CN112916103B - Earphone charging box recovery equipment - Google Patents

Abstract

The invention relates to the field of earphones, in particular to an earphone charging box recycling device which can crush an earphone charging box and comprises a crushing assembly, an outer frame assembly, a power assembly and a screening assembly, wherein the crushing assembly is connected with the outer frame assembly, the outer frame assembly is connected with the power assembly, the screening assembly is connected with the outer frame assembly, a slide rod and a crankshaft sleeve are driven to slide relatively, so that the motion radius of the drive slide rod is changed, the motion amplitude of a rectangular connecting rod is driven to change through a rectangular slide frame, the screening amplitude of a first screening plate and a second screening plate is changed, and the screening speed of the crushed earphone charging box is adjusted by a device.

Description

Earphone charging box recovery equipment

Technical Field

The invention relates to the field of earphones, in particular to an earphone charging box recovery device.

Background

The earphone charging box recovery device is a common device in the field of earphones, but the function of the common earphone charging box recovery device is single.

Disclosure of Invention

The invention aims to provide a recovery device of an earphone charging box, which can realize the crushing of the earphone charging box.

The purpose of the invention is realized by the following technical scheme:

the utility model provides an earphone box recovery plant that charges, includes broken subassembly, frame subassembly, power component, screening subassembly, broken subassembly is connected with the frame subassembly, and the frame subassembly is connected with the power component, and the screening subassembly is connected with the frame subassembly.

As a further optimization of the technical scheme, the invention provides earphone charging box recycling equipment, wherein a crushing assembly comprises a crushing roller outer frame, a crushing rod, an inner end driving rod I, an inner end clamping rod pushing spring I, a rectangular chute I, an inner end boss, an inner end pushing spring I and an inner end driving rod II, the crushing rod is connected with the crushing roller outer frame in a sliding mode, the inner end driving rod II is connected with the crushing rod in a sliding mode, the inner end pushing spring I is connected with the crushing rod in a sleeved mode and arranged between the inner end driving rod II and the crushing rod, the inner end driving rod I is arranged at the inner end of the crushing roller outer frame and connected with the inner end driving rod I in a clamped mode, the inner end clamping rod I is connected with the crushing roller outer frame in a sliding mode, the rectangular chute I is arranged on the crushing roller outer frame, the inner end clamping rod pushing spring I is connected with the inner end clamping rod I in a sleeved mode, and the inner end clamping rod pushing spring I is arranged on the rectangular chute I, the inner end boss is fixedly connected with the inner end driving rod I, and the inner end boss is connected with the inner end driving rod II in a matching mode.

As a further optimization of the technical scheme, the invention relates to an earphone charging box recovery device, which comprises an outer frame assembly, a side wall sliding groove, a side wall roller, an annular groove, a side wall roller rotating shaft, a belt I, a bevel gear II, a bevel gear III, a bevel gear IV, a bevel gear shaft II, a bevel gear shaft I, a rotating sleeve I, an inner end driving rod III, a rotating sleeve II, an inner end fixing rod I, a rotating sleeve III and a rotating sleeve IV, wherein the side wall sliding groove is arranged on the outer frame I, the side wall roller is fixedly connected with the side wall roller rotating shaft, the side wall roller rotating shaft is rotatably connected with the outer frame, the annular groove is arranged on the side wall roller, the inner end driving rod III is slidably connected with the side wall sliding groove, the inner end driving rod III is slidably connected with the annular groove, the belt I is connected between the side wall roller rotating shaft and the bevel gear shaft I, the bevel gear shaft I is fixedly connected with the bevel gear II, and the bevel gear I is fixedly connected with the rotating sleeve III, a third rotating sleeve is rotatably connected with a first rotating sleeve, a fourth rotating sleeve is rotatably connected with a first outer frame, a fourth rotating sleeve is fixedly connected with a first bevel gear, a third bevel gear and a fourth bevel gear are both fixedly connected with a second bevel gear shaft, the second bevel gear shaft is rotatably connected with the first outer frame, the third bevel gear is in meshing transmission with the second bevel gear, the fourth bevel gear is in meshing transmission with the first bevel gear, the first rotating sleeve is rotatably connected with a third inner end driving rod, the first inner end fixing rod is rotatably connected with the third inner end driving rod, the second rotating sleeve is fixedly connected with the first inner end fixing rod, the second rotating sleeve is in sliding fit connection with the fourth rotating sleeve, the fourth rotating sleeve is rotatably connected with the third rotating sleeve, the third rotating sleeve is in sliding fit connection with the first rotating sleeve, and two crushing assemblies are arranged, an inner end driving rod I in one crushing assembly is fixedly connected with an inner end fixing rod I, and an inner end driving rod I in the other crushing assembly is fixedly connected with a rotating sleeve III.

As a further optimization of the technical scheme, the recovery device for the earphone charging box is characterized in that a discharge hole is formed in the lower end of the first outer frame.

As a further optimization of the technical scheme, the invention relates to a recovery device of an earphone charging box, wherein a power assembly comprises a power bottom plate, an input motor, a first transmission roller, a second transmission roller, a first inner rotary column, a first transmission belt, a second inner rotary column, a third inner rotary column, a second driving support, a first clutch rod, a second clutch rod, a first clutch rod push spring, a fifth bevel gear, a sixth bevel gear, a first support chute, a driving rack rod and a driving straight tooth, wherein the input motor is fixedly connected with the power bottom plate, the first transmission roller is rotatably connected with the power bottom plate, the first transmission roller is fixedly connected with an output shaft of the input motor, the second transmission roller is cooperatively connected with the first transmission roller, the second transmission roller is fixedly connected with the first inner rotary column, the first inner rotary column is rotatably connected with the second transmission support, the first transmission belt is connected between the first inner rotary column and the second inner rotary column, the inner rotary column II is rotatably connected with the driving support II, the inner rotary column III is rotatably connected with the power bottom plate, the inner rotary column III is in sliding fit connection with the inner rotary column II, the inner rotary column III is fixedly connected with the clutch rod I, the clutch rod I is in fit connection with the clutch rod II, the clutch slide rod I is in sliding connection with the clutch slide rod II, the clutch slide rod push spring I is in sleeve connection with the clutch slide rod I, the slide rod push spring I is arranged between the clutch rod II and the power bottom plate, the bevel gear V is fixedly connected with the clutch slide rod I, the bevel gear V is in meshing transmission with the bevel gear VI, the support I is fixedly connected with the power bottom plate, the support chute is arranged on the support I, the driving support II is in sliding connection with the support chute, the driving support II is in sliding connection with the driving rack rod, the driving rack rod is in meshing transmission with the driving straight teeth, the driving straight teeth are rotatably connected with the power bottom plate, and the bevel gear VI is fixedly connected with the driving support II.

As a further optimization of the technical scheme, the invention provides earphone charging box recycling equipment, wherein a screening component comprises a screening outer frame, a rotary column a, a transmission belt B, a crankshaft one, a belt pulley one, a screening plate one, an inner end sliding column pushing spring one, a screen mesh one, an inner end sliding column two, an inner end sliding column pushing spring two, a screening plate two, a screen mesh two, a crankshaft sleeve, a driving sliding rod, a crankshaft two, a rectangular connecting rod, a rectangular sliding frame, an inner end clamping groove, an inner end clamping rod and an inner end clamping rod pushing spring, the rotary column a is rotatably connected with the screening outer frame, the transmission belt a is connected with the rotary column a, the transmission belt B is connected between the rotary column a and the belt pulley one, the belt pulley one is fixedly connected with the crankshaft one, the crankshaft one is rotatably connected with the screening outer frame, the inner end sliding column one is fixedly connected with the screening outer frame, the inner end sliding column pushing spring one is connected with the inner end sliding column one in a sleeved mode, the screening plate one is slidably connected with the inner end sliding column one, the screening device comprises screening plates, screening outer frames, screening plates, screening slide columns, a driving slide rod, a rectangular slide frame, a rectangular connecting rod, a screening plate I, a screening plate II, a screening plate I, a screening bevel shaft II, a bevel shaft II and a bevel gear shaft II, wherein the screening plate I is arranged on the screening plate I, the screening plate II is fixedly connected with the screening outer frame, the inner slide column push spring II is connected with the inner slide column II in a sleeved mode, the screening plate II is connected with the inner slide column II in a sliding mode, the driving slide rod is connected with the crankshaft sleeve in a sliding mode, the driving slide rod is connected with the rectangular slide frame in a rotating mode, the rectangular slide frame is connected with the screening plate I in a sliding mode, the rectangular connecting rod is fixedly connected between the screening plate I and the screening plate II, the inner clamping groove is formed in the crankshaft sleeve, the inner clamping rod is connected with the inner clamping groove in a matched mode, the inner clamping rod is connected with the driving slide rod in a sliding mode, the inner clamping rod push spring is arranged between the screening plate I, the outer frame is fixedly connected with the screening outer frame and is communicated with the screening outer frame in a transmission belt A.

The recovery device for the earphone charging box has the beneficial effects that:

according to the recovery device for the earphone charging box, the slide rod and the crankshaft sleeve are driven to slide relatively, so that the movement radius of the drive slide rod is changed, the movement amplitude of the rectangular connecting rod is driven to change through the rectangular slide frame, the screening amplitude of the screening plate I and the screening amplitude of the screening plate II are changed, and the screening speed of the crushed earphone charging box can be adjusted through the device.

Drawings

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

FIG. 1 is a first general structural diagram of the present invention;

FIG. 2 is a second overall structural schematic of the present invention;

FIG. 3 is a first schematic view of the construction of the crushing module 1 of the present invention;

FIG. 4 is a second schematic structural view of the crushing assembly 1 of the present invention;

fig. 5 is a schematic view three of the construction of the crushing assembly 1 of the present invention;

FIG. 6 is a first schematic structural diagram of the outer frame assembly 2 of the present invention;

FIG. 7 is a second schematic structural view of the outer frame assembly 2 of the present invention;

FIG. 8 is a third schematic structural view of the outer frame assembly 2 of the present invention;

FIG. 9 is a first schematic structural view of the power assembly 3 of the present invention;

FIG. 10 is a second schematic structural view of the power assembly 3 of the present invention;

FIG. 11 is a first schematic illustration of the construction of screen assemblies 4 of the present invention;

FIG. 12 is a schematic illustration of screen assemblies 4 of the present invention;

FIG. 13 is a schematic illustration of screen assemblies 4 of the present invention;

figure 14 is a fourth schematic illustration of the construction of screen assemblies 4 of the present invention.

In the figure: a crushing assembly 1; crushing roller outer frames 1-1; a crushing rod 1-2; the inner end drives the rod I1-3; the inner end of the clamping rod I is 1-4; the inner end clamping rod pushes a spring 1-5; 1-6 of a rectangular chute; 1-7 of inner end bosses; the inner end of the push spring I is 1-8; the inner end drives a rod II 1-9; an outer frame component 2; 2-1 of an outer frame; a side wall chute 2-2; side wall rollers 2-3; 2-4 of annular groove; side wall roller rotating shafts 2-5; 2-6 parts of a first belt; 2-7 parts of a first bevel gear; 2-8 parts of a second bevel gear; 2-9 parts of bevel gear III; 2-10 parts of bevel gear; 2-11 parts of a bevel gear shaft II; 2-12 parts of a bevel gear shaft I; rotating the first sleeve 2-13; the inner end drives a rod III 2-14; rotating the second sleeve 2-15; the inner end is fixed with a rod I2-16; rotating the third sleeve 2-17; rotating the sleeve four 2-18; a power assembly 3; a power bottom plate 3-1; inputting a motor 3-2; a first transmission roller 3-3; a second transmission roller 3-4; 3-5 of an inner end rotating column; 3-6 parts of a first transmission belt; 3-7 of an inner end rotary column II; 3-8 of inner end rotating column III; 3-9 parts of a second driving bracket; 3-10 parts of a clutch lever I; a second clutch lever 3-11; 3-12 parts of a clutch slide bar I; a clutch slide bar push spring I is 3-13; 3-14 parts of bevel gear five; 3-15 parts of bevel gear; 3-16 parts of a first bracket; 3-17 of a bracket chute; driving the rack bar 3-18; 3-19 of driving straight teeth; a screen assembly 4; screening the outer frame 4-1; rotary column A4-2; a transmission belt A4-3; a transmission belt B4-4; 4-5 of a crankshaft I; 4-6 of a belt wheel I; 4-7 parts of a first screening plate; 4-8 of inner end sliding column I; the inner end sliding column push spring is 4-9; 4-10 of sieve pores; 4-11 of inner end sliding columns; 4-12 parts of inner end sliding column push spring II; 4-13 parts of a second screening plate; 4-14 mesh openings; 4-15 parts of a crankshaft sleeve; driving the sliding rods 4-16; 4-17 parts of a second crankshaft; rectangular connecting rods 4-18; 4-19 of a rectangular sliding frame; 4-20 parts of inner end clamping grooves; inner end clamping rods 4-21; the inner end clamping rod pushes springs 4-22.

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 following describes the embodiment with reference to fig. 1 to 14, and the earphone charging box recycling device includes a crushing assembly 1, an outer frame assembly 2, a power assembly 3, and a screening assembly 4, where the crushing assembly 1 is connected to the outer frame assembly 2, the outer frame assembly 2 is connected to the power assembly 3, and the screening assembly 4 is connected to the outer frame assembly 2.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-14, and the embodiment further describes the first embodiment, wherein the crushing assembly 1 comprises a crushing roller outer frame 1-1, a crushing rod 1-2, an inner end driving rod 1-3, an inner end clamping rod 1-4, an inner end clamping rod pushing spring 1-5, a rectangular sliding chute 1-6, an inner end boss 1-7, an inner end pushing spring 1-8 and an inner end driving rod two 1-9, the crushing rod 1-2 is connected with the crushing roller outer frame 1-1 in a sliding manner, the inner end driving rod two 1-9 is connected with the crushing rod 1-2 in a sliding manner, the inner end pushing spring 1-8 is connected with the crushing rod 1-2 in a sleeved manner, the inner end pushing spring 1-8 is arranged between the inner end driving rod two 1-9 and the crushing rod 1-2, the inner end driving rod 1-3 is arranged at the inner end of the crushing roller outer frame 1-1, the inner end clamping rod I1-4 is clamped with the inner end driving rod I1-3, the inner end clamping rod I1-4 is connected with the crushing roller outer frame 1-1 in a sliding mode, the rectangular sliding groove I1-6 is arranged on the crushing roller outer frame 1-1, the inner end clamping rod push spring I1-5 is connected with the inner end clamping rod I1-4 in a sleeved mode, the inner end clamping rod push spring I1-5 is arranged on the rectangular sliding groove I1-6, the inner end boss 1-7 is fixedly connected with the inner end driving rod I1-3, and the inner end boss 1-7 is connected with the inner end driving rod II 1-9 in a matched mode.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1-14, and the embodiment further describes the embodiment, where the outer frame assembly 2 includes an outer frame one 2-1, a side wall chute 2-2, a side wall roller 2-3, an annular groove 2-4, a side wall roller rotating shaft 2-5, a belt one 2-6, a bevel gear one 2-7, a bevel gear two 2-8, a bevel gear three 2-9, a bevel gear four 2-10, a bevel gear shaft two 2-11, a bevel gear shaft one 2-12, a rotating sleeve one 2-13, an inner end driving rod three 2-14, a rotating sleeve two 2-15, an inner end fixing rod one 2-16, a rotating sleeve three 2-17, and a rotating sleeve four 2-18, the side wall chute 2-2 is disposed on the outer frame one 2-1, the side wall roller 2-3 is fixedly connected with the side wall roller rotating shaft 2-5, a side wall roller rotating shaft 2-5 is rotationally connected with an outer frame I2-1, an annular groove 2-4 is arranged on a side wall roller 2-3, an inner end driving rod III 2-14 is slidably connected with a side wall sliding groove 2-2, an inner end driving rod III 2-14 is slidably connected with the annular groove 2-4, a belt I2-6 is connected between the side wall roller rotating shaft 2-5 and a bevel gear shaft I2-12, the bevel gear shaft I2-12 is fixedly connected with a bevel gear II 2-8, the bevel gear I2-7 is fixedly connected with a rotating sleeve III 2-17, the rotating sleeve III 2-17 is rotationally connected with the outer frame I2-1, a rotating sleeve IV 2-18 is rotationally connected with the outer frame I2-1, the rotating sleeve IV 2-18 is fixedly connected with the bevel gear I2-7, and the bevel gear III 2-9, The four bevel teeth 2-10 are fixedly connected with the two bevel gear shafts 2-11, the two bevel gear shafts 2-11 are rotatably connected with the first outer frame 2-1, the three bevel teeth 2-9 are in meshing transmission with the two bevel teeth 2-8, the four bevel teeth 2-10 are in meshing transmission with the first bevel teeth 2-7, the first rotating sleeve 2-13 is rotatably connected with the third inner end driving rod 2-14, the first inner end fixing rod 2-16 is rotatably connected with the third inner end driving rod 2-14, the second rotating sleeve 2-15 is fixedly connected with the first inner end fixing rod 2-16, the second rotating sleeve 2-15 is in sliding fit connection with the fourth rotating sleeve 2-18, the fourth rotating sleeve 2-18 is rotatably connected with the third rotating sleeve 2-17, the third rotating sleeve 2-17 is in sliding fit connection with the first rotating sleeve 2-13, two crushing assemblies 1 are arranged, an inner end driving rod I1-3 in one crushing assembly 1 is fixedly connected with an inner end fixing rod I2-16, and an inner end driving rod I1-3 in the other crushing assembly 1 is fixedly connected with a rotating sleeve III 2-17.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 14, and the embodiment further describes a first embodiment, in which a discharge port is provided at the lower end of the outer frame 1-2.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1-14, and the embodiment will be further described, wherein the power assembly 3 includes a power bottom plate 3-1, an input motor 3-2, a first transmission roller 3-3, a second transmission roller 3-4, a first inner rotary column 3-5, a first transmission belt 3-6, a second inner rotary column 3-7, a third inner rotary column 3-8, a second driving support 3-9, a first clutch rod 3-10, a second clutch rod 3-11, a first clutch rod 3-12, a first clutch rod push spring 3-13, a fifth conical tooth 3-14, a sixth conical tooth 3-15, a first support 3-16, a first support chute 3-17, a second driving rack rod 3-18, and a first driving spur gear 3-19, the input motor 3-2 is fixedly connected with the power bottom plate 3-1, a first transmission roller 3-3 is rotationally connected with a power bottom plate 3-1, a first transmission roller 3-3 is fixedly connected with an output shaft of an input motor 3-2, a second transmission roller 3-4 is connected with the first transmission roller 3-3 in a matching way, a second transmission roller 3-4 is fixedly connected with a first inner rotary column 3-5, the first inner rotary column 3-5 is rotationally connected with a second driving bracket 3-9, a first transmission belt 3-6 is connected between the first inner rotary column 3-5 and the second inner rotary column 3-7, the second inner rotary column 3-7 is rotationally connected with the second driving bracket 3-9, a third inner rotary column 3-8 is rotationally connected with the power bottom plate 3-1, a third inner rotary column 3-8 is connected with the second inner rotary column 3-7 in a sliding matching way, and the third inner rotary column 3-8 is fixedly connected with a first clutch lever 3-10, the first clutch rod 3-10 is connected with the second clutch rod 3-11 in a matching way, the first clutch rod 3-12 is connected with the second clutch rod 3-11 in a sliding way, the first clutch rod push spring 3-13 is connected with the first clutch rod 3-12 in a sleeved way, the first slide rod push spring 3-13 is arranged between the second clutch rod 3-11 and the power bottom plate 3-1, the fifth bevel gear 3-14 is fixedly connected with the first clutch rod 3-12, the fifth bevel gear 3-14 is in meshing transmission with the sixth bevel gear 3-15, the first bracket 3-16 is fixedly connected with the power bottom plate 3-1, the first bracket 3-17 is arranged on the first bracket 3-16, the second driving bracket 3-9 is connected with the first bracket chute 3-17 in a sliding way, the second driving bracket 3-9 is connected with the second driving rack rod 3-18 in a sliding way, the first driving rack rod 3-18 is in meshing transmission with the straight driving tooth 3-19, the driving straight teeth 3-19 are rotationally connected with the power bottom plate 3-1, and the bevel gear shaft II 2-11 is fixedly connected with the bevel gear VI 3-15;

starting the input motor 3-2, driving the transmission roller I3-3 to rotate by the input motor 3-2, driving the transmission roller II 3-4 to move by the transmission roller I3-3, driving the inner rotary post I3-5 to move by the transmission roller II 3-4, driving the transmission belt I3-6 to move by the inner rotary post I3-5, driving the inner rotary post II 3-7 to move by the transmission belt I3-6, driving the inner rotary post III 3-8 to rotate by the inner rotary post II 3-7, driving the clutch lever I3-10 to move by the inner rotary post III 3-8, driving the clutch lever II 3-11 to move by the clutch lever I3-10, driving the clutch lever I3-12 to move by the clutch lever II 3-11, the bevel gear V3-14 is driven to move by the clutch sliding rod I3-12, and the bevel gear V3-14 is driven to move by the bevel gear V3-15, so that power output is facilitated; meanwhile, the driving straight teeth 3-19 are rotated manually, the driving rack rods 3-18 are driven to move by the driving straight teeth 3-19, the driving support frames 3-9 are driven to slide along the support frame sliding grooves 3-17 by the driving rack rods 3-18, the inner end rotary columns 3-5 are driven to move along the outer surfaces of the driving rollers 3-3 by the driving support frames 3-9, and the output speed of the conical teeth six 3-15 is changed.

The sixth specific implementation mode:

the first embodiment is further described with reference to fig. 1-14, and the screen assembly 4 includes a screen outer frame 4-1, a rotary column a4-2, a transmission belt a4-3, a transmission belt B4-4, a crankshaft one 4-5, a pulley one 4-6, a screen plate one 4-7, an inner end sliding column one 4-8, an inner end sliding column push spring one 4-9, a sieve pore one 4-10, an inner end sliding column two 4-11, an inner end sliding column push spring two 4-12, a screen plate two 4-13, a sieve pore two 4-14, a crankshaft sleeve 4-15, a driving sliding rod 4-16, a crankshaft two 4-17, a rectangular connecting rod 4-18, a rectangular sliding frame 4-19, an inner end clamping groove 4-20, an inner end clamping rod 4-21, and an inner end clamping rod push spring 4-22, the rotary column A4-2 is rotatably connected with the screening outer frame 4-1, the transmission belt A4-3 is connected with the rotary column A4-2, the transmission belt B4-4 is connected between the rotary column A4-2 and the belt wheel I4-6, the belt wheel I4-6 is fixedly connected with the crankshaft I4-5, the crankshaft I4-5 is rotatably connected with the screening outer frame 4-1, the inner end sliding column I4-8 is fixedly connected with the screening outer frame 4-1, the inner end sliding column push spring I4-9 is connected with the inner end sliding column I4-8 in a sleeved mode, the screening plate I4-7 is connected with the inner end sliding column I4-8 in a sliding mode, the screen hole I4-10 is arranged on the screening plate I4-7, the inner end sliding column II 4-11 is fixedly connected with the screening outer frame 4-1, the inner end sliding column push spring II 4-12 is connected with the inner end sliding column II 4-11 in a sleeved mode, a second screening plate 4-13 is connected with a second inner end sliding column 4-11 in a sliding manner, a second screening hole 4-14 is arranged on the second screening plate 4-13, a first crankshaft 4-5 is fixedly connected with a second crankshaft 4-5, the other first crankshaft 4-5 is fixedly connected with a second crankshaft 4-17, a driving slide rod 4-16 is connected with the second crankshaft 4-15 in a sliding manner, the driving slide rod 4-16 is rotatably connected with a rectangular slide frame 4-19, the rectangular slide frame 4-19 is connected with a rectangular connecting rod 4-18 in a sliding manner, the rectangular connecting rod 4-18 is fixedly connected between the first screening plate 4-7 and the second screening plate 4-13, an inner end clamping groove 4-20 is arranged on the second crankshaft 4-15, an inner end clamping rod 4-21 is connected with the inner end clamping groove 4-20 in a matching manner, and the inner end clamping rod 4-21 is connected with the driving slide rod 4-16 in a sliding manner, the inner end clamping rod push springs 4-22 are arranged between the two inner end clamping rods 4-21, the outer frame I2-1 is fixedly connected and communicated with the screening outer frame 4-1, and the bevel gear shaft II 2-11 is connected with the transmission belt A4-3.

The invention relates to a recovery device of an earphone charging box, which has the working principle that:

when in use, the input motor 3-2 is started, the transmission roller I3-3 is driven to rotate by the input motor 3-2, the transmission roller II 3-4 is driven to move by the transmission roller I3-3, the inner end rotary post I3-5 is driven to move by the transmission roller II 3-4, the transmission belt I3-6 is driven to move by the inner end rotary post I3-5, the inner end rotary post II 3-7 is driven to move by the transmission belt I3-6, the inner end rotary post III 3-8 is driven to rotate by the inner end rotary post II 3-7, the clutch lever I3-10 is driven to move by the inner end rotary post III 3-8, the clutch lever II 3-11 is driven to move by the clutch lever I3-11, and the clutch lever I3-12 is driven to move by the clutch lever II 3-11, the bevel gear V3-14 is driven to move by the clutch sliding rod I3-12, and the bevel gear V3-14 is driven to move by the bevel gear V3-15, so that power output is facilitated; meanwhile, the driving straight teeth 3-19 are rotated manually, the driving rack rods 3-18 are driven to move by the driving straight teeth 3-19, the driving support frames 3-9 are driven to slide along the support frame sliding grooves 3-17 by the driving rack rods 3-18, the inner end rotary columns 3-5 are driven to move along the outer surfaces of the driving rollers 3-3 by the driving support frames 3-9, and the output speed of the conical teeth six 3-15 is changed; the bevel gear six 3-15 rotates to drive the bevel gear shaft two 2-11 to rotate, further the bevel gear three 2-9 and the bevel gear four 2-10 are driven to rotate simultaneously by the bevel gear shaft two 2-11, further the bevel gear two 2-8 and the bevel gear one 2-7 are driven to rotate by the bevel gear three 2-9 and the bevel gear four 2-10 respectively, the bevel gear two 2-8 rotates to drive the rotating sleeve four 2-18 to rotate, further the rotating sleeve two 2-15 is driven to move by the rotating sleeve four 2-18, further the inner end fixing rod one 2-16 is driven to rotate by the rotating sleeve two 2-15, further the inner end driving rod one 1-3 is driven to rotate by the inner end fixing rod one 2-16, further the inner end clamping rod one 1-4 is driven by the inner end driving rod one 1-3, then the crushing roller outer frame 1-1 is driven to move by the inner end clamping rod 1-4, then the crushing roller outer frame 1-1 drives the crushing rod 1-2 to move, further the crushing rod 1-2 is in contact with the earphone charging box, further the crushing of the earphone charging box is realized, meanwhile, the rotating sleeve three 2-17 is driven to rotate by the taper teeth I2-7, further the rotating sleeve one 2-13 is driven to move by the rotating sleeve three 2-17, further the inner end driving rod one 1-3 is driven to rotate by the rotating sleeve one 2-13, further the inner end clamping rod one 1-4 is driven to move by the inner end driving rod one 1-3, further the crushing roller outer frame 1-1 is driven to move by the inner end clamping rod one 1-4, further the crushing roller outer frame 1-1 is driven to move by the crushing roller outer frame 1-2, the crushing rod 1-2 is in contact with the earphone charging box, so that the earphone charging box is crushed; meanwhile, the inner end driving rod I1-3 and the crushing roller outer frame 1-1 are relatively rotated, the inner end boss 1-7 is driven to move through the inner end driving rod I1-3, the inner end driving rod II 1-9 is driven to move through the inner end boss 1-7, the crushing rod 1-2 is driven to move through the inner end driving rod II 1-9, the length of the crushing rod 1-2 extending out of the crushing roller outer frame 1-1 is changed, and the crushing of the earphone charging box through the crushing rod 1-2 is changed; meanwhile, when the bevel gear II 2-8 rotates to drive the bevel gear shaft I2-12 to move, the belt I2-6 is driven by the bevel gear shaft I2-12 to move, the rotating shaft 2-5 of the side wall roller is driven to rotate by the belt I2-6, and the rotating shaft 2-5 of the side wall roller drives the side wall roller 2-3 to move, further drives the annular groove 2-4 through the side wall roller 2-3, drives the inner end driving rod three 2-14 to reciprocate along the inner end of the side wall chute 2-2 through the annular groove 2-4, further drives the outer frame 1-1 of the crushing roller to reciprocate transversely through the transmission relationship disclosed above, the crushing rod 1-2 is driven to move along with the outer frame 1-1 of the crushing roller, so that the crushing effect on the earphone charging box is conveniently increased; the rotation of the second bevel gear shaft 2-11 drives the transmission belt A4-3 to move, the transmission belt A4-3 drives the rotating column A4-2 to move, the rotating column A4-2 drives the transmission belt B4-4 to move, the transmission belt B4-4 drives the belt wheel I4-6 to move, the belt wheel I4-6 drives the crankshaft I4-5 to move, the crankshaft I4-5 drives the driving slide bar 4-16 to move, the driving slide bar 4-16 drives the rectangular slide frame 4-19 to move, the rectangular slide frame 4-19 drives the rectangular connecting rod 4-18 to move, the rectangular connecting rod 4-18 drives the first screening plate 4-7 and the second screening plate 4-13 to move, and the first screening hole 4-10 and the second screening hole 4-14 to move, screening the crushed earphone charging boxes; meanwhile, the slide rods 4-16 and the crankshaft sleeves 4-15 are driven to slide relatively, so that the movement radiuses of the slide rods 4-16 are changed, the movement amplitudes of the rectangular connecting rods 4-18 are changed through the rectangular slide frames 4-19, the screening amplitudes of the first screening plates 4-7 and the second screening plates 4-13 are changed, and the screening speed of the broken earphone charging box is adjusted by the device.

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 (2)

1. The utility model provides an earphone box recovery plant that charges, includes broken subassembly (1), frame subassembly (2), power component (3), screening subassembly (4), its characterized in that: the crushing assembly (1) is connected with the outer frame assembly (2), the outer frame assembly (2) is connected with the power assembly (3), and the screening assembly (4) is connected with the outer frame assembly (2);

the crushing assembly (1) comprises a crushing roller outer frame (1-1), a crushing rod (1-2), an inner end driving rod I (1-3), an inner end clamping rod I (1-4), an inner end clamping rod pushing spring I (1-5), a rectangular sliding chute I (1-6), an inner end boss (1-7), an inner end pushing spring I (1-8) and an inner end driving rod II (1-9), the crushing rod (1-2) is connected with the crushing roller outer frame (1-1) in a sliding mode, the inner end driving rod II (1-9) is connected with the crushing rod (1-2) in a sliding mode, the inner end pushing spring I (1-8) is connected with the crushing rod (1-2) in a sleeved mode, the inner end pushing spring I (1-8) is arranged between the inner end driving rod II (1-9) and the crushing rod (1-2), an inner end driving rod I (1-3) is arranged at the inner end of the crushing roller outer frame (1-1), an inner end clamping rod I (1-4) is clamped with the inner end driving rod I (1-3), the inner end clamping rod I (1-4) is connected with the crushing roller outer frame (1-1) in a sliding mode, a rectangular sliding chute I (1-6) is arranged on the crushing roller outer frame (1-1), an inner end clamping rod push spring I (1-5) is connected with the inner end clamping rod I (1-4) in a sleeved mode, the inner end clamping rod push spring I (1-5) is arranged on the rectangular sliding chute I (1-6), an inner end boss (1-7) is fixedly connected with the inner end driving rod I (1-3), and the inner end boss (1-7) is connected with the inner end driving rod II (1-9) in a matched mode;

the outer frame component (2) comprises an outer frame I (2-1), a side wall sliding groove (2-2), a side wall roller (2-3), an annular groove (2-4), a side wall roller rotating shaft (2-5), a belt I (2-6), a bevel gear I (2-7), a bevel gear II (2-8), a bevel gear III (2-9), a bevel gear IV (2-10), a bevel gear shaft II (2-11), a bevel gear shaft I (2-12), a rotating sleeve I (2-13), an inner end driving rod III (2-14), a rotating sleeve II (2-15), an inner end fixing rod I (2-16), a rotating sleeve III (2-17) and a rotating sleeve IV (2-18), wherein the side wall sliding groove (2-2) is arranged on the outer frame I (2-1), and the side wall roller (2-3) is fixedly connected with the side wall roller rotating shaft (2-5), the side wall roller rotating shaft (2-5) is rotationally connected with the outer frame I (2-1), the annular groove (2-4) is arranged on the side wall roller (2-3), the inner end driving rod III (2-14) is slidably connected with the side wall sliding groove (2-2), the inner end driving rod III (2-14) is slidably connected with the annular groove (2-4), the belt I (2-6) is connected between the side wall roller rotating shaft (2-5) and the bevel gear shaft I (2-12), the bevel gear shaft I (2-12) is fixedly connected with the bevel gear II (2-8), the bevel gear I (2-7) is fixedly connected with the rotating sleeve III (2-17), the rotating sleeve III (2-17) is rotationally connected with the outer frame I (2-1), the rotating sleeve IV (2-18) is rotationally connected with the outer frame I (2-1), a rotating sleeve IV (2-18) is fixedly connected with a bevel gear I (2-7), a bevel gear III (2-9) and a bevel gear IV (2-10) are fixedly connected with a bevel gear shaft II (2-11), the bevel gear shaft II (2-11) is rotatably connected with an outer frame I (2-1), the bevel gear III (2-9) is in meshing transmission with a bevel gear II (2-8), the bevel gear IV (2-10) is in meshing transmission with a bevel gear I (2-7), a rotating sleeve I (2-13) is rotatably connected with an inner end driving rod III (2-14), an inner end fixing rod I (2-16) is rotatably connected with an inner end driving rod III (2-14), a rotating sleeve II (2-15) is fixedly connected with an inner end fixing rod I (2-16), a rotating sleeve II (2-15) is in sliding fit connection with the rotating sleeve IV (2-18), the four (2-18) rotating sleeves are rotatably connected with the three (2-17) rotating sleeves, the three (2-17) rotating sleeves are connected with the first (2-13) rotating sleeves in a sliding fit mode, two crushing assemblies (1) are arranged, one (1-3) at the inner end of one crushing assembly (1) is fixedly connected with one (2-16) fixed rod at the inner end, and one (1-3) at the inner end of the other crushing assembly (1) is fixedly connected with the third (2-17) rotating sleeve;

the power assembly (3) comprises a power bottom plate (3-1), an input motor (3-2), a first transmission roller (3-3), a second transmission roller (3-4), a first inner rotary column (3-5), a first transmission belt (3-6), a second inner rotary column (3-7), a third inner rotary column (3-8), a second driving support (3-9), a first clutch rod (3-10), a second clutch rod (3-11), a first clutch rod (3-12), a first clutch rod push spring (3-13), a fifth conical tooth (3-14), a sixth conical tooth (3-15), a first support (3-16), a first support sliding groove (3-17), a first driving rack rod (3-18) and a first driving tooth (3-19), wherein the input motor (3-2) is fixedly connected with the power bottom plate (3-1), a first transmission roller (3-3) is rotationally connected with the power bottom plate (3-1), the first transmission roller (3-3) is fixedly connected with an output shaft of the input motor (3-2), a second transmission roller (3-4) is matched and connected with the first transmission roller (3-3), a second transmission roller (3-4) is fixedly connected with a first inner rotary column (3-5), a first inner rotary column (3-5) is rotationally connected with a second driving support (3-9), a first transmission belt (3-6) is connected between the first inner rotary column (3-5) and the second inner rotary column (3-7), the second inner rotary column (3-7) is rotationally connected with a second driving support (3-9), a third inner rotary column (3-8) is rotationally connected with the power bottom plate (3-1), and a third inner rotary column (3-8) is slidably matched and connected with the second inner rotary column (3-7), the inner end rotary column III (3-8) is fixedly connected with the clutch rod I (3-10), the clutch rod I (3-10) is connected with the clutch rod II (3-11) in a matching way, the clutch slide rod I (3-12) is connected with the clutch rod II (3-11) in a sliding way, the clutch slide rod push spring I (3-13) is connected with the clutch slide rod I (3-12) in a sleeved way, the slide rod push spring I (3-13) is arranged between the clutch rod II (3-11) and the power bottom plate (3-1), the bevel gear V (3-14) is fixedly connected with the clutch slide rod I (3-12), the bevel gear V (3-14) is in meshing transmission with the bevel gear VI (3-15), the bracket I (3-16) is fixedly connected with the power bottom plate (3-1), the bracket sliding chute (3-17) is arranged on the bracket I (3-16), a second driving support (3-9) is in sliding connection with a second support sliding groove (3-17), the second driving support (3-9) is in sliding connection with a second driving rack rod (3-18), the second driving rack rod (3-18) is in meshing transmission with a first driving straight tooth (3-19), the first driving straight tooth (3-19) is in rotating connection with a power bottom plate (3-1), and a second conical tooth shaft (2-11) is fixedly connected with a sixth conical tooth (3-15);

the screening component (4) comprises a screening outer frame (4-1), a rotary column A (4-2), a transmission belt A (4-3), a transmission belt B (4-4), a crankshaft I (4-5), a belt wheel I (4-6), a screening plate I (4-7), an inner end sliding column I (4-8), an inner end sliding column push spring I (4-9), a sieve mesh I (4-10), an inner end sliding column II (4-11), an inner end sliding column push spring II (4-12), a screening plate II (4-13), a sieve mesh II (4-14), a crankshaft sleeve (4-15), a driving sliding rod (4-16), a crankshaft II (4-17), a rectangular connecting rod (4-18), a rectangular sliding frame (4-19), an inner end clamping groove (4-20), an inner end clamping rod (4-21), An inner end clamping rod push spring (4-22), a rotary column A (4-2) is rotatably connected with a screening outer frame (4-1), a transmission belt A (4-3) is connected with the rotary column A (4-2), a transmission belt B (4-4) is connected between the rotary column A (4-2) and a belt wheel I (4-6), the belt wheel I (4-6) is fixedly connected with a crankshaft I (4-5), the crankshaft I (4-5) is rotatably connected with the screening outer frame (4-1), an inner end sliding column I (4-8) is fixedly connected with the screening outer frame (4-1), an inner end sliding column push spring I (4-9) is connected with an inner end sliding column I (4-8) in a sleeved mode, a screening plate I (4-7) is slidably connected with the inner end sliding column I (4-8), a screen hole I (4-10) is arranged on the screening plate I (4-7), an inner end sliding column II (4-11) is fixedly connected with a screening outer frame (4-1), an inner end sliding column push spring II (4-12) is connected with the inner end sliding column II (4-11) in a sleeved mode, a screening plate II (4-13) is connected with the inner end sliding column II (4-11) in a sliding mode, a screening hole II (4-14) is arranged on the screening plate II (4-13), a crankshaft sleeve (4-15) is fixedly connected with a crankshaft I (4-5), another crankshaft I (4-5) is fixedly connected with a crankshaft II (4-17), a driving sliding rod (4-16) is connected with the crankshaft sleeve (4-15) in a sliding mode, the driving sliding rod (4-16) is connected with a rectangular sliding frame (4-19) in a rotating mode, the rectangular sliding frame (4-19) is connected with a rectangular connecting rod (4-18) in a sliding mode, and the rectangular connecting rod (4-18) is fixedly connected with the screening plate I (4-7), The screening plate II (4-13) is arranged between the screening plates II, the inner end clamping grooves (4-20) are formed in the crankshaft sleeve (4-15), the inner end clamping rods (4-21) are connected with the inner end clamping grooves (4-20) in a matched mode, the inner end clamping rods (4-21) are connected with the driving sliding rods (4-16) in a sliding mode, the inner end clamping rod push springs (4-22) are arranged between the two inner end clamping rods (4-21), the outer frame I (2-1) is fixedly connected and communicated with the screening outer frame (4-1), and the bevel gear shafts II (2-11) are connected with the transmission belt A (4-3).

2. The earphone charging box recycling device according to claim 1, wherein: and a discharge hole is formed in the lower end of the outer frame I (2-1).

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