CN110465623B - Engine psammitolite cleaning treatment equipment - Google Patents

Abstract

The invention relates to cleaning equipment, in particular to engine sand core cleaning and processing equipment which comprises a variable-speed feeding mechanism, a cleaning mechanism, an airing mechanism and a step platform, wherein the equipment can automatically feed materials, can adjust the feeding speed, can clamp a water pipe and can wash sand, can flatten and air the sand, can form weak turbulent air, can accelerate air drying without causing raised dust, and can accelerate drying in a shaking mode.

Description

Engine psammitolite cleaning treatment equipment

Technical Field

The invention relates to cleaning equipment, in particular to cleaning treatment equipment for a sand core of an engine.

Background

In the casting of an engine shell, the application of the sand core is very extensive, but the sand core is dirty after being used for a long time, the traditional sand washing equipment does not have a drying function, and dust is easily raised due to wind power of the traditional drying equipment, so that the engine sand core cleaning treatment equipment is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing the engine sand core cleaning and processing equipment, the equipment can automatically feed, the feeding speed can be adjusted, the equipment can clamp a water pipe, the equipment can wash sand, the equipment can flatten and dry the sand, weak turbulent air can be formed by the equipment, the air drying is accelerated, raised dust cannot be caused, and the drying can be accelerated by the equipment in a shaking mode.

In order to solve the technical problems, the invention relates to a cleaning device, in particular to an engine sand core cleaning treatment device which comprises a variable-speed feeding mechanism, a cleaning mechanism, an airing mechanism and a stepped platform, wherein the device can automatically feed, can adjust the feeding speed, can clamp a water pipe, can wash sand, can flatten and air the sand, can form weak turbulent air, can accelerate air drying without causing raised dust, and can accelerate drying in a shaking mode.

The variable-speed feeding mechanism comprises a vibration seat mechanism, a feeding hopper mechanism, a speed-regulating supporting seat mechanism, a servo regulating motor mechanism, a driving mechanism, a crankshaft mechanism, a driving arm and a supporting mechanism, wherein the vibration seat mechanism is hinged with the feeding hopper mechanism; the vibration seat mechanism comprises a base, an inclined support, a limiting slide rod, a spring and an upper hinge seat, wherein the base is connected with the stepped platform, the base is connected with the inclined support, the inclined support is connected with the limiting slide rod, the spring is sleeved on the limiting slide rod, and the limiting slide rod is slidably connected with the upper hinge seat; the hopper mechanism comprises a hopper body and a groove, the groove is arranged on the hopper body, and the upper hinge seat is hinged with the hopper body; the speed-regulating supporting seat mechanism comprises a seat body and a stepped groove, wherein the stepped groove is formed in the seat body, and the seat body is connected with the stepped platform; the servo adjusting motor mechanism comprises a servo adjusting motor, a coupler and a screw, the servo adjusting motor is connected with the screw through the coupler, the servo adjusting motor is connected with the seat body, and the screw is connected with the seat body in a bearing connection mode; the driving mechanism comprises a step block, an L-shaped seat, a driving motor, a driving coupling, a belt pulley on the belt shaft, a friction belt and a belt pulley under the belt shaft, the step block is connected with the L-shaped seat, the L-shaped seat is connected with the driving motor, the driving motor is connected with the belt pulley under the belt shaft through the driving coupling, the belt pulley under the belt shaft is connected with the L-shaped seat through a bearing, the belt pulley under the belt shaft is connected with the friction belt, the friction belt is connected with the belt pulley on the belt shaft, the belt pulley on the belt shaft is connected with the L-shaped seat through a bearing, the step block is matched with a step groove, and a spiral is connected with the step block through a thread; the crankshaft mechanism comprises a crankshaft body and a conical friction wheel, the crankshaft body is connected with the conical friction wheel, and the conical friction wheel is connected with the friction belt; the supporting mechanism comprises a supporting base and a corner support, the supporting base is connected with the corner support, the corner support is connected with the crankshaft body through a bearing, and the supporting base is connected with the stepped platform.

The variable-speed feeding mechanism is connected with the stepped platform, the cleaning mechanism is connected with the stepped platform, and the airing mechanism is connected with the stepped platform.

As further optimization of the technical scheme, the cleaning mechanism of the engine sand core cleaning treatment equipment comprises a cleaning base, a cleaning box, a cleaning screw, a water pipe fixing mechanism, a fixing screw and a cleaning motor, the cleaning device comprises a motor belt pulley, a belt, a cleaning spiral belt pulley, a sand outlet and a water outlet, wherein the cleaning base is connected with a stepped platform, the cleaning base is connected with a cleaning box, the cleaning box and the cleaning spiral are connected in a bearing mode, a water pipe fixing mechanism is connected with the cleaning box, a fixing screw is connected with the water pipe fixing mechanism, a cleaning motor is connected with the cleaning box, the cleaning motor is connected with the motor belt pulley, the motor belt pulley is in flexible connection with the belt, the belt is in flexible connection with the cleaning spiral belt pulley, the cleaning spiral belt pulley is connected with the cleaning spiral, the sand outlet is formed in the cleaning box, and the water outlet is formed in the cleaning box; the water pipe fixing mechanism comprises a water pipe fixing seat and a water pipe inserting hole, the water pipe fixing seat is connected with the cleaning box, and the water pipe inserting hole is formed in the water pipe fixing seat.

As a further optimization of the technical scheme, the airing mechanism of the engine sand core cleaning treatment equipment comprises a bottom sliding seat mechanism, a driven mechanism, a cam mechanism, a fixed frame mechanism, a floating frame mechanism, an air flowing mechanism and a stirring mechanism, wherein the bottom sliding seat mechanism is connected with the driven mechanism, the driven mechanism is matched with the cam mechanism, the cam mechanism is connected with the bottom sliding seat mechanism, the driven mechanism is matched with the floating frame mechanism, the floating frame mechanism is connected with the fixed frame mechanism, the air flowing mechanism is connected with the stirring mechanism, and the stirring mechanism is connected with the fixed frame mechanism; the bottom sliding seat mechanism comprises a bottom sliding seat body and a stepped groove I, the stepped groove I is formed in the bottom sliding seat body, and the bottom sliding seat body is connected with the stepped platform; the driven mechanism comprises a fixed seat I, a linkage rod, a matching groove, a linkage rod I, a pulley I and a stepped sliding seat A, wherein the fixed seat I is connected with the bottom sliding seat body and is hinged with the linkage rod I; the cam mechanism comprises a bearing seat I, a cam shaft, a cam shaft coupler and a cam motor, wherein the bearing seat I is connected with the bottom sliding seat body, the bearing seat I is connected with the cam shaft, the cam shaft is connected with the cam motor through the cam shaft coupler, and the cam is matched with the pulley I; the fixing frame mechanism comprises a unthreaded hole, a fixed bottom frame, a vertical connecting rod, a vibration spring, a top frame and a bearing seat II, the unthreaded hole is formed in the fixed bottom frame, the fixed bottom frame is connected with the stepped platform, the vertical connecting rod is arranged between the fixed bottom frame and the top frame, the vibration spring is sleeved on the vertical connecting rod, and the bearing seat II is connected with the top frame; the floating rack mechanism comprises an upper movable rod seat, a lower movable rod seat, a limiting boss, a floating drying rack body and a sliding unthreaded hole, the upper movable rod seat and the lower movable rod seat are matched with the matching grooves, the upper movable rod seat and the lower movable rod seat are connected with the limiting boss, the limiting boss is connected with the floating drying rack body, the sliding unthreaded hole is formed in the floating drying rack body, the sliding unthreaded hole is matched with the vertical connecting rod, and the floating drying rack body is matched with the unthreaded hole; the air flow mechanism comprises a welding port, a lower hinge frame, a hinge impeller arm, an impeller, an upper hinge arm I, an upper hinge frame, an adjusting screw A and a sliding hole B, wherein the welding port is formed in the lower hinge frame, the lower hinge frame is hinged with the hinge impeller arm, the hinge impeller arm is connected with the impeller in a bearing link mode, the hinge impeller arm is hinged with the upper hinge arm I, the upper hinge arm I is hinged with the upper hinge frame, the upper hinge frame is connected with the adjusting screw A through threads, the adjusting screw A is connected with the lower hinge frame through a bearing, and the sliding hole B is formed in the upper hinge frame; stirring mechanism includes stirring blade, stirring shaft coupling, stirring motor supports, and stirring blade links to each other with the stirring shaft, and the stirring shaft passes through stirring shaft coupling with stirring motor and links to each other, and stirring motor supports and links to each other with the roof-rack, and the stirring shaft links to each other with bearing frame II, and the stirring shaft cooperatees with sliding hole B, and the stirring shaft links to each other with the welding mouth.

As a further optimization of the technical scheme, the feeding hopper body of the engine sand core cleaning treatment equipment is made of high manganese steel.

As a further optimization of the technical scheme, the friction belt and the conical friction wheel of the engine sand core cleaning treatment equipment are provided with matched transverse grains to prevent slipping.

The engine sand core cleaning treatment equipment has the beneficial effects that:

according to the engine sand core cleaning and processing equipment, the equipment can automatically feed, the feeding speed can be adjusted, the equipment can clamp a water pipe, the equipment can wash sand, the equipment can flatten and dry the sand, weak turbulent air can be formed by the equipment, the air drying is accelerated, no dust is raised, and the drying can be accelerated by the equipment in a shaking manner.

Drawings

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

FIG. 1 is a schematic structural diagram of an engine sand core cleaning treatment device.

Fig. 2 is a schematic structural diagram of a variable-speed feeding mechanism 1 of the engine sand core cleaning treatment equipment.

Fig. 3 is a supplementary structural schematic diagram of the variable speed feeding mechanism 1 of the engine sand core cleaning treatment equipment of the invention.

FIG. 4 is a schematic structural diagram of a vibrating seat mechanism 1-1 of the engine sand core cleaning treatment equipment.

FIG. 5 is a schematic structural diagram of a hopper mechanism 1-2 of the sand core cleaning treatment equipment for the engine.

FIG. 6 is a schematic structural diagram of a speed regulation supporting seat mechanism 1-3 of the engine sand core cleaning treatment equipment.

FIG. 7 is a schematic structural diagram of servo adjusting motor mechanisms 1-4 of the engine sand core cleaning treatment equipment.

FIG. 8 is a schematic structural diagram of a driving mechanism 1-5 of the engine sand core cleaning treatment equipment.

FIG. 9 is a schematic structural diagram of a crankshaft mechanism 1-6 of the engine sand core cleaning treatment equipment.

FIG. 10 is a schematic structural diagram of a supporting mechanism 1-8 of the engine sand core cleaning treatment equipment.

Fig. 11 is a schematic structural diagram of a cleaning mechanism 2 of the engine sand core cleaning treatment equipment.

Fig. 12 is a supplementary structure diagram of a cleaning mechanism 2 of the engine sand core cleaning treatment equipment.

FIG. 13 is a schematic structural diagram of a water pipe fixing mechanism 2-4 of the engine sand core cleaning treatment equipment.

Fig. 14 is a schematic structural diagram of an airing mechanism 3 of the engine sand core cleaning treatment equipment.

Fig. 15 is a supplementary structure diagram of the airing mechanism 3 of the engine sand core cleaning treatment equipment of the invention.

FIG. 16 is a schematic structural diagram of a bottom sliding seat mechanism 3-1 of the engine sand core cleaning treatment equipment.

FIG. 17 is a schematic structural diagram of a passive mechanism 3-2 of the engine sand core cleaning treatment equipment.

FIG. 18 is a schematic structural diagram of a cam mechanism 3-3 of the engine sand core cleaning treatment equipment.

FIG. 19 is a schematic structural diagram of a fixing frame mechanism 3-4 of the engine sand core cleaning treatment equipment.

FIG. 20 is a schematic structural diagram of a floating frame mechanism 3-5 of the engine sand core cleaning treatment equipment.

FIG. 21 is a schematic structural diagram of an air flow mechanism 3-6 of the engine sand core cleaning treatment equipment.

FIG. 22 is a schematic structural view of an agitating mechanism 3-7 of the sand core cleaning treatment equipment of the engine.

In the figure: a variable speed feeding mechanism 1; a vibration seat mechanism 1-1; a base 1-1-1; 1-1-2 of an inclined support; 1-1-3 of a limiting slide bar; 1-1-4 of a spring; an upper hinge base 1-1-5; a hopper mechanism 1-2; a hopper body 1-2-1; tank 1-2-2; a speed regulation supporting seat mechanism 1-3; 1-3-1 of a seat body; 1-3-2 of a stepped groove; servo adjusting motor mechanism 1-4; 1-4-1 of a servo adjusting motor; 1-4-2 of a coupler; helix 1-4-3; a drive mechanism 1-5; 1-5-1 of a step block; 1-5-2 of an L-shaped seat; 1-5-3 of a driving motor; 1-5-4 of a driving coupling; belt wheels on the belt shaft 1-5-5; 1-5-6 of a friction belt; belt pulley 1-5-7 under the belt shaft; 1-6 of a crankshaft mechanism; 1-6-1 of a crankshaft body; 1-6-2 of a conical friction wheel; drive arms 1-7; 1-8 of a support mechanism; a support base 1-8-1; corner supports 1-8-2; a cleaning mechanism 2; cleaning the base 2-1; 2-2 of a cleaning box; cleaning the spiral 2-3; 2-4 parts of a water pipe fixing mechanism; 2-4-1 of a water pipe fixing seat; the water pipe is inserted into the opening 2-4-2; 2-5 of a fixing screw; cleaning the motor 2-6; 2-7 of a motor belt pulley; 2-8 parts of a belt; cleaning the spiral belt pulley 2-9; 2-10 of a sand outlet; 2-11 parts of a water outlet; a drying mechanism 3; a bottom sliding seat mechanism 3-1; a bottom sliding seat body 3-1-1; a stepped groove I3-1-2; a passive mechanism 3-2; a fixed seat I3-2-1; a linkage rod 3-2-2; a matching groove 3-2-3; a linkage rod I3-2-4; pulley I3-2-5; a step sliding seat A3-2-6; 3-3 of a cam mechanism; bearing seat I3-3-1; a camshaft 3-3-2; 3-3-3 of the cam; 3-3-4 parts of a camshaft coupling; 3-3-5 parts of a cam motor; a fixing frame mechanism 3-4; 3-4-1 of a light hole; 3-4-2 of a fixed underframe; 3-4-3 of a vertical connecting rod; 3-4-4 of a vibration spring; 3-4-5 of a top frame; bearing seat II 3-4-6; 3-5 of a floating frame mechanism; 3-5-1 of an upper movable rod seat and a lower movable rod seat; 3-5-2 parts of a limiting boss; 3-5-3 parts of a floating drying rack body; 3-5-4 of a sliding unthreaded hole; 3-6 parts of air flow mechanism; 3-6-1 of a welding port; 3-6-2 of a lower hinge frame; 3-6-3 hinged impeller arms; 3-6-4 parts of an impeller; upper articulated arm I3-6-5; 3-6-6 of an upper hinge frame; adjusting helix A3-6-7; a sliding hole B3-6-8; 3-7 of a stirring mechanism; 3-7-1 of stirring blades; 3-7-2 of a stirring shaft; 3-7-3 of a stirring coupler; 3-7-4 parts of a stirring motor; 3-7-5 of a stirring motor support; a step platform 4.

Detailed Description

The first embodiment is as follows:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, fig. 19, fig. 20, fig. 21, and fig. 22, and the present invention relates to a cleaning apparatus, and more specifically, to an engine core cleaning processing apparatus, including a variable speed feeding mechanism 1, a cleaning mechanism 2, an airing mechanism 3, and a step platform 4, the apparatus being capable of automatically feeding, adjusting the feeding speed, clamping a water pipe, washing sand, flattening and airing the sand, forming a weak turbulent flow, accelerating the air drying without causing dust, and accelerating the drying by shaking.

The variable-speed feeding mechanism 1 comprises a vibration seat mechanism 1-1, a feeding hopper mechanism 1-2, a speed-regulating supporting seat mechanism 1-3, a servo regulating motor mechanism 1-4, a driving mechanism 1-5, a crankshaft mechanism 1-6, a driving arm 1-7 and a supporting mechanism 1-8, the vibration seat mechanism 1-1 is hinged with the feeding hopper mechanism 1-2, the speed regulation supporting seat mechanism 1-3 is connected with the servo regulation motor mechanism 1-4, the servo regulation motor mechanism 1-4 is connected with the driving mechanism 1-5, the driving mechanism 1-5 is flexibly connected with the crankshaft mechanism 1-6, the crankshaft mechanism 1-6 is hinged with the driving arm 1-7, the driving arm 1-7 is hinged with the feeding hopper mechanism 1-2, and the crankshaft mechanism 1-6 is connected with the supporting mechanism 1-8; the vibration seat mechanism 1-1 comprises a base 1-1-1, an inclined support 1-1-2, a limiting slide bar 1-1-3, a spring 1-1-4 and an upper hinged seat 1-1-5, wherein the base 1-1-1 is connected with a step platform 4, the base 1-1-1 is connected with the inclined support 1-1-2, the inclined support 1-1-2 is connected with the limiting slide bar 1-1-3, the spring 1-1-4 is sleeved on the limiting slide bar 1-1-3, and the limiting slide bar 1-1-3 is in sliding connection with the upper hinged seat 1-1-5; the feeding hopper mechanism 1-2 comprises a feeding hopper body 1-2-1 and a groove 1-2-2, wherein the groove 1-2-2 is arranged on the feeding hopper body 1-2-1, and an upper hinged seat 1-1-5 is hinged with the feeding hopper body 1-2-1; the speed regulation supporting seat mechanism 1-3 comprises a seat body 1-3-1 and a step groove 1-3-2, wherein the step groove 1-3-2 is formed on the seat body 1-3-1, and the seat body 1-3-1 is connected with a step platform 4; the servo adjusting motor mechanism 1-4 comprises a servo adjusting motor 1-4-1, a coupler 1-4-2 and a screw 1-4-3, the servo adjusting motor 1-4-1 is connected with the screw 1-4-3 through the coupler 1-4-2, the servo adjusting motor 1-4-1 is connected with the seat body 1-3-1, and the screw 1-4-3 is connected with the seat body 1-3-1 through a bearing; the driving mechanism 1-5 comprises a step block 1-5-1, an L-shaped seat 1-5-2, a driving motor 1-5-3, a driving coupling 1-5-4, a belt shaft upper belt pulley 1-5-5, a friction belt 1-5-6 and a belt shaft lower belt pulley 1-5-7, wherein the step block 1-5-1 is connected with the L-shaped seat 1-5-2, the L-shaped seat 1-5-2 is connected with the driving motor 1-5-3, the driving motor 1-5-3 is connected with the belt shaft lower belt pulley 1-5-7 through the driving coupling 1-5-4, the belt shaft lower belt pulley 1-5-7 is connected with the L-shaped seat 1-5-2 through a bearing, the belt shaft lower belt pulley 1-5-7 is connected with the friction belt 1-5-6, the friction belt 1-5-6 is connected with the belt pulley 1-5-5 on the belt shaft, the belt pulley 1-5-5 on the belt shaft is connected with the L-shaped seat 1-5-2 through a bearing, the step block 1-5-1 is matched with the step groove 1-3-2, the spiral 1-4-3 is connected with the step block 1-5-1 through a screw thread, the coupler 1-4-2 is driven to rotate through the operation of the servo adjusting motor 1-4-1, the rotation of the coupler 1-4-2 can drive the spiral 1-4-3 to rotate, the rotation of the spiral 1-4-3 can drive the step block 1-5-1 to move, the movement of the step block 1-5-1 can drive the L-shaped seat 1-5-2 to move, the L-shaped seat 1-5-2 moves to drive the friction belt 1-5-6 to move, so that the contact position of the friction belt 1-5-6 and the conical friction wheel 1-6-2 is changed, and the rotating speed of the conical friction wheel 1-6-2 can be changed under the condition that the rotating speed of the driving motor 1-5-3 is not changed, so that the feeding speed is changed; the crankshaft mechanism 1-6 comprises a crankshaft body 1-6-1 and a conical friction wheel 1-6-2, the crankshaft body 1-6-1 is connected with the conical friction wheel 1-6-2, the conical friction wheel 1-6-2 is connected with a friction belt 1-5-6, a driving coupling 1-5-4 is driven to rotate through the operation of a driving motor 1-5-3, the driving coupling 1-5-4 rotates to drive a belt shaft lower belt pulley 1-5-7 to rotate, the belt shaft lower belt pulley 1-5-7 rotates to drive a friction belt 1-5-6 to move, the friction belt 1-5-6 moves to drive the conical friction wheel 1-6-2 to rotate, and the conical friction wheel 1-6-2 rotates to drive the crankshaft body 1-6-1 to rotate The crankshaft body 1-6-1 rotates to drive the end, close to the driving arm 1-7, of the feeding hopper body 1-2-1 to reciprocate up and down through the driving arm 1-7, so that the reciprocating end of the feeding hopper body 1-2-1 is lifted upwards to dump sand in the feeding hopper body 1-2-1 forwards, automatic feeding is achieved, in the process, when the sand moves forwards, weight can be pressed on the upper end of the vibration seat mechanism 1-1, the spring 1-1-4 can be compressed at the moment, then the spring 1-1-4 can rebound, and therefore the sand can move forwards better, particularly the sand with high humidity; the supporting mechanism 1-8 comprises a supporting base 1-8-1 and a corner support 1-8-2, the supporting base 1-8-1 is connected with the corner support 1-8-2, the corner support 1-8-2 is connected with the crankshaft body 1-6-1 through a bearing, and the supporting base 1-8-1 is connected with the stepped platform 4.

The variable-speed feeding mechanism 1 is connected with the step platform 4, the cleaning mechanism 2 is connected with the step platform 4, and the airing mechanism 3 is connected with the step platform 4.

The second embodiment is as follows:

the embodiment is further described with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, fig. 19, fig. 20, fig. 21, fig. 22. in the embodiment, the cleaning mechanism 2 includes a cleaning base 2-1, a cleaning tank 2-2, a cleaning screw 2-3, a water pipe fixing mechanism 2-4, a fixing screw 2-5, a cleaning motor 2-6, a motor pulley 2-7, a belt 2-8, a cleaning screw pulley 2-9, a sand outlet 2-10, and a water outlet 2-11, the cleaning base 2-1 is connected to a stepped platform 4, the cleaning base 2-1 is connected to the cleaning tank 2-2, the cleaning tank 2-2 is connected to the cleaning screw 2-3 by a bearing, the water pipe fixing mechanism 2-4 is connected with the cleaning box 2-2, the fixing screw 2-5 is connected with the water pipe fixing mechanism 2-4, the cleaning motor 2-6 is connected with the cleaning box 2-2, the cleaning motor 2-6 is connected with the motor belt pulley 2-7, the motor belt pulley 2-7 is flexibly connected with the belt 2-8, the belt 2-8 is flexibly connected with the cleaning spiral belt pulley 2-9, the cleaning spiral belt pulley 2-9 is connected with the cleaning spiral 2-3, the sand outlet 2-10 is arranged on the cleaning box 2-2, and the water outlet 2-11 is arranged on the cleaning box 2-2; the water pipe fixing mechanism 2-4 comprises a water pipe fixing seat 2-4-1 and a water pipe inserting opening 2-4-2, the water pipe fixing seat 2-4-1 is connected with the cleaning box 2-2, the water pipe inserting opening 2-4-2 is formed in the water pipe fixing seat 2-4-1, a water pipe is inserted from the water pipe inserting opening 2-4-2, then a fixing screw 2-5 is screwed, and the water pipe is pressed tightly by the fixing screw 2-5; the equipment can be used for washing sand, water is added into a water pipe, then a washing motor 2-6 is operated to drive a motor belt pulley 2-7 to rotate, the motor belt pulley 2-7 rotates to drive a washing spiral belt pulley 2-9 to rotate through a belt 2-8, the washing spiral belt pulley 2-9 rotates to drive a washing spiral 2-3 to rotate, the washing spiral 2-3 rotates to drive sand to move towards the end of a sand outlet 2-10, water flows towards the end of a water outlet 2-11, the sand is washed by the water, sewage is discharged from the water outlet 2-11, and the sand is discharged from the sand outlet 2-10 and enters a floating airing frame body 3-5-3.

The third concrete implementation mode:

the embodiment is further described with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, fig. 19, fig. 20, fig. 21, fig. 22. the embodiment is further described, wherein the airing mechanism 3 comprises a bottom sliding seat mechanism 3-1, a driven mechanism 3-2, a cam mechanism 3-3, a fixed frame mechanism 3-4, a floating frame mechanism 3-5, an air flowing mechanism 3-6, a stirring mechanism 3-7, a bottom sliding seat mechanism 3-1 is connected with the driven mechanism 3-2, the driven mechanism 3-2 is connected with the cam mechanism 3-3, the cam mechanism 3-3 is connected with the bottom sliding seat mechanism 3-1, the driven mechanism 3-2 is connected with the floating frame mechanism 3-5, the floating frame mechanism 3-5 is connected with the fixed frame mechanism 3-4, the air flow mechanism 3-6 is connected with the stirring mechanism 3-7, and the stirring mechanism 3-7 is connected with the fixed frame mechanism 3-4; the bottom sliding seat mechanism 3-1 comprises a bottom sliding seat body 3-1-1 and a stepped groove I3-1-2, the stepped groove I3-1-2 is arranged on the bottom sliding seat body 3-1-1, and the bottom sliding seat body 3-1-1 is connected with a stepped platform 4; the passive mechanism 3-2 comprises a fixed seat I3-2-1, a linkage rod 3-2-2, a matching groove 3-2-3, a linkage rod I3-2-4, a pulley I3-2-5 and a step sliding seat A3-2-6, the fixed seat I3-2-1 is connected with the bottom sliding seat body 3-1-1, the fixed seat I3-2-1 is hinged with the linkage rod 3-2-2, the linkage rod 3-2-2 is hinged with the linkage rod I3-2-4, the matching groove 3-2-3 is arranged on the linkage rod 3-2-2, the pulley I3-2-5 is connected with the linkage rod I3-2-4, the linkage rod I3-2-4 is hinged with the step sliding seat A3-2-6, the step sliding seat A3-2-6 is matched with the step groove I3-1-2; the cam mechanism 3-3 comprises a bearing seat I3-3-1, a cam shaft 3-3-2, a cam 3-3-3, a cam shaft coupler 3-3-4 and a cam motor 3-3-5, wherein the bearing seat I3-3-1 is connected with a bottom sliding seat body 3-1-1, the bearing seat I3-3-1 is connected with the cam shaft 3-3-2, the cam shaft 3-3-2 is connected with the cam 3-3-3, the cam shaft 3-3-2 is connected with the cam motor 3-3-5 through the cam shaft coupler 3-3-4, and the cam 3-3-3 is matched with a pulley I3-2-5; the fixing frame mechanism 3-4 comprises a unthreaded hole 3-4-1, a fixed underframe 3-4-2, a vertical connecting rod 3-4-3, a vibration spring 3-4-4, a top frame 3-4-5 and a bearing seat II3-4-6, wherein the unthreaded hole 3-4-1 is arranged on the fixed underframe 3-4-2, the fixed underframe 3-4-2 is connected with a step platform 4, the vertical connecting rod 3-4-3 is arranged between the fixed underframe 3-4-2 and the top frame 3-4-5, the vibration spring 3-4-4 is sleeved on the vertical connecting rod 3-4-3, and the bearing seat II3-4-6 is connected with the top frame 3-4-5; the floating frame mechanism 3-5 comprises an upper movable rod seat 3-5-1, a lower movable rod seat 3-5-2, a floating drying frame body 3-5-3 and a sliding unthreaded hole 3-5-4, wherein the upper movable rod seat 3-5-1 and the lower movable rod seat are matched with a matching groove 3-2-3, the upper movable rod seat 3-5-1 and the lower movable rod seat 3-5-2 are connected with the limiting lug boss 3-5-2, the limiting lug boss 3-5-2 is connected with the floating drying frame body 3-5-3, the sliding unthreaded hole 3-5-4 is arranged on the floating drying frame body 3-5-3, the sliding unthreaded hole 3-5-4 is matched with a vertical connecting rod 3-4-3, the floating drying frame body 3-5-3 is matched with the unthreaded hole 3-4-1, the cam motor 3-3-5 is operated to drive the cam shaft coupling 3-3-4 to rotate, the cam shaft coupling 3-3-4 rotates to drive the cam shaft 3-3-2 to rotate, the cam shaft 3-3-2 rotates to drive the cam 3-3-3 to rotate, the cam 3-3-3 rotates to drive the linkage rod I3-2-4 to press downwards through matching with the pulley I3-2-5, the linkage rod I3-2-4 drives the linkage rod 3-2-2 to press downwards, the linkage rod 3-2-2 drives the upper and lower movable rod seats 3-5-1 to move downwards through the matching groove 3-2-3, the downward movement of the upper and lower movable rod seats 3-5-1 drives the floating drying rack body 3-5-3 to move downwards, the floating drying rack body 3-5-3 moves downwards to compress the vibration spring 3-4-4, then the vibration spring 3-4-4 rebounds to drive the floating drying rack body 3-5-3 to reset, and the floating drying rack body 3-5-3 continuously vibrates under the matching of the cam 3-3-3 and the vibration spring 3-4-4, so that the exchange between the sand and air flow is accelerated while the water in the washed sand flows out, and the drying is accelerated; the air flow mechanism 3-6 comprises a welding port 3-6-1, a lower hinged frame 3-6-2, a hinged impeller arm 3-6-3, an impeller 3-6-4, an upper hinged arm I3-6-5, an upper hinged frame 3-6-6, an adjusting screw A3-6-7 and a sliding hole B3-6-8, wherein the welding port 3-6-1 is arranged on the lower hinged frame 3-6-2, the lower hinged frame 3-6-2 is hinged with the hinged impeller arm 3-6-3, the hinged impeller arm 3-6-3 is connected with the impeller 3-6-4 by a bearing, the hinged impeller arm 3-6-3 is hinged with the upper hinged arm I3-6-5, the upper hinged arm I3-6-5 is hinged with the upper hinged frame 3-6-6, the upper hinge frame 3-6-6 is connected with the adjusting screw A3-6-7 through threads, the adjusting screw A3-6-7 is connected with the lower hinge frame 3-6-2 through a bearing, the sliding hole B3-6-8 is formed in the upper hinge frame 3-6-6, the stirring shaft 3-7-2 can drive the air flow mechanism 3-6 to rotate in the rotating process, when the air flow mechanism 3-6 rotates, the impeller 3-6-4 can form weak airflow which can accelerate air flow and dry, but dust can not be raised, the upper hinge frame 3-6-6 can be driven to move upwards or downwards through the screwing of the adjusting screw A3-6-7, the upper hinge frame 3-6-6 can be driven to move through the upper hinge arm I3-6-5 to drive the hinge impeller arm 3-6-3 to move, thus, the angle of the hinged impeller arm 3-6-3 can be changed, thereby changing the direction and the position of the formed airflow and being convenient for better drying; the stirring mechanism 3-7 comprises a stirring blade 3-7-1, a stirring shaft 3-7-2, a stirring coupler 3-7-3, a stirring motor 3-7-4 and a stirring motor support 3-7-5, wherein the stirring blade 3-7-1 is connected with the stirring shaft 3-7-2, the stirring shaft 3-7-2 is connected with the stirring motor 3-7-4 through the stirring coupler 3-7-3, the stirring motor 3-7-4 is connected with the stirring motor support 3-7-5, the stirring motor support 3-7-5 is connected with the top frame 3-4-5, the stirring shaft 3-7-2 is connected with a bearing seat II3-4-6, the stirring shaft 3-7-2 is matched with a sliding hole B3-6-8, the stirring shaft 3-7-2 is connected with the welding port 3-6-1, the stirring shaft 3-7-2 is driven to rotate by the operation of the stirring motor 3-7-4, the stirring shaft 3-7-2 drives the stirring blade 3-7-1 to rotate, and the sand is flattened by the rotation of the stirring blade 3-7-1.

The fourth concrete implementation mode:

the present embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, and 22, and the present embodiment further describes a first embodiment in which the material of the hopper body 1-2-1 is high manganese steel.

The fifth concrete implementation mode:

the present embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, and 22, and the present embodiment further describes the first embodiment in which the friction belt 1-5-6 and the conical friction wheel 1-6-2 are provided with cross grooves that are engaged with each other to prevent slippage.

The working principle of the device is as follows: the device can automatically feed, the driving coupling 1-5-4 is driven to rotate by the operation of the driving motor 1-5-3, the driving coupling 1-5-4 rotates to drive the belt shaft lower belt pulley 1-5-7 to rotate, the belt shaft lower belt pulley 1-5-7 rotates to drive the friction belt 1-5-6 to move, the friction belt 1-5-6 moves to drive the cone friction wheel 1-6-2 to rotate, the cone friction wheel 1-6-2 rotates to drive the crankshaft body 1-6-1 to rotate, the crankshaft body 1-6-1 rotates to drive the feeding hopper body 1-2-1 to move up and down through the driving arm 1-7 at the end close to the driving arm 1-7, in the process, when the sand moves forwards, the weight is pressed on the upper end of the vibrating seat mechanism 1-1, the spring 1-1-4 is compressed, and then the spring 1-1-4 rebounds, so that the sand can better move forwards, and particularly the sand with high humidity; the equipment can adjust the feeding speed, the coupler 1-4-2 is driven to rotate by the operation of the servo adjusting motor 1-4-1, the coupler 1-4-2 rotates to drive the screw 1-4-3 to rotate, the screw 1-4-3 rotates to drive the step block 1-5-1 to move, the step block 1-5-1 moves to drive the L-shaped seat 1-5-2 to move, the L-shaped seat 1-5-2 moves to drive the friction belt 1-5-6 to move, so that the contact position of the friction belt 1-5-6 and the conical friction wheel 1-6-2 is changed, the rotating speed of the conical friction wheel 1-6-2 can be changed under the condition that the rotating speed of the driving motor 1-5-3 is not changed, thereby changing the feed rate; the device can clamp the water pipe, the water pipe is inserted from the water pipe insertion opening 2-4-2, then the fixing screw 2-5 is screwed, and the fixing screw 2-5 can compress the water pipe; the equipment can be used for washing sand, adding water into a water pipe, then operating a washing motor 2-6 to drive a motor belt pulley 2-7 to rotate, driving a washing spiral belt pulley 2-9 to rotate through a belt 2-8 when the motor belt pulley 2-7 rotates, driving a washing spiral 2-3 to rotate when the washing spiral belt pulley 2-9 rotates, driving sand to move towards one end of a sand outlet 2-10 when the washing spiral 2-3 rotates, and meanwhile, flowing water towards one end of a water outlet 2-11, so that the water can wash the sand, discharging sewage from the water outlet 2-11, and discharging the sand from the sand outlet 2-10 into a floating airing frame body 3-5-3; the equipment can be used for flattening and airing the sand, the stirring shaft 3-7-2 is driven to rotate by the operation of the stirring motor 3-7-4, the stirring shaft 3-7-2 drives the stirring blade 3-7-1 to rotate by the rotation, and the sand is flattened by the rotation of the stirring blade 3-7-1; the device can form weak turbulent wind, accelerate wind drying, but can not cause dust raising, the stirring shaft 3-7-2 can drive the air flow mechanism 3-6 to rotate in the rotating process, when the air flow mechanism 3-6 rotates, the impellers 3-6-4 will form weak air flow which will accelerate air flow, accelerate drying, but does not cause dust emission, the upper hinge bracket 3-6-6 can be driven to move upwards or downwards by screwing the adjusting screw A3-6-7, the upper hinge bracket 3-6-6 can drive the hinge impeller arm 3-6-3 to move through the upper hinge arm I3-6-5, thus, the angle of the hinged impeller arm 3-6-3 can be changed, thereby changing the direction and the position of the formed airflow and being convenient for better drying; the equipment can accelerate drying by a shaking mode, the cam motor 3-3-5 is operated to drive the camshaft coupler 3-3-4 to rotate, the camshaft coupler 3-3-4 rotates to drive the camshaft 3-3-2 to rotate, the camshaft 3-3-2 rotates to drive the cam 3-3-3 to rotate, the cam 3-3-3 rotates to drive the linkage rod I3-2-4 to press downwards by matching with the pulley I3-2-5, the linkage rod I3-2-4 drives the linkage rod 3-2-2 to press downwards, the linkage rod 3-2-2 drives the upper and lower movable rod seats 3-5-1 to move downwards by matching with the grooves 3-2-3, the downward movement of the upper movable rod seat 3-5-1 and the lower movable rod seat can drive the floating drying rack body 3-5-3 to move downwards, the downward movement of the floating drying rack body 3-5-3 can compress the vibration spring 3-4-4, then the vibration spring 3-4-4 can rebound to drive the floating drying rack body 3-5-3 to reset, and the floating drying rack body 3-5-3 can continuously vibrate under the matching of the cam 3-3-3 and the vibration spring 3-4-4, so that the exchange of sand and air flow can be accelerated when water in the washed sand flows out, and the drying is accelerated.

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 (5)

1. The utility model provides an engine psammitolite washs treatment facility, includes variable speed feed mechanism (1), wiper mechanism (2), sunning mechanism (3), ladder platform (4), its characterized in that: the variable-speed feeding mechanism (1) comprises a vibration seat mechanism (1-1), a feeding hopper mechanism (1-2), a speed-regulating supporting seat mechanism (1-3), a servo regulating motor mechanism (1-4), a driving mechanism (1-5), a crankshaft mechanism (1-6), a driving arm (1-7) and a supporting mechanism (1-8), wherein the vibration seat mechanism (1-1) is hinged with the feeding hopper mechanism (1-2), the speed-regulating supporting seat mechanism (1-3) is connected with the servo regulating motor mechanism (1-4), the servo regulating motor mechanism (1-4) is connected with the driving mechanism (1-5), the driving mechanism (1-5) is flexibly connected with the crankshaft mechanism (1-6), and the crankshaft mechanism (1-6) is hinged with the driving arm (1-7), the driving arm (1-7) is hinged with the feeding hopper mechanism (1-2), and the crankshaft mechanism (1-6) is connected with the supporting mechanism (1-8); the vibration seat mechanism (1-1) comprises a base (1-1-1), an inclined support (1-1-2), a limiting slide rod (1-1-3), a spring (1-1-4) and an upper hinge seat (1-1-5), wherein the base (1-1-1) is connected with a step platform (4), the base (1-1-1) is connected with the inclined support (1-1-2), the inclined support (1-1-2) is connected with the limiting slide rod (1-1-3), the spring (1-1-4) is sleeved on the limiting slide rod (1-1-3), and the limiting slide rod (1-1-3) is connected with the upper hinge seat (1-1-5) in a sliding manner; the feeding hopper mechanism (1-2) comprises a feeding hopper body (1-2-1) and a groove (1-2-2), wherein the groove (1-2-2) is arranged on the feeding hopper body (1-2-1), and an upper hinged seat (1-1-5) is hinged with the feeding hopper body (1-2-1); the speed regulation supporting seat mechanism (1-3) comprises a seat body (1-3-1) and a step groove (1-3-2), wherein the step groove (1-3-2) is formed in the seat body (1-3-1), and the seat body (1-3-1) is connected with a step platform (4); the servo adjusting motor mechanism (1-4) comprises a servo adjusting motor (1-4-1), a coupler (1-4-2) and a screw (1-4-3), the servo adjusting motor (1-4-1) is connected with the screw (1-4-3) through the coupler (1-4-2), the servo adjusting motor (1-4-1) is connected with the seat body (1-3-1), and the screw (1-4-3) is connected with the seat body (1-3-1) in a bearing mode; the driving mechanism (1-5) comprises a step block (1-5-1), an L-shaped seat (1-5-2), a driving motor (1-5-3), a driving coupling (1-5-4), a belt pulley (1-5-5) on the belt shaft, a friction belt (1-5-6) and a belt pulley (1-5-7) under the belt shaft, the step block (1-5-1) is connected with the L-shaped seat (1-5-2), the L-shaped seat (1-5-2) is connected with the driving motor (1-5-3), the driving motor (1-5-3) is connected with the belt pulley (1-5-7) under the belt shaft through the driving coupling (1-5-4), the belt pulley (1-5-7) under the belt shaft is connected with the L-shaped seat (1-5-2) in a bearing way, the belt shaft lower belt pulley (1-5-7) is connected with the friction belt (1-5-6), the friction belt (1-5-6) is connected with the belt shaft upper belt pulley (1-5-5), the belt shaft upper belt pulley (1-5-5) is connected with the L-shaped seat (1-5-2) in a bearing mode, the step block (1-5-1) is matched with the step groove (1-3-2), and the spiral (1-4-3) is connected with the step block (1-5-1) through threads; the crankshaft mechanism (1-6) comprises a crankshaft body (1-6-1) and a cone friction wheel (1-6-2), wherein the crankshaft body (1-6-1) is connected with the cone friction wheel (1-6-2), and the cone friction wheel (1-6-2) is connected with a friction belt (1-5-6); the supporting mechanism (1-8) comprises a supporting base (1-8-1) and a corner support (1-8-2), the supporting base (1-8-1) is connected with the corner support (1-8-2), the corner support (1-8-2) is connected with the crankshaft body (1-6-1) in a bearing mode, and the supporting base (1-8-1) is connected with the stepped platform (4);

variable speed feed mechanism (1) link to each other with ladder platform (4), wiper mechanism (2) link to each other with ladder platform (4), sunning mechanism (3) link to each other with ladder platform (4).

2. The engine sand core cleaning treatment device as claimed in claim 1, wherein: the cleaning mechanism (2) comprises a cleaning base (2-1), a cleaning box (2-2), a cleaning screw (2-3), a water pipe fixing mechanism (2-4), a fixing screw (2-5), a cleaning motor (2-6), a motor belt pulley (2-7), a belt (2-8), a cleaning screw belt pulley (2-9), a sand outlet (2-10) and a water outlet (2-11), wherein the cleaning base (2-1) is connected with a stepped platform (4), the cleaning base (2-1) is connected with the cleaning box (2-2), the cleaning box (2-2) is connected with the cleaning screw (2-3) in a bearing way, the water pipe fixing mechanism (2-4) is connected with the cleaning box (2-2), and the fixing screw (2-5) is connected with the water pipe fixing mechanism (2-4), the cleaning motor (2-6) is connected with the cleaning box (2-2), the cleaning motor (2-6) is connected with the motor belt pulley (2-7), the motor belt pulley (2-7) is flexibly connected with the belt (2-8), the belt (2-8) is flexibly connected with the cleaning spiral belt pulley (2-9), the cleaning spiral belt pulley (2-9) is connected with the cleaning spiral (2-3), the sand outlet (2-10) is arranged on the cleaning box (2-2), and the water outlet (2-11) is arranged on the cleaning box (2-2); the water pipe fixing mechanism (2-4) comprises a water pipe fixing seat (2-4-1) and a water pipe inserting opening (2-4-2), the water pipe fixing seat (2-4-1) is connected with the cleaning tank (2-2), and the water pipe inserting opening (2-4-2) is formed in the water pipe fixing seat (2-4-1).

3. The engine sand core cleaning treatment device as claimed in claim 1, wherein: the airing mechanism (3) comprises a bottom sliding seat mechanism (3-1), a driven mechanism (3-2), a cam mechanism (3-3), a fixed frame mechanism (3-4), a floating frame mechanism (3-5), an air flow mechanism (3-6) and a stirring mechanism (3-7), wherein the bottom sliding seat mechanism (3-1) is connected with the driven mechanism (3-2), the driven mechanism (3-2) is matched with the cam mechanism (3-3), the cam mechanism (3-3) is connected with the bottom sliding seat mechanism (3-1), the driven mechanism (3-2) is matched with the floating frame mechanism (3-5), the floating frame mechanism (3-5) is connected with the fixed frame mechanism (3-4), the air flow mechanism (3-6) is connected with the stirring mechanism (3-7), the stirring mechanism (3-7) is connected with the fixed frame mechanism (3-4); the bottom sliding seat mechanism (3-1) comprises a bottom sliding seat body (3-1-1) and a stepped groove I (3-1-2), wherein the stepped groove I (3-1-2) is formed in the bottom sliding seat body (3-1-1), and the bottom sliding seat body (3-1-1) is connected with a stepped platform (4); the passive mechanism (3-2) comprises a fixed seat I (3-2-1), a linkage rod (3-2-2), a matching groove (3-2-3), a linkage rod I (3-2-4), a pulley I (3-2-5) and a stepped sliding seat A (3-2-6), the fixed seat I (3-2-1) is connected with a bottom sliding seat body (3-1-1), the fixed seat I (3-2-1) is hinged with the linkage rod (3-2-2), the linkage rod (3-2-2) is hinged with the linkage rod I (3-2-4), the matching groove (3-2-3) is opened on the linkage rod (3-2-2), the pulley I (3-2-5) is connected with the linkage rod I (3-2-4), the linkage rod I (3-2-4) is hinged with the step sliding seat A (3-2-6), and the step sliding seat A (3-2-6) is matched with the step groove I (3-1-2); the cam mechanism (3-3) comprises a bearing seat I (3-3-1), a cam shaft (3-3-2) and a cam (3-3-3), the device comprises a camshaft coupling (3-3-4) and a cam motor (3-3-5), wherein a bearing seat I (3-3-1) is connected with a bottom sliding seat body (3-1-1), the bearing seat I (3-3-1) is connected with a camshaft (3-3-2), the camshaft (3-3-2) is connected with a cam (3-3-3), the camshaft (3-3-2) is connected with the cam motor (3-3-5) through the camshaft coupling (3-3-4), and the cam (3-3-3) is matched with a pulley I (3-2-5); the fixed frame mechanism (3-4) comprises a unthreaded hole (3-4-1), a fixed underframe (3-4-2), a vertical connecting rod (3-4-3), a vibration spring (3-4-4), a top frame (3-4-5) and a bearing seat II (3-4-6), the unthreaded hole (3-4-1) is formed in a fixed bottom frame (3-4-2), the fixed bottom frame (3-4-2) is connected with a step platform (4), a vertical connecting rod (3-4-3) is arranged between the fixed bottom frame (3-4-2) and a top frame (3-4-5), a vibration spring (3-4-4) is sleeved on the vertical connecting rod (3-4-3), and a bearing seat II (3-4-6) is connected with the top frame (3-4-5); the floating frame mechanism (3-5) comprises an upper movable rod seat (3-5-1), a limiting boss (3-5-2), a floating drying frame body (3-5-3) and a sliding unthreaded hole (3-5-4), the upper movable rod seat (3-5-1) is matched with the matching groove (3-2-3), the upper movable rod seat (3-5-1) is connected with the limiting boss (3-5-2), the limiting boss (3-5-2) is connected with the floating drying frame body (3-5-3), the sliding unthreaded hole (3-5-4) is formed in the floating drying frame body (3-5-3), the sliding unthreaded hole (3-5-4) is matched with the vertical connecting rod (3-4-3), the floating drying rack body (3-5-3) is matched with the unthreaded hole (3-4-1); the air flow mechanism (3-6) comprises a welding port (3-6-1), a lower hinged frame (3-6-2), a hinged impeller arm (3-6-3), an impeller (3-6-4), an upper hinged arm I (3-6-5), an upper hinged frame (3-6-6), an adjusting screw A (3-6-7) and a sliding hole B (3-6-8), wherein the welding port (3-6-1) is arranged on the lower hinged frame (3-6-2), the lower hinged frame (3-6-2) is hinged with the hinged impeller arm (3-6-3), the hinged impeller arm (3-6-3) is connected with the impeller (3-6-4) in a bearing mode, and the hinged impeller arm (3-6-3) is hinged with the upper hinged arm I (3-6-5) The upper articulated arm I (3-6-5) is articulated with the upper articulated frame (3-6-6), the upper articulated frame (3-6-6) is connected with the adjusting screw A (3-6-7) through threads, the adjusting screw A (3-6-7) is connected with the lower articulated frame (3-6-2) through a bearing, and the sliding hole B (3-6-8) is formed in the upper articulated frame (3-6-6); the stirring mechanism (3-7) comprises stirring blades (3-7-1), a stirring shaft (3-7-2), a stirring coupler (3-7-3), a stirring motor (3-7-4) and a stirring motor support (3-7-5), wherein the stirring blades (3-7-1) are connected with the stirring shaft (3-7-2), the stirring shaft (3-7-2) is connected with the stirring motor (3-7-4) through the stirring coupler (3-7-3), the stirring motor (3-7-4) is connected with the stirring motor support (3-7-5), the stirring motor support (3-7-5) is connected with the top frame (3-4-5), the stirring shaft (3-7-2) is connected with the bearing seat II (3-4-6), the stirring shaft (3-7-2) is matched with the sliding hole B (3-6-8), and the stirring shaft (3-7-2) is connected with the welding port (3-6-1).

4. The engine sand core cleaning treatment device as claimed in claim 1, wherein: the material of the feeding hopper body (1-2-1) is high manganese steel.

5. The engine sand core cleaning treatment device as claimed in claim 1, wherein: the friction belt (1-5-6) and the conical friction wheel (1-6-2) are provided with matched transverse grains to prevent slipping.

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