CN112691779A - Be used for old and useless gypsum treatment facility of bone surgery - Google Patents

Abstract

For solving above-mentioned technical problem, a be used for old and useless gypsum treatment facility of bone surgery, including installation discharging equipment, control extrusion device, grinding eduction gear, through the getting into of installation discharging equipment installation other device and control waste material and getting rid of broken back crushed aggregates, control extrusion device extrudees the waste material and control installation discharging equipment's reinforced and the ejection of compact, and grinding eduction gear grinds the crushed aggregates and discharges and provide functions such as the power of equipment work, its characterized in that: the mounting and discharging device is mounted and fixed on the grinding and discharging device.

Description

Be used for old and useless gypsum treatment facility of bone surgery

Technical Field

The invention relates to waste gypsum treatment equipment for orthopedic surgery, in particular to waste gypsum treatment equipment for orthopedic surgery.

Background

The most traditional bone-knitting method is that the bone is fixed by the set plaster and then is repaired by the bone-knitting plaster, the plaster is not used after healing, and in order to make the plaster reusable, the waste plaster treatment equipment for the bone surgery is invented.

Disclosure of Invention

The invention relates to waste gypsum treatment equipment for orthopedic surgery, in particular to waste gypsum treatment equipment for orthopedic surgery, which has the functions of installing other devices through an installation and discharge device, controlling the entering of waste materials and the discharge of crushed materials after crushing, controlling the extrusion device to extrude the waste materials, controlling the charging and discharging of the installation and discharge device, grinding and discharging the crushed materials through a grinding and discharge device, providing power for the operation of the equipment and the like.

For solving above-mentioned technical problem, a be used for old and useless gypsum treatment facility of bone surgery, including installation discharging equipment, control extrusion device, grinding eduction gear, through the getting into of installation discharging equipment installation other device and control waste material and getting rid of broken back crushed aggregates, control extrusion device extrudees the waste material and control installation discharging equipment's reinforced and the ejection of compact, and grinding eduction gear grinds the crushed aggregates and discharges and provide functions such as the power of equipment work, its characterized in that: the mounting and discharging device is mounted and fixed on the grinding and discharging device.

As a further optimization of the technical scheme, the invention relates to waste gypsum treatment equipment for orthopedic surgery, which comprises an installation box, a feeding pipe, a fixed bolt, a control stop door, a first spring, a feeding hole, a connecting bolt, a second spring, a control pushing plate, a first fixed sliding column, a third spring, a discharge control plate, a fourth spring, a limiting pull-up column and a discharge pipe, wherein the feeding pipe is installed and fixed on the installation box, the fixed bolt is installed and fixed on the installation box, the control stop door is installed on the fixed bolt and inside the installation box in a sliding manner, the spring is sleeved on the fixed bolt, the feeding hole is arranged on the control stop door, the connecting bolt is installed and fixed on the control stop door, the spring is sleeved on the connecting bolt, the control pushing plate is installed on the connecting bolt and inside the installation box in a sliding manner, the fixed sliding column is installed and fixed inside the installation box, the third spring is sleeved on the fixed sliding column, the discharging control plate is slidably mounted on the fixed sliding column, the spring four is mounted inside the discharging control plate, the limiting pull-up column is slidably mounted inside the discharging control plate, and the discharging pipe is fixedly mounted on the mounting box.

As a further optimization of the technical scheme, the invention relates to waste gypsum treatment equipment for orthopedic surgery, which comprises a detection frame block, a rotating shaft, a connecting block, a connecting spline, a cross hole transmission gear, a first gear, a second gear, a mounting seat, a first transmission shaft, a receiving gear, an output bevel gear, a receiving shaft with a bevel gear, an output belt wheel, a transmission belt, a mounting support plate, a second transmission shaft, a receiving belt wheel, an output semi-bevel gear, a rotating threaded cylinder, a receiving bevel gear, a movable threaded column, an extrusion block, a connecting frame, a matching limit pull-up ball, a control push bolt and a spring five, wherein the detection frame block is fixedly arranged on the control push bolt, the rotating shaft is rotatably arranged on the detection frame block, the connecting block is fixedly arranged on the rotating shaft, the connecting spline is fixedly arranged on the rotating shaft, the cross hole transmission gear is rotatably arranged, one gear is rotatably installed inside the installation box, the first gear is respectively meshed with the cross-hole transmission gear and the second gear, the second gear is rotatably installed inside the installation box, the installation seat is installed and fixed on the installation box, the first transmission shaft is rotatably installed on the installation seat, the receiving gear is installed and fixed on the first transmission shaft, the receiving gear is meshed with the second gear, the output bevel gear is installed and fixed on the first transmission shaft, the receiving shaft with the bevel gear is rotatably installed on the installation seat, the output belt wheel is installed and fixed on the receiving shaft with the bevel gear, the transmission belt is installed on the output belt wheel and the receiving belt wheel, the installation support plate is installed and fixed on the installation box, the second transmission shaft is rotatably installed on the installation support plate, the receiving belt wheel is installed and fixed on the second transmission shaft, the output semi-bevel gear is installed and fixed on the second, remove the screw thread post and install on rotating the screw thread section of thick bamboo, remove screw thread post and rotate screw thread section of thick bamboo screw-thread fit, the extrusion piece erection fixation is on removing the screw thread post, and the extrusion piece slidable mounting is inside the install bin, and the link erection is fixed on the extrusion piece, and the spacing pull-up ball erection of cooperation is fixed on the link, and the slip mounting is tied inside the install bin in the control promotion, and five controls of spring promote to tie and install the incasement portion.

As a further optimization of the technical scheme, the invention relates to waste gypsum treatment equipment for bone surgery, wherein the grinding and discharging device comprises a grinding cylinder, a feed inlet II, a sliding material cavity, a mounting frame, a transmission connecting square hole cylinder, a grinding and discharging hole plate, a transmission square column, a transmission connecting square hole cylinder II, a transmission square column II, a rotating shaft, a mounting and fixing seat, a pushing and stirring shaft, a matching wheel, a pushing spiral plate, a fixed connecting bolt, a spring VI, a movable connecting sleeve, a matching ball, a packing vibrating ring, a vibrating groove and a material discharging port, wherein a mounting box is fixedly arranged on the grinding cylinder, the feed inlet II is arranged on the grinding cylinder, a discharging pipe is fixedly arranged on the feed inlet II, the sliding material cavity is arranged inside the grinding cylinder, the transmission connecting square hole cylinder is rotatably arranged on the mounting frame, and the grinding and discharging hole plate is fixedly arranged on the fixed connecting bolt, the grinding device comprises a grinding cylinder, a transmission square column, a transmission connection square hole cylinder, a transmission square column, a transmission square hole cylinder, a transmission square column cylinder, a transmission connection square hole cylinder, a transmission square column.

As a further optimization of the technical scheme, the waste gypsum treatment equipment for the bone surgery comprises two connecting bolts, two springs, two control pushing plates, two fixed sliding columns, two springs, two material discharging control plates and two material discharging pipes, and four springs and four limiting pull-up columns.

As a further optimization of the technical scheme, the waste gypsum treatment equipment for the bone surgery is provided with two feeding holes of the grinding and discharging device, three mounting fixing seats, three pushing and stirring shafts and three matching wheels, and a matched motor is arranged on a rotating shaft.

The waste gypsum treatment equipment for the orthopedic surgery has the beneficial effects that:

the invention relates to waste gypsum treatment equipment for orthopedic surgery, which has the functions of installing other devices through an installation and discharge device, controlling the entering of waste materials and the discharge of crushed materials after crushing, controlling the extrusion device to extrude the waste materials, controlling the charging and discharging of the installation and discharge device, grinding and discharging the crushed materials through a grinding and discharge device, providing power for the operation of the equipment and the like.

Drawings

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

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

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

Fig. 3 is a third schematic view of the overall structure of the present invention.

FIG. 4 is a first schematic view of the installation and drainage device of the present invention.

FIG. 5 is a second schematic view of the installation and drainage device of the present invention.

Fig. 6 is a third schematic structural diagram of the installation and discharge device of the present invention.

Fig. 7 is a fourth schematic view of the installation drain device of the present invention.

Fig. 8 is a fifth structural schematic diagram of the installation and discharge device of the present invention.

FIG. 9 is a first structural diagram of a controlled extrusion device according to the present invention.

FIG. 10 is a second schematic structural diagram of the extrusion control device of the present invention.

FIG. 11 is a first schematic structural diagram of a polishing discharge apparatus according to the present invention.

FIG. 12 is a schematic view of a polishing discharge apparatus according to the present invention

Fig. 13 is a third schematic structural view of the polishing discharge device of the present invention.

In the figure: installing the discharge device 1; an installation box 1-1; a feed pipe 1-2; 1-3 of a fixing bolt; controlling a stop door 1-4; 1-5 parts of a first spring; 1-6 parts of a feed hole; 1-7 of a connecting bolt; 1-8 parts of a second spring; controlling the push plate 1-9; 1-10 of a fixed sliding column; 1-11 parts of a spring; 1-12 of a discharge control plate; 1-13 parts of spring; limiting and pulling up the columns 1-14; 1-15 parts of a discharge pipe; controlling the extrusion device 2; a detection frame block 2-1; 2-2 of a rotating shaft; 2-3 of a connecting block; connecting splines 2-4; a cross hole transmission gear 2-5; 2-6 parts of a first gear; 2-7 parts of a second gear; 2-8 of a mounting seat; a first transmission shaft 2-9; receiving gears 2-10; output bevel gears 2-11; a bevel gear receiving shaft 2-12; an output pulley 2-13; 2-14 parts of a transmission belt; mounting support plates 2-15; a second transmission shaft 2-16; receiving pulleys 2-17; output half bevel gears 2-18; rotating the thread cylinder 2-19; receiving bevel gears 2-20; moving the threaded columns 2-21; 2-22 parts of an extrusion block; 2-23 of a connecting frame; matching with a limit pull-up ball 2-24; controlling the pushing bolt 2-25; five springs 2-26; a grinding discharge device 3; 3-1 of a grinding cylinder; a second feeding hole 3-2; 3-3 of a material sliding cavity; mounting frames 3-4; the square hole barrel is in transmission connection with 3-5; grinding the discharge orifice plate 3-6; 3-7 parts of a transmission square column; 3-8 parts of a square hole cylinder II is in transmission connection; 3-9 parts of a second transmission square column; 3-10 parts of a rotating shaft; installing a fixed seat 3-11; 3-12 parts of a material pushing stirring shaft; 3-13 of a matching wheel; 3-14 parts of pushing spiral plate; 3-15 parts of fixed connecting bolts; six springs 3-16; moving the connecting sleeve 3-17; 3-18 of a matching ball; 3-19 parts of a packing vibrating ring; 3-20 parts of a vibration groove; and material discharge ports 3-21.

Detailed Description

The first embodiment is as follows:

for solving above-mentioned technical problem, a be used for old and useless gypsum treatment facility of bone surgery, including installation discharging equipment 1, control extrusion device 2, grind eduction gear 3, through the getting into of installation discharging equipment installation other device and control waste material and getting rid of broken back crushed aggregates, control extrusion device extrudees the waste material and control installation discharging equipment's reinforced and the ejection of compact, grind eduction gear to the crushed aggregates and grind functions such as emission and the power that provides equipment work, its characterized in that: the mounting and discharging device 1 is mounted and fixed on the grinding and discharging device 3.

The second embodiment is as follows:

the embodiment is described below by combining with figures 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 and 13, and the embodiment is further described, wherein the installation and discharge device 1 comprises an installation box 1-1, a feeding pipe 1-2, a fixed bolt 1-3, a control stop door 1-4, a spring I1-5, a feeding hole 1-6, a connecting bolt 1-7, a spring II 1-8, a control push plate 1-9, a fixed sliding column 1-10, a spring III 1-11, a discharge control plate 1-12, a spring IV 1-13, a limit pull-up column 1-14 and a discharge pipe 1-15, gypsum is added into the installation box 1-1 from the feeding pipe 1-2 of the installation and discharge device 1, a squeezing block 2-22 is contacted with the control push plate 1-9, and then the connecting bolt 1-8 is pulled through the spring II 1-8 7, the connecting bolt 1-7 drives the control stop door 1-4 to move to block the feeding pipe 1-2, then the spring II 1-8 can enable the control stop door 1-4 to continuously move when not moving or enable the extrusion block 2-22 to continuously move, the extrusion block 2-22 and the detection frame block 2-1 which continuously move crush and extrude the gypsum, then the extrusion block 2-24 is matched with the limit pull-up ball 2-24 to move to the lower end of the limit pull-up column 1-14, then when the extrusion block 2-22 moves upwards, the extrusion block 2-22 is matched with the limit pull-up ball 2-24 to drive the discharge control plate 1-12 to move upwards on the fixed sliding column 1-10 and then compress the spring III 1-11, then the crushed gypsum on the detection frame block 2-1 rolls down to the discharge pipe 1-15 along the inclined plane of the detection frame block 2-1 and then falls into the grinding and discharging device 3 for grinding, the detection frame block 2-1 is reset by a spring five 2-26 for removing the crushed aggregates on the detection frame block 2-1 through controlling a pushing bolt 2-25, then the detection frame block 2-1 pulls a rotating shaft 2-2 to separate a connecting spline 2-4 from a cross hole transmission gear 2-5, a connecting block 2-3 is separated from a transmission connecting square hole cylinder 3-5, meanwhile, an extrusion block 2-22 moves back to the uppermost end, a limiting pull-up ball 2-24 is matched to be separated from a material discharge control plate 1-12 from the lower end of a limiting pull-up column 1-14, the position of a discharge port is reset at a spring three 1-11 to be blocked, a control baffle door 1-4 is also reset to the original position at the spring one 1-5 to enable a feed hole 1-6 and a feed pipe 1-2 to coincide and continue to add the waste materials, the feed pipe 1-2 is installed and fixed on the installation box 1-, a fixed bolt 1-3 is fixedly arranged on an installation box 1-1, a control baffle door 1-4 is slidably arranged on the fixed bolt 1-3 and inside the installation box 1-1, a spring I1-5 is sleeved on the fixed bolt 1-3, a feeding hole 1-6 is arranged on the control baffle door 1-4, a connecting bolt 1-7 is fixedly arranged on the control baffle door 1-4, a spring II 1-8 is sleeved on the connecting bolt 1-7, a control push plate 1-9 is slidably arranged on the connecting bolt 1-7 and inside the installation box 1-1, a fixed sliding column 1-10 is fixedly arranged inside the installation box 1-1, a spring III 1-11 is sleeved on the fixed sliding column 1-10, a discharge control plate 1-12 is slidably arranged on the fixed sliding column 1-10, the four springs 1-13 are arranged inside the discharging control plate 1-12, the limiting pull-up columns 1-14 are slidably arranged inside the discharging control plate 1-12, and the discharging pipes 1-15 are fixedly arranged on the installation box 1-1.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 and 13, and the embodiment is further described, wherein the extrusion control device 2 comprises a detection frame block 2-1, a rotating shaft 2-2, a connecting block 2-3, a connecting spline 2-4, a cross hole transmission gear 2-5, a gear I2-6, a gear II 2-7, a mounting seat 2-8, a transmission shaft I2-9, a receiving gear 2-10, an output bevel gear 2-11, a bevel gear receiving shaft 2-12, an output belt wheel 2-13, a transmission belt 2-14, a mounting support plate 2-15, a transmission shaft II 2-16, a receiving belt wheel 2-17, an output semi-bevel gear 2-18, a rotating threaded cylinder 2-19, a connecting rod 2-2, 3, 2-, Receiving bevel gears 2-20, moving threaded columns 2-21, extrusion blocks 2-22, connecting frames 2-23, matched limiting pull-up balls 2-24, control push bolts 2-25 and springs five 2-26, then gypsum is stacked on detection frame blocks 2-1 of a control extrusion device 2, the detection frame blocks 2-1 drive the control push bolts 2-25 and a rotating shaft 2-2 to move downwards along with the increase of the amount of the gypsum, then the control push bolts 2-25 compress the springs five 2-26, when the amount of the gypsum is stacked to a certain amount, the detection frame blocks 2-1 drive the rotating shaft 2-2 to move a certain position, then the rotating shaft 2-2 drives a connecting spline 2-4 and a cross hole transmission gear 2-5 to adapt, the rotating shaft 2-2 drives a connecting block 2-3 to slide into a grinding discharge orifice plate 3-6, then the rotating shaft 3-10 rotates under the action of a matched motor, the transmission connecting square hole cylinder 3-5 drives the connecting block 2-3 to rotate, the connecting block 2-3 drives the rotating shaft 2-2 to rotate, the rotating shaft 2-2 drives the cross hole transmission gear 2-5 to rotate through the connecting spline 2-4, the cross hole transmission gear 2-5 drives the gear II 2-7 to rotate through the gear I2-6, the gear II 2-7 drives the transmission shaft I2-9 to rotate through the receiving gear 2-10, the transmission shaft I2-9 drives the output bevel gear 2-11 to rotate, the output bevel gear 2-11 drives the output belt wheel 2-13 to rotate through the bevel gear receiving shaft 2-12, and the output belt wheel 2-13 drives the receiving belt wheel 2-17 to rotate through the transmission belt 2-14, the receiving belt wheels 2-17 drive the output half bevel gears 2-18 to rotate through the transmission shafts 2-16, the two output half bevel gears 2-18 are meshed with the receiving bevel gears 2-20 in a reciprocating manner, the rotating threaded cylinders 2-19 which rotate in a reciprocating manner drive the extrusion blocks 2-22 to move in a reciprocating manner through the moving threaded columns 2-21, when the extrusion blocks 2-22 move downwards, the connecting frames 2-23 and the matched limiting pull-up balls 2-24 are driven to move, the detection frame block 2-1 is fixedly arranged on the control push bolt 2-25, the rotating shaft 2-2 is rotatably arranged on the detection frame block 2-1, the connecting block 2-3 is fixedly arranged on the rotating shaft 2-2, and the connecting spline 2-4 is fixedly arranged on the rotating shaft 2-2, a cross hole transmission gear 2-5 is rotatably arranged inside an installation box 1-1, a gear I2-6 is rotatably arranged inside the installation box 1-1, a gear I2-6 is respectively meshed with the cross hole transmission gear 2-5 and a gear II 2-7, the gear II 2-7 is rotatably arranged inside the installation box 1-1, an installation seat 2-8 is fixedly arranged on the installation box 1-1, a transmission shaft I2-9 is rotatably arranged on the installation seat 2-8, a receiving gear 2-10 is fixedly arranged on the transmission shaft I2-9, the receiving gear 2-10 is meshed with the gear II 2-7, an output bevel gear 2-11 is fixedly arranged on the transmission shaft I2-9, a receiving shaft with a bevel gear 2-12 is rotatably arranged on the installation seat 2-8, an output belt wheel 2-13 is fixedly arranged on a receiving shaft 2-12 with a bevel gear, a transmission belt 2-14 is arranged on the output belt wheel 2-13 and a receiving belt wheel 2-17, an installation support plate 2-15 is fixedly arranged on an installation box 1-1, a transmission shaft II 2-16 is rotatably arranged on the installation support plate 2-15, the receiving belt wheel 2-17 is fixedly arranged on the transmission shaft II 2-16, an output semi-bevel gear 2-18 is fixedly arranged on the transmission shaft II 2-16, a rotating threaded cylinder 2-19 is rotatably arranged on the installation box 1-1, a receiving bevel gear 2-20 is fixedly arranged on a rotating threaded cylinder 2-19, a moving threaded column 2-21 is arranged on the rotating threaded cylinder 2-19, the moving threaded column 2-21 is in threaded fit with the rotating threaded cylinder 2-19, the extrusion blocks 2-22 are fixedly installed on the movable threaded columns 2-21, the extrusion blocks 2-22 are installed inside the installation box 1-1 in a sliding mode, the connecting frames 2-23 are fixedly installed on the extrusion blocks 2-22, the pull-up balls 2-24 are fixedly installed on the connecting frames 2-23 in a matched limiting mode, the control push bolts 2-25 are installed inside the installation box 1-1 in a sliding mode, and the springs five 2-26 control the push bolts 2-25 and the installation box 1-1 in a pushing mode.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 and 13, and the embodiment further describes the embodiment, where the grinding and discharging device 3 includes a grinding cylinder 3-1, a feed inlet two 3-2, a material sliding cavity 3-3, a mounting rack 3-4, a transmission connection square hole cylinder 3-5, a grinding and discharging hole plate 3-6, a transmission square column 3-7, a transmission connection square hole cylinder two 3-8, a transmission square column two 3-9, a rotation shaft 3-10, a mounting and fixing seat 3-11, a material pushing and stirring shaft 3-12, a matching wheel 3-13, a material pushing spiral plate 3-14, a fixed connection bolt 3-15, a spring six 3-16, a movable connection sleeve 3-17, a matching ball 3-18, 3-19 parts of packing vibrating ring, 3-20 parts of vibrating groove and 3-21 parts of material outlet, wherein 3-10 parts of rotating shaft drive two transmission square columns 3-9 to rotate, 3-9 parts of transmission square columns drive two grinding and discharging pore plates 3-6 to rotate through two transmission connection square hole cylinders 3-8, 3-6 parts of grinding and discharging pore plates drive 3-5 parts of transmission connection square hole cylinders through 3-7 parts of transmission square columns, 3-6 parts of rotating grinding and discharging pore plates drive 3-17 parts of movable connection sleeves to rotate on 3-19 parts of packing vibrating ring through 3-15 parts of fixed connection bolts, and then when 3-17 parts of movable connection sleeves move to 3-20 parts of vibrating groove, 3-6 parts of grinding and discharging pore plates move downwards to separate 3-1 parts of grinding cylinder to generate vibration to shake ground materials, and materials in sliding cavity 3-3 parts of grinding cylinder are vibrated The grinding and discharging device slides on a grinding and discharging orifice plate 3-6, then a connecting sleeve 3-17 is moved to rotate through a vibration groove 3-20, then the grinding and discharging orifice plate 3-6 and a grinding cylinder 3-1 are continuously ground, meanwhile, a rotating shaft 3-10 drives a material pushing and stirring shaft 3-12 to rotate around the rotating shaft 3-10, simultaneously, the material pushing and stirring shaft 3-12 drives a material pushing spiral plate 3-14 to push ground leaked materials to a material discharging port 3-21 under the action of the rotating shaft 3-10 and then discharge the materials, an installation box 1-1 is fixedly arranged on the grinding cylinder 3-1, a material feeding port two 3-2 is arranged on the grinding cylinder 3-1, a material discharging pipe 1-15 is fixedly arranged on the material feeding port two 3-2, a material sliding cavity 3-3 is arranged inside the grinding cylinder 3-1, the mounting frame 3-4 is fixedly arranged inside the grinding cylinder 3-1, the transmission connecting square hole cylinder 3-5 is rotatably arranged on the mounting frame 3-4, the grinding discharge pore plate 3-6 is fixedly arranged on the fixed connecting bolt 3-15, the transmission square column 3-7 is fixedly arranged on the grinding discharge pore plate 3-6, the transmission connecting square hole cylinder two 3-8 is fixedly arranged on the grinding discharge pore plate 3-6, the transmission square column two 3-9 is slidably arranged on the transmission connecting square hole cylinder two 3-8, the transmission square column two 3-9 is fixedly arranged on the rotating shaft 3-10, the rotating shaft 3-10 is rotatably arranged on the grinding cylinder 3-1, the mounting fixing seat 3-11 is fixedly arranged on the rotating shaft 3-10, the material pushing stirring shaft 3-12 is rotatably arranged on the mounting fixing seat 3-11, the matching wheels 3-13 are fixedly arranged on the pushing stirring shaft 3-12, the pushing spiral plate 3-14 is fixedly arranged on the pushing stirring shaft 3-12, the fixed connecting bolts 3-15 are slidably arranged on the movable connecting sleeves 3-17, the springs six 3-16 are fixedly arranged on the fixed connecting bolts 3-15, the matching balls 3-18 are rotatably arranged on the movable connecting sleeves 3-17, the packing vibrating rings 3-19 are fixedly arranged in the grinding cylinder 3-1, the vibrating grooves 3-20 are arranged on the packing vibrating rings 3-19, and the material discharge ports 3-21 are arranged on the grinding cylinder 3-1. The fifth concrete implementation mode:

the second embodiment is further described with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 and 13. the second embodiment is further described, the number of the connecting bolts 1-7, the springs two 1-8, the control push plates 1-9, the fixed sliding columns 1-10, the springs three 1-11, the discharging control plates 1-12 and the discharging pipes 1-15 of the installation and discharge device 1 is two, and the number of the springs four 1-13 and the limit pull-up columns 1-14 is four.

The sixth specific implementation mode:

the following describes the present embodiment with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, and 13, and the present embodiment further describes the fourth embodiment, where two feed inlets two 3-2 of the grinding and discharging device 3 are provided, three mounting holders 3-11, three pushing and stirring shafts 3-12, and three matching wheels 3-13 are provided, and the rotating shafts 3-10 are provided with matching motors.

The working principle of the invention is as follows:

a working principle of waste gypsum treatment equipment for bone surgery is that before use, whether the connection condition between the devices meets requirements is checked, waste gypsum is added into an installation box 1-1 from a feeding pipe 1-2 of an installation and discharge device 1, then the gypsum is stacked on a detection frame block 2-1 of a control extrusion device 2, the detection frame block 2-1 drives a control pushing bolt 2-25 and a rotating shaft 2-2 to move downwards along with the increase of the amount of the gypsum, then the control pushing bolt 2-25 compresses a spring five 2-26, when the amount of the gypsum is stacked to a certain amount, the detection frame block 2-1 drives the rotating shaft 2-2 to move to a certain position, then the rotating shaft 2-2 drives a connecting spline 2-4 and a cross hole transmission gear 2-5 to adapt to each other, the rotating shaft 2-2 drives the connecting block 2-3 to slide into the grinding and discharging orifice plate 3-6, then the rotating shaft 3-10 rotates under the action of a matched motor, the rotating shaft 3-10 drives the transmission square column II 3-9 to rotate, the transmission square column II 3-9 drives the grinding and discharging orifice plate 3-6 to rotate through the transmission connection square hole cylinder II 3-8, the grinding and discharging orifice plate 3-6 drives the transmission connection square hole cylinder 3-5 to rotate through the transmission square column 3-7, the rotating grinding and discharging orifice plate 3-6 drives the movable connecting sleeve 3-17 to rotate on the filler vibrating ring 3-19 through the fixed connecting bolt 3-15, and then the grinding and discharging orifice plate 3-6 moves downwards when the movable connecting sleeve 3-17 moves to the position of the vibrating groove 3-20, so that the grinding and discharging orifice plate 3-6 and the grinding cylinder 3-1 are separated to generate vibration The ground material is shaken off, meanwhile, the material in the material sliding cavity 3-3 slides on the grinding discharge orifice plate 3-6, then the connecting sleeve 3-17 is moved to rotate through the vibration groove 3-20, then the grinding discharge orifice plate 3-6 and the grinding cylinder 3-1 are continuously ground, meanwhile, the rotating shaft 3-10 drives the material pushing stirring shaft 3-12 to rotate around the rotating shaft 3-10, simultaneously, the material pushing stirring shaft 3-12 drives the material pushing spiral plate 3-14 to push the ground leaked material to the material discharge port 3-21 under the action of the rotating shaft 3-10, the transmission connecting square orifice cylinder 3-5 drives the connecting block 2-3 to rotate, the connecting block 2-3 drives the rotating shaft 2-2 to rotate, and the rotating shaft 2-2 drives the cross-hole transmission gear 2-5 to rotate through the connecting spline 2-4, the cross-hole transmission gear 2-5 drives a gear II 2-7 to rotate through a gear I2-6, the gear II 2-7 drives a transmission shaft I2-9 to rotate through a receiving gear 2-10, the transmission shaft I2-9 drives an output bevel gear 2-11 to rotate, the output bevel gear 2-11 drives an output belt wheel 2-13 to rotate through a bevel gear receiving shaft 2-12, the output belt wheel 2-13 drives a receiving belt wheel 2-17 to rotate through a transmission belt 2-14, the receiving belt wheel 2-17 drives an output half bevel gear 2-18 to rotate through a transmission shaft II 2-16, the rotating threaded cylinders 2-19 rotate in a reciprocating mode due to the fact that the two output half bevel gears 2-18 reciprocate and the receiving bevel gears 2-20 are meshed, and the rotating threaded cylinders 2-19 rotating in a reciprocating mode drive extrusion blocks 2-22 to move in a reciprocating mode through the moving threaded cylinders 2- When the extrusion block 2-22 moves downwards, the connection frame 2-23 and the matched limit pulling ball 2-24 are driven to move, the extrusion block 2-22 is in contact with the control push plate 1-9 and then the connection bolt 1-7 is driven to move through the spring II 1-8, the connection bolt 1-7 drives the control baffle door 1-4 to move to block the feeding pipe 1-2, then the spring II 1-8 can enable the control baffle door 1-4 to still enable the extrusion block 2-22 to move continuously, the extrusion block 2-22 and the detection frame block 2-1 which move continuously crush and extrude gypsum, then the limit pulling ball 2-24 is matched to move to the lower end of the limit pulling column 1-14, and then when the extrusion block 2-22 moves upwards, the limit pulling ball 2-24 is matched to drive the discharge control plate 1-12 to move upwards on the fixed sliding column 1-10 The springs III 1-11 are compressed after the movement, then the crushed gypsum on the detection frame block 2-1 rolls down to the discharge pipe 1-15 along the inclined surface of the detection frame block 2-1 and then falls into the grinding and discharging device 3 for grinding, the detection frame block 2-1 is reset by controlling the push bolts 2-25 along with the discharge springs V2-26 for discharging the crushed material on the detection frame block 2-1, then the detection frame block 2-1 pulls the rotating shaft 2-2 to separate the connecting spline 2-4 from the cross hole transmission gear 2-5, the connecting block 2-3 is separated from the transmission connecting square hole cylinder 3-5, meanwhile, the extrusion block 2-22 moves back to the uppermost end, the limiting pull balls 2-24 are matched to be separated from the lower ends of the limiting pull columns 1-14 from the discharge control plates 1-12, and the discharge ports are blocked after the springs III 1-11 are reset, the control stop gate 1-4 also returns to the original position by the spring 1-5, so that the feeding hole 1-6 and the feeding pipe 1-2 are coincided to continue feeding the waste material.

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 (6)

1. The utility model provides a be used for old and useless gypsum treatment facility of bone surgery, is including installation discharging equipment (1), control extrusion device (2), grinding eduction gear (3), its characterized in that: the mounting and discharging device (1) is mounted and fixed on the grinding and discharging device (3).

2. The waste gypsum processing apparatus for bone surgery as set forth in claim 1, wherein: the installation and discharge device (1) comprises an installation box (1-1), a feeding pipe (1-2), a fixing bolt (1-3), a control stop door (1-4), a spring I (1-5), a feeding hole (1-6), a connecting bolt (1-7), a spring II (1-8), a control push plate (1-9), a fixed sliding column (1-10), a spring III (1-11), a discharge control plate (1-12), a spring IV (1-13), a limiting pull-up column (1-14) and a discharge pipe (1-15), wherein the feeding pipe (1-2) is fixedly installed on the installation box (1-1), the fixing bolt (1-3) is fixedly installed on the installation box (1-1), the control stop door (1-4) is slidably installed on the fixing bolt (1-3) and inside the installation box (1-1), the first spring (1-5) is sleeved on the fixed bolt (1-3), the feeding hole (1-6) is arranged on the control stop door (1-4), the connecting bolt (1-7) is fixedly installed on the control stop door (1-4), the second spring (1-8) is sleeved on the connecting bolt (1-7), the control push plate (1-9) is slidably installed on the connecting bolt (1-7) and inside the installation box (1-1), the fixed sliding column (1-10) is fixedly installed inside the installation box (1-1), the third spring (1-11) is sleeved on the fixed sliding column (1-10), the material discharge control plate (1-12) is slidably installed on the fixed sliding column (1-10), the fourth spring (1-13) is installed inside the material discharge control plate (1-12), the limiting pull-up columns (1-14) are slidably arranged inside the discharge control panels (1-12), and the discharge pipes (1-15) are fixedly arranged on the installation box (1-1).

3. The waste gypsum processing apparatus for bone surgery as set forth in claim 1, wherein: the extrusion control device (2) comprises a detection frame block (2-1), a rotating shaft (2-2), a connecting block (2-3), a connecting spline (2-4), a cross hole transmission gear (2-5), a gear I (2-6), a gear II (2-7), a mounting seat (2-8), a transmission shaft I (2-9), a receiving gear (2-10), an output bevel gear (2-11), a bevel gear receiving shaft (2-12), an output belt wheel (2-13), a transmission belt (2-14), a mounting support plate (2-15), a transmission shaft II (2-16), a receiving belt wheel (2-17), an output semi-bevel gear (2-18), a rotating threaded cylinder (2-19), a receiving bevel gear (2-20), The device comprises a movable threaded column (2-21), an extrusion block (2-22), a connecting frame (2-23), a matched limit pull-up ball (2-24), a control push bolt (2-25) and a spring five (2-26), wherein a detection frame block (2-1) is fixedly arranged on the control push bolt (2-25), a rotating shaft (2-2) is rotatably arranged on the detection frame block (2-1), a connecting block (2-3) is fixedly arranged on the rotating shaft (2-2), a connecting spline (2-4) is fixedly arranged on the rotating shaft (2-2), a cross hole transmission gear (2-5) is rotatably arranged in an installation box (1-1), a gear I (2-6) is rotatably arranged in the installation box (1-1), and the gear I (2-6) is respectively meshed with a cross hole transmission gear (2-5) and a gear II (2-7), a second gear (2-7) is rotatably arranged in the mounting box (1-1), a mounting seat (2-8) is fixedly arranged on the mounting box (1-1), a first transmission shaft (2-9) is rotatably arranged on the mounting seat (2-8), a receiving gear (2-10) is fixedly arranged on the first transmission shaft (2-9), the receiving gear (2-10) is meshed with the second gear (2-7), an output bevel gear (2-11) is fixedly arranged on the first transmission shaft (2-9), a receiving shaft with bevel gears (2-12) is rotatably arranged on the mounting seat (2-8), an output belt wheel (2-13) is fixedly arranged on a receiving shaft with bevel gears (2-12), a transmission belt (2-14) is arranged on the output belt wheel (2-13) and the receiving belt wheel (2-17), the mounting support plate (2-15) is fixedly arranged on the mounting box (1-1), the transmission shaft II (2-16) is rotatably arranged on the mounting support plate (2-15), the receiving belt wheel (2-17) is fixedly arranged on the transmission shaft II (2-16), the output half bevel gear (2-18) is fixedly arranged on the transmission shaft II (2-16), the rotating threaded cylinder (2-19) is rotatably arranged on the mounting box (1-1), the receiving bevel gear (2-20) is fixedly arranged on the rotating threaded cylinder (2-19), the moving threaded column (2-21) is in threaded fit with the rotating threaded cylinder (2-19), the extrusion block (2-22) is fixedly arranged on the moving threaded column (2-21), the extrusion block (2-22) is slidably mounted inside the mounting box (1-1), the connecting frame (2-23) is fixedly mounted on the extrusion block (2-22), the matched limiting pull-up ball (2-24) is fixedly mounted on the connecting frame (2-23), the control push bolt (2-25) is slidably mounted inside the mounting box (1-1), and the spring five (2-26) controls the push bolt (2-25) and the mounting box (1-1).

4. The waste gypsum processing apparatus for bone surgery as set forth in claim 1, wherein: the grinding and discharging device (3) comprises a grinding cylinder (3-1), a feeding port II (3-2), a sliding material cavity (3-3), a mounting frame (3-4), a transmission connection square hole cylinder (3-5), a grinding and discharging hole plate (3-6), a transmission square column (3-7), a transmission connection square hole cylinder II (3-8), a transmission square column II (3-9), a rotating shaft (3-10), a mounting and fixing seat (3-11), a material pushing and stirring shaft (3-12), a matching wheel (3-13), a material pushing spiral plate (3-14), a fixed connecting bolt (3-15), a spring VI (3-16), a movable connecting sleeve (3-17), a matching ball (3-18), a filler vibrating ring (3-19), a vibrating groove (3-20), A material discharge port (3-21), an installation box (1-1) is fixedly installed on a grinding cylinder (3-1), a feed inlet II (3-2) is arranged on the grinding cylinder (3-1), a discharge pipe (1-15) is fixedly installed on the feed inlet II (3-2), a material sliding cavity (3-3) is arranged inside the grinding cylinder (3-1), an installation frame (3-4) is fixedly installed inside the grinding cylinder (3-1), a transmission connection square hole cylinder (3-5) is rotatably installed on the installation frame (3-4), a grinding discharge orifice plate (3-6) is fixedly installed on a fixed connection bolt (3-15), a transmission square column (3-7) is fixedly installed on the grinding discharge orifice plate (3-6), and a transmission connection square hole cylinder II (3-8) is fixedly installed on the grinding discharge orifice plate (3-6), a second transmission square column (3-9) is slidably arranged on a second transmission connection square hole cylinder (3-8), the second transmission square column (3-9) is fixedly arranged on a rotating shaft (3-10), the rotating shaft (3-10) is rotatably arranged on a grinding cylinder (3-1), a mounting fixing seat (3-11) is fixedly arranged on the rotating shaft (3-10), a pushing stirring shaft (3-12) is rotatably arranged on the mounting fixing seat (3-11), a matching wheel (3-13) is fixedly arranged on the pushing stirring shaft (3-12), a pushing spiral plate (3-14) is fixedly arranged on the pushing stirring shaft (3-12), a fixed connection bolt (3-15) is slidably arranged on a movable connection sleeve (3-17), and a spring six (3-16) is fixedly arranged on the fixed connection bolt (3-15), the matching balls (3-18) are rotatably arranged on the movable connecting sleeves (3-17), the packing vibrating ring (3-19) is fixedly arranged in the grinding cylinder (3-1), the vibrating groove (3-20) is arranged on the packing vibrating ring (3-19), and the material outlet (3-21) is arranged on the grinding cylinder (3-1).

5. The waste gypsum processing apparatus for bone surgery as set forth in claim 2, wherein: the device is characterized in that the number of the connecting bolts (1-7) for installing the discharging device (1), the number of the springs II (1-8), the number of the control pushing plates (1-9), the number of the fixed sliding columns (1-10), the number of the springs III (1-11), the number of the discharging control plates (1-12) and the number of the discharging pipes (1-15) are two, and the number of the springs IV (1-13) and the number of the limiting pull-up columns (1-14) are four.

6. The waste gypsum processing apparatus for bone surgery as set forth in claim 4, wherein: two feed inlets II (3-2) of the grinding and discharging device (3) are provided, three mounting fixing seats (3-11), three pushing and stirring shafts (3-12) and three matching wheels (3-13) are provided, and a matching motor is arranged on the rotating shaft (3-10).

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