CN204799389U - A device for broken ore of continuous discharge - Google Patents

Abstract

The utility model provides a device for broken ore of continuous discharge, high -pressure discharge electrode part is equipped with insulating cover between the two in stretching into the deionized water container, is equipped with deionized water in the deionized water container, and the fixed low pressure discharge electrode in deionized water container middle part, is equipped with on the low pressure discharge electrode and holds the chamber, holds the chamber bottom surface and offers the sieve mesh, and the high -pressure discharge electrode stretches into the appearance chamber on the partial alignment low pressure discharge electrode, and the axis of rotation of motor is connected to high -pressure discharge electrode upper end. The beneficial effect of the utility model: can realize the broken ore of continuous discharge, overcome the electrode and discharged and have the problem at the dead angle of discharging, improve the electric crushing efficiency of ore, reduce the engineering degree of difficulty of subsequent processing ore.

Description

A kind of device for continuous discharge breaking ores

Technical field

The utility model relates to one can realize ore continuous crushing, obtains the device that certain particle diameter ore can overcome again high-low pressure sparking electrode electric discharge dead angle.

Background technology

Pulsed discharge breaking ores is the broken new technology of one grown up in the past few decades, the mechanics effect of the shock wave utilizing pulsed discharge to produce, jet or plasma channel produces destruction to ore, broken process without slungshot, produce without poisonous and harmful substance, discharge process is easy to control.When utilizing electric discharge to carry out fragmentation to ore, the ore particle of composition ore there are differences in electrical conductivity and dielectric constant, metal particle can be made more easily to come out, improve the efficiency of ore dressing, reduce the use of the harmful chemical such as sulfuric acid, hydrogen cyanide, this technology receives increasingly extensive concern in recent years.

Traditional high pressure pulse discharge breaking ores is batch-type.Its typical discharging structure is pin-barrel structure, ore is positioned between high-low pressure electrode, ore occurs broken, after several times electric discharge, is inclined to by the ore of fragmentation from discharge cavity, ore (the Kovalchuk of certain particle diameter is obtained after sieving, B., A.Kharlov, etal. (2010), High-voltagepulsedgeneratorfordynamicfragmentationofrock s, ReviewofScientificInstruments).The defect that this method exists is: one is that operation can not be continuous, and two is that broken particle diameter is not easy to control, and the ore after fragmentation needs to sieve, and the ore failing to reach broken particle diameter needs to return discharge cavity and re-starts fragmentation.

Utility model content

The utility model, for above problem, provides one can realize ore continuous crushing, and the ore obtaining certain broken particle diameter can overcome again the device that high-low pressure electric discharge exists electric discharge dead angle.

A kind of device for continuous discharge breaking ores, comprise high-voltage pulse power source, high-voltage discharging electrode, pulse transmission line, low pressure discharge electrode, deionized water container, ore deposit liquid separating apparatus, water circulation processing unit and motor, high-voltage discharging electrode part stretches in deionized water container, be provided with insulation sleeve between the two, deionized water container content has deionized water, and fix low pressure discharge electrode in the middle part of deionized water container, low pressure discharge electrode is provided with cavity volume, sieve aperture is offered in cavity volume bottom surface, high-voltage discharging electrode stretches into the cavity volume on part aligning low pressure discharge electrode, high-voltage discharging electrode upper end connects the turning cylinder of motor, be provided with insulating lid between the two, high-voltage discharging electrode is by the high pressure cable core of rotary electric contactor electrical connection burst transmissions line output terminal, the high pressure cable core of pulse transmission line input connects the high-voltage output end of high-voltage pulse power source, low pressure discharge electrode is by the low pressure cable skin of deionized water container electrical connection burst transmissions line output terminal, and the low pressure cable skin of pulse transmission line input connects the low-voltage output of high-voltage pulse power source, deionized water container bottoms sidewall connects pump one, and pump one connects ore deposit liquid separating apparatus, and ore deposit liquid separating apparatus connects ore collector and water circulation processing unit respectively, and water circulation processing unit is connected in deionized water container by pump two again.

Further, be provided with insulation sleeve between high-voltage discharging electrode and deionized water container, high-voltage discharging electrode middle part is wrapped up by insulation sleeve, and insulation sleeve is inserted on deionized water container, and insulation sleeve part stretches in deionized water container; Be provided with insulating lid between the turning cylinder of high-voltage discharging electrode upper end and motor, insulating lid and high-voltage discharging electrode upper end are fixed, and rotary electric contactor is located between insulating lid and insulation sleeve, and and are provided with connector between the high pressure cable core of burst transmissions line output terminal.

Further, insulation sleeve outer wall is provided with limited step, and limited step covers on deionized water container, and contact surface is smooth between the two.

Further, deionized water container inner wall is provided with the support level of fixing low pressure discharge electrode, and the cavity volume bottom surface of low pressure discharge electrode down, and cavity volume is opening up.

Further, high-voltage discharging electrode stretches into part near cavity volume opening.

Further, deionized water container also connects deionized water supplementary units.

Further, deionized water container is canister, deionized water container bears each component weight, inside fills deionized water, deionized water container is fixed with low pressure discharge electrode and is electrically connected, and the discharge cavity of high-voltage discharging electrode and low pressure discharge electrode composition is flooded by deionized water, and the bottom surface in deionized water container is an inclined plane, inclined plane least significant end place deionized water chamber wall connects pump one, and deionized water container bottom connects ground connection.

Further, deionized water container is provided with ore entrance, and ore connecting gear, through ore entrance, enters in deionized water container, and ore connecting gear goes out the cavity volume opening that mine mouth aims at low pressure discharge electrode.

Further, low pressure discharge electrode is provided with cavity volume, and cavity volume is hemispherical.

The beneficial effects of the utility model are: one is the electric crushing efficiency that can improve ore, reduce the engineering difficulty of subsequent treatment ore, using water wisely, reduce production cost; Two is can directly screen the ore obtaining meeting Particle size requirements; Three is that high-field electrode rotates under the drive of motor, makes the electric discharge between high-field electrode and low-field electrode more even, overcomes the problem that electric discharge exists dead angle.

Accompanying drawing explanation

Accompanying drawing 1 is the structural representation of the device for continuous discharge breaking ores.

Accompanying drawing 2 is schematic diagrames that plasma channel develops in ore.

Accompanying drawing 3 is schematic diagrames of plasma channel breaking ores.

Accompanying drawing 4 is circuit diagrams of device.

Detailed description of the invention

Below in conjunction with specific embodiment, the utility model is described in further detail:

Embodiment 1, by reference to the accompanying drawings 1-4,

A kind of device for continuous discharge breaking ores, comprise high-voltage pulse power source 17, high-voltage discharging electrode 1, pulse transmission line 14, low pressure discharge electrode 5, deionized water container 7, ore deposit liquid separating apparatus 21, water circulation processing unit 20 and motor 10, high-voltage discharging electrode 1 part to stretch in deionized water container 7, be provided with insulation sleeve 26 between the two, deionized water container 7 is built with deionized water 4, and fix low pressure discharge electrode 5 in the middle part of deionized water container 7, low pressure discharge electrode 5 is provided with cavity volume, sieve aperture is offered in cavity volume bottom surface, high-voltage discharging electrode 1 stretches into the cavity volume on part aligning low pressure discharge electrode 5, high-voltage discharging electrode 1 upper end connects the turning cylinder of motor 10, be provided with insulating lid 9 between the two, high-voltage discharging electrode 1 is electrically connected the high pressure cable core of pulse transmission line 14 output by rotary electric contactor 11, the high pressure cable core of pulse transmission line 14 input connects the high-voltage output end 15 of high-voltage pulse power source 17, low pressure discharge electrode 5 is electrically connected the low pressure cable skin of pulse transmission line 14 output by deionized water container 7, and the low pressure cable skin of pulse transmission line 14 input connects the low-voltage output 16 of high-voltage pulse power source 17, deionized water container 7 bottom surface sidewall connects pump 1, pump 1 connects ore deposit liquid separating apparatus 21, ore deposit liquid separating apparatus 21 connects ore collector 22 and water circulation processing unit 20 respectively, and water circulation processing unit 20 is connected in deionized water container 7 by pump 2 19 again.

A kind of device for continuous discharge breaking ores, insulation sleeve 26 is provided with between high-voltage discharging electrode 1 and deionized water container 7, high-voltage discharging electrode 1 middle part is wrapped up by insulation sleeve 26, and insulation sleeve 26 is inserted on deionized water container 7, and insulation sleeve 26 part stretches in deionized water container 7; Insulating lid 9 is provided with between the turning cylinder of high-voltage discharging electrode 1 upper end and motor 10, insulating lid 9 and high-voltage discharging electrode 1 upper end are fixed, rotary electric contactor 11 is located between insulating lid 9 and insulation sleeve 26, and and is provided with connector 13 between the high pressure cable core of pulse transmission line 14 output.

For a device for continuous discharge breaking ores, insulation sleeve 26 outer wall is provided with limited step 12, and limited step 12 covers on deionized water container 7, and contact surface is smooth between the two.

For a device for continuous discharge breaking ores, deionized water container 7 inwall is provided with the support level 6 of fixing low pressure discharge electrode 5, and the cavity volume bottom surface of low pressure discharge electrode 5 down, and cavity volume is opening up.

For a device for continuous discharge breaking ores, high-voltage discharging electrode 1 stretches into part near cavity volume opening.

For a device for continuous discharge breaking ores, deionized water container 7 also connects deionized water supplementary units 18.

A kind of device for continuous discharge breaking ores, deionized water container 7 is canister, deionized water container 7 bears each component weight, inside fills deionized water 4, deionized water container 7 is fixed with low pressure discharge electrode 5 and is electrically connected, the discharge cavity that high-voltage discharging electrode 1 and low pressure discharge electrode 5 form is flooded by deionized water 4, bottom surface 8 in deionized water container 7 is an inclined plane, inclined plane least significant end place deionized water chamber wall 7 connects pump 1, and bottom deionized water container 7,8 connect ground connection.

For a device for continuous discharge breaking ores, deionized water container 7 is provided with ore entrance, and ore connecting gear 25, through ore entrance, enters in deionized water container 7, and ore connecting gear 25 goes out the cavity volume opening that mine mouth aims at low pressure discharge electrode 5.

For a device for continuous discharge breaking ores, low pressure discharge electrode 5 is provided with cavity volume, and cavity volume is hemispherical.

A kind of device for continuous discharge breaking ores, deionized water container 7 wall is provided with outlet pipe 24 and connects pump 1, pump 1 connects the liquid feeding end of ore deposit liquid separating apparatus 21, the water side of ore deposit liquid separating apparatus 21 connects the water inlet end of water circulation processing unit 20, the water side of water circulation processing unit 20 is connected with deionized water container 7 by pump 2 19, and the discharge end of ore deposit liquid separating apparatus 21 is connected with the feed end of ore collector 22.

For a device for continuous discharge breaking ores, high-voltage discharging electrode 1 discharge end is single head electrode structure, double end electrode structure, three tip electrode structures and multiple head electrode structure.

A kind of device for continuous discharge breaking ores, ore 3 is placed between high-voltage discharging electrode 1 and low pressure discharge electrode 5, and ore 3 is immersed in deionized water 4, after apply high pressure-burst pulse between high-voltage discharging electrode 1 and low pressure discharge electrode 5, discharge between high-voltage discharging electrode 1 and low pressure discharge electrode 5, ore 3 is electrically shocked to be worn, and form plasma channel 2, in circuit, subsequent power continues to be injected in plasma channel 2, plasma channel 2 expanded by heating, stress rupture is produced to the ore body of surrounding, when exceeding the stress intensity of ore 3, there is fragmentation in ore 3.

A kind of device for continuous discharge breaking ores, high-voltage discharging electrode 1 and low pressure discharge electrode 5 are electric discharge mechanisms, the discharge cavity that high-voltage discharging electrode 1 and low pressure discharge electrode 5 form is flooded by deionized water 4, ore 3 to be broken is entered in the discharge cavity that high-field electrode 1 and low pressure discharge electrode 5 form by feed arrangement 25, and the sieve aperture of the ore particles after fragmentation on low pressure discharge chamber falls into deionized water container 7.

A kind of device for continuous discharge breaking ores, lower port bottom deionized water container 7 is connected with the water inlet of outlet pipe 24, the delivery port of outlet pipe 24 is connected with the water inlet of pump 1, the delivery port of pump 1 is connected with the liquid feeding end of ore deposit liquid separating apparatus 21, the water side of ore deposit liquid separative element 21 is connected with the water inlet end of unit for treating water 20, the discharge end of ore deposit liquid separative element 21 is connected with ore collector 22, the water side of unit for treating water 20 is connected with the water inlet of pump 2 19, the delivery port of pump 2 19 is connected with deionized water container 7, the delivery port of deionized water water replanishing device 18 is also connected with deionized water container 7.

A kind of device for continuous discharge breaking ores; high-voltage pulse power source 17 is short pulse generating means; primary pulse power supply is to primary pulse capacitor charging; diode D and resistance R is the protection circuit of IGCT Th; after reaching charging voltage; IGCT Th triggering and conducting; the electric current produced is coupled on secondary loop through transformer Tr; the high pressure that secondary loop produces charges to high-voltage charging electric capacity Th; when reaching certain value; spark switch S punctures, and the high pressure-burst pulse of generation transfers on load F through pulse transmission line L.To this example, load F is electric discharge chamber.

A kind of device for continuous discharge breaking ores, high-voltage pulse power source 17 produces high pressure-burst pulse, transfer on high-voltage discharging electrode 1 and low pressure discharge electrode 5 through pulse transmission line 14, cause the electric discharge between high-voltage discharging electrode 1 and low pressure discharge electrode 5, there is electrical breakdown in the ore 3 between high-field electrode 1 and voltage electrode 5, oarse-grained ore 3 is by the ore pulverized as fine particle, when particle diameter is less than the sieve aperture on the wall of low pressure discharge electrode 5 chamber, particle can enter in deionization container 7 by sieve aperture under gravity, oarse-grained ore 3 can be stayed in discharge cavity until be broken for the particle meeting less particle diameter, oarse-grained ore 3 can enter into the discharge cavity of high-voltage discharging electrode 1 and low pressure discharge electrode 5 composition through charging aperture 25 by feeding device, under the effect of repetition pulse, the continuous crushing to ore 3 can be realized.

For a device for continuous discharge breaking ores, under the drive of motor 10, the process limit that high-voltage discharging electrode 1 discharges on limit rotates.Its benefit is: effectively can avoid dead angle of discharging, and enables ore more uniformly broken.In preferred scheme, adopt multiple head electrode, the even row of electric discharge can be improved further, avoid the uneven ablation of electrode, improve the service life of sparking electrode.

A kind of device for continuous discharge breaking ores, the fine particle entering deionized water container 7 can drop to the bottom of deionized water container 7 under gravity further, the bottom of deionized water container 7 tilts, be conducive to like this collecting tiny mineral, under the effect of pump 1, broken fine particle mineral and portions of de-ionized water are delivered to ore deposit liquid separating apparatus 21 after pump one, mineral grain and deionized water 4 can be separated by ore deposit liquid separating apparatus 21, isolated mineral grain enters into ore collector 22 through slag notch, isolated deionized water enters into unit for treating water 20, unit for treating water 20 is through filtering, after the process such as ion-exchange, electrical conductivity in deionized water can be reduced further, water outlet is promoted in deionization container 7 through pump 2 19, thus realize recycling of deionized water, deionized water has certain loss in the process used, as mineral grain can take the water of a part out of, by deionized water water replanishing device 18, the deionized water of cleaning is supplemented in deionized water container 7.

A kind of device of continuous discharge breaking ores is used for the method for breaking ores, ore 3 is sent in the cavity volume on low pressure discharge electrode 5 by ore connecting gear 25, and by deionized water 4 submergence, the electric discharge chamber that high-voltage discharging electrode 1 and low pressure discharge electrode 5 form, high-voltage pulse power source 17 produces high pressure-burst pulse, high-voltage discharging electrode 1 is transferred to through pulse transmission line 14, high-voltage discharging electrode 1 and low pressure discharge electrode 5 is caused to discharge, ore 3 is made to be broken into the ore particle of fine particle size by electricity, motor 10 drives it to rotate at high-voltage discharging electrode 1 while electric discharge, make height, electric discharge between low pressure discharge electrode is more even, overcome electric discharge dead angle, the sieve aperture of ore on low pressure discharge electrode 5 after broken and fall in deionized water container 7 lower floor, it is inclined-plane bottom deionized water container 7, be provided with inclination angle, ore is assembled to side bottom inclination angle, ore deposit liquid separating apparatus 21 is entered into through outlet pipe 24 and pump 1, after isolated fragmentation, ore enters in ore collector 22, isolated water enters unit for treating water 20, after unit for treating water 20 processes, electrical conductivity of water reduces, enter deionized water container 7 through pump 2 19 to utilize further.

Although the utility model is described by reference to preferred embodiment, those of ordinary skill in the art should understand, and can be not limited to the description of above-described embodiment, in the scope of claims, can make the various changes in form and details.

Claims (9)

1. A device for continuously discharging ore crushing, comprising a high-voltage pulse power supply, a high-voltage discharge electrode, a pulse transmission line, a low-voltage discharge electrode, a deionized water container, an ore liquid separation device, a water circulation processing unit and a motor, characterized in that: high voltage The discharge electrode part extends into the deionized water container, and an insulating sleeve is arranged between the two. The deionized water container is filled with deionized water, and the middle part of the deionized water container is fixed with a low-voltage discharge electrode. A sieve hole is set on the bottom of the cavity, and the high-voltage discharge electrode extends into the cavity on the low-voltage discharge electrode. The upper end of the high-voltage discharge electrode is connected to the rotating shaft of the motor, and an insulating cover is arranged between the two. Connect the high-voltage cable core at the output end of the pulse transmission line, and connect the high-voltage cable core at the input end of the pulse transmission line to the high-voltage output end of the high-voltage pulse power supply; the low-voltage discharge electrode is electrically connected to the low-voltage cable sheath at the output end of the pulse transmission line through the deionized water container, and the low-voltage cable sheath at the input end of the pulse transmission line Connect to the low-voltage output end of the high-voltage pulse power supply; the bottom and side walls of the deionized water container are connected to the pump one, the pump one is connected to the mineral liquid separation device, and the mineral liquid separation device is respectively connected to the ore collector and the water circulation processing unit, and the water circulation processing unit is connected through the pump two into the deionized water container. 2. The device for continuous discharge ore crushing according to claim 1, characterized in that: an insulating sleeve is provided between the high-voltage discharge electrode and the deionized water container, and the insulating sleeve wraps the middle part of the high-voltage discharge electrode, and the insulating sleeve is inserted in the On the deionized water container, the insulating sleeve part extends into the deionized water container; an insulating cover is provided between the upper end of the high-voltage discharge electrode and the rotating shaft of the motor, and the insulating cover is fixed to the upper end of the high-voltage discharge electrode. There is a connecting piece between the insulating sleeve and the high-voltage cable core at the output end of the pulse transmission line. 3. The device for continuous discharge ore crushing according to claim 2, characterized in that: the outer wall of the insulating sleeve is provided with a limit step, the limit step covers the deionized water container, and the contact surface between the two is smooth. 4. The device for continuous discharge ore crushing according to claim 1, characterized in that: the inner wall of the deionized water container is provided with a support step for fixing the low-voltage discharge electrode, and the bottom of the cavity of the low-voltage discharge electrode is facing downward, and the container can accommodate Cavity opening upwards. 5. The device for continuous discharge ore crushing according to claim 1, characterized in that: the protruding part of the high-voltage discharge electrode is near the opening of the cavity. 6. The device for continuous discharge ore crushing according to claim 1, characterized in that: the deionized water container is also connected to a deionized water replenishment unit. 7. The device for continuous discharge ore crushing according to claim 1, characterized in that the deionized water container is a metal container and is safely grounded, the deionized water container bears the weight of each component, and the deionized water is filled inside, and the deionized water container is deionized. The ionized water container is fixed and electrically connected to the low-voltage discharge electrode. The discharge chamber composed of the high-voltage discharge electrode and the low-voltage discharge electrode is submerged in deionized water. The wall is connected to pump one, and the bottom of the deionized water container is connected to ground. 8. The device for continuous discharge ore crushing according to claim 1, characterized in that: the deionized water container is provided with an ore inlet, and the ore transmission mechanism enters the deionized water container through the ore inlet, and the ore is conveyed The ore outlet of the mechanism is aligned with the cavity opening of the low-voltage discharge electrode. 9. The device for continuous discharge ore crushing according to claim 1, characterized in that: the low-voltage discharge electrode is provided with a cavity, and the cavity is hemispherical.