CN114178064A

CN114178064A - Numerical control cutter machining device

Info

Publication number: CN114178064A
Application number: CN202111410457.6A
Authority: CN
Inventors: 莫艳妮
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-11-25
Filing date: 2021-11-25
Publication date: 2022-03-15

Abstract

The invention discloses a coating device using a numerical control cutter, which comprises a shell, wherein the shell is provided with a mixing cavity function cavity communicated with the outside, a stirring mechanism, a reversing mechanism and a conveying mechanism are arranged in the shell, and a passage door is arranged in the coating device, so that the inlet and the outlet of a coating can be controlled, the coating space can be closed in time when a machine fails, the loss of the coating is reduced, and when a spray head fails, if the passage door is not controlled, the coating can be splashed, or the pressure of the spray head is increased to cause the device to burst and cause loss due to the fact that a pressurizing mechanism still works when the spray head is blocked; utilize the filter screen that sets up, can filter coating to prevent that the pore cover from blockking up, the long-time sediment of coating can have bigger granule in the coating, perhaps forms the caking after the coating is dry at the container inner wall, helps improving pore cover life-span like this, reduce the cost.

Description

Numerical control cutter machining device

Technical Field

The application relates to the field of numerical control cutters, in particular to a numerical control cutter machining device.

Background

Numerical control cutter is when doing the motion of cutting, can paint the one deck protection film for the cutter in order to increase the life-span of cutter, prevent the oxidation of cutter material, it is wear-resisting at the in-process coating of cutting, high temperature resistant, it is firm, so can guarantee that the wearing and tearing of cutter slow down, thereby reach the purpose that increases the cutter life-span, and when the spraying has the coating of diamond, because the hardness of diamond is very big, so uneven size can appear in the diamond powder granule of processing, the shower nozzle of coating is blockked up easily to big diamond powder, so often influence the progress of paining, and if long-time not clear up the shower nozzle also can lead to the jam of shower nozzle, and the clearance blocks up very trouble, it is with high costs to change the accessory.

Disclosure of Invention

An object of the application is to provide a numerical control cutter processingequipment, adopt following technical scheme:

a numerical control cutter machining device is characterized in that a shell is provided with a mixing cavity function cavity communicated with the outside, a stirring mechanism, a reversing mechanism and a conveying mechanism are arranged in the shell, the reversing mechanism can enable a cutter to turn, and the conveying mechanism can clamp the cutter;

the stirring mechanism comprises a cleaning mechanism capable of cleaning a filter screen, an upper container is fixedly connected to the upper end wall of the functional cavity, an air cylinder is fixedly connected to the upper container, a stirring motor is fixedly connected to the air cylinder, a stirring shaft is dynamically connected to the stirring motor, a stirring rod is fixedly connected to the stirring shaft, a rotating shaft is fixedly connected to the lower end face of the stirring rod, the rotating shaft can distinguish the position of liquid, a lower container is fixedly connected to the lower end wall of the functional cavity, the upper container is fixedly connected to a connecting pipe communicated with the lower container, the rotating shaft is fixedly connected to the lower container, a channel door is rotationally connected to the lower container and the upper container, a rotating motor is fixedly connected to the lower container, the rotating shaft is dynamically connected to the rotating motor, the channel door is fixedly connected to the rotating shaft, and a fine hole cover is fixedly connected to the lower ends of the upper container and the lower container, and pressure pumps are arranged in the upper container and the lower container.

Preferably, the cleaning mechanism comprises the upper container and a filter screen fixedly connected with the lower container, the lower end face of the upper container and the lower container is connected with a moving motor in a sliding manner, the moving motor is connected with a moving shaft in a power manner, and the moving shaft is fixedly connected with a moving gear.

Preferably, the movable motor is fixedly connected with a collecting bag, a suction block is arranged in the collecting bag, the suction block can clean particles blocked on the filter screen, the upper container and the lower container right end face are fixedly connected with a sealing block, the sealing block is fixedly connected with a dust collector, the dust collector is fixedly connected with a collecting box, the end wall of the functional cavity is fixedly connected with an air pump, the air pump is fixedly connected with an air pipe, and a push block is slidably connected in the lower container.

Preferably, the reversing mechanism comprises a clamping motor fixedly connected with the right end wall of the function cavity, the clamping motor is in power connection with a clamping shaft, the clamping shaft is fixedly connected with a clamp, the clamp is fixedly connected with an armature, and the clamp is fixedly connected with an electromagnet.

Preferably, the lower container and the right end face of the upper container are fixedly connected with a fixed shell, the fixed shell is fixedly connected with a fan, the fan can blow air, and heating wires are arranged in the fixed shell.

Preferably, the conveying mechanism comprises a belt wheel motor fixedly connected with the right end wall of the function cavity, the belt wheel motor is in power connection with a belt wheel shaft, the belt wheel shaft is fixedly connected with a driving belt wheel, the lower end wall of the function cavity is fixedly connected with a support, the support rotates to be connected with an auxiliary shaft, the auxiliary shaft is fixedly connected with an auxiliary belt wheel, the auxiliary belt wheel is connected with the driving belt wheel through a belt, the left end wall of the function cavity is fixedly connected with a hydraulic rod, the hydraulic rod is in sliding connection with a fixed rod, the fixed rod is in interactive connection with a movable block, the fixed rod is fixedly connected with a motor, the motor is in power connection with a power shaft, and the power shaft is fixedly connected with a gear.

Preferably, a reversing motor is fixedly connected to the rear end of the moving block, a reversing shaft is dynamically connected to the reversing motor, a driving clamping rod is fixedly connected to the reversing shaft, and a rubber layer is fixedly connected to the driving clamping rod and the fixing rod.

Compared with the prior art, the invention provides a numerical control tool machining device which has the following beneficial effects: the passage door can control the paint to enter and exit, so that when a machine fails, the paint space can be closed in time, the loss of the paint is reduced, when a spray head fails, if the passage door is not controlled, the paint is splashed, or when the spray head is blocked, the pressure of the spray head is increased to cause the device to burst and the loss is caused because a pressurizing mechanism still works;

utilize the filter screen that sets up, can filter coating to prevent that the pore cover from blockking up, the long-time sediment of coating can have bigger granule in the coating, perhaps forms the caking after the coating is dry at the container inner wall, helps improving pore cover life-span like this, reduce the cost.

Drawings

FIG. 1 is a schematic diagram of the internal structure of a numerical control tool machining apparatus according to the present invention;

FIG. 2 is a schematic view of A-A of FIG. 1 in accordance with the present invention;

FIG. 3 is a schematic view of B-B of FIG. 1 according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1 to 3, a numerical control tool machining apparatus according to an embodiment of the present invention includes a housing 10, the housing 10 is provided with a mixing chamber function chamber 60 communicating with the outside, a stirring mechanism 61, a reversing mechanism 63 and a conveying mechanism 64 are provided in the housing 10, the reversing mechanism 63 can turn a tool, and the conveying mechanism 64 can clamp the tool;

the stirring mechanism 61 comprises a cleaning mechanism 62 capable of cleaning a filter screen, the upper end wall of the functional cavity 60 is fixedly connected with an upper container 47, the upper container 47 is fixedly connected with a cylinder 50, the cylinder 50 is fixedly connected with a stirring motor 49, the stirring motor 49 is in power connection with a stirring shaft 51, the stirring shaft 51 is fixedly connected with a stirring rod 48, the lower end surface of the stirring rod 48 is fixedly connected with a rotating shaft 31, the rotating shaft 31 can distinguish the position of liquid, the lower end wall of the functional cavity 60 is fixedly connected with a lower container 39, the upper container 47 is fixedly connected with a connecting pipe 32 communicated with the lower container 39, the rotating shaft 31 is fixedly connected in the lower container 39, the lower container 39 and the upper container 47 are rotatably connected with a passage door 26, the lower container 39 is fixedly connected with a rotating motor 30, the rotating motor 30 is in power connection with the rotating shaft 31, and the rotating shaft 31 is fixedly connected with the passage door 26, the lower ends of the upper container 47 and the lower container 39 are fixedly connected with a fine hole cover 42, a pressure pump 40 is arranged in the upper container 47 and the lower container 39, the rotating motor 30 is started to drive the rotating shaft 31 to rotate, so that the access door 26 is driven to rotate, the holes in the access door 26 and the lower container 39 are aligned, the upper end wall of the function cavity 60 is fixedly connected with a solution pool 14, and the solution pool 14 is connected with the upper container 47 through a conveying pipe 20.

In the embodiment of the present invention, the cleaning mechanism 62 includes a filter screen 25 fixedly connected to the upper container 47 and the lower container 39, the filter screen 25 is provided with a plurality of fine meshes capable of filtering particles with a certain diameter, a moving motor 59 is slidably connected to the lower end surfaces of the upper container 47 and the lower container 39, the moving motor 59 is power-connected to a moving shaft 57, the moving shaft 57 is fixedly connected to a moving gear 58, the lower container 39 is provided with a rack, the moving gear 58 is engaged with the rack, the moving motor 59 is fixedly connected to a collecting bag 24, the collecting bag 24 is provided with a suction block 23, the suction block 23 is capable of cleaning particles blocked on the filter screen 25, the right end surfaces of the upper container 47 and the lower container 39 are fixedly connected to a sealing block 36, the sealing block 36 is fixedly connected to a dust collector 37, the dust collector 37 is capable of sucking solid particles on the collecting bag 24, the dust collector 37 is fixedly connected with a collecting box 38, the lower end wall of the functional cavity 60 is fixedly connected with an air pump 29, the air pump 29 is fixedly connected with an air pipe 28, and the lower container 39 is internally and slidably connected with a push block 27.

In the embodiment of the present invention, the reversing mechanism 63 includes a clamping motor 46 fixedly connected to the right end wall of the function chamber 60, the clamping motor 46 is dynamically connected to a clamping shaft 45, the clamping shaft 45 is fixedly connected to a clamp 44, the clamp 44 is fixedly connected to an armature, the clamp 44 is fixedly connected to an electromagnet 41, the electromagnet 41 can attract the armature, the right end faces of the lower container 39 and the upper container 47 are fixedly connected to a fixing shell 33, the fixing shell 33 is fixedly connected to a fan 35, the fan 35 can blow air, and the fixing shell 33 is internally provided with an electric heating wire 34.

In the embodiment of the present invention, the conveying mechanism 64 includes a pulley motor 52 fixedly connected to the right end wall of the function chamber 60, the pulley motor 52 is in power connection with a pulley shaft 53, the pulley shaft 53 is fixedly connected with a driving pulley 11, the lower end wall of the function chamber 60 is fixedly connected with a bracket, the bracket is rotatably connected with a counter shaft 21, the counter shaft 21 is fixedly connected with a counter pulley 43, the counter pulley 43 and the driving pulley 11 are connected through a belt 22, the left end wall of the function chamber 60 is fixedly connected with a hydraulic rod 12, the hydraulic rod 12 is slidably connected with a fixed rod 18, the fixed rod 18 is interactively connected with a movable block 19, the fixed rod 18 is fixedly connected with a motor 17, the motor 17 is in power connection with a power shaft 16, the power shaft 16 is fixedly connected with a gear 15, the gear 15 is engaged with the movable block 19, and the rear end of the movable block 19 is fixedly connected with a reversing motor 54, the reversing motor 54 is in power connection with a reversing shaft 55, the reversing shaft 55 is fixedly connected with a driving clamping rod 56, and the driving clamping rod 56 and the fixing rod 18 are both fixedly connected with the rubber layer 13.

The invention relates to a numerical control cutter machining device, which comprises the following working procedures:

in the initial state, the fixing lever 18 and the active clamping lever 56 are at the leftmost position, the hydraulic lever 12 is in the contracted state, the push block 27 is at the lowest position, and the collecting bag 24 is at the leftmost position.

When processing is needed, the paint is filled in the solution tank 14, if the paint is not supplemented in time, the paint in the solution tank 14 enters the upper container 47 through the delivery pipe 20, the stirring motor 49 is started to drive the stirring shaft 51 to rotate, the stirring rod 48 is driven to rotate, the air cylinder 50 is started to extend and contract, the stirring rod 48 is driven to move up and down, the paint is uniformly stirred, then the connecting pipe 32 is opened, the paint is filled into the lower container 39, the connecting pipe 32 is closed after the rotating shaft 31 in the lower container 39 detects that the water level reaches a certain height, then the upper container 47 continues, when the rotating shaft 31 on the stirring rod 48 detects the water level, the air cylinder 50 and the stirring motor 49 are closed through the delivery pipe 20, the electric heating wire 34 in the fixed shell 33 is preheated, the cutter is placed on the belt 22, then the belt wheel motor 52 is started, the belt wheel shaft 53 is driven to rotate, and the driving belt wheel 11 is driven to rotate, thereby rotating the belt 22 and causing the cutter to move forward;

then, until the cutter contacts the rubber layer 13 on the fixed rod 18, at this time, the belt wheel motor 52 is stopped, the reversing motor 54 is started to drive the reversing shaft 55 to rotate by one hundred eighty, so as to drive the active clamping rod 56 to rotate, and at the same time, the motor 17 is started to drive the power shaft 16 to rotate, so as to drive the gear 15 to rotate, so as to drive the moving block 19 to move forward, so as to drive the active clamping rod 56 to clamp the cutter, at this time, the hydraulic rod 12 is started to extend, so as to drive the cutter to move rightward, and then when passing between the fine hole covers 42, the rotating motor 30 is started, so as to drive the rotating shaft 31 to rotate, so as to open the lower container 39, then, the air pump 29 is started to blow air, so as to push the push block 27 to move upward, the paint in the upper container 47 flows downward, and then passes through the filter screen 25 and is pressurized by the pressure pump 40, so that the paint is sprayed out of the fine hole covers 42, so that the coating is uniformly sprayed on the cutter, then the fan 35 is started, and the cutter is dried and heated after passing through the fan 35;

after one layer of coating is dried, the cutter enters between the clamps 44, then the hydraulic rod 12 is stopped, then the electromagnet 41 is started to drive the armature to be attracted, thereby clamping the cutter, meanwhile, the motor 17 moves reversely, thereby driving the moving block 19 to move backwards, then the cutter is loosened, then the clamping motor 46 is started at the moment, thereby driving the clamping shaft 45 to rotate, thereby driving the clamps 44 to rotate ninety degrees, then the motor 17 is started, thereby enabling the active clamping rod 56 to clamp the cutter, then the electromagnet 41 is stopped, then the clamping motor 46 is started reversely, thereby driving the clamps 44 to reset, at the moment, the hydraulic rod 12 is started to contract, then the pressure pump 40 is continuously started to pressurize the coating on the cutter, the spraying is finished, then the hydraulic rod 12 is started to extend, the coating is dried, then the hydraulic rod 12 is contracted and reset, the motor 17 is started reversely, the moving block 19 is reset, the reversing motor 54 is started reversely, the driving clamping rod 56 is reset, and then the belt wheel motor 52 is started reversely, so that the cutter is driven to reset, the cutter with the coating is arranged, and a new cutter is placed;

at this time, after the processing is completed, the rotating motor 30 is started after the machine is stopped, so that the access door 26 is reset, the moving motor 59 is started, so that the moving shaft 57 is driven to rotate, so that the moving gear 58 is driven to rotate and not drive the moving motor 59 to move rightwards, so that the collecting bag 24 is driven to move rightwards, then the suction block 23 starts large particles adsorbed on the filter screen 25 to be collected in the collecting bag 24, after the collecting bag 24 is completely contacted with the sealing block 36, the dust collector 37 starts to clean the solids on the collecting bag 24 to be collected in the collecting box 38, when the pushing block 27 is lifted to the vicinity of the rotating shaft 31, the device is stopped, then the connecting pipe 32 is opened, the paint is filled, and when the rotating shaft 31 on the stirring rod 48 detects that the water level in the upper container 47 is too low, the conveying pipe 20 is automatically opened to fill the paint.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. A numerical control cutter machining device comprises a machine shell (10), and is characterized in that: the machine shell (10) is provided with a mixing cavity function cavity (60) communicated with the outside, a stirring mechanism (61), a reversing mechanism (63) and a conveying mechanism (64) are arranged in the machine shell (10), the reversing mechanism (63) can enable the cutter to turn, and the conveying mechanism (64) can clamp the cutter; the stirring mechanism (61) comprises a cleaning mechanism (62) capable of cleaning a filter screen, the upper end wall of the functional cavity (60) is fixedly connected with an upper container (47), the upper container (47) is fixedly connected with an air cylinder (50), the air cylinder (50) is fixedly connected with a stirring motor (49), the stirring motor (49) is in power connection with a stirring shaft (51), the stirring shaft (51) is fixedly connected with a stirring rod (48), the lower end surface of the stirring rod (48) is fixedly connected with a rotating shaft (31), the rotating shaft (31) can distinguish the liquid position, the lower end wall of the functional cavity (60) is fixedly connected with a lower container (39), the upper container (47) is fixedly connected with a connecting pipe (32) communicated with the lower container (39), the lower container (39) is internally and fixedly connected with the rotating shaft (31), the lower container (39) and the upper container (47) are rotationally connected with a passage door (26), the lower container (39) is fixedly connected with a rotating motor (30), the rotating motor (30) is in power connection with a rotating shaft (31), the rotating shaft (31) is fixedly connected with the passage door (26), the upper container (47) and the lower end of the lower container (39) are fixedly connected with a fine hole cover (42), and a pressure pump (40) is arranged in the upper container (47) and the lower container (39).

2. A numerically controlled tool machining apparatus according to claim 1, wherein: clearance mechanism (62) include go up container (47) with filter screen (25) of container (39) fixed connection down, go up container (47) with container (39) lower terminal surface sliding connection has moving motor (59) down, moving motor (59) power connection has removal axle (57), removal axle (57) fixedly connected with removes gear (58).

3. A numerically controlled tool machining apparatus according to claim 2, wherein: the utility model discloses a filter screen, including mobile motor (59), collection bag (24), be equipped with suction piece (23) in collection bag (24), suction piece (23) can clean the jam and be in granule on filter screen (25), go up container (47) with container (39) right-hand member face fixedly connected with seals soon (36) down, it seals soon (36) fixedly connected with dust catcher (37) to seal, dust catcher (37) fixedly connected with collecting box (38), terminal wall fixedly connected with air pump (29) under function chamber (60), air pump (29) fixedly connected with trachea (28), sliding connection has ejector pad (27) down in container (39).

4. A numerically controlled tool machining apparatus according to claim 1, wherein: reversing mechanism (63) include function chamber (60) right-hand member wall fixed connection press from both sides tight motor (46), press from both sides tight motor (46) power connection and press from both sides tight axle (45), press from both sides tight axle (45) fixedly connected with anchor clamps (44), anchor clamps (44) fixedly connected with armature, anchor clamps (44) fixedly connected with electro-magnet (41).

5. A numerically controlled tool machining apparatus according to claim 1, wherein: the lower container (39) and the right end face of the upper container (47) are fixedly connected with a fixed shell (33), the fixed shell (33) is fixedly connected with a fan (35), the fan (35) can blow air, and heating wires (34) are arranged in the fixed shell (33).

6. A numerically controlled tool machining apparatus according to claim 1, wherein: the conveying mechanism (64) comprises a belt wheel motor (52) fixedly connected with the right end wall of the function cavity (60), the belt wheel motor (52) is in power connection with a belt wheel shaft (53), the belt wheel shaft (53) is fixedly connected with a driving belt wheel (11), the lower end wall of the function cavity (60) is fixedly connected with a support, the support is in rotating connection with an auxiliary shaft (21), the auxiliary shaft (21) is fixedly connected with an auxiliary belt wheel (43), the auxiliary belt wheel (43) is connected with the driving belt wheel (11) through a belt (22), the left end wall of the function cavity (60) is fixedly connected with a hydraulic rod (12), the hydraulic rod (12) is in sliding connection with a fixed rod (18), the fixed rod (18) is in interactive connection with a movable block (19), the fixed rod (18) is fixedly connected with a motor (17), and the motor (17) is in power connection with a power shaft (16), the power shaft (16) is fixedly connected with a gear (15).

7. A numerically controlled tool machining apparatus according to claim 6, wherein: the rear end of the moving block (19) is fixedly connected with a reversing motor (54), the reversing motor (54) is in power connection with a reversing shaft (55), the reversing shaft (55) is fixedly connected with a driving clamping rod (56), and the driving clamping rod (56) and the fixing rod (18) are both fixedly connected with a rubber layer (13).