RU2477798C2 - Method for mist formation - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: mist formation method during underground development, at which water without air addition under pressure minimum 200 bar is supplied, at least, through one nozzle and then to flat reflective surface for spraying in a form of mist.

EFFECT: creation of highly effective water mist.

9 cl, 4 dwg

Description

The present invention relates to a method of forming fog during underground mining.

The formation of water fog is known in the art to reduce the risk of explosion during underground mining, in particular to prevent methane explosions, by forming a water-air mixture by mixing water and air flows. True, for this it is necessary to provide for the presence of relatively complex nozzles, and, along with water under pressure, also compressed air.

The objective of the invention is to provide a method and device with which it is possible economically simple and reliable to form a highly efficient water fog.

The solution to this problem is carried out using the signs of the independent claims and, in particular, due to the fact that in the method of forming fog during underground mining, water without adding air is supplied at a pressure of at least 200 bar and through at least one nozzle, and then sent to a reflective surface for spraying water into droplets of fog. Due to this, in a very simple way using only water - available during underground mining as a working fluid in the hydraulic system - water fog can be formed in an efficient way. With the method according to the invention there is no need for complex nozzle systems. Moreover, it is sufficient that water under high pressure is passed through the constriction and then onto a reflective surface.

Preferred embodiments of the invention are described in the description, drawings, as well as in the dependent claims.

According to a first preferred embodiment, the reflective surface is set at an angle, and in particular at an obtuse angle to the axis of the nozzle. Thanks to this, a particularly effective spraying is obtained, and the mist arising from spraying, thanks to the inclination of the reflecting surface, already acquires a preferred direction in which it can be supplied.

It may be preferable that water is supplied from an opening with a diameter of <1 mm, since due to this, fog can form with droplets of about 1-100 microns.

In particular, if water is supplied through a nozzle at a pressure of at least 300 bar, fog is generated with very small droplet sizes, since the energy required for spraying is proportional to the surface created, and it, in turn, is indirectly proportional to the diameter of the droplets. As a result of the use of the reflective surface according to the invention, when fog is formed due to liquid friction, as little energy as possible is converted into heat. Using a nozzle with a diameter of <1 mm, water is released in the order of 7 l / min.

Moreover, according to another preferred embodiment, for the formation of fog in dry air, water can be passed through one or more nozzles with a high volumetric flow rate, and to maintain the fog formed in this way, water can be passed through at least one nozzle with a lower volumetric flow rate. Using this nozzle with a lower volumetric flow rate, the amount of water that is generated from the fog as a result of droplet formation or condenses on the walls can be additionally supplied.

The amount of water in the working face during underground mining with a reservoir thickness of about 3 m (with a flow cross section of about 6-8 m ² and an average air speed of 2 m / s) is about 16 m ³ per second. As a result of spraying water fog with a flow rate of about 10 l / min, the limit of explosive methane concentration rises by about 1 percent. In this case, in order not to interfere with the work of the mining machine operator in the face, the formation is regulated depending on the position of the mining machine.

In the method according to the invention, the control valves for initiating the formation of fog can also themselves work with sprayed water. In this case, the valves can be actuated by the existing driving shield control device. The latter has information about the location of the mining machine and can initiate the opening and closing of valves depending on the location and speed of the mining machine.

In the device for implementing the above methods according to the invention, a one-piece structural element is provided which has at least one nozzle channel and at least one corresponding reflective surface extending at an angle to the axis of the nozzle channel. Such a device is made simply and economically, since in the integral structural element, for example in a metal block, only the nozzle channel and the reflecting surface should be provided. This can be done in the simplest way in one machining center without the subsequent installation of various parts. The fog generator made in this way is extremely reliable and, therefore, perfectly suitable for use in mining.

It turned out to be preferable to make the reflective surface flat. Such a surface, on the one hand, is especially easy to manufacture. On the other hand, this ensures uniform fogging. Particularly good spraying can be achieved due to the fact that the reflecting surface is at least partially bounded by a sharp edge. Such an edge can be located at a distance of several millimeters from the point of intersection of the axis with the nozzle channel.

Finally, it may be preferable that several nozzle channels with corresponding metal surfaces be provided in the structural element, the perpendiculars to the reflective surfaces, in particular, being directed in space at different angles. Thus, with one single structural element, it is possible to create a dense fog formed by spraying, covering a large spatial angle.

Below the present invention is described only by way of example of a preferred embodiment and with reference to the attached drawings, in which

figure 1 depicts a device for the formation of fog during underground mining with three built-in nozzles;

figure 2 is a top view of the lower side of the device of figure 1;

figure 3 is a section along the line aa in figure 2 and

figure 4 is a view along the line bb in figure 2.

Figure 1 shows a device for the formation of fog during underground mining, containing an integral structural element in the form of a metal block 10, for which, in the illustrated embodiment, three nozzle systems are provided in total. As shown in FIG. 4, each of the three nozzle systems has a nozzle channel 12 having a portion of a larger diameter extending from the outside of the structural member 10 into the latter, as well as an adjacent portion of a smaller diameter 14. Section 14 of a smaller diameter in the illustrated embodiment has a diameter of 0.8 mm. In the output region of the nozzle channel 12, the structural element 10 is provided with a corresponding reflective surface 16 extending at an angle of 130 ° to the surface of the nozzle channel 12 and made in a solid metal block 10. The reflective surface 16 is flat and is limited in some places along the curved edge portion by a sharp edge 18 The distance between the point of intersection with the axis of the nozzle channel 12 and the edge 18 is a few millimeters.

As shown in particular in FIGS. 1 and 2, a total of three identical nozzle systems are provided in the structural element 10, the corresponding reflecting surfaces of the nozzle systems being set so that the perpendiculars to the reflecting surfaces are directed in space at different angles. In this case, an angular range α of the order of 40 ° is formed between the output axes of the first and third nozzle systems. Figure 3 shows that the nozzle channels 12 are connected to each other by a common power hole 20, and each nozzle channel 12 on the outer surface of the structural element 10 is closed by a plug 22, so that the water supplied through the power hole 20 can flow out of the channel nozzles exclusively through an opening 14 of a smaller diameter.

24 and 1 indicate a plug connector, which is fixed in a known manner in the structural element 10 with a clamp collar 26. 28 indicates a filter device that filters the inflowing fluid flow. Positions 29 and 30 indicate the fixing screws.

In the known method according to the invention, “water” is understood to mean that liquid that is usually used as a working fluid of a hydraulic system during underground mining, and in this case, of course, this should not be pure water, but water with appropriate additives or additives.

According to the invention, such a hydraulic fluid without adding air through the plug connector 14 and the supply channel 20 is passed through the channels 12 of the nozzles, and then fed to reflective surfaces to ensure the formation of fog, shown in the figures. The liquid is supplied at a pressure of at least 200 bar, preferably 300 bar or more. When such a large energy is supplied, fog is formed with a very small droplet size of the order of 1-100 μm, whereby a single-component nozzle can be used, and there is no need for air supply.

With a diameter of about 0.8 mm, about 7-10 l / min of water is discharged. In order to regulate the required amount of water, groups of nozzles with different volume flows can be used. For the formation of fog in initially dry air, a group of nozzles with a high volumetric flow rate is used. Then, a group of nozzles or a nozzle with a lower flow rate can be used to maintain the formed fog.

The nozzle systems according to the invention can be controlled by a high-pressure pump of the order of 300 bar and a capacity of about 100 l / min, and the control valves that control the pressure supply to the nozzles can themselves also work with irrigation water.

Claims (9)

1. A method of forming fog during underground mining, in which water without adding air under a pressure of at least 200 bar is passed through at least one nozzle and then fed onto a flat reflective surface for spraying in the form of mist droplets. 2. The method according to claim 1, characterized in that the reflective surface is performed at an angle, in particular at an obtuse angle to the axis of the nozzle. 3. The method according to claim 1, characterized in that the water is passed through an opening with a diameter of less than 1 mm 4. The method according to claim 1, characterized in that the water is passed through a nozzle under a pressure of at least 300 bar. 5. The method according to any one of claims 1 to 4, characterized in that for the formation of fog in dry air, water is passed through at least one nozzle with one volumetric flow, and to maintain fog, water is passed through at least one nozzle with another volumetric flow, and the first volumetric flow rate is greater than the second volumetric flow rate. 6. A device for implementing the method according to any one of claims 1 to 5, characterized in that it comprises an integral structural element (10), in which at least one nozzle channel (12) is provided and on which at least one related to flat reflecting surface (16) passing at an angle to the nozzle channel. 7. The device according to claim 6, characterized in that the reflective surface (16) is at least in some areas limited by a sharp edge. 8. The device according to claim 6, characterized in that the reflecting surface (16) ends at a distance of several millimeters from the point of intersection with the axis of the nozzle channel (12). 9. The device according to claim 6, characterized in that the structural element is a metal body (10), in which several nozzle channels (12) are made with corresponding flat reflective surfaces, the perpendiculars to the reflecting surfaces directed in space at different angles.

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