CN111589537A

CN111589537A - Ore wet-type crushing equipment

Info

Publication number: CN111589537A
Application number: CN202010237149.7A
Authority: CN
Inventors: 赵丽丽
Original assignee: Pan'an Yelian Coal Mine Equipment Co ltd
Current assignee: Pingquan Dechang calcium Industry Co., Ltd
Priority date: 2020-03-30
Filing date: 2020-03-30
Publication date: 2020-08-28

Abstract

The invention discloses wet ore crushing equipment, which comprises a casing, wherein a feeding cavity with an opening at the upper end communicated with the outside is arranged in the casing, a control cavity communicated with the feeding cavity is arranged in the lower end wall of the feeding cavity, a falling cavity is arranged in the casing, a rotating cavity is arranged in the left end wall of the control cavity, a crushing cavity is arranged in the casing, a power cavity is arranged in the upper end wall of the crushing cavity, a water storage cavity with an upper end communicated with the outside is arranged in the right end wall of the power cavity, a drying cavity is arranged in the left end wall of the falling cavity, a heating plate is arranged at the communication part of the drying cavity and the falling cavity, a fan is arranged in the drying cavity, a driving cavity is arranged in the casing, a containing cavity is arranged in the lower end wall of the control cavity, a bearing plate capable of descending along with the weight of ore is arranged in the casing, a crushing shaft is, and the lower end wall of the driving cavity is fixedly connected with a driving motor.

Description

Ore wet-type crushing equipment

Technical Field

The invention relates to the technical field of ores, in particular to wet ore crushing equipment.

Background

However, the existing ore crushing devices, such as jaw crushers, roller crushers and the like, have the disadvantages of large volume, high energy consumption and uneven ore crushing particles, are not suitable for ore crushing work in rooms or other small places and cannot well crush ores convenient to part of wet crushing, the quantity of ores crushed by one time by the existing crushers is often manually controlled, the quantity of ores crushed by one time is not equal, and if too many ores are crushed by one time, the crushing effect is poor.

Disclosure of Invention

The object of the present invention is to provide a wet ore crushing plant that overcomes the above-mentioned drawbacks of the prior art.

The wet ore crushing equipment comprises a casing, wherein a feeding cavity with an upper end opening communicated with the outside is arranged in the casing, a moving cavity is arranged in the left end wall of the feeding cavity, a control cavity communicated with the feeding cavity is arranged in the lower end wall of the feeding cavity, a lifting cavity is arranged in the lower end wall of the control cavity, a rotating cavity is arranged in the left end wall of the control cavity, a crushing cavity is arranged in the casing, a communicating cavity communicated with the control cavity and the crushing cavity is arranged in the casing, a power cavity is arranged in the upper end wall of the crushing cavity, a water storage cavity with an upper end communicated with the outside is arranged in the right end wall of the power cavity, a falling cavity with a lower end communicated with the outside and an upper end communicated with the crushing cavity is arranged in the lower end wall of the crushing cavity, a drying cavity is arranged in the left end wall of the falling cavity, a heating plate is arranged at, the heating plate can heat the air fanned out by the fan when being started so as to dry the ores, a translation cavity is arranged in the right end wall of the falling cavity, a driving cavity is arranged in the shell, an accommodating cavity is arranged in the lower end wall of the control cavity, a quantitative mechanism is arranged among the feeding cavity, the control cavity, the moving cavity, the lifting cavity and the lifting cavity, a crushing mechanism is arranged among the power cavity, the crushing cavity, the water storage cavity, the falling cavity, the translation cavity and the containing cavity, the driving cavity and the rotating cavity are directly provided with a transmission mechanism, the quantitative mechanism comprises a bearing plate which can descend along with the weight of the ore, the crushing mechanism comprises a crushing cutter rotating in the crushing cavity, the crushing shaft is provided with a crushing cavity capable of crushing ores, and the transmission mechanism comprises a driving motor fixedly connected with the lower end wall of the driving cavity.

On the basis of the technical scheme, the transmission mechanism comprises a driving shaft in power connection with the driving motor, a driving dial plate is fixedly connected with the driving shaft, the lower end wall of the driving cavity is rotatably connected with a transmission shaft, the lower end of the transmission shaft is fixedly connected with a transmission grooved pulley meshed with the driving dial plate, the upper end of the transmission shaft is fixedly connected with a transmission gear, the lower end wall of the driving cavity is rotatably connected with a rotating shaft, the upper end of the rotating shaft is positioned in the rotating cavity, the lower end of the rotating shaft is fixedly connected with a driven gear meshed with the transmission gear, the diameters of the transmission gear and the driven gear are four to one, the upper end surface of the rotating shaft is fixedly connected with a rotating disc, a moving plate is slidably connected in the rotating cavity, the right end surface of the moving plate is fixedly connected with a moving block, the right end of, the lower end wall of the driving cavity is rotatably connected with a winding shaft, and the upper end of the winding shaft is fixedly connected with a winding grooved wheel meshed with the driving plate.

On the basis of the technical scheme, the quantitative mechanism comprises a stop plate which is connected in a sliding manner in the moving cavity, a stop spring which is fixedly connected with the left end wall of the moving cavity and the stop plate is arranged in the moving cavity, the moving cavity is communicated with the driving cavity, a connecting rope which is connected with the left end surface of the stop plate and the lower end of the winding shaft is arranged at the communication position, the left end surface of the control cavity is fixedly connected with a moving block, a control plate is connected in a sliding manner in the lifting cavity, the upper end surface of the control plate is fixedly connected with a connecting rod of which the other end is fixedly connected with the bearing plate, a vertical spring which is connected with the control plate and the lower end wall of the lifting cavity is arranged in the lifting cavity, the upper end of the sliding connection is provided with a sealing plate which is positioned in the control cavity, the lower, and a traction rope for connecting the lower end face of the connecting plate and the lower end of the winding shaft is arranged at the position communicated with the driving cavity.

On the basis of the technical scheme, the crushing mechanism comprises a crushing motor fixedly connected with the upper end wall of the power cavity, the crushing motor is in power connection with the crushing shaft, the lower end wall of the left side of the water storage cavity is provided with a water pump, the water pump is communicated with the crushing cavity, the translation cavity is internally and slidably connected with a translation plate, the left end surface of the translation plate is fixedly connected with a sealing plate of which the left end is positioned in the falling cavity, the left end wall of the sealing plate is internally provided with a sensor positioned in the falling cavity, the right end wall of the translation cavity is fixedly connected with an electromagnet, the translation cavity is internally provided with a connecting spring for connecting the translation plate with the electromagnet, the communication part of the translation cavity and the accommodating cavity is provided with a rope for connecting the left end surface of the translation plate and the lower end surface of the switch, and the accommodating cavity is internally provided, the front end wall of the right side of the falling cavity is rotatably connected with a rotating pin, and a baffle is fixedly connected to the rotating pin.

On the basis of the technical scheme, the driving drive plate just drives the winding grooved wheel to rotate, the elastic force of the sealing spring is larger than the sum of the elastic force of the sealing plate, the gravity of the connecting plate and the elastic force of the blocking spring, the control plate is in contact with the switch to start the driving motor to output power so as to drive the driving shaft to rotate for a circle, the driving motor is started to start the crushing motor and the water storage cavity for starting fixed time after being closed, the fan, the sensor, the heating plate and the electromagnet are started when the crushing motor stops, the sensor can detect whether ore falls, the fan, the sensor, the heating plate and the electromagnet are closed when the ore falls, and the electromagnet is started to attract the translation plate and the attraction force is larger than the elastic force of the connecting spring.

The invention has the beneficial effects that: according to the invention, the crushing shaft and the crushing cutter arranged on the crushing shaft are arranged, so that ores can be crushed, the water pump and the water storage tank are arranged, water can be injected when the ores are crushed, so that the wet crushing of the ores is realized, the crushing effect of the ores is good, meanwhile, the heating plate and the fan are also arranged, the crushed ores can be dried, and the subsequent transportation or treatment is convenient.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic view of a wet ore crushing plant according to the present invention;

FIG. 2 is an enlarged schematic view of the structure of FIG. 1 according to an embodiment of the present invention;

fig. 3 is an enlarged schematic view of the sheave mechanism according to an embodiment of the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-3, for the sake of convenience, the orientations described hereinafter being defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1-3, a wet ore crushing apparatus according to an embodiment of the present invention includes a casing 10, a feeding cavity 31 having an upper end opening communicating with the outside is provided in the casing 10, a moving cavity 24 is provided in a left end wall of the feeding cavity 31, a control cavity 27 communicating with the feeding cavity 31 is provided in a lower end wall of the feeding cavity 31, a lifting cavity 48 is provided in a lower end wall of the control cavity 27, a rotating cavity 17 is provided in a left end wall of the control cavity 27, a crushing cavity 39 is provided in the casing 10, a communicating cavity 33 communicating the control cavity 27 and the crushing cavity 39 is provided in the casing 10, a power cavity 34 is provided in an upper end wall of the crushing cavity 39, a water storage cavity 37 having an upper end communicating with the outside is provided in a right end wall of the power cavity 34, a falling cavity 42 having a lower end communicating with the outside and an upper end communicating with the crushing cavity 39 is provided in a lower end wall of the crushing cavity 39, the drying cavity 44 and the connection position of the falling cavity 42 are provided with a heating plate 43, a fan 45 is arranged in the drying cavity 44, the heating plate 43 can heat air fanned out by the fan 45 when being started, so as to dry ores, a translation cavity 62 is arranged in the right end wall of the falling cavity 42, a driving cavity 11 is arranged in the casing 10, a 66 is arranged in the casing 10, a containing cavity 51 is arranged in the lower end wall of the control cavity 27, a feeding cavity 31, the control cavity 27, a moving cavity 24, the 66 and a quantitative mechanism 70 is arranged between the lifting cavity 48, a power cavity 34, a crushing cavity 39, a water storage cavity 37, the falling cavity 42, the translation cavity 62 and the containing cavity 51 are provided with a crushing mechanism 71, the driving cavity 11 and the rotating cavity 17 are directly provided with a transmission mechanism 72, the quantitative mechanism 70 comprises a bearing plate 28 capable of descending along with the weight of ores, the crushing mechanism 71 comprises a crushing shaft 40 which rotates in the crushing cavity 39, a crushing knife which can crush ores is arranged on the crushing shaft 40, and the transmission mechanism 72 comprises a driving motor 55 which is fixedly connected with the lower end wall of the driving cavity 11.

In addition, in one embodiment, the transmission mechanism 72 includes a driving shaft 56 in power connection with the driving motor 55, a driving dial 54 fixedly connected to the driving shaft 56, a transmission shaft 58 rotatably connected to a lower end wall of the driving cavity 11, a transmission grooved pulley 57 engaged with the driving dial 54 and fixedly connected to a lower end of the transmission shaft 58, a transmission gear 14 fixedly connected to an upper end of the transmission shaft 58, a rotating shaft 12 having an upper end located in the rotating cavity 17 and rotatably connected to a lower end wall of the driving cavity 11, a driven gear 13 engaged with the transmission gear 14 and fixedly connected to a lower end of the rotating shaft 12, the transmission gear 14 and the driven gear 13 have a diameter of four to one, a rotating disc 20 fixedly connected to an upper end face of the rotating shaft 12, a moving block 21 having a right end located in the moving plate control cavity 27 and fixedly connected to a right end face of the moving plate 19, the movable plate 19 is provided with a groove therein, the groove is rotatably connected with a rotating pin 18 with a lower end fixedly connected with the upper end surface of the rotating disc 20, the lower end wall of the driving cavity 11 is rotatably connected with a winding shaft 52, and the upper end of the winding shaft 52 is fixedly connected with a winding grooved wheel 53 engaged with the driving dial 54.

In addition, in one embodiment, the quantitative mechanism 70 includes a blocking plate 25 slidably connected in the moving cavity 24, a blocking spring 23 fixedly connected between the left end wall of the moving cavity 24 and the blocking plate 25 is disposed in the moving cavity 24, a connecting rope 22 connected between the left end surface of the blocking plate 25 and the lower end of the winding shaft 52 is disposed at a position where the moving cavity 24 is communicated with the driving cavity 11 and the communicating position, the moving block 21 is fixedly connected in the control cavity 27, the control plate 16 is slidably connected in the lifting cavity 48, a connecting rod 29 fixedly connected between the upper end surface of the control plate 16 and the receiving plate 28 is fixedly connected in the upper end surface of the control plate 16, a vertical spring 15 connecting the control plate 16 and the lower end wall of the lifting cavity 48 is disposed in the lifting cavity 48, and a sealing plate 32 with an upper end located in the control cavity 27 is slidably connected in the lifting, the lower end of the sealing plate 32 is fixedly connected with a connecting plate 41, a sealing spring 46 for connecting the connecting plate 41 and the lower end wall of the connecting plate 66 is arranged in the sealing plate 66, the connecting plate 66 is communicated with the driving cavity 11, and a traction rope 47 for connecting the lower end face of the connecting plate 41 and the lower end of the winding shaft 52 is arranged at the communication position.

In addition, in one embodiment, the crushing mechanism 71 includes a crushing motor 35 fixedly connected to the upper end wall of the power cavity 34, the crushing motor 35 is in power connection with the crushing shaft 40, the lower end wall of the left side of the water storage cavity 37 is provided with a water pump 36, the water pump 36 is communicated with the crushing cavity 39, a translation plate 65 is slidably connected to the translation cavity 62, the left end surface of the translation plate 65 is fixedly connected with a closing plate 67 whose left end is located in the falling cavity 42, a sensor 59 located in the falling cavity 42 is arranged in the left end wall of the closing plate 67, the right end wall of the translation cavity 62 is fixedly connected with an electromagnet 63, a connecting spring 64 connecting the translation plate 65 and the electromagnet 63 is arranged in the translation cavity 62, the translation cavity 62 is communicated with the accommodating cavity 51, and a rope 50 connecting the left end surface of the translation plate 65 and the lower end surface of the switch 49 is arranged in the communication, a return spring 68 connected with the switch 49 and the lower end wall of the accommodating cavity 51 is arranged in the accommodating cavity 51, a rotating pin 61 is rotatably connected with the right front end wall of the falling cavity 42, and a baffle 60 is fixedly connected on the rotating pin 61.

In addition, in one embodiment, the drive dial 54 just drives the wrap sheave 53 to rotate, the elastic force of the sealing spring 46 is greater than the sum of the weight of the sealing plate 32 and the connecting plate 41 and the elastic force of the blocking spring 23, contact of the control panel 16 with the switch 49 activates the drive motor 55 to output power, thereby driving the driving shaft 56 to rotate for one circle, starting the crushing motor 35 and the water storage cavity 37 for a fixed time after the driving motor 55 is switched off, the fan 45, the sensor 59, the heating plate 43 and the electromagnet 63 are activated when the crushing motor 35 is stopped, the sensor 59 is started to detect whether ore falls or not, the fan 45, the sensor 59, the heating plate 43 and the electromagnet 63 are closed when the ore fall is not detected, the electromagnet 63 is activated to attract the translational plate 65 and the attraction force is larger than the elastic force of the connecting spring 64.

In the initial state, the blocking plate 25 is located at the leftmost position, the push plate 26 is located at the leftmost position, the sealing plate 32 is located at the uppermost position, the switch 49 is located at the uppermost position, the closing plate 67 is located at the leftmost position, the blocking spring 23 is in a compressed state, the vertical spring 15 is in a relaxed state, the sealing spring 46 is in a compressed state, and the connecting spring 64 is in a relaxed state.

When crushing ore, ore is put into the receiving plate 28 in the control cavity 27 through the feeding cavity 31, along with the increase of ore, the receiving plate 28 is moved downward by the gravity of ore, thereby driving the connecting rod 29 to move downward, thereby driving the control plate 16 to move downward and compressing the vertical spring 15, when the ore reaches a certain weight, the receiving plate 28 is lowered to the lowest position, thereby driving the connecting rod 29 and the control plate 16 to be lowered to the lowest position, thereby contacting the switch 49, the switch 49 starts the driving motor 55 to output power, thereby driving the driving shaft 56 to rotate for one circle, the driving shaft 56 rotates to drive the driving dial 54 to rotate, thereby driving the winding sheave 53 to rotate for one quarter of a circle, the winding sheave 53 rotates to drive the winding shaft 52 to rotate, the winding shaft 52 rotates to loosen the connecting rope 22, thereby the blocking plate 25 moves rightward to separate the feeding cavity 31 from the outside under the elastic force of the blocking spring 23, simultaneously, the shaft 52 is wound to wind the traction rope 47, so that the connecting plate 41 is pulled to move downwards and compress the sealing spring 46, the connecting plate 41 descends to enable the control cavity 27 to be communicated with the communication cavity 33, the driving dial 54 continuously rotates to drive the driving grooved pulley 57 to rotate for a quarter of a circle, so that the driving shaft 58 is driven to rotate for a quarter of a circle, so that the driving gear 14 is driven to rotate for a quarter of a circle, so that the driven gear 13 is driven to rotate for a circle, so that the rotating disc 20 is driven to rotate for a circle, so that the rotating pin 18 is driven to move rightwards and then leftwards to return to the initial position, so that the moving plate 19 and the moving block 21 are driven to move rightwards and then leftwards to return to the initial position, so that the push plate 26 is driven to move rightwards and then leftwards to return to the, then the driving motor 55 is turned off, the connecting plate 41 and the sealing plate 32 move upwards under the action of the elastic force of the sealing spring 46 to return to the initial position, so that the pulling rope 47 is pulled to drive the winding shaft 52 to rotate, the connecting rope 22 is wound to drive the blocking plate 25 to return to the initial position and compress the blocking spring 23, the feeding cavity 31 is communicated with the control cavity 27, and the ore is continuously put in;

ore enters the crushing cavity 39, the crushing motor 35 starts output power, thereby driving the crushing shaft 40 to rotate, thereby crushing the ore through the crushing cutter 38, meanwhile, the water pump 36 starts to pump water in the water storage cavity 37 into the crushing cavity 39, thereby assisting the crushing of the ore, after the ore crushing is completed, the crushing motor 35 and the water pump 36 are closed, the electromagnet 63 starts to attract the translation plate 65 to move rightwards to compress the connecting spring 64, the translation plate 65 moves rightwards to drive the closing plate 67 and the sensor 59 to move rightwards, so that the closing plate 67 no longer blocks the movement of the baffle 60, meanwhile, the translation plate 65 moves rightwards to drive the switch 49 to move downwards through the rope 50 and compress the reset spring 68, so that the switch 49 enters the accommodating cavity 51, so that the switch 49 cannot be contacted, meanwhile, the baffle 60 rotates around the rotating pin 61 under the gravity action of the crushed ore, so that the crushing cavity 39 is communicated with the, the ore after the breakage drops to the external world through whereabouts chamber 42, sensor 59 simultaneously, fan 45 starts with dry chamber 44, sensor 59 starts to detect the ore of whereabouts, fan 45 fan gets into the interior dry with the ore of whereabouts chamber 42 through heating plate 43 heating, accomplish the breakage of ore, sensor 59 detects and closes electro-magnet 63 behind the ore that does not fall, fan 45, hot plate 43, translation board 65 under the effect of coupling spring 64 elasticity, closing plate 67, sensor 59 gets back to initial position, drive baffle 60 and return to initial position, switch 49 gets back to initial position under the effect of reset spring 68 elasticity, the device is accomplished and is reset.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. An ore wet-type crushing device comprises a casing, wherein a feeding cavity with an upper end opening communicated with the outside is arranged in the casing, a moving cavity is arranged in the left end wall of the feeding cavity, a control cavity communicated with the feeding cavity is arranged in the lower end wall of the feeding cavity, a lifting cavity is arranged in the lower end wall of the control cavity, a rotating cavity is arranged in the left end wall of the control cavity, a crushing cavity is arranged in the casing, a communicating cavity communicated with the control cavity and the crushing cavity is arranged in the casing, a power cavity is arranged in the upper end wall of the crushing cavity, a water storage cavity with an upper end communicated with the outside is arranged in the right end wall of the power cavity, a falling cavity with a lower end communicated with the outside and an upper end communicated with the crushing cavity is arranged in the lower end wall of the crushing cavity, a drying cavity is arranged in the left end wall of the falling cavity, the heating plate can heat the air fanned out by the fan when being started so as to dry the ores, a translation cavity is arranged in the right end wall of the falling cavity, a driving cavity is arranged in the machine shell, a containing cavity is arranged in the lower end wall of the control cavity, a quantitative mechanism is arranged among the feeding cavity, the control cavity, the moving cavity and the lifting cavity, a crushing mechanism is arranged among the power cavity, the crushing cavity, the water storage cavity, the falling cavity, the translation cavity and the containing cavity, the driving cavity and the rotating cavity are directly provided with a transmission mechanism, the quantitative mechanism comprises a bearing plate which can descend along with the weight of the ore, the crushing mechanism comprises a crushing shaft rotating in the crushing cavity, a crushing knife capable of crushing ores is arranged on the crushing shaft, and the transmission mechanism comprises a driving motor fixedly connected with the lower end wall of the driving cavity.

2. A wet ore crushing plant as claimed in claim 1 wherein: the transmission mechanism comprises a driving shaft in power connection with the driving motor, a driving drive plate is fixedly connected with the driving shaft, the lower end wall of the driving cavity is rotatably connected with a transmission shaft, the lower end of the transmission shaft is fixedly connected with a transmission grooved pulley meshed with the driving drive plate, the upper end of the transmission shaft is fixedly connected with a transmission gear, the lower end wall of the driving cavity is rotatably connected with a rotating shaft, the upper end of the rotating shaft is positioned in the rotating cavity, the lower end of the rotating shaft is fixedly connected with a driven gear meshed with the transmission gear, the diameters of the transmission gear and the driven gear are four to one, the upper end surface of the rotating shaft is fixedly connected with a rotating disc, the rotating cavity is internally and slidably connected with a moving plate, the right end surface of the moving plate is fixedly connected with a moving block, the right end, the lower end wall of the driving cavity is rotatably connected with a winding shaft, and the upper end of the winding shaft is fixedly connected with a winding grooved wheel meshed with the driving plate.

3. A wet ore crushing plant as claimed in claim 2 wherein: the quantitative mechanism comprises a stop plate which is connected in a sliding way in the moving cavity, a stop spring which is fixedly connected with the left end wall of the moving cavity and the stop plate is arranged in the moving cavity, the moving cavity is communicated with the driving cavity, a connecting rope which is connected with the left end surface of the stop plate and the lower end of the winding shaft is arranged at the communication position, the left end surface of the control cavity is fixedly connected with the moving block, the lifting cavity is internally connected with a control plate in a sliding way, the upper end surface of the control plate is fixedly connected with a connecting rod of which the other end is fixedly connected with the bearing plate, a vertical spring which is connected with the control plate and the lower end wall of the lifting cavity is arranged in the lifting cavity, a sealing plate of which the upper end is positioned in the control cavity is connected in the sliding way, a connecting, and a traction rope for connecting the lower end face of the connecting plate and the lower end of the winding shaft is arranged at the position communicated with the driving cavity.

4. A wet ore crushing plant as claimed in claim 2 wherein: the crushing mechanism comprises a crushing motor fixedly connected with the upper end wall of the power cavity, the crushing motor is in power connection with the crushing shaft, the lower end wall of the left side of the water storage cavity is provided with a water pump, the water pump is communicated with the crushing cavity, the translation cavity is internally and slidably connected with a translation plate, the left end surface of the translation plate is fixedly connected with a sealing plate of which the left end is positioned in the falling cavity, the left end wall of the sealing plate is internally provided with a sensor positioned in the falling cavity, the right end wall of the translation cavity is fixedly connected with an electromagnet, the translation cavity is internally provided with a connecting spring for connecting the translation plate with the electromagnet, the translation cavity is communicated with the accommodating cavity, the communicating part of the translation cavity and the accommodating cavity is provided with a rope for connecting the left end surface of the translation plate and the lower end surface of the switch, the accommodating cavity is internally provided with a reset, and the rotating pin is fixedly connected with a baffle.

5. A wet ore crushing plant as claimed in claim 4 wherein: the driving plate drives the winding grooved wheel to rotate just, the elastic force of the sealing spring is larger than the sum of the elastic force of the sealing plate, the gravity of the connecting plate and the elastic force of the blocking spring, the control plate is in contact with the switch to start the driving motor to output power so as to drive the driving shaft to rotate for a circle, the crushing motor and the water storage cavity are started for starting fixed time after the driving motor is closed, the fan, the sensor, the heating plate and the electromagnet are started when the crushing motor stops, the sensor can detect whether ore falls or not, the fan, the sensor, the heating plate and the electromagnet are closed when the ore cannot fall, and the electromagnet is started to attract the translation plate and the attraction force is larger than the elastic force of the connecting spring.