RU92171U1 - EXPLOSION DEVICE (OPTIONS) - Google Patents

Abstract

The utility model relates to the field of blasting, in particular to systems and means of blasting.

The essence of the utility model: an explosive device for autonomous operation consists of an explosive high-frequency device UVV-1M, an electric explosion circuit of induction electric detonators with a transformer protection unit and an electric wire and inductor connected at one end to an explosive high-frequency device UVV-1M, and at the other end to electric wire of an electric explosion network; during remote operation, the blasting device contains a remote control.

The utility model is aimed at increasing the efficiency of blasting operations by increasing the reliability, reliability and safety of operations when initiating a small number of induction electric detonators with a transformer protection unit.

3 of FIG.

Description

The utility model relates to the field of blasting, in particular to systems and means of blasting.

Known blasting device, including an explosive high-frequency device UVV-1M, a remote control connected by a two-wire remote control line up to 1.5 km long from a wire with a resistance of not more than 50 Ohm / km to an explosive high-frequency device UVV-1M through a connector on its side surface (1) accepted by the authors as a prototype.

The high-frequency explosive device UVV-1M (hereinafter referred to as UVV-1M) is designed to initiate up to 100 series-connected electric detonators with a transformer protection unit of type ED-24, EDZI with an inductance of 2 μH each and is intended for explosive work on the earth's surface and in underground mines and mines that are not dangerous for gas or dust, dangerous for manifestations of stray currents, leakage currents, static electricity and electromagnetic effects. UVV-1M operates both in stand-alone mode and in remote control mode via a two-wire line up to 1.5 km long with a remote control located outside the danger zone. The blast network is carried out by an electric wire of the VP1x0.8 brand, the inductance of a single wire is 0.7-0.8 μH / m, and the twisted electrical wire of the same brand is 0.8 μH / m.

The UVV-1M is equipped with 3 pairs of clamps for connecting the explosive circuit, designed for different nominal parameters in resistance and inductance, allowing the use of explosive lines with different lengths of electrical wires:

- clamps 1-2 R _n = (35 + 5) Ohm, L _n ⁼ (550 + 150) μH, (35-10) (550-100) - clamps 1-3 R _n = (45 + 5) Ohm, L _n = 900 ± 100 μH, (45-10) clamps 1-4 R _n = 60 ± 10 Ohms L _n = 1300 ± 100 μH,

where: -R _H is the nominal value of the active resistance of the electric explosion circuit, Ohm,

- L _H is the nominal value of the inductance of the electric explosive circuit, μH.

Depending on the number of induction electric detonators, the length of the connecting and main electric wires changes the magnitude of the electrical resistance and inductance of the entire explosive network. Therefore, before the explosion, the actual resistance of the explosive circuit (R _f ) is checked for compliance with R _n by measurement with a special device.

The actual inductance of the explosive circuit (L _f ) is estimated by calculation by the formula:

L _f = L _mag + nL _ed , μH,

Where:

-L _magician - the inductance of the line, depends on the length and brand of the electric wire;

-n is the number of detonators connected to the circuit;

-L _ed - the inductance of one electric detonator,

or measure with a special instrument. The actual values of the inductance L _f and resistance (R _f ) are compared with the nominal parameters L _H and R _H UVV-1M. Depending on the actual values of R _f and L _{f, the} explosive circuit is connected to terminals 1-2, 1-3, 1-4 in accordance with the characteristics of air-blast-1M in accordance with R _H and L _H.

In industrial practice, especially in the production of special blasting operations, it becomes necessary to produce explosive explosives using a limited number of induction electric detonators. For example, for a number of cases with the use of 1-2 induction electric detonators with a shortened main wire, it becomes impossible to use the UVV-1M due to the mismatch between the electrical parameters of the electric blasting circuit and the permissible nominal values of R _n and L _n . In this case, the inductance of the explosive circuit of the blasting device will be significantly less than the nominal value of the inductance at any of the UVV-1M clamps, therefore the blasting device - the prototype cannot provide trouble-free and safe operation for the explosion of the explosive charge.

The technical task of creating a utility model is to ensure the reliability, reliability and safety of using the blasting device when an explosive pulse is supplied to detonate up to 10 electric detonators of the type ED-24, EDZI with a transformer protection unit or similar electrical parameters during blasting operations.

The problem was solved by the development of an explosive device and its version, working in stand-alone mode and in remote control mode:

- option 1 - for offline operation -

- an explosive device comprising an explosive high-frequency device UVV-1M and an electric explosion network consisting of induction electric detonators with a transformer protection unit and an electric wire, which further comprises an inductor connected at one end to an explosive high-frequency device UVV-1M, and the other end to an electric wire electric explosion network;

- option 2 - for remote operation -

- an explosive device including an explosive high-frequency device UVV-1M, an electric explosion network consisting of induction electric detonators with a transformer protection unit and an electric wire, a remote control connected to the explosive high-frequency device UVV-1M by a two-wire remote control line, which further comprises an inductor, connected at one end to an explosive high-frequency device UVV-1M, and at the other end to an electric wire of an electric explosion network;

The inductor is a dielectric tube on which an insulated electric wire is wound and designed to balance the parameters of the explosive circuit. It has equal inductance and resistance, for example, 900 μH and 50 Ohms. An explosive circuit simulator included in the UVV-1M kit, which is used for prestart control for the failure-free operation of an explosive device, can also be used as an inductor.

The utility model is illustrated in figures 1-3.

Figure 1 - blasting device for offline operation, consisting of an explosive high-frequency device UVV-1M, an inductor (simulator of an explosive circuit) and a first induction electric detonator.

Figure 2 - an explosive device for remote operation, consisting of an explosive high-frequency device UVV-1M, a remote control, an inductor (simulator of an explosive circuit) and a first induction electric detonator.

Figure 3 - view of the front panel of the remote control.

UVV-1M is structurally made in the form of a rectangular housing 1, in which a power supply and two circuit boards with an electronic circuit are located. On the front panel of UVV-1M there are clamps 2 (1-2, 1-3, 1-4) for connecting the explosive circuit, lettering is applied - LED indicators - power, pulse and explosion, switch socket 3 for the key, which is closed with a plug. An impulse can be supplied to detonate electric detonators by turning the key 4 on the front panel of the UVV-1M or using the remote control 5 located outside the danger zone. On the side wall of the UVV-1M there is a connector 6 for connecting it to the remote control and is closed with a plug inoperative. The bottom case is closed by a cover, which is attached to the case with four screws. The case is equipped with a handle 7 for carrying.

The remote control is designed to supply an explosion signal to the explosive circuit of electric detonators through the UVV-1M, as well as for prestart control of the UVV-1M, to check the charging of capacitors and the integrity of the explosive circuit. The remote control provides protection against unauthorized activation of UVV-1M. The remote control is structurally made in the form of a box in which the power supply and the circuit board with an electronic circuit are located. The remote control is closed by a lid 9, which is attached to the box using two hinges and a lock. On the outside of the lid is a belt for carrying it. On the front panel of the remote control there are lettering - LED indicators - on, off, ready, there are tumblers B1, B2, B3, a start button, a cover for the power compartment.

The main wire of the electric blasting circuit 10 is intended for laying a surface electric blasting network and is made of an electric wire for blasting of the VP1x0.8 or VP1x0.7 brand

The two-wire remote control line 11 is designed to connect the remote control to the UVV-1M and is made of a wire with a resistance of not more than 50 Ohm / km with connectors 6 and 12 at the ends in the form of a plug of type 2RM14KPN4G1V1 and a socket of type 2RM14KPN4Sh1V1, closed with plugs in idle mode, and provides the possibility of placing the remote control of the explosion at a distance of 1.5 km from the place of detonation of electric detonators 14.

The inductor 12 is connected at one end to the terminal 2 of the explosive high-frequency device UVV-1M, and at the other end to the electric wire 13 of the electric explosive network 10 in series with the induction electric detonator 14.

The operation order of UVV-1M in stand-alone mode:

The prepared and tested explosive circuit 10 is connected to terminals 2 (1-2, 1-3, 1-4) of the UVV-1M depending on the length of the explosive chain, the plug of the switch socket is turned off and the key 4 is inserted into socket 3. The key is rotated to the EXPLOSION position and is held in this position until the PULSE indicator lights up. After the explosion, the key is transferred to its original position, removed from the socket of the switch, the socket is closed with a plug. Explosive circuit wires are disconnected from the clamps and shorted.

The operation order of the UVV-1M in remote explosion control mode.

The prepared and tested explosive circuit 10 is connected to the terminals 2 (1-2, 1-3, 1-4) of the UVV-1M depending on the length of the explosive chain (values of R _f and L _f ).

During operation, the remote control line 11 is connected at one end to the UVV-1M connector 6, and the other end of the line, after removing the plugs, is connected to the remote control line connector 8.

The detonation of detonators is as follows:

On the UVV-1M, the plug is turned off from the switch socket and the key is inserted into the socket. The key rotates to the ON position. The POWER indicator should light up.

On the remote control, the toggle switch B1 is turned on. After a few seconds, the READY and OFF indicators should start flashing. Then the toggle switch B2 is set to the ON position.

The START button is pressed and released. On this command, the ON indicator should start flashing. The sound signal confirms that the storage capacitors UVV-1M are charging. After the end of the charge (as indicated by the termination of the sound signal), the START button on the remote control is pressed and released; UVV-1M should give explosive impulses to the load.

After the issuance of explosive pulses, the tumbler B2 on the remote control is set to the OFF position. The START button is pressed - the OFF indicator should start flashing. Toggle switch B1 is set to POWER. Remote control line 11 is disconnected from connector 8 on the remote control. From the remote control side, a cap is put on the remote control line.

The proposed blasting device allows you to detonate one or more series-connected induction electric detonators type ED-24, EDZI with a transformer protection unit or similar electrical parameters.

Example - an explosive network is made of an electric wire for blasting of the VP1x0.8 brand with an inductance of 0.8 μH / m 30 m long and one EDJI induction electric detonator with an inductance of 2 μH. An electric explosion circuit through an inductor (simulator of an explosive circuit) with an inductance of 800 μH and a resistance of 50 Ω is connected to terminals 1-3 of UVV-1M. The induction electric detonator is initiated (detonated) by an explosive high-frequency device UVV-1M using a two-wire remote control from a wire with a resistance of not more than 50 Ohm / km connected to the connectors UVV-1M and remote control. The remote control is located outside the danger zone at a distance of ~ 0.1 km from the place of detonation.

The proposed blasting device provides the claimed technical result - increasing the reliability, reliability and safety of blasting when applying an explosive pulse to detonate a small number of induction electric detonators due to:

- connecting an electric explosion circuit through an inductor (explosive circuit simulator);

- reducing the number of simultaneously detonated electric detonators to one due to the connection of an inductor (simulator of an explosive circuit) both in stand-alone mode of operation and in remote mode of operation.

The proposed blasting device and its variant has been industrially tested during blasting operations when disposing of worn tire covers with explosion energy.

Information sources

1 High-frequency explosive device UVV-1M. TU 7276-022-11692478-2001.

2 RF patent for utility model No. 66508.

Claims (2)

1. The blasting device, comprising a high-frequency explosive device UVV-1M and an electric explosion network consisting of induction electric detonators with a transformer protection unit and an electric wire, characterized in that it further comprises an inductance coil connected at one end to an explosive high-frequency device UVV-1M, and the other end - to the electric wire of the electric explosion network. 2. An explosive device, including a high-frequency explosive device UVV-1M, an electric explosion network consisting of induction electric detonators with a transformer protection unit and an electric wire, a remote control connected to the explosive high-frequency device UVV-1M by a two-wire remote control line, characterized in that it additionally contains an inductor connected at one end to an explosive high-frequency device UVV-1M, and at the other end to an electric wire ovzryvnoy network.