F of the wire rope 32 of the slot milling machine satisfies the following third set formula (S3): f 1 <F, wherein F 1 A tension is set for the wire rope 32 of the slot milling machine. F 1 The setting value may be set in advance and stored in the controller 10.
In step S500', if the second setting formula (S2) is satisfied, it indicates that the current operation torque of the mill wheel driving device is low, the milling speed is slow, and the efficiency is low. At this time, the real-time tension value F of the steel wire rope 32 needs to be further compared with the set tension F of the steel wire rope 32 of the slot milling machine 1 The size of (2).
a) When the tension value F of the steel wire rope 32 is smaller than the set tension F of the steel wire rope 32 1 When the tool rest 4 is in a state of being stuck by rock soil remaining in a slotted hole, the controller 10 needs to control the winch to withdraw the steel wire rope 32, lift the tool rest 4 by a certain height, and then perform milling. If the above-mentioned step, i.e. step S600', does not satisfy the above-mentioned third setting formula (S3),the wire rope 32 is tightened to lift the tool holder 4 of the slot milling machine.
b) When the tension value F of the steel wire rope 32 is larger than or equal to the set tension F of the steel wire rope 32 1 In time, it is indicated that the tool holder 4 is not clamped, and this time, the milling speed is relatively slow and the efficiency is relatively low. The controller 10 needs to control the winch to increase the releasing speed of the steel wire rope 32, increase the lowering speed of the tool rest 4 and improve the working efficiency. Step S700': if the third set formula (S3) is met, the steel wire rope 32 is put down in an accelerated manner, and the cutter frame 4 of the slot milling machine is put down, namely, the working depth of the cutter frame 4 of the slot milling machine is increased.
In some embodiments, the slotter control method further comprises the steps of:
step S800', if the second set formula (S2) is not satisfied, continuously judging whether the real-time torque T of the slot milling machine satisfies the following fourth set formula (S4): t is 2 <T≤T 3 (ii) a Wherein, T 3 Setting an upper limit value for the second;
step S900', if the fourth setting formula (S4) is satisfied, the lowering speed of the wire rope 32 is slowed down.
If the fourth setting formula (S4) is satisfied, the fourth setting formula (S4) is: t is a unit of 2 ≤T≤T 3 It is stated that the mill wheel drive is in high-load operation at this point, which is more efficient, but there is a risk of damage to the mill 6 and the mill wheel drive. In order to avoid unnecessary damage, the controller 10 controls the winch to reduce the release speed of the wire rope 32, and reduces the lowering speed of the tool rest 4.
In some embodiments, the slotter control method further comprises the steps of:
and step S1000', if the fourth set formula (S4) is not satisfied, tightening the steel wire rope 32 to lift the tool rest 4 of the slot milling machine.
If the real-time torque T of the slot milling machine does not meet the fourth set formula (S4), the real-time torque T of the slot milling machine is larger than T2, the milling wheel driving device is in a serious overload state at the moment, the possibility that the milling device 6 and the milling wheel driving device are damaged is remarkably increased, the controller 10 needs to immediately control the winch to recover the steel wire rope 32, the tool rest 4 is lifted to a certain height, and then the tool rest is lowered to perform milling.
In some embodiments, the slotter control method further comprises the steps of:
in step S1100', if the first setting formula (S1) is satisfied, the operating state of the wire rope 32 of the slot milling machine is maintained. If the first set formula (S1) is met, the milling wheel driving device is in a better working state, so that the working efficiency can be ensured, and no overload risk exists. At this time, the controller 10 controls the winch to keep the current motion state, and the steel wire rope 32 lifts the tool rest 4 to keep the current speed for feeding and milling.
According to the technical scheme, the feeding and the lowering of the cutter rest 4 are directly controlled through the torque value of the milling wheel, so that the changes of the slurry density, the specification of the cutter rest 4 and the like can be avoided, and the control precision is improved; the idle running of the milling wheel during bucket clamping is avoided, the efficiency is improved, the service lives of the reduction gearbox and the motor are prolonged, and the best working efficiency is brought into play. And in the working process, the tool rest body is subjected to gravity, ground uplift force, steel wire rope tension and buoyancy and the friction force of the side wall of the tool rest body in slurry, wherein the buoyancy is changed, and the friction force is unknown and changed. The ground anti-support force is a key factor for controlling the descending speed of construction, and in the prior art, the ground support force is inversely calculated through the tension value of a steel wire rope, and an accurate value cannot be obtained due to the change of buoyancy and friction. According to the technical scheme of the embodiment of the invention, the ground anti-support force is directly judged according to the load condition acting on the driving device, and the changed buoyancy and friction force do not need to be considered.
In the description of the present invention, it is to be understood that the terms "central", "longitudinal", "lateral", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be considered as limiting the scope of the present invention.
Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: it is to be understood that modifications may be made to the technical solutions described in the foregoing embodiments, or equivalents may be substituted for some of the technical features thereof, but such modifications or substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.
Claims (8)
1. A slot milling machine, comprising:
a host (1);
a boom (2) mounted to the main body (1) in a variable-width manner;
a drive mechanism (3) comprising a drive member (31) and a wire rope (32); the driving part (31) is mounted on the host (1), one end of the steel wire rope (32) is in driving connection with the driving part (31), and the other end of the steel wire rope (32) bypasses the suspension arm (2);
the tool rest (4) is hung and mounted at the other end of the steel wire rope (32);
a mill wheel drive assembly (5) mounted to the tool holder (4);
the milling device (6) is in driving connection with the milling wheel driving device assembly (5);
a load sensing element (7) connected to the mill wheel drive assembly (5) to sense the load of the mill wheel drive assembly (5);
a tension detection element (8) mounted to the boom (2) or a wire rope (32) and configured to detect a tension of the wire rope (32); and
and the speed detection element (9) is arranged on the driving piece (31) and is used for detecting the winding and unwinding speed of the steel wire rope (32).
2. Slot milling machine according to claim 1, characterized in that the mill wheel drive assembly (5) comprises a first mill wheel drive (51) and a second mill wheel drive (52) both mounted to the tool holder (4), the milling device (6) comprising a first mill wheel (61) and a second mill wheel (62); the first milling wheel driving device (51) is in driving connection with the first milling wheel (61), and the second milling wheel driving device (52) is in driving connection with the second milling wheel (62).
3. A slot milling machine according to claim 2, characterized in that the load detecting element (7) comprises:
a first pressure detecting element (71) mounted to the first mill wheel driving means (51) to detect a pressure of the first mill wheel driving means (51); and
a second pressure detecting element (72) mounted to the second cutterhead drive (52) to detect a pressure of the second cutterhead drive (52).
4. A slot milling machine according to claim 2, characterized in that the load detecting element (7) comprises:
a first torque sensing element (71') mounted to the first mill wheel drive (51) to sense torque of the first mill wheel drive (51); and
a second torque sensing element (72') mounted to the second cutterhead drive (52) for sensing torque of the second cutterhead drive (52).
5. A slot milling machine as set forth in claim 1, further comprising:
the controller (10) is in communication connection with the load detection element (7), the tension detection element (8) and the speed detection element (9); the controller (10) is configured to control the winding and unwinding of the steel wire rope (32) according to data transmitted by the load detection element (7), the tension detection element (8) and the speed detection element (9).
6. A slot milling machine as set forth in claim 5, further comprising:
a display (11) communicatively coupled to the controller (10); the display (11) is configured to display a feed speed of the milling device (6).
7. Slotter as claimed in claim 1, characterized in that the tension detection element (8) is mounted at the top end of the boom (2).
8. A slot milling machine according to claim 1, characterised in that the drive member (31) comprises one of the following: hoisting and oil cylinder.
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