RU2165525C2 - Device for minimizing hazard of ignition of gas mixture with use of tunneling machines of partial cutting - Google Patents

Abstract

FIELD: mining; applicable in minimizing hazard of ignition of gas mixtures in operation of tunneling machines with nozzles supplying air and/or water-air mixtures. SUBSTANCE: device has nozzles for throwing of air and/or water-air mixtures. Nozzles are installed on nozzle holder connected with cutting jib. At least some quantity of nozzles in any position of cutting jib covers angle of tunneling machine up to 45 dwg in direction of breast. Nozzles may be installed in nozzle holder for turning. Nozzle holder and/or nozzles may be installed for turning depending on position of turning of jib. Nozzle holder or nozzles may be installed for their separate engagement. Nozzles directed to floor may encompass horizontal zone from both sides of cutting heads over central angle of less than 90 deg as measured in projection on floor. Exit angles in top view on horizontal zones may cover angle of 30 deg inside, and up to 60 deg outside as measured from parallel longitudinal axis of tunneling machine through vertex of these angles. In addition to nozzles directed to floor and horizontally oriented nozzles, nozzles directed upward to breast may be installed with discharge of mixture by these nozzles not less than 33 vol.% of other nozzles. Air may be blown at velocity of more than 75% of sound velocity. Water and air flow rate may be selected within 1: 250-1:2000 l/min. Water is supplied at pressure higher than that of air supply. Velocity of impact of air jet may be set no more 1.0 m/s. EFFECT: reliable prevention of ignition of gas mixture liberating from broken rocks without considerable consumption of cooling water and softening of ground. 10 cl, 6 dwg

Description

 The invention relates to mining and can be used in devices to reduce the risk of ignition during operation of tunneling machines with nozzles for supplying air and / or water-air mixtures.

 A device is known to reduce the risk of ignition when using tunneling machines with nozzles, some of whose axes are oriented to the exposed bottom, and the nozzles are mounted on a nozzle holder that can be rotated (German application No. 3609754, class E 21 C 35/22, publ. 09.24.78).

 The closest known device is to reduce the risk of ignition when using tunneling machines with nozzles for discharging air and / or water-air mixtures, in which at least a part of the axes of the nozzles are oriented to the exposed bottom and directed towards the broken rock lying in front of the loading device, nozzles mounted on a nozzle holder connected to a notch bar with the possibility of rotation and separate connection (German application N 2635405, class E 21 C 35/22, publ. 14.12.78).

 During prolonged use, the cutters are subject to wear, which can lead to chipping away of extremely hot parts from the cutters and their contact with the sole of the mine. The rock, chopped by a tunneling or mining partial cutting machine, also at least partially falls on the sole before being captured by a shipping conveyor or loading device. Hot parts of incisors or steel bodies, as well as pyrite inclusions, can also have such flammable potential when hit on such broken rock that methane exiting the surface of the broken rock can ignite. A significant increase in the amount of cooling water, which could subsequently cause appropriate cooling of the sole, however, has the disadvantage that the latter can soften, which is why reliable and accurate movement of the cutting or sinking machine is no longer provided.

 The objective of the invention is to reliably prevent the ignition of the gas mixture leaving the broken rock, without significantly increasing the amount of cooling water and at the same time to ensure that the soil is unacceptably softened.

To solve this problem, in a device for reducing the risk of ignition when using tunneling machines of partial cutting, containing nozzles for discharging air and / or water-air mixtures, the nozzles are mounted on a nozzle holder connected to a notch bar, with at least a part of the nozzle axes in any rotation position of the notch bar covers an angle perpendicular to the bedding from 30 ^o in the direction of the chest face. The nozzles can be rotatably mounted in the nozzle holder. The nozzle holder and / or nozzles can be rotatably mounted depending on the rotation position of the bar. Nozzle holders or nozzles can be installed with the possibility of a separate connection. The nozzles directed to the sole can cover a horizontal area on both sides of the notch heads with a central angle of less than 90 ^° , measured in projection onto the sole. The output angles when viewed from above into horizontal zones can cover an angle of from 30 ^o inward and up to 60 ^o outward, measured from a parallel to the longitudinal axis of the sinking machine straight through the top of these angles. In addition to nozzles directed towards the sole and horizontally oriented, nozzles directed upward to the bottom of the face can be made, in which the ejected amount is 33 vol.% Of other nozzles. Air can be emitted at a speed of more than 75% of the speed of sound. The flow rate of water and air can be selected 1: 250-1: 2000 l / min, while water is supplied at a higher pressure than air. Nozzles directed directly to the broken rock should prevent the formation of a combustible mixture in the area of the broken rock. For this, in principle, there is enough air at the corresponding speed of impact, and water-air mixtures can be used, in which the risk of softening the sole is eliminated with a small fraction of water. These nozzles directed to the broken rock, as corresponds to the preferred embodiment of the device, can be located on the nozzle holder connected to the cutting bar, the nozzles being advantageously rotatably mounted in the nozzle holder. Due to the possibility of turning the nozzles in such a nozzle holder, if necessary communicating with it, the corresponding desired angle of impact can be precisely set while minimizing the amount of impact water, so that the danger of ignition can be reliably eliminated. Due to the possibility of rotation of the entire nozzle holder or separate connection of nozzle holders or nozzles, it is also possible to realize an embodiment in which, irrespective of the rotation position of the cutting bar and, in particular, regardless of the rotation of such a cutting bar upward, only the broken rock is reliably irrigated, due to which the angle of impact at which air or air-water mixture should be ejected onto the broken rock, and thereby also the output amount can be significantly reduced.

The output angles directed to the nozzle base cover an angle perpendicular to the bedding from 30 ^° in the direction of the tunneling machine to 45 ^° in the direction of the bottom of the face, and such a design even without the possibility of turning the nozzle holder provides reliable irrigation and prevents the risk of ignition of the broken rock in all lifting positions of the cutting bar. These angles can of course be substantially reduced if the nozzle holder and / or nozzles are rotatably mounted depending on the rotation position of the bar.

The nozzles directed to the sole can cover a horizontal zone on both sides of the cutter heads with a central angle of less than 90 ^o measured in the projection onto the sole, thereby reliably eliminating the risk of ignition of the zone in which parts of cutters or steel bodies or pyrite inclusions can break off and fall onto broken rock. The invention can be implemented in such a way that the output angles, when viewed from above in horizontal zones, cover an angle of from 30 ^° inward and up to 60 ^° outward, measured from a straight line parallel to the longitudinal axis of the tunneling machine through the top of these angles.

 If, with the same irrigation, general irrigation should also be provided in the form of spray mist also above the area covered by the notch tools, the implementation is advantageously realized in such a way that, in addition to the nozzles directed to the sole and horizontally oriented, upward nozzles are provided which have an ejected quantity less than 33% vol. other nozzles, and here to prevent the danger of ignition is enough, of course, less emitted.

 In order to guarantee sufficient liquefaction of possibly existing or exiting methane when using air, it is preferable that the air is emitted at a speed of more than 75% of the speed of sound, and the speed of impact of the air stream is predominantly set to more than 1.0 m / s.

 When using water-air mixtures, it is possible to minimize the flow rate of water and reduce the risk of softening the soles so that the flow rate of water and air is chosen to be 1: 250-1: 2000 l / min, and water is supplied at a higher pressure than air.

 The invention is illustrated by means of an exemplary embodiment schematically shown in the drawing, in which in FIG. 1, 2 and 3 show a notch bar in the lowered position while simultaneously displaying the spray angles of the individual nozzles located on the cutting bar, and FIG. 4, 5 and 6 - similar images with the notched bar raised up.

 In FIG. 1 schematically shows a cutting or sinking machine 1 with a cutting bar 3 mounted rotatably around a vertical axis of rotation 2. The rotation of the cutting bar 3 with the cutting heads 4 around the vertical axis 2 causes a horizontal rotation of the cutting bar 3, and in addition to such a horizontal rotation, an upward rotation is provided around the horizontal axis of rotation 5. At the front end of the crawler running gear 6 of the cutting machine, a loading device 7 is installed. At the rear end, the discharge end 8 of the transport device 9 is visible.

On the notch bar 3 are nozzle holders 10, carrying a large number of downward directed nozzles. In FIG. 1, three downward nozzles with axes 11 are visible. The hatched sections 12 indicate the amount of air or air and water emitted by such nozzles to the surface, and the sections 12 at the same time explain the distribution of the quantities over the area. In general, three such nozzles with axes 11 span an angle of 30 ^° in the direction of the loading device 7 and approximately 45 ^° in the direction of the face chest 13, whereby the broken rock and exposed bottom under the cutting tools or cutting heads 4 are reliably irrigated with air or water-air mixtures.

In FIG. 2 the longitudinal axis of the sinking machine is schematically indicated by pos. 14. Two horizontal zones 15 are shown, covered by nozzles having axes 11. The nozzles are oriented so that the jets emerging from them converge on the longitudinal middle or on the longitudinal middle axis 14 and cover the horizontal zones, and the angles starting from the parallel longitudinal middle axis 14 straight in the direction of the middle of the machine, are about 30 ^o , and in the direction outward - a maximum of 60 ^o .

 In FIG. 3 is a schematic front view in the direction of arrow III in FIG. 2, wherein horizontal distribution of two jets having axis II is shown here. In general, with a similar arrangement of nozzles and a relatively small discharge quantity, reliable irrigation of the broken rock in front of the cutting machine occurs. The selected angles are also sufficient so that when turning the notch bar up, as shown in FIG. 4,5 and 6, reliably irrigate the broken rock without turning the nozzle holder.

 As can be seen from FIG. 4, when turning the notch bar 3 up to the roof 16, it is enough to turn off one of the three nozzles. Thus, it is sufficient if there are air or water-air mixtures to both rear nozzles with axles II, and the forward nozzle is turned off in order to still guarantee an appropriate angle of irrigation of the broken rock. Also sufficient, as can be seen from FIG. 6, in the upwardly turned position, reduce the number of nozzles to which air or water-air mixtures are supplied so that they nevertheless reliably cover the required area.

Claims (10)

1. Device for reducing the risk of ignition when using tunneling machines I of partial cutting, containing nozzles for discharging air and / or water-air mixtures, moreover, the nozzles are mounted on a nozzle holder 10 connected to the cutting bar 3, characterized in that at least part of the axes II nozzles in any rotation position of the notch bar 3 cover an angle perpendicular to the bedding from 30 ^o in the direction of the tunneling machine I to 45 ^o in the direction of the chest face.  2. The device according to claim 1 or 2, characterized in that the nozzles are mounted in the nozzle holder with the possibility of rotation.  3. The device according to claim 2, characterized in that the nozzle holder and / or nozzles are mounted for rotation depending on the rotation position of the bar.  4. The device according to one of claims 1 to 3, characterized in that the nozzle holders or nozzles are installed with the possibility of a separate connection. 5. The device according to one of claims 1 to 4, characterized in that the nozzles directed to the sole cover a horizontal zone on both sides of the notch heads along a central angle of less than 90 ^° , measured in projection onto the sole. 6. The device according to claim 5, characterized in that the output angles when viewed from above in horizontal zones cover an angle of from 30 ^o inward and up to 60 ^o outward, measured from a parallel longitudinal axis of the tunneling machine straight through the top of these angles.  7. The device according to one of claims 1 to 6, characterized in that in addition to the nozzles directed to the sole and horizontally oriented, nozzles directed upward to the bottom of the face are made, in which the ejected amount is less than 33% by volume of the other nozzles.  8. The device according to one of claims 1 to 7, characterized in that the air is emitted at a speed of more than 75% of the speed of sound.  9. The device according to one of claims 1 to 8, characterized in that the flow rate of water and air is selected 1: 250 - 1: 2000 l / min, and the water is supplied at a higher pressure than air.  10. The device according to one of claims 1 to 8, characterized in that the impact velocity of the air stream is preferably set to more than 1.0 m / s.

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