1. Field of the Invention
The invention relates to a control device for an extracting unit in the face of a mine.
2. Description of Related Art
A control of this type is generally known.
However, the prior art suffers from the problem that the main valves and the pilot valves can be subject to inner leakage; in particular, in the presence of high pressures of 450 bars that occur. Due to the high energies of leakage flows, they cause damage to the main valves and/or pilot valves rendering them inoperable; in addition, a drop of hydraulically supported loads results.
Consequently, attempts are being made for detecting leaks early. However, this is a difficult feat in cases of inner leaks between main pressure and/or main return lines and return pressure and/or return lines. Attempts to detect such leaks by means of sound measurements have been unsuccessful to date, because it is not possible to distinguish permissible noises, in particular flow noises, from impermissible flow noises.
Therefore, it is the object of the present invention to be able to detect leaks at any time involving only minimal complexity in terms of devices and labor, even in existing systems while said systems are in operation.
The solution according to one embodiment is based on the realization that, although the main pressure of the face is applied to pilot and main valves from a joint main pressure line, the indicated device-related steps, as specified according to some embodiments as well as the method steps according to other embodiments allow, all the same, for differentiated leak detection on main and pilot valves.
The type of measuring instrument that is employed for measuring escaping hydraulic fluid is for the most part optional. The significant aspect of any selection provides that pressures of 300 bars and higher can be accommodated, and that, at very low pressure and flow rate, at least a qualitative measurement should be possible.
The improvement according to some embodiments allows for an automated leak measurement without the need for a further switching step, as soon as the main and pilot valves are in an operating state in which the connection to the return is shut off. To this end, the recoil spring of the check valve is adjusted in such a way that there is a correlation of the pressures, which are necessary, on the one hand for the operation of the measuring instrument and, on the other hand, on the inside of the return line for opening the check valve as well as for connecting the return line (9) to the main return line (5).
In the improvement according to one embodiment, a branch-off is provided upstream of the check valve, which is available as a standard solution, for the discharge of leaked fluid to the measuring instrument. While the check valve opens and closes the return line in relation to the main return line automatically and pressure-dependently, a closure can be provided for the discharge of leaked fluid to the measuring instrument (20) in order to accommodate the operational special aspects of the measuring instrument.
The improvement according to another embodiment has the advantage that the measuring instrument remains in operation during all operational states of the control. The output signal of the measuring instrument is continuously detected; however, it is only evaluated as a leakage measurement in such operational states when the return line is not actuated by the pilot and main valves and is, therefore, switched pressure-less, meaning it should be closed by the check valve. This allows for a continuous recording of leakage measurements. It is thus possible to detect if the leakage unexpectedly increases thus pointing to the presence of a defect, or if the leakage exceeds a preset limit value requiring service and repair work on the system.
Automation is achieved in that the check valve closes the connection of the main return line to the bypass, and which check valve is shut off in the direction of flow from the bypass to the main return line (5) by a recoil spring that is considerably weaker than the recoil spring of the check valve in the return line. It is thus achieved that the bypass in relation to the main return line is open even at low pressures in the presence of which the return line to the main return line and the tank is still shut off.
Due to the fact that the flow volume meter is disposed in a bypass of the return line (9) with connection to the main return line (5), it must be able to withstand very large flow volumes, and/or it must be effectively protected against great and, in particular, flow volume pulses while, on the other hand, it is automatically actuated with sufficient precision, when the system is at a standstill. This protection is provided by the improvement as set forth in another embodiment.
Many model types of flow volume meters are commercially available and with a variety of principles of action. Some embodiments reflect the essential principles of action. Static, meaning volumetric flow volume meters, are also expedient for detecting the smallest leaks. Hydrodynamic flow volume meters with pressure measuring instrument require a flow rate; however, on the other hand, they are robust and not vulnerable even when exposed to pressure pulses.
The drawing explains the invention using embodiments.
Each power-transmission device can be connected by means of lines 2 and 3 with the main pressure line 4 and the main return line 5. The main pressure line and the main return line extend through the entire the work face, meaning all extracting units are connected thereto in the shown manner. Each power-transmission device has an associated main valve 6 that controls the connection of the lines 2 and 3 to the main pressure line and the main return line. To this end, all main valves 6 are connected via pressure line 8 to the main pressure line 4 and via return line 9 to the main return line 5.
For their actuation, the main valves 6 are hydraulically pilot-controlled by pilot valves 7. To this end, the pilot valves are actuated by magnets, not shown here, of the electronic input means 10 in such a way that the main valves are actuated by means of the hydraulic control lines 11,12 in the one or the other sense. For this purpose, the pilot valves are also connected to the main pressure line 4 and the main return line 5; specifically, to the main pressure line 4 via the line path from pressure line 8 and pilot pressure line 13, and to the main return line 5 via the line path from return line 9 and pilot return line 14. Using the pilot valves, the necessary pressure for adjusting and holding the pressure in the main valves is adjusted in lines 11 and 12.
Furthermore, the hydraulic system is provided with check valves and filters that do not require any further description in the present context.
A filter 17 is mounted in the pilot pressure line 13 that is common to all pilot valves. Said filter can be exchanged with a barrier that is presently additionally depicted as shut-off valve 18.
Regarding
A branch-off valve is installed in the return line 9 that is common to all valves, meaning main and pilot valves, that shuts off the connection to the main return line 5 and by means of which the return line can be connected to a measuring instrument 20.
However, the return line can also be shut off solely by means of the check valve 21 alone, which must always be present to prevent that any pressure that may become built up in the main return line from reaching the return line 9. Said check valves 21 is preloaded by a recoil spring 24, for example, having a spring force corresponding to 2 bars. The branch-off valve 19 is replaced by a T-piece 22 in the return line 9, having the branch-off for the discharge of leakage to the measuring instrument 20 serving for measuring the leak.
This can be seen in the detail view as depicted in
The measuring instrument can be, for example, a measuring vessel that collects the volume of the leaked hydraulic fluid occurring over a given time unit, and by which it can be measured.
Preferably, all of the valves and lines shown herein, including filters, check valves, etc. of a powered supply assembly or of a group of force-transmission devices of the powered support assembly are housed and arranged inside a steel block. This has, until now, impeded the detection of leaks on the inside of such a steel block because said steel block is connected to the main pressure line pressure, (e.g.) 450 bars, as well as the main pressure return line pressure, (e.g.) 30 bars, which is why leaks do not escape to the outside.
However, by means of the additional equipment according to the invention, it is possible to detect if inner leaks of impermissible size are present and, if so, in what amount said leaks must be associated with leakage at the location of the pilot or main valves.
To this end, first, by actuating the shut-off valve 18 or exchange of the filter 17, the pilot pressure line 13 is shut off by means of a (not shown) shut-off element. The branch-off valve 19 is then readjusted in order to shut off the connection of the return line 9 to the main return line 5, establishing instead the connection to the measuring instrument 20. The leakage during a given time unit provides the first measured value. The pilot pressure line is now reopened and the leak is measured once more for the given time unit as a second measured value. The first measured value represents any leakage solely of the main valves; the second measured value represents the inner leak for the entire system. The difference between the first and second measured values represents the leakage for the pilot values. If one of these values and/or the difference exceeds a preset limit, the system is deactivated until the leak has been repaired by a replacement of the affected valve elements.
Regarding
A T-shaped branch-off 19 is mounted in the return line 9 that is common to all valves, meaning main and pilot valves, to which a bypass 27 with connection to the main return line 5 is connected. Bypass 27 circumvents the check valve 21. A flow volume meter is disposed in the bypass as a measuring instrument 20, as well as a second check valve 25. Said check valve 25 has the same flow direction as the check valve 21 and prevents pressure that can build up in the main return line from reaching the bypass 27. Said check valve 25, however, is considerably weaker by means of the recoil spring 26, which is, for example, the preload is less than 1 bar, than the check valve 21, on the other hand, which has a recoil spring 24 having, for example, a preload of 2 bars. A damper is disposed upstream of the flow volume meter as a flow resistance 23. This way, it is possible to limit the flow volume of the bypass as well as the pressure upstream of the flow volume meter to such a measure as is allowable for the flow volume meter and tolerable as volume loss for the pilot control. Instead of or in addition to the damper, bypass 27 can be equipped with a shut-off valve 28 that is only opened for leakage measurements, see
Moreover, using the equipment according to
Number | Date | Country | Kind |
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10 2010 020 361 | May 2010 | DE | national |
Number | Name | Date | Kind |
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4903529 | Hodge | Feb 1990 | A |
5845679 | Hayashi et al. | Dec 1998 | A |
Number | Date | Country | |
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20130048093 A1 | Feb 2013 | US |
Number | Date | Country | |
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Parent | PCT/DE2011/001063 | May 2011 | US |
Child | 13586604 | US |