CN111545095A

CN111545095A - Putty powder and processing system and processing method thereof

Info

Publication number: CN111545095A
Application number: CN202010467214.5A
Authority: CN
Inventors: 李龙啸
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-05-28
Filing date: 2020-05-28
Publication date: 2020-08-18

Abstract

The invention relates to putty powder processing, in particular to putty powder and a processing system and a processing method thereof, which comprise a device bracket, a stirring mechanism I, a discharging mechanism, a stirring mechanism II, a transmission mechanism, a feeding mechanism, a receiving mechanism and a sensor, wherein the stirring mechanism II drives the transmission mechanism to rotate for a half circle, and different raw materials respectively fall into feeding tanks with different corresponding depths; the discharging mechanism moves downwards to enable putty powder in the stirring support to fall out; the discharging mechanism closes the bottom of the stirring support, the stirring mechanism II pushes the transmission mechanism to rotate for a half circle, and putty powder raw materials of different types and different weights in the feeding tank fall into the stirring support; the stirring mechanism II reciprocates to continuously and efficiently process putty powder; the putty powder consists of quicklime powder 18-20 wt%, formaldehyde absorbent 5 wt%, cotton fiber powder 6-7 wt%, nanometer titania 4-6 wt%, calcite powder 49-51 wt% and other anti-cracking cured rubber powder.

Description

Putty powder and processing system and processing method thereof

Technical Field

The invention relates to putty powder processing, in particular to putty powder and a processing system and a processing method thereof.

Background

For example, a putty powder production and processing device disclosed in publication No. CN110026108A comprises a box body, wherein a stirring cavity which penetrates through the box body from top to bottom is arranged in the box body, a containing cavity is communicated and arranged in the lower end wall of the stirring cavity, a supporting table for placing raw materials is fixedly arranged on the left end face of the box body, a supporting frame which is abutted against the ground is fixedly arranged on the lower end face of the supporting table, a stirring device for stirring putty powder is arranged in the upper end face of the box body, a discharging device for controlling the putty powder to topple over and preventing the putty powder from being blocked is arranged on the lower side of the stirring device, and the equipment adopts a stirring device; the invention has the disadvantage that the putty powder can not be continuously and efficiently processed.

Disclosure of Invention

The invention aims to provide a putty powder processing system which can continuously and efficiently process putty powder.

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

a putty powder processing system comprises a device support, a stirring mechanism I, a discharging mechanism, a stirring mechanism II, a transmission mechanism, a feeding mechanism, a storage mechanism and a sensor, wherein the stirring support is fixedly connected to the device support, the stirring mechanism I is fixedly connected to the stirring support, the discharging mechanism is slidably connected to the lower end of the stirring support, the discharging mechanism is fixedly connected to the device support, the stirring mechanism II is connected to the device support, the stirring mechanism II can be inserted into the stirring support, the transmission mechanism is rotatably connected to the device support, the stirring mechanism II can be in transmission connection with the transmission mechanism, the feeding mechanism is provided with a plurality of feeding mechanisms, the plurality of feeding mechanisms are fixedly connected to the device support, the plurality of feeding mechanisms are communicated with the stirring support, the plurality of stirring supports are in transmission connection, the transmission mechanism is in transmission connection with one of the feeding mechanisms, and the sensor is fixedly connected, the sensor is connected with the discharging mechanism, the stirring mechanism II can extrude the sensor, and the containing mechanism is fixedly connected between the stirring support and the stirring mechanism II.

As further optimization of the technical scheme, the putty powder processing system comprises a device support, a side support I, a side support II, a connecting plate, a sliding rail, a rotating support and a feeding support, wherein the connecting plate is fixedly connected between the lower ends of the side support I and the side support II, the sliding rail is fixedly connected between the two sides of the side support I and the side support II, the rotating support is fixedly connected between the upper ends of the side support I and the side support II, a plurality of feeding supports are fixedly connected between the rear sides of the upper ends of the side support I and the side support II, a transmission mechanism is rotatably connected onto the rotating support, a sensor is fixedly connected onto the connecting plate, and the sensor is located on the front side of the transmission mechanism.

According to the putty powder processing system, the stirring support comprises a stirring cylinder, a rectangular cavity I and a rectangular cavity II, the lower end of the stirring cylinder is fixedly connected with the rectangular cavity I, the lower end of the rectangular cavity I is fixedly connected with the rectangular cavity II, the stirring cylinder is fixedly connected to the side support II, and the width of the rectangular cavity II is larger than that of the rectangular cavity I.

As further optimization of the technical scheme, the putty powder processing system comprises a stirring mechanism I, a stirring disc and stirring rods, wherein the stirring mechanism I is fixedly connected to the rear end of a stirring cylinder, the stirring disc is fixedly connected to an output shaft of the stirring cylinder, and the stirring rods are fixedly connected to the stirring disc.

As the further optimization of the technical scheme, the putty powder processing system comprises the telescopic mechanism I and the discharge baffle, wherein the telescopic mechanism I is fixedly connected to the connecting plate, the telescopic end of the telescopic mechanism I is fixedly connected with the discharge baffle, the upper end of the discharge baffle is obliquely arranged, and the discharge baffle is slidably connected into the rectangular cavity I.

As a further optimization of the technical scheme, the putty powder processing system comprises a telescopic mechanism II, a sliding support, a stirring motor II, a rack, a boat-shaped push plate, a covering disc, a gear ring, a rotating rod and spiral stirring shafts, wherein the telescopic mechanism II is fixedly connected to a side support I, the sliding support is fixedly connected to the telescopic end of the telescopic mechanism II, the stirring motor II is fixedly connected to the sliding support, the rack and the boat-shaped push plate are respectively and fixedly connected to the upper end and the lower end of the stirring motor II, the covering disc is fixedly connected to the sliding support, the gear ring is fixedly connected to the covering disc, the rotating rod is fixedly connected to the output shaft of the stirring motor II, the two spiral stirring shafts are rotatably connected to the rotating rod, the two spiral stirring shafts are in meshing transmission with the gear ring, the sliding support is slidably connected between the two sliding rails, and the covering disc can be covered on a stirring, the rack can be meshed with the transmission mechanism for transmission, the rack pushes the transmission mechanism to rotate for a half circle at each time, the ship-shaped push plate can extrude the sensor, and the sensor is electrically connected with the telescopic mechanism I.

As a further optimization of the technical scheme, the putty powder processing system comprises a feeding mechanism, arc baffles, feeding rotary drums, a feeding groove, a telescopic mechanism III, a feeding bottom plate and a feeding pipeline, wherein the two arc baffles are fixedly connected in the feeding mechanism, the feeding rotary drum is rotatably connected between the two arc baffles, the feeding rotary drum is provided with the feeding groove, the telescopic mechanism III is fixedly connected in the feeding groove, the telescopic end of the telescopic mechanism III is fixedly connected with the feeding bottom plate, the feeding bottom plate is slidably connected in the feeding groove, the feeding pipeline is fixedly connected on the feeding box, the feeding mechanism is provided with a plurality of feeding rotary drums, the plurality of feeding rotary drums are in transmission connection, the transmission ratio among the plurality of feeding rotary drums is one, one feeding rotary drum is in transmission connection with the transmission mechanism, the transmission ratio among the feeding rotary drums and the transmission mechanism is one, the plurality of feeding boxes are respectively and fixedly connected on a plurality of feeding supports, and the plurality of feeding pipelines are communicated with the mixing drum.

According to the putty powder processing system, the containing mechanism comprises the containing box and the sliding box, the containing box is fixedly connected to the rectangular cavity II, the sliding box is connected to the containing box in a sliding mode, and the sliding box is fixedly connected to the sliding support.

A putty powder processing method comprises the following steps:

the method comprises the following steps: putting different putty powder raw materials into different feeding mechanisms respectively;

step two: the stirring mechanism II is pulled out of the stirring support, the stirring mechanism II drives the transmission mechanism to rotate for a half circle, the transmission mechanism drives the plurality of feeding rotary drums to rotate for a half circle, the plurality of feeding grooves move to the upper side, and different raw materials respectively fall into the feeding grooves with different corresponding depths;

step three: the stirring mechanism II extrudes the sensor, the sensor drives the discharging mechanism to move, and the discharging mechanism moves downwards to enable putty powder in the stirring support to fall out;

step four: the stirring mechanism II moves towards the stirring support, the sensor is extruded by the discharging mechanism again to move upwards, the discharging mechanism closes the bottom of the stirring support, the stirring mechanism II pushes the transmission mechanism to rotate for a half circle, the transmission mechanism drives the plurality of feeding rotary drums to rotate for a half circle, the plurality of feeding grooves move to the lower side, and putty powder raw materials of different types and different weights in the feeding grooves fall into the stirring support;

step five: and starting the stirring mechanism I and the stirring mechanism II to stir the putty powder raw materials in the stirring support.

The putty powder consists of quicklime powder 18-20 wt%, formaldehyde absorbent 5 wt%, cotton fiber powder 6-7 wt%, nanometer titania 4-6 wt%, calcite powder 49-51 wt% and other anti-cracking cured rubber powder.

The putty powder and the processing system and the processing method thereof have the beneficial effects that:

according to the putty powder and the processing system and the processing method thereof, different putty powder raw materials can be respectively placed in different feeding mechanisms; the stirring mechanism II is pulled out of the stirring support, the stirring mechanism II drives the transmission mechanism to rotate for a half circle, the transmission mechanism drives the plurality of feeding rotary drums to rotate for a half circle, the plurality of feeding grooves move to the upper side, and different raw materials respectively fall into the feeding grooves with different corresponding depths; the stirring mechanism II extrudes the sensor, the sensor drives the discharging mechanism to move, and the discharging mechanism moves downwards to enable putty powder in the stirring support to fall out; the stirring mechanism II moves towards the stirring support, the sensor is extruded by the discharging mechanism again to move upwards, the discharging mechanism closes the bottom of the stirring support, the stirring mechanism II pushes the transmission mechanism to rotate for a half circle, the transmission mechanism drives the plurality of feeding rotary drums to rotate for a half circle, the plurality of feeding grooves move to the lower side, and putty powder raw materials of different types and different weights in the feeding grooves fall into the stirring support; starting stirring mechanism I and stirring mechanism II and stirring the putty powder raw materials in the stirring support, II reciprocating motion of stirring mechanism can high efficiency processing putty powder in succession.

Drawings

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

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

FIG. 1 is a schematic view of the overall structure of the putty powder processing system of the present invention;

FIG. 2 is a schematic structural view of a cross-sectional view of a putty powder processing system of the present invention;

FIG. 3 is a schematic view of the device support structure of the present invention;

FIG. 4 is a schematic view of the stirring support structure of the present invention;

FIG. 5 is a schematic structural diagram of a stirring mechanism I of the present invention;

FIG. 6 is a schematic structural view of the discharge mechanism of the present invention;

FIG. 7 is a schematic structural diagram of a stirring mechanism II of the present invention;

FIG. 8 is a schematic view of the transmission mechanism of the present invention;

FIG. 9 is a first schematic structural view of the feeding mechanism of the present invention;

FIG. 10 is a second schematic structural view of the feeding mechanism of the present invention;

FIG. 11 is a third schematic structural view of the feeding mechanism of the present invention;

fig. 12 is a schematic structural view of the storage mechanism of the present invention.

In the figure: a device holder 1; a side bracket I101; a side bracket II 102; a connecting plate 103; a slide rail 104; a rotating bracket 105; a feed support 106; a stirring support 2; a mixing drum 201; a rectangular cavity I202; a rectangular cavity II 203; a stirring mechanism I3; a stirring motor I301; a stir plate 302; a stirring rod 303; a discharging mechanism 4; a telescoping mechanism I401; a discharge baffle 402; a stirring mechanism II 5; a telescoping mechanism II 501; a sliding bracket 502; a stirring motor II 503; a rack 504; a boat-shaped push plate 505; a cover tray 506; a ring gear 507; rotating the rod 508; a helical stirring shaft 509; a transmission mechanism 6; a feeding mechanism 7; a supply tank 701; a circular arc baffle 702; a feed drum 703; a supply tank 704; a telescoping mechanism III 705; a feed shoe 706; a feed conduit 707; a storage mechanism 8; a storage box 801; a slide box 802; and a sensor 9.

Detailed Description

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

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1-12, a putty powder processing system, which comprises a device support 1, a stirring support 2, a stirring mechanism i 3, a discharging mechanism 4, a stirring mechanism ii 5, a transmission mechanism 6, a feeding mechanism 7, a receiving mechanism 8 and a sensor 9, wherein the stirring support 2 is fixedly connected to the device support 1, the stirring mechanism i 3 is fixedly connected to the stirring support 2, the discharging mechanism 4 is slidably connected to the lower end of the stirring support 2, the discharging mechanism 4 is fixedly connected to the device support 1, the stirring mechanism ii 5 is connected to the device support 1, the stirring mechanism ii 5 can be inserted into the stirring support 2, the transmission mechanism 6 is rotatably connected to the device support 1, the stirring mechanism ii 5 can be in transmission connection with the transmission mechanism 6, the feeding mechanism 7 is provided with a plurality, the feeding mechanisms 7 are all fixedly connected to the device support 1, and the feeding mechanisms 7 are all communicated with the stirring support 2, a plurality of stirring support 2 between the transmission are connected, and

drive mechanism

6 and 7 transmissions of one of them feed mechanism are connected, fixedly connected with sensor 9 on the device support 1, and sensor 9 and discharge mechanism 4 are connected, and stirring mechanism II 5 can extrude sensor 9, and receiving mechanism 8 fixed connection is between stirring support 2 and stirring mechanism II 5.

The second embodiment is as follows:

the present embodiment is described below with reference to fig. 1 to 12, and the present embodiment further describes the first embodiment, where the apparatus bracket 1 includes a side bracket i 101, a side bracket ii 102, a connecting plate 103, a sliding rail 104, a rotating bracket 105 and a feeding bracket 106, the connecting plate 103 is fixedly connected between the lower ends of the side bracket i 101 and the side bracket ii 102, the sliding rail 104 is fixedly connected between the two sides of the side bracket i 101 and the side bracket ii 102, the rotating bracket 105 is fixedly connected between the upper ends of the side bracket i 101 and the side bracket ii 102, the plurality of feeding brackets 106 are fixedly connected between the rear sides of the upper ends of the side bracket i 101 and the side bracket ii 102, the transmission mechanism 6 is rotatably connected to the rotating bracket 105, the sensor 9 is fixedly connected to the connecting plate 103, and the sensor 9 is located at the front side of the transmission mechanism 6.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 12, and the second embodiment is further described in the present embodiment, where the stirring support 2 includes a stirring cylinder 201, a rectangular cavity i 202, and a rectangular cavity ii 203, the lower end of the stirring cylinder 201 is fixedly connected with the rectangular cavity i 202, the lower end of the rectangular cavity i 202 is fixedly connected with the rectangular cavity ii 203, the stirring cylinder 201 is fixedly connected to the side support ii 102, and the width of the rectangular cavity ii 203 is greater than the width of the rectangular cavity i 202.

The fourth concrete implementation mode:

the third embodiment is further described with reference to fig. 1 to 12, in which the stirring mechanism i 3 includes a stirring motor i 301, a stirring disk 302 and a stirring rod 303, the stirring motor i 301 is fixedly connected to the rear end of the stirring cylinder 201, the stirring disk 302 is fixedly connected to the output shaft of the stirring cylinder 201, and the stirring disk 302 is fixedly connected to a plurality of stirring rods 303.

The fifth concrete implementation mode:

the fourth embodiment is further described with reference to fig. 1 to 12, in which the discharging mechanism 4 includes a telescopic mechanism i 401 and a discharging baffle 402, the telescopic mechanism i 401 is fixedly connected to the connecting plate 103, the telescopic end of the telescopic mechanism i 401 is fixedly connected to the discharging baffle 402, the upper end of the discharging baffle 402 is obliquely arranged, and the discharging baffle 402 is slidably connected to the rectangular cavity i 202.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1 to 12, and the fifth embodiment is further described in the present embodiment, where the stirring mechanism ii 5 includes a telescopic mechanism ii 501, a sliding support 502, a stirring motor ii 503, a rack 504, a boat-shaped push plate 505, a closing plate 506, a gear ring 507, a rotating rod 508 and a spiral stirring shaft 509, the telescopic mechanism ii 501 is fixedly connected to the side support i 101, the telescopic end of the telescopic mechanism ii 501 is fixedly connected to the sliding support 502, the sliding support 502 is fixedly connected to the stirring motor ii 503, the upper and lower ends of the stirring motor ii 503 are respectively fixedly connected to the rack 504 and the boat-shaped push plate 505, the sliding support 502 is fixedly connected to the closing plate 506, the closing plate 506 is fixedly connected to the gear ring 507, the output shaft of the stirring motor ii 503 is fixedly connected to the rotating rod 508, the rotating rod 508 is rotatably connected to two spiral stirring shafts 509, and both spiral stirring shafts 509 are in meshing, the sliding support 502 is connected between the two sliding rails 104 in a sliding mode, the covering disc 506 can be covered on the stirring barrel 201, the rack 504 can be meshed with the transmission mechanism 6 for transmission, the rack 504 pushes the transmission mechanism 6 to rotate for a half circle at each time, the boat-shaped push plate 505 can extrude the sensor 9, and the sensor 9 is electrically connected with the telescopic mechanism I401.

The seventh embodiment:

the present embodiment is described below with reference to fig. 1 to 12, and the present embodiment further describes an embodiment six, where the feeding mechanism 7 includes a feeding box 701, arc baffles 702, a feeding drum 703, a feeding groove 704, a telescopic mechanism iii 705, a feeding bottom plate 706 and a feeding pipeline 707, two arc baffles 702 are fixedly connected in the feeding box 701, a feeding drum 703 is rotatably connected between the two arc baffles 702, the feeding drum 703 is provided with a feeding groove 704, a telescopic mechanism iii 705 is fixedly connected in the feeding groove 704, the telescopic end of the telescopic mechanism iii 705 is fixedly connected with the feeding bottom plate 706, the feeding bottom plate 706 is slidably connected in the feeding groove 704, the feeding pipeline 707 is fixedly connected to the feeding box 701, the feeding mechanism 7 is provided with a plurality of feeding drums 703, the feeding drums 703 are in transmission connection, a transmission ratio between the feeding drums 703 is one, one of the feeding drums 703 is in transmission connection with the transmission mechanism 6, the transmission ratio between the feeding drum 703 and the transmission mechanism 6 is one, the plurality of feeding boxes 701 are respectively and fixedly connected to the plurality of feeding supports 106, and the plurality of feeding pipelines 707 are all communicated with the mixing drum 201.

The specific implementation mode is eight:

the present embodiment will be described with reference to fig. 1 to 12, and a seventh embodiment will be further described in the present embodiment, in which the storage mechanism 8 includes a storage box 801 and a sliding box 802, the storage box 801 is fixedly connected to the rectangular cavity ii 203, the sliding box 802 is slidably connected to the storage box 801, and the sliding box 802 is fixedly connected to the sliding bracket 502.

A putty powder processing method comprises the following steps:

the method comprises the following steps: different putty powder raw materials are respectively placed in different feeding mechanisms 7;

step two: the stirring mechanism II 5 is pulled out of the stirring support 2, the stirring mechanism II 5 drives the transmission mechanism 6 to rotate for a half circle, the transmission mechanism 6 drives the plurality of feeding rotary drums 703 to rotate for a half circle, the plurality of feeding grooves 704 move to the upper side, and different raw materials respectively fall into the feeding grooves 704 with different corresponding depths;

step three: the stirring mechanism II 5 extrudes the sensor 9, the sensor 9 drives the discharging mechanism 4 to move, and the discharging mechanism 4 moves downwards to enable putty powder in the stirring support 2 to fall out;

step four: the stirring mechanism II 5 moves towards the stirring support 2, the sensor 9 is extruded by the discharging mechanism 4 again to move upwards, the discharging mechanism 4 closes the bottom of the stirring support 2, the stirring mechanism II 5 pushes the transmission mechanism 6 to rotate for a half circle, the transmission mechanism 6 drives the plurality of feeding rotary drums 703 to rotate for a half circle, the plurality of feeding grooves 704 move to the lower side, and putty powder raw materials with different types and weights in the feeding grooves 704 fall into the stirring support 2;

step five: and starting the stirring mechanism I3 and the stirring mechanism II 5 to stir the putty powder raw materials in the stirring support 2.

The invention relates to putty powder and a processing system and a processing method thereof, wherein the working principle is as follows:

when the putty powder mixing device is used, different putty powder preparation raw materials are respectively placed in different feeding boxes 701, as shown in fig. 1, when a stirring mechanism II 5 is in a state of being inserted into a stirring support 2, a covering disc 506 covers a stirring cylinder 201, a feeding groove 704 is arranged downwards after being opened, the materials in the feeding boxes 701 cannot fall into the feeding groove 704, a telescopic mechanism III 705 can be a hydraulic cylinder or an electric push rod, the sliding position of a feeding bottom plate 706 in the feeding groove 704 can be adjusted when the telescopic mechanism III is started, the amount of the putty powder raw materials which can be filled into the feeding groove 704 can be adjusted, the size of each feeding groove 704 is adjusted according to use requirements, the amount of the components of each raw material is adjusted when a transmission mechanism 6 feeds the stirring support 2 each time, and the proportion of each putty powder raw material is adjusted; starting a telescopic mechanism II 501, wherein the telescopic mechanism II 501 can be a hydraulic cylinder or an electric push rod, the telescopic mechanism II 501 stretches backwards, the telescopic end of the telescopic mechanism II 501 drives a sliding support 502 to move backwards, the sliding support 502 drives a rack 504 and a boat-shaped push plate 505 to move backwards, the rack 504 moves backwards and contacts with a transmission mechanism 6, in order to ensure that the transmission mechanism 6 and the rack 504 can smoothly enter into meshing transmission, a proper damping device can be arranged at the joint of the two ends of the transmission mechanism 6 and a rotating support 105, the rack 504 and the transmission mechanism 6 enter into meshing transmission, the number of teeth of the rack 504 is equal to the number of teeth of a half-circle of a meshing gear of the transmission mechanism 6, so that the rack 504 pushes the transmission mechanism 6 to rotate for a half-circle each time when passing through the transmission mechanism 6, the transmission ratio among a plurality of feeding rotary drums 703 is one, one of the feeding rotary drums 703 is in transmission connection, the transmission ratio between the feeding rotary drum 703 and the transmission mechanism 6 is one, the transmission mechanism 6 drives the feeding rotary drum 703 to rotate for half a circle, the plurality of feeding grooves 704 move to the upper side, and different raw materials respectively drop into the feeding grooves 704 with different corresponding depths; the sliding support 502 continues to move towards the front side, the sensor 9 is positioned at the front side of the transmission mechanism 6, the sensor 9 can be a contact sensor or a pressure sensor, the sensor 9 is connected with the telescoping mechanism I401 through an electric control means, the telescoping mechanism I401 moves when the sensor 9 is extruded, the telescoping mechanism I401 can be a hydraulic cylinder or an electric push rod, the telescoping mechanism I401 can also be other mechanical mechanisms capable of reciprocating, the boat-shaped push plate 505 extrudes the sensor 9, the sensor 9 controls the telescoping mechanism I401 to move, the transportation speed of the telescoping mechanism I401 and the length of the boat-shaped push plate 505 need to be adjusted, the time when the boat-shaped push plate 505 extrudes the sensor 9 each time is just the time when the telescoping end of the telescoping mechanism I401 moves downwards to the limit position, the telescoping end of the telescoping mechanism I401 is fixedly connected with the discharge baffle plate 402, the upper end of the discharging baffle 402 is obliquely arranged, the discharging baffle 402 is connected in the rectangular cavity I202 in a sliding mode, the width of the rectangular cavity II 203 is larger than that of the rectangular cavity I202, when the discharging baffle 402 moves downwards into the rectangular cavity II 203, raw materials on the discharging baffle 402 fall off, and the raw materials in the stirring barrel 201 fall out; the second telescopic mechanism 501 is started again, the telescopic end of the second telescopic mechanism 501 moves towards the stirring support 2, the sensor 9 is extruded by the extrusion discharging mechanism 4 again to move upwards, the discharging mechanism 4 closes the bottom of the stirring support 2, the second stirring mechanism 5 pushes the transmission mechanism 6 to rotate for a half circle, the transmission mechanism 6 drives the plurality of feeding rotary drums 703 to rotate for a half circle, the plurality of feeding grooves 704 move to the lower side, and putty powder raw materials of different types and different weights in the feeding grooves 704 fall into the stirring support 2; starting the stirring mechanism I3 and the stirring mechanism II 5 to stir the putty powder raw material in the stirring support 2, as shown in FIG. 7, the stirring motor II 503 is preferably a reciprocating rotating motor, an output shaft of the stirring motor II 503 drives a rotating rod 508 to rotate, the rotating rod 508 drives two spiral stirring shafts 509 to revolve, and simultaneously, a gear ring 507 pushes the two spiral stirring shafts 509 to rotate, so that the stirring effect of the putty powder raw material is improved, a containing box 801 is fixedly connected to a rectangular cavity II 203, a sliding box 802 is slidably connected to the containing box 801, the sliding box 802 is fixedly connected to the sliding support 502, when the stirring mechanism II 5 leaves the stirring cylinder 201, the putty powder raw material is prevented from falling out, and the containing mechanism 8 can be used for containing; the stirring mechanism II 5 reciprocates to continuously and efficiently process the putty powder.

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

Claims

1. The utility model provides a putty powder system of processing, includes device support (1), stirring support (2), rabbling mechanism I (3), discharge mechanism (4), rabbling mechanism II (5), drive mechanism (6), feed mechanism (7), receiving mechanism (8) and sensor (9), its characterized in that: the device is characterized in that a stirring support (2) is fixedly connected onto a device support (1), a stirring mechanism I (3) is fixedly connected onto the stirring support (2), a discharging mechanism (4) is connected to the lower end of the stirring support (2) in a sliding manner, the discharging mechanism (4) is fixedly connected onto the device support (1), a stirring mechanism II (5) is connected onto the device support (1), the stirring mechanism II (5) can be inserted into the stirring support (2), a transmission mechanism (6) is rotatably connected onto the device support (1), the stirring mechanism II (5) can be in transmission connection with the transmission mechanism (6), a plurality of feeding mechanisms (7) are arranged, the plurality of feeding mechanisms (7) are fixedly connected onto the device support (1), the plurality of feeding mechanisms (7) are communicated with the stirring support (2), the plurality of stirring supports (2) are in transmission connection, the transmission mechanism (6) is in transmission connection with one of the feeding mechanisms (7), fixedly connected with sensor (9) on device support (1), sensor (9) are connected with discharge mechanism (4), and rabbling mechanism II (5) can extrude sensor (9), and receiving mechanism (8) fixed connection is between rabbling support (2) and rabbling mechanism II (5).

2. The putty powder processing system of claim 1, characterized in that: device support (1) is including collateral branch frame I (101), collateral branch frame II (102), connecting plate (103), slip track (104), rotate support (105) and feeding support (106), fixedly connected with connecting plate (103) between the lower extreme of collateral branch frame I (101) and collateral branch frame II (102), fixedly connected with slip track (104) between the both sides of collateral branch frame I (101) and collateral branch frame II (102), fixedly connected with rotates support (105) between the upper end of collateral branch frame I (101) and collateral branch frame II (102), a plurality of feeding supports (106) of fixedly connected with between the rear side of collateral branch frame I (101) and collateral branch frame II (102) upper end, drive mechanism (6) rotate to be connected on rotating support (105), sensor (9) fixed connection is on connecting plate (103), sensor (9) are located the front side of drive mechanism (6).

3. The putty powder processing system of claim 2, wherein: stirring support (2) are including churn (201), rectangle cavity I (202) and rectangle cavity II (203), the lower extreme fixedly connected with rectangle cavity I (202) of churn (201), the lower extreme fixedly connected with rectangle cavity II (203) of rectangle cavity I (202), churn (201) fixed connection is on collateral branch frame II (102), the width of rectangle cavity II (203) is greater than the width of rectangle cavity I (202).

4. The putty powder processing system of claim 3, characterized in that: rabbling mechanism I (3) include agitator motor I (301), agitator disk (302) and puddler (303), agitator motor I (301) fixed connection is in the rear end of churn (201), fixedly connected with agitator disk (302) on the output shaft of churn (201), a plurality of puddlers of fixedly connected with (303) on agitator disk (302).

5. The putty powder processing system of claim 4, characterized in that: discharge mechanism (4) are including telescopic machanism I (401) and discharge baffle (402), and telescopic machanism I (401) fixed connection is on connecting plate (103), and telescopic machanism I (401) is served fixedly connected with discharge baffle (402), and the upper end slope of discharge baffle (402) sets up, and discharge baffle (402) sliding connection is in rectangle cavity I (202).

6. The putty powder processing system of claim 5, characterized in that: the stirring mechanism II (5) comprises a telescopic mechanism II (501), a sliding support (502), a stirring motor II (503), a rack (504), a boat-shaped push plate (505), a covering disc (506), a gear ring (507), a rotating rod (508) and a spiral stirring shaft (509), the telescopic mechanism II (501) is fixedly connected to the side support I (101), the telescopic end of the telescopic mechanism II (501) is fixedly connected with the sliding support (502), the sliding support (502) is fixedly connected with the stirring motor II (503), the upper end and the lower end of the stirring motor II (503) are respectively fixedly connected with the rack (504) and the boat-shaped push plate (505), the sliding support (502) is fixedly connected with the covering disc (506), the covering disc (506) is fixedly connected with the gear ring (507), the output shaft of the stirring motor II (503) is fixedly connected with the rotating rod (508), the rotating rod (508) is rotatably connected with the two spiral stirring shaft (509), two spiral stirring shafts (509) are in meshing transmission with a gear ring (507), a sliding support (502) is in sliding connection between two sliding rails (104), a covering disc (506) can be covered on the stirring drum (201), a rack (504) can be in meshing transmission with a transmission mechanism (6), the rack (504) pushes the transmission mechanism (6) to rotate for a half circle at each time, a ship-shaped push plate (505) can extrude a sensor (9), and the sensor (9) is in electric control connection with a telescopic mechanism I (401).

7. The putty powder processing system of claim 6, characterized in that: the feeding mechanism (7) comprises a feeding box (701), arc baffles (702), feeding rotary drums (703), a feeding groove (704), a telescopic mechanism III (705), a feeding bottom plate (706) and a feeding pipeline (707), wherein the feeding box (701) is internally and fixedly connected with the two arc baffles (702), the feeding rotary drum (703) is rotatably connected between the two arc baffles (702), the feeding groove (704) is arranged on the feeding rotary drum (703), the telescopic mechanism III (705) is fixedly connected in the feeding groove (704), the telescopic end of the telescopic mechanism III (705) is fixedly connected with the feeding bottom plate (706), the feeding bottom plate (706) is slidably connected in the feeding groove (704), the feeding pipeline (707) is fixedly connected on the feeding box (701), the feeding mechanism (7) is provided with a plurality of feeding rotary drums (703) which are in transmission connection, the transmission ratio among the feeding rotary drums (703) is one, one of the feeding rotating cylinders (703) is in transmission connection with the transmission mechanism (6), the transmission ratio between the feeding rotating cylinder (703) and the transmission mechanism (6) is one, the feeding boxes (701) are respectively and fixedly connected onto the feeding supports (106), and the feeding pipelines (707) are communicated with the stirring cylinder (201).

8. The putty powder processing system of claim 7, wherein: the containing mechanism (8) comprises a containing box (801) and a sliding box (802), the containing box (801) is fixedly connected to the rectangular cavity II (203), the sliding box (802) is connected to the containing box (801) in a sliding mode, and the sliding box (802) is fixedly connected to the sliding support (502).

9. The method for processing putty powder by using the putty powder processing system as claimed in claim 8, which is characterized in that: the method comprises the following steps:

the method comprises the following steps: different putty powder raw materials are respectively placed in different feeding mechanisms (7);

step two: the stirring mechanism II (5) is pulled out from the stirring support (2), the stirring mechanism II (5) drives the transmission mechanism (6) to rotate for a half circle, the transmission mechanism (6) drives the plurality of feeding rotary drums (703) to rotate for a half circle, the plurality of feeding grooves (704) move to the upper side, and different raw materials respectively fall into the feeding grooves (704) with different depths;

step three: the stirring mechanism II (5) extrudes the sensor (9), the sensor (9) drives the discharging mechanism (4) to move, and the discharging mechanism (4) moves downwards to enable putty powder in the stirring support (2) to fall out;

step four: the stirring mechanism II (5) moves towards the stirring support (2), the sensor (9) is extruded by the discharging mechanism (4) to move upwards again, the discharging mechanism (4) closes the bottom of the stirring support (2), the stirring mechanism II (5) pushes the transmission mechanism (6) to rotate for a half circle, the transmission mechanism (6) drives the plurality of feeding rotary drums (703) to rotate for a half circle, the plurality of feeding grooves (704) move to the lower side, and putty powder raw materials of different types and different weights in the feeding grooves (704) fall into the stirring support (2);

step five: and starting the stirring mechanism I (3) and the stirring mechanism II (5) to stir the putty powder raw materials in the stirring support (2).

10. The putty powder processed by the putty powder processing system of claim 8, wherein: the anti-cracking and curing adhesive powder comprises, by weight, 18% -20% of quicklime powder, 5% of formaldehyde absorbent, 6% -7% of cotton fiber powder, 4% -6% of nano titanium dioxide, 49% -51% of calcite powder and the balance anti-cracking and curing adhesive powder.