CN112517112A

CN112517112A - Broken stone sorting machine

Info

Publication number: CN112517112A
Application number: CN202011346821.2A
Authority: CN
Inventors: 杨玉顺
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-11-26
Filing date: 2020-11-26
Publication date: 2021-03-19

Abstract

The invention relates to the field of buildings, in particular to a crushed stone separator. Can break stone; screening stone particles; cleaning the powder ash; the water circulation improves the stone breaking efficiency, reduces the environmental pollution and reduces the water consumption. Including frame main part, screening plant, perpendicular lifting device, jaw breaker, sand washing device, realized crushing stone material through the front and back extrusion motion of crushing tooth in the jaw breaker with control horizontal dislocation, washed the grit through the water washing of water pump, then the sewage reflux of sand washing advances the sedimentation tank, the water recirculation sand washing after the processing, the grit gets into and divides the sieve device sieve to fall into the stone of different granule sizes, has saved the water source, has saved electric power, has reduced the pollution.

Description

Broken stone sorting machine

Technical Field

The invention relates to the field of buildings, in particular to a crushed stone separator.

Background

The existing stone crusher has lower efficiency, serious environmental pollution and larger water consumption.

Disclosure of Invention

The invention relates to the field of buildings, in particular to a broken stone separator which can break stone; screening stone particles; cleaning the powder ash; the water circulation improves the stone breaking efficiency, reduces the environmental pollution and reduces the water consumption.

In order to solve the technical problem, the invention relates to the field of buildings, and particularly relates to a crushed stone separator which comprises a rack main body, a screening device, a vertical lifting device, a jaw type crushing device and a sand washing device.

As a further optimization of the technical scheme, the frame main body of the crushed stone separator comprises a feeding conveying belt motor, a feeding conveying belt, a medium sand conveying belt motor, a fine sand conveying belt, a coarse sand conveying belt motor, a support body, a bevel gear C, a bevel gear B, a bevel gear A, a large belt pulley A, a belt A, a small belt pulley B, a belt B, a large belt pulley B, a motor shaft B, a motor A, a motor shaft A, a small belt pulley E, a belt E, a large belt pulley E, a small belt pulley D, a large belt pulley D, a small belt pulley C, a belt C, a large belt pulley C, a rotary swing arm, a frame swing shaft and rollers, wherein the feeding conveying belt is connected between two adjacent rollers, the medium sand conveying belt is connected between two adjacent rollers, the fine sand conveying belt is connected between two adjacent rollers, the coarse sand conveying belt is connected between two adjacent rollers, the rollers are rotationally connected on a bracket body, the rollers are fixedly connected on a feeding conveying belt motor transmission shaft, the rollers are fixedly connected on a medium sand conveying belt motor transmission shaft, the rollers are fixedly connected on a fine sand conveying belt motor transmission shaft, the rollers are fixedly connected on the coarse sand conveying belt motor transmission shaft, a large belt pulley D is rotationally connected on the bracket body, one end of a belt D is connected with a large belt pulley D, the other end of the belt D is connected with a small belt pulley D, the small belt pulley D is fixedly connected on a motor shaft A, the motor shaft A is fixedly connected on a motor A transmission shaft, the large belt pulley A is rotationally connected on the bracket body, one end of the belt A is connected with the large belt pulley A, the other end of the belt A is connected with the small belt pulley A, the small belt pulley A, a small belt pulley B is fixedly connected at the right end of a motor shaft B, one end of a belt B is connected with the small belt pulley B, the other end of the belt B is connected with a large belt pulley B, the large belt pulley B is rotatably connected on a bracket body, a bevel gear A is fixedly connected at the left end of the large belt pulley B, the motor A is fixedly connected on the bracket body, the small belt pulley E is fixedly connected on the motor shaft A, one end of the belt E is connected with the large belt pulley E, the other end of the belt E is connected with the small belt pulley E, the large belt pulley E is rotatably connected on the bracket body, the large belt pulley C is rotatably connected on the bracket body, the small belt pulley C is fixedly connected on the motor shaft A, one end of the belt C is connected with the large belt pulley C, the other end of the belt C is connected with the small belt pulley C, the bevel gear B is, bevel gear C meshes with bevel gear B.

As a further optimization of the technical scheme, the screening device of the crushed stone separator comprises a coarse screen box, a screen vibration mechanism, a coarse material hopper, a fine material hopper, a middle screen box, a screening tower body, a screen chute, a screen vibration arm, a screen vibration driven shaft and a screen vibration main shaft, wherein the coarse screen box is connected to the screening tower body in a sliding manner, the screen vibration mechanism is fixedly connected to the front end of the coarse screen box, the screen vibration mechanism is fixedly connected to the front end of the middle screen box, the coarse material hopper is fixedly connected to the screening tower body, the fine material hopper is fixedly connected to the screening tower body, the middle screen box is connected to the screening tower body in a sliding manner, the screen chute is arranged on the screen vibration mechanism, the screen vibration main shaft is rotatably connected to the screening tower body, the screen vibration arm is fixedly connected to the left end of the screen vibration main shaft, the screen vibration driven shaft is fixedly, the screening and vibrating main shaft is fixedly connected to the large belt pulley A.

As a further optimization of the technical scheme, the vertical lifting device of the crushed stone separator comprises an upper guide groove, a spiral pump bevel gear, a spiral pump blade shaft, a spiral pump shell and a lower pool, wherein the upper guide groove is fixedly connected to the spiral pump shell, the spiral pump bevel gear is fixedly connected to the spiral pump blade shaft, the spiral pump blade shaft is rotatably connected to the inner end of the spiral pump shell, the lower pool is fixedly connected to a support body, the spiral pump shell is fixedly connected to the support body, and the spiral pump bevel gear is meshed with the bevel gear a.

As a further optimization of the technical scheme, the jaw crushing device of the crushed stone separator comprises a crusher feeding port, a crusher shell, a coarse screen, a driven shaft B, a driven arm, a driven shaft A, a coarse screen shaft B, a coarse screen shaft A, a left-right arm swinging device, a coarse screen connecting arm, a vibration shaft B, a vibration arm, a vibration shaft A, front-back moving teeth, left-right tooth shafts, left-right moving teeth and left-right swinging grooves, wherein the crusher feeding port is fixedly connected to the crusher shell, the crusher shell is fixedly connected to a bracket body, the coarse screen shaft B is fixedly connected to the coarse screen, the coarse screen shaft A is fixedly connected to the coarse screen, the coarse screen shaft B is slidably connected to the crusher shell, the coarse screen connecting arm is fixedly connected to the coarse screen, the coarse screen connecting arm is fixedly connected to the left-right moving teeth, the vibration shaft A is rotatably connected to the vibration arm, the vibration shaft A is fixedly connected to the front-back moving teeth, the vibration shaft B is fixedly connected to the vibration arm, the left and right gear shafts are fixedly connected to left and right movable teeth, the left and right gear shafts are slidably connected to the crusher shell, the driven shaft B is rotatably connected to a driven arm, the driven shaft A is fixedly connected to the driven arm, the driven shaft B is fixedly connected to front and rear movable teeth, the driven shaft A is rotatably connected to the crusher shell, the left and right arm swing devices are fixedly connected to left and right movable teeth, the left and right arm swing devices are slidably connected to left and right swing grooves formed in the left and right arm swing devices, the vibration shaft B is rotatably connected to the crusher shell, the vibration shaft B is fixedly connected to an upper large belt pulley E, and the frame swing shaft is.

As a further optimization of the technical scheme, the sand washing device of the crushed stone separator comprises a sand washing sedimentation tank, a sand washing water suction pipe, a sand washing circulating pump, a sand washing water return pipe, a sand washing transmission shaft C, a sand washing tank, a sand washing water spray pipe, a sand washing pump blade shaft, a sand washing discharge chute, a sand washing pump driven gear, a sand washing pump main gear, a sand washing transmission shaft A, a cross-shaped coupling A, a sand washing transmission shaft B, a cross-shaped coupling B and a sand washing base, wherein the sand washing water suction pipe is fixedly connected to the sand washing circulating pump, the sand washing circulating pump is fixedly connected to the sand washing base, the sand washing water return pipe is fixedly connected to the sand washing tank, the sand washing transmission shaft C is rotatably connected to the sand washing tank, the sand washing pump driven gear is meshed with the sand washing pump main gear, the sand washing pump main gear is fixedly connected to the sand washing transmission shaft A, the sand washing transmission shaft A is rotatably connected to the sand washing discharge chute, the sand washing discharge chute is fixedly connected to the sand, the sand washing transmission shaft A is rotatably connected to the cross-shaped coupling A, the cross-shaped coupling A is rotatably connected to the sand washing transmission shaft B, the sand washing transmission shaft B is rotatably connected to the cross-shaped coupling B, the cross-shaped coupling B is rotatably connected to the sand washing transmission shaft C, the sand washing pump vane shaft is fixedly connected to the sand washing pump driven gear, the sand washing pump vane shaft is rotatably connected to the sand washing discharge chute, the sand washing spray pipe is fixedly connected to the sand washing circulating pump, the sand washing transmission shaft C is fixedly connected to the large belt pulley D, the sand washing sedimentation tank is fixedly connected to the support body, the sand washing base is fixedly connected to the support body, and the sand washing tank is fixedly connected to the support body.

As a further optimization of the technical scheme, the crushed stone separator has eight rollers, and the motor A is a double-shaft motor.

The crushed stone separator has the beneficial effects that:

the invention relates to the field of buildings, in particular to a crushed stone separator which realizes crushing of stone through forward and backward extrusion movement and horizontal movement of crushing teeth in a jaw crushing device, washing of sand through water of a water pump, backflow of sand washing sewage into a sedimentation tank, recycling of the treated water for sand washing, and sieving of the sand into stones with different particle sizes through a separating and sieving device, so that water sources are saved, electric power is saved, and pollution is reduced.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the overall structure of the present invention.

Fig. 3 is a first structural diagram of the rack body according to the present invention.

Fig. 4 is a schematic view of a main structure of the rack of the present invention.

Fig. 5 is a third schematic structural diagram of the rack body according to the present invention.

Fig. 6 is a fourth schematic structural diagram of the rack body according to the present invention.

Fig. 7 is a fifth structural schematic diagram of the rack main body according to the present invention.

Fig. 8 is a sixth structural schematic diagram of the rack main body according to the present invention.

Fig. 9 is a seventh structural diagram of the rack body according to the present invention.

Fig. 10 is an eighth structural schematic diagram of the rack body of the present invention.

Fig. 11 is a first structural schematic diagram of the screening device of the present invention.

Fig. 12 is a schematic structural diagram of a screening device of the present invention.

Fig. 13 is a schematic structural diagram of a screening device of the present invention.

Fig. 14 is a fourth schematic structural view of the screening device of the present invention.

Fig. 15 is a schematic structural view of the vertical lifting device of the present invention.

Fig. 16 is a first structural schematic view of the jaw crusher of the present invention.

Fig. 17 is a second schematic structural view of the jaw crusher of the present invention.

Fig. 18 is a third schematic structural view of the jaw crusher of the present invention.

Fig. 19 is a fourth schematic view of the jaw crusher arrangement of the present invention.

Fig. 20 is a fifth schematic view of the jaw crusher arrangement of the present invention.

Fig. 21 is a sixth schematic view of the jaw crusher arrangement of the present invention.

Fig. 22 is a seventh structural view of the jaw crusher of the present invention.

Fig. 23 is a schematic view eight of the jaw crusher structure of the present invention.

Fig. 24 is a nine-dimensional view of the jaw crusher arrangement of the present invention.

Fig. 25 is a ten-fold schematic view of the jaw crusher arrangement of the present invention.

Fig. 26 is a first structural schematic diagram of the sand washing device of the present invention.

Fig. 27 is a second structural schematic diagram of the sand washing device of the present invention.

Fig. 28 is a third schematic structural view of the sand washing device of the present invention.

In the figure: a frame main body 1; a feed conveyor motor 1-1; a feed conveyor 1-2; 1-3 of a medium sand conveyor belt; a middle sand conveyer belt motor 1-4; a fine sand conveyer belt motor 1-5; 1-6 of a fine sand conveyor belt; a coarse sand conveyor belt 1-7; a coarse sand conveyer belt motor 1-8; 1-9 parts of a bracket body; bevel gears C1-10; bevel gear B1-11; bevel gear A1-12; a large belt pulley A1-13; belt A1-14; a small belt pulley A1-15; a small belt pulley B1-16; belt B1-17; a large belt pulley B1-18; a motor shaft B1-19; motor A1-20; a motor shaft A1-21; a small belt pulley E1-22; belts E1-23; a large belt pulley E1-24; a small belt pulley D1-25; a large pulley D1-26; belts D1-27; a small belt pulley C1-28; belts C1-29; a large belt pulley C1-30; 1-31 parts of a rotary swing arm; 1-32 of frame swing shaft; 1-33 of rollers; a screening device 2; 2-1 of a coarse screen box; a screen vibrating mechanism 2-2; 2-3 of a coarse material funnel; 2-4 of a fine material funnel; 2-5 of a medium material funnel; 2-6 parts of a middle sieve box; 2-7 of a screening tower body; 2-8 parts of a sieve chute; 2-9 parts of a screening and vibrating arm; vibrating the shaft 2-10; screening and vibrating the main shaft 2-11; a vertical lifting device 3; an upper diversion trench 3-1; a spiral pump bevel gear 3-2; 3-3 parts of a spiral pump blade shaft; 3-4 parts of a screw pump shell; 3-5 of a lower pool; a jaw crusher 4; a feeding port 4-1 of the crusher; a pulverizer housing 4-2; 4-3 of a coarse screen; from axis B4-4; 4-5 of a driven arm; from axis A4-6; coarse screen shaft B4-7; a coarse screen axis A4-8; 4-9 of left and right arm swinging devices; 4-10 parts of coarse screening connecting arm; hypocenter B4-11; 4-12 of a vibration arm; a seismic axis A4-13; front and back moving teeth 4-14; 4-15 of left and right gear shafts; 4-16 of left and right moving teeth; 4-17 of left and right swinging grooves; a sand washing device 5; 5-1 of a sand washing sedimentation tank; 5-2 parts of a sand washing water suction pipe; 5-3 of a sand washing circulating pump; 5-4 of a sand washing water return pipe; a sand washing transmission shaft C5-5; 5-6 of a sand washing tank; 5-7 parts of sand washing water spraying pipe; 5-8 parts of a sand washing pump blade shaft; 5-9 parts of a sand washing discharge chute; the sand washing pump driven gear is 5-10; 5-11 parts of a main gear of the sand washing pump; a sand washing transmission shaft A5-12; an Oldham coupling A5-13; a sand washing transmission shaft B5-14; an Oldham coupling B5-15; and 5-16 parts of a sand washing base.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the invention relates to the field of buildings, in particular to a crushed stone classifier which comprises a rack main body 1, a screening device 2, a vertical lifting device 3, a jaw type crushing device 4 and a sand washing device 5, wherein the screening device 2 is connected with the rack main body 1, the vertical lifting device 3 is connected with the rack main body 1, the jaw type crushing device 4 is connected with the rack main body 1, and the sand washing device 5 is connected with the rack main body 1.

The second embodiment is as follows:

the present embodiment will be described with reference to fig. 1 to 28, and the present embodiment will further describe the first embodiment, wherein the housing body 1 includes a feeding conveyor belt motor 1-1, a feeding conveyor belt (1-2), a medium sand conveyor belt 1-3, a medium sand conveyor belt motor 1-4, a fine sand conveyor belt motor 1-5, a fine sand conveyor belt 1-6, a coarse sand conveyor belt 1-7, a coarse sand conveyor belt motor 1-8, a bracket body 1-9, a bevel gear C1-10, a bevel gear B1-11, a bevel gear a1-12, a large pulley a1-13, a belt a1-14, a small pulley a1-15, a small pulley B1-16, a belt B1-17, a large pulley B1-18, a motor shaft B1-19, a motor a1-20, a motor shaft a1-21, a motor shaft B, Small belt pulley E1-22, belt E1-23, large belt pulley E1-24, small belt pulley D1-25, large belt pulley D1-26, belt D1-27, small belt pulley C1-28, belt C1-29, large belt pulley C1-30, swing arm 1-31, frame swing shaft 1-32, roller 1-33, feeding transmission belt 1-2 is connected between two adjacent rollers 1-33, middle sand transmission belt 1-3 is connected between two adjacent rollers 1-33, fine sand transmission belt 1-6 is connected between two adjacent rollers 1-33, coarse sand transmission belt 1-7 is connected between two adjacent rollers 1-33, roller 1-33 is connected on bracket body 1-9 in a rotating way, roller 1-33 is fixedly connected on feeding transmission belt motor 1-1 transmission shaft, the rollers 1-33 are fixedly connected on a transmission shaft of a middle sand conveying belt motor 1-4, the rollers 1-33 are fixedly connected on a transmission shaft of a fine sand conveying belt motor 1-5, the rollers 1-33 are fixedly connected on a transmission shaft of a coarse sand conveying belt motor 1-8, a large belt pulley D1-26 is rotatably connected on a bracket body 1-9, one end of a belt D1-27 is connected with a large belt pulley D1-26, the other end of the belt D1-27 is connected with a small belt pulley D1-25, the small belt pulley D1-25 is fixedly connected on a motor shaft A1-21, a motor shaft A1-21 is fixedly connected on a transmission shaft of a1-20, the large belt pulley A1-13 is rotatably connected on the bracket body 1-9, one end of the belt A1-14 is connected with a large belt pulley A1-13, the other end of the belt A1-14 is connected, the small belt pulleys A1-15 are fixedly connected on the motor shafts B1-19, the motor shafts B1-19 are fixedly connected on the transmission shafts of the motors A1-20, the small belt pulleys B1-16 are fixedly connected at the right ends of the motor shafts B1-19, one ends of the belts B1-17 are connected with the small belt pulleys B1-16, the other ends of the belts B1-17 are connected with the large belt pulleys B1-18, the large belt pulleys B1-18 are rotatably connected on the bracket bodies 1-9, the bevel gears A1-12 are fixedly connected at the left ends of the large belt pulleys B1-18, the motors A1-20 are fixedly connected on the bracket bodies 1-9, the small belt pulleys E1-22 are fixedly connected on the motor shafts A1-68621, one ends of the belts E1-23 are connected with the large belt pulleys E1-24, the other ends of the belts E, big belt wheels E1-24 are rotationally connected to support bodies 1-9, big belt wheels C1-30 are rotationally connected to support bodies 1-9, small belt wheels C1-28 are fixedly connected to motor shafts A1-21, one ends of belts C1-29 are connected with big belt wheels C1-30, the other ends of belts C1-29 are connected with small belt wheels C1-28, bevel gears B1-11 are fixedly connected to big belt wheels C1-30, bevel gears C1-10 are rotationally connected to support bodies 1-9, swing arms 1-31 are fixedly connected to the right ends of bevel gears C1-10, frame swing shafts 1-32 are fixedly connected to swing arms 1-31, bevel gears C1-10 are meshed with bevel gears B1-11, motor shafts B1-19 rotate to drive small belt wheels A1-15 and small belt wheels B1-16, the motor A1-20 drives a plurality of components to rotate, and the motor is saved.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 28, which further describes the first embodiment, wherein the screening device 2 includes a coarse screen box 2-1, a screen vibration mechanism 2-2, a coarse material funnel 2-3, a fine material funnel 2-4, a medium material funnel 2-5, a medium screen box 2-6, a screening tower 2-7, a screen chute 2-8, a screen vibration arm 2-9, a screen vibration shaft 2-10, and a screen vibration main shaft 2-11, the coarse screen box 2-1 is slidably connected to the screening tower 2-7, the screen vibration mechanism 2-2 is fixedly connected to the front end of the coarse screen box 2-1, the screen vibration mechanism 2-2 is fixedly connected to the front end of the medium screen box 2-6, the coarse material funnel 2-3 is fixedly connected to the screening tower 2-7, the fine material funnel 2-4 is fixedly connected to the screening tower 2-7, the medium material hopper 2-5 is fixedly connected to the screening tower body 2-7, the medium screen box 2-6 is connected to the screening tower body 2-7 in a sliding mode, the screen vibrating mechanism 2-2 is provided with a screen sliding groove 2-8, the screen vibrating main shaft 2-11 is connected to the screening tower body 2-7 in a rotating mode, the screen vibrating arm 2-9 is fixedly connected to the left end of the screen vibrating main shaft 2-11, the screen vibrating driven shaft 2-10 is fixedly connected to the left end of the screen vibrating arm 2-9, the screen vibrating driven shaft 2-10 is connected to the inner end of the screen sliding groove 2-8 in a sliding mode, the screen vibrating main shaft 2-11 is fixedly connected to a large belt pulley A1-13, the screen vibrating main shaft 2-11 rotates to drive the screen vibrating shaft 2-10 to do circular motion, the screen vibrating shaft 2-10 slides up and down in the screen sliding groove 2-8 and, the screen vibrating mechanism 2-2 drives the coarse screen box 2-1 and the middle screen box 2-6 to horizontally vibrate.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 28, and the embodiment further describes the first embodiment, where the vertical lifting device 3 includes an upper guiding gutter 3-1, a spiral pump bevel gear 3-2, a spiral pump blade shaft 3-3, a spiral pump casing 3-4, and a lower sump 3-5, the upper guiding gutter 3-1 is fixedly connected to the spiral pump casing 3-4, the spiral pump bevel gear 3-2 is fixedly connected to the spiral pump blade shaft 3-3, the spiral pump blade shaft 3-3 is rotatably connected to the inner end of the spiral pump casing 3-4, the lower sump 3-5 is fixedly connected to a bracket 1-9, the spiral pump casing 3-4 is fixedly connected to the bracket 1-9, the spiral pump bevel gear 3-2 is engaged with a bevel gear a1-12, and a motor a1-20 transmits power to the spiral pump bevel gear 3-2 through a transmission mechanism to drive the spiral pump blade shaft 3-2 to drive the spiral pump blade shaft 3-3, conveying the sand and stone in the lower pond 3-5 to the upper diversion trench 3-1, and then flowing out from one side of the upper diversion trench 3-1, wherein the upper diversion trench 3-1 is installed at an inclination angle of 45 degrees, so that the sand and stone can flow out conveniently.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1-28, and the embodiment will be further described, wherein the jaw crusher 4 comprises a crusher feed port 4-1, a crusher housing 4-2, a coarse screen 4-3, a driven shaft B4-4, a driven arm 4-5, a driven shaft a4-6, a coarse screen shaft B4-7, a coarse screen shaft a4-8, left and right arm swing devices 4-9, a coarse screen connecting arm 4-10, a vibration shaft B4-11, a vibration arm 4-12, a vibration shaft a4-13, front and rear movable teeth 4-14, left and right tooth shafts 4-15, left and right movable teeth 4-16, and left and right swing grooves 4-17, the crusher feed port 4-1 is fixedly connected to the crusher housing 4-2, the crusher housing 4-2 is fixedly connected to a bracket body 1-9, a coarse screen shaft B4-7 is fixedly connected on a coarse screen 4-3, a coarse screen shaft A4-8 is fixedly connected on the coarse screen 4-3, a coarse screen shaft B4-7 is slidably connected on a crusher shell 4-2, a coarse screen shaft A4-8 is slidably connected on the crusher shell 4-2, a coarse screen connecting arm 4-10 is fixedly connected on the coarse screen 4-3, a coarse screen connecting arm 4-10 is fixedly connected on a left movable tooth 4-16 and a right movable tooth 4-16, a vibration shaft A4-13 is rotatably connected on a vibration arm 4-12, a vibration shaft A4-13 is fixedly connected on the front movable tooth 4-14 and the rear movable tooth 4-14, a vibration shaft B4-11 is fixedly connected on the vibration arm 4-12, a left tooth shaft 4-15 and a right tooth shaft 4-15 are fixedly connected on the left movable tooth 4-16 and the right tooth shaft 4-15 is slidably connected on the, the driven shaft B4-4 is rotationally connected to the driven arm 4-5, the driven shaft A4-6 is fixedly connected to the driven arm 4-5, the driven shaft B4-4 is fixedly connected to the front and rear moving teeth 4-14, the driven shaft A4-6 is rotationally connected to the crusher shell 4-2, the left and right arm swinging devices 4-9 are fixedly connected to the left and right moving teeth 4-16, the left and right arm swinging devices 4-9 are slidably connected, left and right swinging grooves 4-17 are arranged on the left and right arm swinging devices 4-9, the vibration shaft B4-11 is rotationally connected to the crusher shell 4-2, the vibration shaft B4-11 is fixedly connected to the upper large belt pulley E1-24, the frame swinging shafts 1-32 are slidably connected to the left and right swinging grooves 4-17, the coarse screen 4-3 and the left and right moving teeth 4-16 are fixed together to conveniently do left and right, the left-right swinging groove 4-17 is a generating mechanism for left-right water movement, and the left-right swinging groove 4-17 and the left-right moving tooth 4-16 are fixed together.

The sixth specific implementation mode:

the following describes the embodiment with reference to fig. 1 to 28, which further describes the first embodiment, wherein the sand washing device 5 comprises a sand washing sedimentation tank 5-1, a sand washing water suction pipe 5-2, a sand washing circulating pump 5-3, a sand washing water return pipe 5-4, a sand washing transmission shaft C5-5, a sand washing tank 5-6, a sand washing water spray pipe 5-7, a sand washing pump blade shaft 5-8, a sand washing discharge chute 5-9, a sand washing pump driven gear 5-10, a sand washing pump main gear 5-11, a sand washing transmission shaft a5-12, a cross coupling a5-13, a sand washing transmission shaft B5-14, a cross coupling B5-15, and a sand washing base 5-16, the sand washing water suction pipe 5-2 is fixedly connected to the sand washing circulating pump 5-3, the sand washing circulating pump 5-3 is fixedly connected to the sand washing base 5-16, a sand washing water return pipe 5-4 is fixedly connected on a sand washing pool 5-6, a sand washing transmission shaft C5-5 is rotatably connected on the sand washing pool 5-6, a sand washing pump driven gear 5-10 is meshed with a sand washing pump main gear 5-11, the sand washing pump main gear 5-11 is fixedly connected on a sand washing transmission shaft A5-12, a sand washing transmission shaft A5-12 is rotatably connected on a sand washing discharge chute 5-9, the sand washing discharge chute 5-9 is fixedly connected on the sand washing pool 5-6, a sand washing transmission shaft A5-12 is rotatably connected on a cross coupling A5-13, a cross coupling A5-13 is rotatably connected on a sand washing transmission shaft B5-14, a sand washing transmission shaft B5-14 is rotatably connected on a cross coupling B5-15, a cross coupling B5-15 is rotatably connected on a sand washing transmission shaft C5-5, the sand washing pump is characterized in that a sand washing pump blade shaft 5-8 is fixedly connected to a sand washing pump driven gear 5-10, the sand washing pump blade shaft 5-8 is rotatably connected to a sand washing discharge chute 5-9, a sand washing water spray pipe 5-7 is fixedly connected to a sand washing circulating pump 5-3, a sand washing transmission shaft C5-5 is fixedly connected to a large belt pulley D1-26, a sand washing sedimentation tank 5-1 is fixedly connected to a support body 1-9, a sand washing base 5-16 is fixedly connected to the support body 1-9, a sand washing tank 5-6 is fixedly connected to the support body 1-9, power is input through the sand washing transmission shaft C5-5 and is transmitted to the sand washing pump blade shaft 5-8, the sand washing pump blade shaft 5-8 continuously stirs and cleans sand and water in the sand washing tank 5-6, and conveys sand at the bottom of sediment out.

The seventh embodiment:

the embodiment is described below with reference to fig. 1 to 28, and the second embodiment is further described in the present embodiment, the number of the rollers 1 to 33 is eight, and the motors a1 to 20 are two-shaft motors.

The working principle of the invention is as follows:

a broken stone sorting machine has the working principle that stones enter a jaw type crushing device 4 through a feeding conveyor belt 1-2 to be crushed, the crushed stones enter a sand washing device 5 to be cleaned, the cleaned stones enter a screening device 2 to be screened according to the particle size to be divided into stones with three sizes, the crushing work of the jaw type crushing device 4 is jointly completed by the front and back extrusion motion of front and back moving teeth 4-14 and the left and right horizontal movement of left and right moving teeth 4-16, the rotation of a swing arm 1-31 can drive a swing shaft 1-32 of a rack to do circular motion, the left and right arm swing device 4-9 does horizontal vibration under the combined action of a left and right swing groove 4-17 and the swing shaft 1-32, the rotation of a swing shaft B4-11 can drive a swing shaft A4-13 to do circular motion and the connecting rod action of a driven arm 4-5 can enable the front and back moving teeth 4-14 to generate front and back extrusion impact motion, the horizontal vibration of the coarse screen 4-3 is beneficial to the screening of sand and stone, the sand washing circulating pump 5-3 sends water on the upper layer of the sand washing sedimentation tank 5-1 to the sand washing tank 5-6 to wash sand and stone, sewage in the sand washing tank 5-6 is discharged into the sand washing sedimentation tank 5-1 through the sand washing water return pipe 5-4 to be precipitated for water recovery and purification, sand washing pump blade shafts 5-8 stir and clean sand and stone in the sand washing tank 5-6 and convey the sand and stone to the lower tank 3-5, the screw pump blade shafts 3-3 rotate to convey sand and stone in the lower tank 3-5 to the high position, the sand and stone are conveniently conveyed into the screening device 2, the screen vibration mechanism 2-2 horizontally vibrates under the combined action of the rotation of the screen vibration arm 2-9, the screen chute 2-8 and the screen vibration shaft 2-10, the screen vibration mechanism 2-2 drives the coarse screen box 2-1 to vibrate with the middle screen box 2-6, the vibration of the coarse screen box 2-1 and the middle screen box 2-6 is beneficial to the smooth operation of screening work, the stones are divided into three types of coarse, middle and fine after screening, the whole process only needs a small amount of manual intervention, the manpower is greatly reduced, meanwhile, the efficiency is greatly improved due to the semi-mechanical automation, a large amount of water resources are saved due to the adoption of circulating water cleaning, the pollution is also reduced, and the horizontal vibration crushing efficiency of the crusher is improved.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. A broken stone sorter which is characterized in that: the sand washing machine comprises a frame main body (1), a screening device (2), a vertical lifting device (3), a jaw type crushing device (4) and a sand washing device (5), wherein the screening device (2) is connected with the frame main body (1), the vertical lifting device (3) is connected with the frame main body (1), the jaw type crushing device (4) is connected with the frame main body (1), and the sand washing device (5) is connected with the frame main body (1).

2. A crushed stone separator according to claim 1 wherein: the machine frame main body (1) comprises a feeding conveyor belt motor (1-1), a feeding conveyor belt (1-2), a medium sand conveyor belt (1-3), a medium sand conveyor belt motor (1-4), a fine sand conveyor belt motor (1-5), a fine sand conveyor belt (1-6), a coarse sand conveyor belt (1-7), a coarse sand conveyor belt motor (1-8), a support body (1-9), a bevel gear C (1-10), a bevel gear B (1-11), a bevel gear A (1-12), a large belt pulley A (1-13), a belt A (1-14), a small belt pulley A (1-15), a small belt pulley B (1-16), a belt B (1-17), a large belt pulley B (1-18), a motor shaft B (1-19), A motor A (1-20), a motor shaft A (1-21), a small belt pulley E (1-22), a belt E (1-23), a large belt pulley E (1-24), a small belt pulley D (1-25), a large belt pulley D (1-26), a belt D (1-27), a small belt pulley C (1-28), a belt C (1-29), a large belt pulley C (1-30), a rotary swing arm (1-31), a frame swing shaft (1-32) and rollers (1-33), wherein a feeding conveying belt (1-2) is connected between two adjacent rollers (1-33), a medium sand conveying belt (1-3) is connected between two adjacent rollers (1-33), a fine sand conveying belt (1-6) is connected between two adjacent rollers (1-33), a coarse sand conveyor belt (1-7) is connected between two adjacent rollers (1-33), the rollers (1-33) are rotatably connected on the bracket bodies (1-9), the rollers (1-33) are fixedly connected on a transmission shaft of a feeding conveyor belt motor (1-1), the rollers (1-33) are fixedly connected on a transmission shaft of a medium sand conveyor belt motor (1-4), the rollers (1-33) are fixedly connected on a transmission shaft of a fine sand conveyor belt motor (1-5), the rollers (1-33) are fixedly connected on a transmission shaft of a coarse sand conveyor belt motor (1-8), a large belt pulley D (1-26) is rotatably connected on the bracket bodies (1-9), one end of a belt D (1-27) is connected with the large belt pulley D (1-26), the other end of the belt D (1-27) is connected with a small belt pulley D (1-25), the small belt pulleys D (1-25) are fixedly connected on the motor shafts A (1-21), the motor shafts A (1-21) are fixedly connected on the transmission shafts of the motors A (1-20), the large belt pulleys A (1-13) are rotatably connected on the support bodies (1-9), one ends of the belts A (1-14) are connected with the large belt pulleys A (1-13), the other ends of the belts A (1-14) are connected with the small belt pulleys A (1-15), the small belt pulleys A (1-15) are fixedly connected on the motor shafts B (1-19), the motor shafts B (1-19) are fixedly connected on the transmission shafts of the motors A (1-20), the small belt pulleys B (1-16) are fixedly connected at the right ends of the motor shafts B (1-19), one ends of the belts B (1-17) are connected with the small belt pulleys B (1-16), the other end of the belt B (1-17) is connected with a big belt pulley B (1-18), the big belt pulley B (1-18) is rotationally connected on a bracket body (1-9), a bevel gear A (1-12) is fixedly connected at the left end of the big belt pulley B (1-18), a motor A (1-20) is fixedly connected on the bracket body (1-9), a small belt pulley E (1-22) is fixedly connected on a motor shaft A (1-21), one end of the belt E (1-23) is connected with a big belt pulley E (1-24), the other end of the belt E (1-23) is connected with a small belt pulley E (1-22), the big belt pulley E (1-24) is rotationally connected on the bracket body (1-9), the big belt pulley C (1-30) is rotationally connected on the bracket body (1-9), the small belt pulley C (1-28) is fixedly connected to the motor shaft A (1-21), one end of the belt C (1-29) is connected with the large belt pulley C (1-30), the other end of the belt C (1-29) is connected with the small belt pulley C (1-28), the bevel gear B (1-11) is fixedly connected to the large belt pulley C (1-30), the bevel gear C (1-10) is rotatably connected to the support body (1-9), the rotary swing arm (1-31) is fixedly connected to the right end of the bevel gear C (1-10), the frame swing shaft (1-32) is fixedly connected to the rotary swing arm (1-31), and the bevel gear C (1-10) is meshed with the bevel gear B (1-11).

3. A crushed stone separator according to claim 1 wherein: the screening device (2) comprises a coarse screening box (2-1), a screening vibration mechanism (2-2), a coarse screening funnel (2-3), a fine screening funnel (2-4), a middle screening funnel (2-5), a middle screening box (2-6), a screening tower body (2-7), a screening sliding chute (2-8), a screening vibration arm (2-9), a screening vibration driven shaft (2-10) and a screening vibration main shaft (2-11), wherein the coarse screening box (2-1) is connected to the screening tower body (2-7) in a sliding manner, the screening vibration mechanism (2-2) is fixedly connected to the front end of the coarse screening box (2-1), the screening vibration mechanism (2-2) is fixedly connected to the front end of the middle screening box (2-6), and the coarse screening funnel (2-3) is fixedly connected to the screening tower body (2-7), the fine material hopper (2-4) is fixedly connected to the screening tower body (2-7), the medium material hopper (2-5) is fixedly connected to the screening tower body (2-7), the medium screen box (2-6) is connected to the screening tower body (2-7) in a sliding mode, the screen vibrating mechanism (2-2) is provided with a screen sliding groove (2-8), the screen vibrating main shaft (2-11) is connected to the screening tower body (2-7) in a rotating mode, the screen vibrating arm (2-9) is fixedly connected to the left end of the screen vibrating main shaft (2-11), the screen vibrating auxiliary shaft (2-10) is fixedly connected to the left end of the screen vibrating arm (2-9), the screen vibrating auxiliary shaft (2-10) is connected to the inner end of the screen sliding groove (2-8) in a sliding mode, and the screen vibrating main shaft (2-11) is fixedly connected to the large belt pulley A (.

4. A crushed stone separator according to claim 1 wherein: the vertical lifting device (3) comprises an upper flow guide groove (3-1), a spiral pump bevel gear (3-2), a spiral pump blade shaft (3-3), a spiral pump shell (3-4) and a lower pool (3-5), wherein the upper flow guide groove (3-1) is fixedly connected to the spiral pump shell (3-4), the spiral pump bevel gear (3-2) is fixedly connected to the spiral pump blade shaft (3-3), the spiral pump blade shaft (3-3) is rotatably connected to the inner end of the spiral pump shell (3-4), the lower pool (3-5) is fixedly connected to a support body (1-9), the spiral pump shell (3-4) is fixedly connected to the support body (1-9), and the spiral pump bevel gear (3-2) is meshed with a bevel gear A (1-12).

5. A crushed stone separator according to claim 1 wherein: the jaw crushing device (4) comprises a crusher feeding port (4-1), a crusher shell (4-2), a coarse screen (4-3), a driven shaft B (4-4), a driven arm (4-5), a driven shaft A (4-6), a coarse screen shaft B (4-7), a coarse screen shaft A (4-8), a left and right arm swinging device (4-9), a coarse screen connecting arm (4-10), a vibration shaft B (4-11), a vibration arm (4-12), a vibration shaft A (4-13), a front and back moving tooth (4-14), a left and right tooth shaft (4-15), a left and right moving tooth (4-16) and a left and right swinging groove (4-17), the crusher feeding port (4-1) is fixedly connected to the crusher shell (4-2), the crusher shell (4-2) is fixedly connected to a support body (1-9), a coarse screen shaft B (4-7) is fixedly connected on a coarse screen (4-3), a coarse screen shaft A (4-8) is fixedly connected on the coarse screen (4-3), the coarse screen shaft B (4-7) is slidably connected on a crusher shell (4-2), the coarse screen shaft A (4-8) is slidably connected on the crusher shell (4-2), a coarse screen connecting arm (4-10) is fixedly connected on the coarse screen (4-3), a coarse screen connecting arm (4-10) is fixedly connected on a left movable tooth (4-16) and a right movable tooth (4-16), a vibration shaft A (4-13) is rotatably connected on a vibration arm (4-12), a vibration shaft A (4-13) is fixedly connected on a front movable tooth (4-14) and a rear movable tooth (4-14), a vibration shaft B (4-11) is fixedly connected on the vibration arm (4-12), a left tooth shaft and a right tooth shaft (4-15) are fixedly connected on the left movable tooth (4-16), left and right gear shafts (4-15) are connected on a crusher shell (4-2) in a sliding way, a driven shaft B (4-4) is connected on a driven arm (4-5) in a rotating way, a driven shaft A (4-6) is fixedly connected on the driven arm (4-5), the driven shaft B (4-4) is fixedly connected on front and back moving teeth (4-14), the driven shaft A (4-6) is connected on the crusher shell (4-2) in a rotating way, left and right arm swinging devices (4-9) are fixedly connected on left and right moving teeth (4-16), left and right arm swinging devices (4-9) are connected in a sliding way, left and right arm swinging grooves (4-17) are arranged on the left and right arm swinging devices (4-9), a vibration shaft B (4-11) is connected on the crusher shell (4-2) in a rotating way, the vibration shaft B (4-11) is fixedly connected on an upper large belt pulley E (, the frame swing shafts (1-32) are connected on the left and right swing grooves (4-17) in a sliding way.

6. A crushed stone separator according to claim 1 wherein: the sand washing device (5) comprises a sand washing sedimentation tank (5-1), a sand washing water suction pipe (5-2), a sand washing circulating pump (5-3), a sand washing water return pipe (5-4), a sand washing transmission shaft C (5-5), a sand washing tank (5-6), a sand washing water spray pipe (5-7), a sand washing pump blade shaft (5-8), a sand washing discharge chute (5-9), a sand washing pump driven gear (5-10), a sand washing pump main gear (5-11), a sand washing transmission shaft A (5-12), a cross coupling A (5-13), a sand washing transmission shaft B (5-14), a cross coupling B (5-15) and a sand washing base (5-16), the sand washing water suction pipe (5-2) is fixedly connected to the sand washing circulating pump (5-3), and the sand washing circulating pump (5-3) is fixedly connected to the sand washing base (5-16), a sand washing water return pipe (5-4) is fixedly connected on a sand washing pool (5-6), a sand washing transmission shaft C (5-5) is rotatably connected on the sand washing pool (5-6), a sand washing pump driven gear (5-10) is meshed with a sand washing pump main gear (5-11), the sand washing pump main gear (5-11) is fixedly connected on a sand washing transmission shaft A (5-12), the sand washing transmission shaft A (5-12) is rotatably connected on a sand washing discharge chute (5-9), the sand washing discharge chute (5-9) is fixedly connected on the sand washing pool (5-6), the sand washing transmission shaft A (5-12) is rotatably connected on a cross coupling A (5-13), the cross coupling A (5-13) is rotatably connected on a sand washing transmission shaft B (5-14), the sand washing transmission shaft B (5-14) is rotatably connected on a coupling cross coupling B (5-15), the cross coupling B (5-15) is rotatably connected to a sand washing transmission shaft C (5-5), a sand washing pump blade shaft (5-8) is fixedly connected to a sand washing pump driven gear (5-10), the sand washing pump blade shaft (5-8) is rotatably connected to a sand washing discharge chute (5-9), a sand washing spray pipe (5-7) is fixedly connected to a sand washing circulating pump (5-3), the sand washing transmission shaft C (5-5) is fixedly connected to a large belt pulley D (1-26), a sand washing sedimentation tank (5-1) is fixedly connected to a support body (1-9), a sand washing base (5-16) is fixedly connected to the support body (1-9), and a sand washing tank (5-6) is fixedly connected to the support body (1-9).

7. A crushed stone separator according to claim 2, wherein: the number of the rollers (1-33) is eight, and the motor A (1-20) is a double-shaft motor.