Control of the actuation of hydraulic consumers

The invention relates to a method for the simultaneous actuation of a plurality of hydraulic consumers by means of intrinsically-safe electro-hydraulic valves. The consumers are connected by hydraulic directional control valves to a pressure line and/or a return line. These hydraulic directional control valves can be connected in a predetermined manner, via pre-control valves to a control line. The pre-control valves are pressureless, and possess electro-magnets with a current consumption of less than 50 milliamps. By connection of a series-connected electro-hydraulic directional control valve means, the pre-control valves are connected to the control line, and at the same time are hydraulically locked.

BACKGROUND TO THE INVENTION 
This invention relates to a method of actuating hydraulic consumers by 
means of intrinsically-safe electro-hydraulic valves, and to an 
arrangement for controlling the actuation of such hydraulic consumers. In 
particular, the hydraulic consumers are hydraulic rams used in underground 
mining installations. 
When winning coal in underground longwall mine workings, it is usual to use 
roof support units to support the roof. These support units include a 
plurality of hydraulic consumers, such as for example support props, 
advance rams and roof bar extension rams. The supply of pressurised 
hydraulic fluid to these consumers is usually controlled by means of 
electro-hydraulic valves. 
Where electrically-actuatable hydraulic control valves are used in 
firedamp-endangered areas of underground mines, it must be ensured that no 
firedamp can be ignited by the energy supplied to the valves. The power 
consumption of such electro-hydraulic control systems is, therefore, 
correspondingly limited. These control systems have for example a current 
intensity of 1 to 1.5 amps for an operating voltage of 12 volts. 
By reason of the high hydraulic pressure level usual in mining, the 
electro-hydraulic control valves usually used have a relatively high power 
consumption of up to 500 milliamps. With the support control systems used 
hitherto in underground workings, it is not possible to actuate a 
plurality of electro-hydraulic control valves at the same time. Such 
valves have to be actuated in sequence. 
In the past various attempts have been made to overcome this disadvantage. 
For example, electro-magnetic valves are known which have a current 
consumption of about 125 milliamps with a voltage of 12 volts. However, 
these electro-magnetic valves have a relatively small flow cross-section, 
and consequently can permit the passage of only small quantities of liquid 
per unit of time. 
A known electrically-actuatable hydraulic control valve has an electric 
drive mechanism which comprises an energy store in the form of a 
compression spring. The compression spring is initially compressed by 
means of a low-power electric geared motor, and liberates the energy 
stored in the compression spring suddenly for the opening of the valve. 
(See DE-OS No. 3 123 224). 
The aim of the invention is to provide a method of, and an apparatus for, 
controlling the simultaneous actuation of a plurality of hydraulic 
consumers in use in a firedamp-endangered surrounding. 
SUMMARY OF THE INVENTION 
The present invention provides a method of actuating hydraulic consumers, 
each hydraulic consumer being connected to a hydraulic pressure line by a 
respective hydraulic directional control valve, wherein each of the 
hydraulic directional control valves is actuatable to connect the 
associated hydraulic consumer to the hydraulic pressure line by a 
respective electro-hydraulic pre-control valve, and wherein the 
pre-control valves are associated with electro-hydraulic directional 
control valve means in such a manner that the pre-control valves operate 
against substantially no hydraulic pressure. 
Advantageously, actuation of the electro-hydraulic directional control 
valve means causes any previously-actuated pre-control valve to be 
hydraulically locked. 
The invention also provides an arrangement for controlling the actuation of 
hydraulic consumers, the hydraulic consumers being connectible to a 
hydraulic pressure line, the control arrangement comprising a respective 
hydraulic directional control valve associated with each of the hydraulic 
consumers, a respective electro-hydraulic pre-control valve associated 
with each of the hydraulic directional control valves, and 
electro-hydraulic directional control valve means associated with the 
pre-control valves, each of the hydraulic consumers being connected to the 
hydraulic pressure line via the associated hydraulic directional control 
valve, wherein each hydraulic directional control valve is actuatable by a 
control line leading from the output side of the associated pre-control 
valve, and wherein the input sides of the pre-control valves are connected 
directly to a hydraulic return line and indirectly, via the 
electro-hydraulic directional control valve means, to the hydraulic return 
line or to a hydraulic control line. 
Thus, the various hydraulic consumers are connected via their hydraulic 
directional control valves (3/2-way control valves) directly to the return 
line and to the pressure line. The hydraulic directional control valves 
are each held in an initial working postion by a spring, so that the 
hydraulic consumers are connected to the return line. 
The pre-control valves are electrically-actuatable 3/2-way directional 
control valves. The direct or indirect connection of the input sides of 
the pre-control valves to the return line ensures that the pre-control 
valves are "pressureless". 
In a preferred embodiment, the arrangement further comprises a control box 
for actuating the pre-control valves and the electro-hydraulic directional 
control valve means via electric control leads. Preferably, the 
pre-control valves are connected to the return line via hydraulic lines. 
In order to actuate a plurality of hydraulic consumers at the same time, 
the corresponding "pressureless" pre-control valves are electrically 
actuated, for example by keys or the like arranged on the control box. 
Since actuation of the electro-hydraulic directional control valve means 
causes the pre-control valves to be hydraulically locked, the electric 
actuation of the pre-control valves can then be interrupted. The hydraulic 
directional control valves are then actuated, via their control lines, to 
connect the selected hydraulic consumers to the pressure line. 
Advantageously, the pre-control valves are electro-hydraulic seating valves 
having electro-magnets whose current consumption is less than 50 
milliamps, and preferably is about 10 milliamps. 
Preferably, each of the pre-control valves includes a stepped valve stem 
slidably mounted within a valve sleeve, first and second valve seats, and 
a valve piston constituting a double valve closure member, the valve 
piston being formed as a double cone. The electro-magnet of each 
pre-control valve acts on the stepped valve stem of that valve, the valve 
stem sliding, sealingly surrounded by a valve sleeve, in a valve guide 
bush. The valve sleeve and the valve stem together form a 
hydraulically-loadable annular area having an external diameter D2. The 
valve piston formed in the style of a double cone is formed on the valve 
stem on that side thereof remote from the electro-magnet. The cone side of 
the valve piston pointing in the direction of the electro-magnet, in 
combination with a corresponding valve seat, forms a 
hydraulically-loadable annular area with an external diameter D1. The 
opposite side of the double-cone valve piston lies, when the 
electro-magnet is energised, on a further valve seat; in this case the 
hydraulically-loadable annular area has the external diameter D3.

DESCRIPTION OF PREFERRED EMBODIMENTS 
FIG. 1 shows a hydraulic control arrangement for a mine roof support 
assembly positioned in a longwall working. The control arrangement is 
associated with a low pressure line 1, a high pressure line 2, a control 
line 3 and a return line 4. The lines 1 to 4 pass along the longwall 
working, and supply the various hydraulic consumers of the mine roof 
support units which constitute the roof support assembly. FIG. 1 also 
shows two hydraulic rams 5 and 6 which are controlled by the control 
arrangement. The rams 5 and 6 are connected, via hydraulic lines 7 and 8 
respectively, to the high pressure line 2 and the return line 4. The 
cylindrical chambers 9 and 11 and the annular working chambers 10 and 12 
of the rams 5 and 6 are connected, via 3/2-way directional control valves 
13, 14, 15 and 16, to either the high pressure line 2 or the return line 
4. The directional control valves 13, 14, 15 and 16 are biassed by springs 
17 towards an operational position in which they connect the working 
chambers 9, 10, 11 and 12 of the rams 5 and 6 to the return line 4. Each 
directional control valve 13, 14, 15 and 16 has a hydraulic servo-piston 
(not shown), and is hydraulically actuatable by means of a respective 
control line 18. On charging of the servo-pistons, the appropriate working 
chambers 9, 10, 11 and 12 of the rams 5 and 6 are connected to the high 
pressure line 2. 
The control lines 18 are connected to the output sides of pre-control 
valves 19, 20, 21 and 22, the input sides of these valves being connected, 
via hydraulic lines 23 and 24, to the return line 4. Further 3/2-way 
directional control valves 25 and 26 are connected into the hydraulic 
conduits 24. The pre-control valves 19, 20, 21 and 22 can be actuated by 
control lines 27; and the directional control valves 25 and 26 can be 
actuated by control lines 29, from a control box 28. 
As may be seen from FIG. 1, the directional control valves 25 and 26 are 
biassed by springs 30 towards an operational position in which they 
connect the line 24 to the return line 4. Since, in this position, the 
lines 23 and 24 are both connected to the return line 4, no hydraulic 
pressure is present on the input sides of the pre-control valves 19, 20, 
21 and 22. The pre-control valves 19, 20, 21 and 22 are biassed by springs 
31 towards an operational position in which they connect the control lines 
18 to the hydraulic line 23, and thus connect it to the return line 4. 
Since the pre-control valves 19, 20, 21 and 22 are operated against no 
hydraulic pressure, these control valves can incorporate electro-magnets 
whose current consumption is minimal. In practice, the current consumption 
of the pre-control valves 19, 20, 21 and 22 can be less than 50 milliamps, 
and is preferably about 10 milliamps. 
The hydraulic control arrangement (which is constituted by the control 
valves 13 to 16, 19 to 22, 25 and 26 and by the control box 28) works as 
follows: 
With all the valves in the initial position as illustrated, the pre-control 
valves 19 and 21 are actuated from the control box 28, for example by 
actuation of keys 32 and 33. The control lines 18 are then connected to 
the hydraulic line 24, which is still connected to the return line 4. By 
actuation of the keys 34 and 35, the directional control valves 25 and 26 
are actuated to connect the control line 3 to the hydraulic line 24. The 
control lines 18 are then supplied with pressurised hydraulic fluid, via 
the pre-control valves 19 and 21, and operate the directional control 
valves 13 and 15 through their servo-pistons. In this operational 
position, the cylindrical working chambers 9 and 11 of the rams 5 and 6 
are connected to the high pressure line 2, so that the rams are extended. 
The pre-control valves 19, 20, 21 and 22 are hydraulically self-locking, 
which means that, as soon as pressure is present in the hydraulic line 24, 
the electric actuation of the pre-control valves can be interrupted. The 
pre-control valves 19, 20, 21 and 22 remain hydraulically locked as long 
as the directional control valves 25 and 26 are electrically charged by 
way of the keys 34 and 35. 
The pre-control valves 19, 20, 21 and 22 are identical, and so the 
constructional details of only one of these (the valve 19) will now be 
described with reference to FIG. 2. Thus, the pre-control valve 19 
consists of an actuator 36, in which an electro-magnet (not shown) is 
arranged, and of a hydraulic control part 37. The actuator 36 is screwed 
on to the control part 37, or the two components are arranged in one 
common housing. 
The control pulse triggered in the actuator 36 by the electro-magnet acts 
upon a valve stem 38 in the direction of the arrow F, and shifts the valve 
stem against the force of a valve spring 39. The valve stem 38 is of 
multi-stepped construction, and its upper region is surrounded by a 
sealingly-abutting valve sleeve 43. The valve sleeve 43 is fixed by a 
clamping sleeve 44 to the valve stem 38, and slides in a valve guide bush 
52. At its end opposite to the electro-magnet, the valve stem 38 is 
provided with a piston 40. The valve piston 40 is of double conical 
construction so as to define upper and lower cone seats. When the 
electro-magent is not energised, the upper cone seat is pressed by the 
valve spring 39 against an upper valve seat 41. When the electro-magnet is 
energised, that is to say when the valve stem 38 is shifted downwards 
against the force of the valve spring 39, the lower cone seat of the valve 
piston 40 is forced against a lower valve seat 42. The control part 37 has 
a central reception bore 45, which receives the valve stem 38, and bores 
46, 47 and 48. The bore 46 is connected to the hydraulic line 24, the bore 
47 is connected to the control line 18, and the bore 48 is connected to 
the hydraulic line 23. 
If the pre-control valve 19 is supplied with pressurised hydraulic fluid 
via the hydraulic line 24 and the bore 46 (that is to say when the 
directional control valve 25 has been operated) without its electro-magnet 
having previously been energised, then the hydraulic fluid present in the 
valve antechamber 49 acts upon an upper annular area of the valve piston 
40, the annular area having an external diameter D1. The hydraulic fluid 
in the valve antechamber 49 also acts upon the lower end of the valve 
sleeve 43, and thus generates an oppositely-acting force component. Since 
the annular area having an external diameter D2 which is defined by the 
valve sleeve 43, is larger than the annular area with the external 
diameter D1, the valve piston 40 is pressed more firmly against the valve 
seat 41. In this operational position, the pre-control valve 19 is closed 
in relation to the control line 3. The control line 18 is connected to the 
hydraulic line 23 and thus to the return line 4. 
If the pre-control valve 19 is actuated, its electro-magnet forces the 
valve piston 40 against the lower valve seat 42. In this case, the valve 
piston 40 is pressurised by the hydraulic fluid supplied by the line 24, 
on an upper annular area having an external diameter D3. Since the 
external diameter D3 is larger than the external diameter D2, the 
pressurised upper annular area of the valve piston 40 is larger than the 
annular area effective on the valve sleeve 43, so that the valve piston 
will be pressed by the hydraulic pressure against the lower valve seat 42 
and held fast there, even when the electro-magnet is switched off. In this 
operational position, the hydraulic line 24 is connected to the control 
line 18. This operational position is released only when the directional 
control valve 25 is switched off.