RU46299U1 - DEVICE FOR CREATING DISTRIBUTED CHARGES AND FORMING AIR SPACES IN WELLS - Google Patents

Abstract

A utility model relates to the development of minerals using blasting and can be used, for example, in the explosive breaking of overburden in opencast mining. The technical task of creating a utility model is to simplify the design of the device and increase the reliability of its operation. A device for creating dispersed charges and the formation of air gaps in wells is proposed, including a sleeve of elastic material with a load closed from the lower end. The essence of the utility model is that the device is equipped with a funnel 4 of elastic material and a rigid ring 6, with the lower base of the funnel connected to the upper end of the sleeve 1, and a ring 6 mounted in the upper base. The diameters of the sleeve and ring are 10- 20 mm and 150-250 mm more than the diameter of the well. The sleeve and funnel can be made of woven polypropylene. The device may contain at least two sleeves of elastic material of different lengths with funnels and rings placed one in the other.

Description

A utility model relates to the development of minerals using blasting and can be used, for example, in the explosive breaking of overburden in opencast mining.

A device for dispersing the explosive charge through the air gap is made in the form of a support with an elastic shutter in the form of a cone with a corrugated side wall (USSR author's certificate No. 614658, class E 21 C 37/00, published in 1979, B. No. 39 )

The main disadvantages of the known device are:

the complexity of the installation in a given section of the well, because in the presence of failures in the wall of the well, a change in its diameter, and for other reasons, the shutter may become stuck above a given place;

low reliability of well shutoff, especially when loading with loose explosives.

Partially indicated disadvantages are eliminated in the device for loading wells with running water according to the Russian patent No. 2133343 (class F 42 D 1/08, published in 2001, B. No. 5). The known device contains an elastic polyethylene sleeve, closed from the ends, and a fitting connected to a source of compressed air is built into its upper end. The principle of operation of the known device is that a polyethylene sleeve is lowered into the well with the help of a load and inflated with gas under pressure, displacing water into the array, after which explosives are supplied. To create an air gap in a predetermined interval of the well, lower the sleeve and inflate it, after which loading of the well is continued.

The main disadvantage of this device is the need to have a source of compressed air at the place of work.

In addition, the device has a rather complex design and low reliability, which is associated with the possibility of loss of tightness.

A device is proposed for creating dispersed charges and the formation of air gaps in wells, including an elastic sleeve with a load closed from the lower end.

The difference is that it is equipped with a rigid ring and a funnel of elastic material, the lower base of which is connected to the upper end of the sleeve, and the rigid ring is mounted in the upper base, while the diameters of the elastic sleeve and the rigid ring are made larger than the diameter of the well. In particular, the diameters of the sleeve and the rigid ring can be made, respectively, 10-20 mm and 150-250 mm larger than the diameter of the well.

The difference is also that the device may contain more than one elastic sleeve with funnels and rigid rings, while they have different lengths and are placed one in the other.

The elastic sleeve and funnel can be made of woven polypropylene.

The purpose of the utility model is to create air gaps in the borehole charges and to separate the dry upper parts of the charges from non-waterproof explosives from the lower flooded parts of the borehole charges in open pit mining in all climatic zones.

The use of charges with air gaps, in addition to improving rock crushing, reduces the average specific explosive consumption by 10-25%, and in some cases this value reaches 30-35%. The output of oversized pieces on average decreases by two to three times or more. The increase in the yield of rock mass from 1 m of the well is up to 1.5 times. In addition, the angle of slope of the ledge increases, the collapse of the blasted rock mass is more compact and convenient for excavation, while the productivity of the excavator increases by 13-50%.

The proposed device allows you to create air gaps in any part of the well and ensures their retention for a long time.

The essence of the utility model is illustrated by the drawing, where Fig. 1 shows a general view of the device, and Fig. 2 shows the placement in the well of a device forming two air gaps.

A device for creating dispersed charges and the formation of air gaps in wells contains a sleeve 1 made of an elastic material, for example, a polyethylene film, when dispersing charges from non-water-resistant explosives in the flooded part of the well, or from woven polypropylene, when dispersing charges in dry wells or in dry parts of the well. Woven polypropylene is more preferred since it is a more durable material than polyethylene. At the lower end, sleeve 1 is closed by forming a transverse seam 2. A load 3 is attached to the lower end of the sleeve to accelerate immersion in the well. The sleeve can be made from one cut of fabric, sewn from separate cuts with transverse seams, etc. The diameter of the sleeve 1 should be larger than the diameter of the well in which it will be placed. It is recommended to produce hoses with a diameter of 10-20 mm larger than the diameter of the wells. For example, for wells with a diameter of d _SLE = 160 mm, the diameter of the sleeve (d _p ) should be at least 170-180 mm, with d _SLE = 214 mm d _p = 224-234 mm, etc. Such an increase in the diameter of the sleeve provides a reliable extension of the sleeve in the well and a decrease in the load on it. At lower d _{p, the} spacer in the borehole wall decreases, and accordingly, the load on the sleeve increases, which can lead to its rupture. With an increase in d _{p by} more than 20 mm, difficulties arise in moving it along the well.

To the upper end of the elastic sleeve 1 is attached, for example, in the form of a cone funnel 4, made of the same material as the sleeve. The lower base of the funnel has the same diameter as the sleeve and is connected with it by a transverse seam 5, and a rigid ring 6 is sewn into the upper base, having a diameter (d _k ) exceeding the diameter of the well (d _well ) by 150-250

mm The ring is made of a metal bar with a diameter of 6.5 mm. The diameter of the ring is taken from the calculation of reliable overlapping of the wellhead when filling the sleeve 1 and excluding the retraction of the funnel into the well. The studies showed that the pressure of powder and granular bulk materials on the bottom or barrier in the well in the proposed device design increases only with an increase in charge height of up to 2 m. A further increase in charge height does not lead to an increase in pressure due to lateral expansion of the material into the well walls. The initial pulling force of the sleeve into the well until the material expands through the polypropylene fabric into the well walls does not exceed the weight of one linear meter of material in the well, i.e. with a bore diameter of 214 mm, this weight is 31-36 kg. With a further increase in the height of the column of powder or granular material, the pulling force will decrease, and when two meters are reached, the pulling will stop. Given the possible dynamic loads and friction forces of the material moving along the sleeve, the maximum load on a device made of woven polypropylene can be 60 kg for 5 minutes. Studies show that explosive charges with one air gap in small-block and highly weathered rocks can be rationally used for charges up to 12 m long, in medium-sized large-block rocks - up to 18 m long, in strong very and very large-block rocks - up to 24-27 m. With a larger charge length, it is necessary to use several dispersion intervals.

Figure 2 shows an example of the use of the device when the charge is dispersed by two air gaps. The number and magnitude of air gaps, the magnitude of the individual parts of the charge, and also the stemming height for each well are determined by calculation. To create two air gaps in the well, a device containing two elastic arms with funnels and rings is used. The first part 8 of the charge is poured into the well 7 with a diameter of 214 mm to the place of formation of the first air gap 9, after which the sleeve 1 is lowered into the well

the length of which corresponds to the length of the well to the first air gap 9. Under the action of the load 3, sleeve 1 hangs in the well on the funnel ring 6. The second charge part 10 is poured into the sleeve 1 through the funnel, above which a second air gap 11 is created. To create this air gap, a second sleeve 12 with a load 13, a funnel 14 and a ring 15 is introduced into the sleeve 1. The length of the sleeve 12 is taken so that between the second part 10 of the charge and the lower end of the sleeve 12, an air gap 11 of a predetermined value was formed. After that, the third part 16 of the charge is poured into the sleeve 12 and the stemming unit 17 is introduced. Initiation of all parts of the dispersed charge is carried out simultaneously, for example, using a detonating cord laid along the entire length of the well.

The device has a simple design and provides reliable charge dispersion by air gaps.

Claims (4)

1. A device for creating dispersed charges and the formation of air gaps in wells, including a sleeve closed from the lower end of an elastic material with a load, characterized in that it is equipped with a rigid ring and a funnel of elastic material, the lower base of which is connected to the upper end of the sleeve, and a rigid ring is mounted in the upper base, while the diameters of the sleeve and the rigid ring are made larger than the diameter of the well. 2. The device according to claim 1, characterized in that the diameters of the sleeve and the rigid ring are made, respectively, 10-20 mm and 150-250 mm larger than the diameter of the well. 3. The device according to claim 1, characterized in that it contains at least two sleeves of different lengths with a funnel and rigid rings placed one in the other. 4. The device according to any one of claims 1 to 3, characterized in that the sleeve and funnel are made of woven polypropylene.