CN112403662A

CN112403662A - Chip separation stirring device of numerical control machine tool

Info

Publication number: CN112403662A
Application number: CN202011213199.8A
Authority: CN
Inventors: 王学金
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-11-04
Filing date: 2020-11-04
Publication date: 2021-02-26

Abstract

The invention relates to a chip separating and stirring device of a numerical control machine tool, which comprises a chip box, wherein a chip cavity with an upward opening is arranged in the chip box, the lower wall of the cutting cavity is connected with sliding blocks which are symmetrical from front to back in a left-right sliding manner, a pushing cavity which is communicated from front to back is arranged in the sliding blocks, the lower wall of the cutting cavity is communicated with a guide sliding cavity, the lower side of the guide sliding cavity is provided with a transmission cavity, the lower wall of the transmission cavity is rotatably connected with a main shaft which penetrates through the guide sliding cavity and extends upwards into the cutting cavity, the oscillating ring is fixedly connected with the outer circular surface of one side of the main shaft, which is positioned in the chip cavity, the oscillating ring can separate chips made of different materials by the buoyancy of cooling liquid, and the reciprocating rotating wheel is arranged, so that the chips wound in the cutting process can be better separated, therefore, the cutting chips can be better recovered, and the piston type push rod is arranged at the cutting fluid circulating water path.

Description

Chip separation stirring device of numerical control machine tool

Technical Field

The invention relates to the field of numerical control machines, in particular to a chip separating and dispersing device of a numerical control machine.

Background

The digit control machine tool has solved complicacy, it is accurate, small batch, the part machining problem of many varieties betterly, be a flexible, high-efficiency automatic lathe, the digit control machine tool is because the work piece material kind of processing is more, so often recoverable and unrecoverable smear metal can be mixed together, and these smear metals carry out the manual separation effect relatively poor, and can consume more manpower and time, and some smear metal splitter of current are difficult to stir to winding smear metal and scatter, so be difficult to separate some impurity in the smear metal of twining, the effect is relatively poor.

Disclosure of Invention

The invention aims to provide a chip separating and stirring device of a numerical control machine tool, and solves the problem that chips made of different materials of the numerical control machine tool are difficult to separate well.

The invention is realized by the following technical scheme.

The invention relates to a chip separating and stirring device of a numerical control machine tool, which comprises a chip box, wherein a chip cavity with an upward opening is arranged in the chip box, sliding blocks with symmetrical front and back are connected in a left-right sliding manner on the lower wall of the chip cavity, a pushing cavity which is communicated with the front and back is arranged in the sliding block, a sliding guide cavity is communicated with the lower wall of the chip cavity, a transmission cavity is arranged on the lower side of the sliding guide cavity, the lower wall of the transmission cavity is rotatably connected with a main shaft which penetrates through the sliding guide cavity and extends upwards into the chip cavity, the outer circular surface of one side of the main shaft, which is positioned in the chip cavity, is fixedly connected with a swinging ring, the outer circular surface of the swinging ring is fixedly connected with swinging rods which are symmetrical front and back and can penetrate through the pushing cavity and respectively extend to the front and back sides of the sliding blocks, an upward extending, the upper end face of the threaded connecting block is communicated with a drainage cavity which extends downwards, the lower end of the drainage cavity extends to the left side and the right side of the drainage cavity symmetrically and is communicated with the left end face and the right end face of the threaded connecting block, the left side and the right side of the guide sliding cavity are communicated with a communicating cavity, the rear wall of the communicating cavity is communicated with a circulating cavity which extends backwards, the upper wall and the lower wall of the transmission cavity are fixedly connected with a steering block, the steering block is internally provided with a steering mechanism, the left wall of the chip cavity is vertically and slidably connected with a separating block, the separating block is internally provided with a vertically and vertically through cavity, the left wall of the through cavity is communicated with a filter plate cavity, the right end face of the separating block is fixedly connected with a rack which is vertically and slidably connected with the right wall of the chip cavity, the top end face of the rack is fixedly connected with a top plate, the right wall of the chip, the novel kitchen ventilator is characterized in that a sealed guide sliding cavity with an upward opening is formed in the upper side of the fan cavity in a communicated mode, a fan block is fixedly connected to the upper wall of the fan cavity, a suction mechanism extending upwards into the fan cavity is arranged in the gear cavity, a pull rope connecting cavity is formed in the left wall of the cutting cavity in a communicated mode, and a pull rope cavity is formed in the left side of the pull rope connecting cavity in a communicated mode.

Preferably, reciprocating mechanism includes the motor chamber that is equipped with in the sliding block, motor chamber upper wall is equipped with stirs the motor, it upwards extends to stir motor up end power connection has the motor shaft of sliding block upside, motor shaft top end fixedly connected with stirs the wheel.

Preferably, the steering mechanism comprises a motor base which is vertically slidably connected with the left wall of the transmission cavity, a steering motor is fixedly connected with the right end surface of the motor base, a steering shaft which penetrates through the steering cavity and extends to the right side of the steering block is dynamically connected with the right end surface of the steering motor, a steering block which is vertically slidably connected with the steering cavity is rotatably connected with the outer circular surface of one side of the steering shaft, which is positioned in the steering cavity, a steering spring is fixedly connected between the upper end surface and the lower end surface of the steering block and the upper wall and the lower wall of the steering cavity, magnetic blocks are fixedly connected with the right end of the upper end surface and the lower end surface of the steering block, electromagnets corresponding to the magnetic blocks are arranged on the upper wall and the lower wall of the steering cavity, a lower bevel gear is fixedly connected with the outer circular surface of one side of the main shaft, which is, and the outer circular surface of the tail end of the right side of the steering shaft is fixedly connected with a steering bevel gear which can be meshed with the lower bevel gear and the upper bevel gear.

Preferably, the suction mechanism comprises a lifting motor arranged on the rear wall of the gear cavity, the front end face of the lifting motor is in power connection with a lifting gear shaft which is in rotary connection with the front wall of the gear cavity, the front and rear walls of the gear cavity are in rotary connection with a transmission shaft which is arranged on the lower side of the lifting gear shaft, a transmission belt is in power connection between the lifting gear shaft and the transmission shaft, the lifting gear shaft and the outer circular surface of the transmission shaft are fixedly connected with a lifting gear which is arranged on the rear side of the transmission belt and meshed with the rack, the fan cavity is in up-and-down sliding connection with a sealing plate which can extend into the sealing and sliding guide cavity, the bottom end of the left end face of the sealing plate is fixedly connected with a top block, a fan block cavity is arranged in the fan block, a fan motor is arranged on the right, and the outer circular surface of the tail end of the left side of the fan shaft is fixedly connected with a fan.

Preferably, the top end of the guide sliding cavity is fixedly connected with a material blocking filter plate penetrated by the main shaft, the filter plate cavity is connected with a filter plate push plate in a left-right sliding mode, the right end face of the filter plate push plate is fixedly connected with a separation filter plate, the left end face of the filter plate push plate is fixedly connected with a pull rope connecting cavity penetrated by the pull rope connecting cavity and extends leftwards to a pull rope fixedly connected with the top end of the left wall of the pull rope cavity, and a filter plate spring positioned on the upper side of the pull rope is fixedly connected between the left end face of the filter plate push plate and.

The invention has the beneficial effects that: the invention can separate the cuttings of different materials by the buoyancy of the cooling liquid, is provided with the reciprocating rotary wheel, can better separate the cuttings wound in the cutting process, can better recycle the cuttings, is provided with the piston type push rod at the cutting liquid circulating water path, can prevent blockage, is provided with the fan suction mechanism capable of switching the communication state, and can better collect the light cuttings.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is an enlarged view in the direction A-A of FIG. 1 according to an embodiment of the present invention;

FIG. 3 is an enlarged schematic view of the embodiment of the present invention at B in FIG. 1;

FIG. 4 is an enlarged schematic view of the embodiment of the present invention at C in FIG. 1;

FIG. 5 is an enlarged schematic view of the embodiment of the present invention at D in FIG. 1;

FIG. 6 is an enlarged schematic view of the embodiment of the present invention at E in FIG. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-6, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The chip separating and stirring device for the numerical control machine tool, which is described in conjunction with fig. 1-6, includes a chip box 11, a chip cavity 12 with an upward opening is arranged in the chip box 11, sliding blocks 18 which are symmetrical front and back are connected to the lower wall of the chip cavity 12 in a left-right sliding manner, a pushing cavity 19 which is through front and back is arranged in the sliding block 18, a guiding and sliding cavity 27 is arranged in the lower wall of the chip cavity 12 in a communicating manner, a transmission cavity 30 is arranged at the lower side of the guiding and sliding cavity 27, a main shaft 15 which penetrates through the guiding and sliding cavity 27 and extends upward into the chip cavity 12 is connected to the lower wall of the transmission cavity 30 in a rotating manner, a swing ring 16 is fixedly connected to the outer circular surface of one side of the main shaft 15 which is located in the chip cavity 12, swing rods 17 which are symmetrical front and back and can penetrate through the pushing cavity 19 and respectively extend to the front and back sides and, the spindle 15 is located in the sliding guide cavity 27, a threaded connecting block 26 is in threaded connection with an outer circular surface on one side of the spindle, the upper end surface of the threaded connecting block 26 is communicated with a downward extending water drainage cavity 68, the lower end of the threaded connecting block 26 extends to the left side and the right side respectively to form symmetrical water drainage cavities 68 communicated with the left end surface and the right end surface of the threaded connecting block 26, the left side and the right side of the sliding guide cavity 27 are communicated with a communicating cavity 28, the rear wall of the communicating cavity 28 is communicated with a backward extending circulation cavity 29, the upper wall and the lower wall of the transmission cavity 30 are fixedly connected with a turning block 37, the turning block 37 is internally provided with a left-right through turning cavity 38, the transmission cavity 30 is internally provided with a turning mechanism 102, the left wall of the cutting chip cavity 12 is in up-down sliding connection with a separation block 13, the separation block 13 is internally provided with a through cavity 14 which is through up-down, the, rack 51 preceding terminal surface top fixedly connected with roof 52, smear metal chamber 12 right wall is equipped with gear chamber 53, smear metal chamber 12 right wall intercommunication is equipped with and is located the fan chamber 61 of gear chamber 53 upside, fan chamber 61 upside intercommunication is equipped with the ascending sealed chamber 62 that leads of opening, fan chamber 61 upper wall fixedly connected with fan piece 63, be equipped with in the gear chamber 53 and upwards extend to suction mechanism 103 in the fan chamber 61, smear metal chamber 12 left wall intercommunication is equipped with stay cord and connects chamber 50, stay cord connection chamber 50 left side intercommunication is equipped with stay cord chamber 49.

Advantageously, the reciprocating mechanism 101 comprises a motor cavity 21 arranged in the sliding block 18, the upper wall of the motor cavity 21 is provided with a stirring motor 22, the upper end face of the stirring motor 22 is in power connection with a motor shaft 23 extending upwards to the upper side of the sliding block 18, and the top end of the motor shaft 23 is fixedly connected with a stirring wheel 24.

Beneficially, the steering mechanism 102 includes a motor base 31 slidably connected to the left wall of the transmission cavity 30 up and down, a steering motor 32 is fixedly connected to the right end face of the motor base 31, a steering shaft 33 extending through the steering cavity 38 and extending to the right side of the steering block 37 is dynamically connected to the right end face of the steering motor 32, a steering block 39 slidably connected to the steering cavity 38 up and down is rotatably connected to an outer circumferential face of one side of the steering shaft 33 located in the steering cavity 38, a steering spring 40 is fixedly connected between an upper end face and a lower end face of the steering block 39 and an upper end face and a lower end face of the steering cavity 38, magnetic blocks 42 are fixedly connected to the right end of the upper end face and the lower end face of the steering block 39, electromagnets 41 corresponding to the magnetic blocks 42 are arranged on the upper and lower walls of the steering cavity 38, a lower bevel gear 35 is fixedly connected to an outer circumferential face of one side of the main shaft 15 located in the transmission cavity 30, and a bevel gear 35 And an upper bevel gear 36 on the upper side, and a steering bevel gear 34 capable of meshing with the lower bevel gear 35 and the upper bevel gear 36 is fixedly connected to the outer circumferential surface of the right-side end of the steering shaft 33.

Beneficially, the suction mechanism 103 includes a lifting motor 58 disposed on the rear wall of the gear cavity 53, a lifting gear shaft 56 rotatably connected to the front wall of the gear cavity 53 is connected to the front end surface of the lifting motor 58, a transmission shaft 57 rotatably connected to the front wall and the rear wall of the gear cavity 53 is located on the lower side of the lifting gear shaft 56, a transmission belt 55 is rotatably connected between the lifting gear shaft 56 and the transmission shaft 57, the lifting gear shaft 56 and the outer circumferential surface of the transmission shaft 57 are fixedly connected to a lifting gear 54 located on the rear side of the transmission belt 55 and engaged with the rack 51, the fan cavity 61 is slidably connected to a sealing plate 60 capable of extending into the sealing slide guide cavity 62 up and down, a top block 59 is fixedly connected to the bottom end of the left end surface of the sealing plate 60, a fan block cavity 67 is disposed in the fan block 63, and a fan motor 66, the left end surface of the fan motor 66 is dynamically connected with a fan shaft 65 extending leftwards to the left side of the fan block 63, and the outer circular surface of the left end of the fan shaft 65 is fixedly connected with a fan 64.

Beneficially, the top end of the guide sliding cavity 27 is fixedly connected with a material blocking filter plate 25 penetrated by the main shaft 15, the filter plate cavity 43 is connected with a filter plate push plate 45 in a left-right sliding manner, the right end face of the filter plate push plate 45 is fixedly connected with a separation filter plate 44, the left end face of the filter plate push plate 45 is fixedly connected with a pull rope 48 penetrated through the pull rope connecting cavity 50 and extended leftwards to be fixedly connected with the top end of the left wall of the pull rope cavity 49, and a filter plate spring 46 positioned on the upper side of the pull rope 48 is fixedly connected between the left end face of the filter plate push plate 45 and the left.

In the initial state, the top end of the right end face of the rack 51 is meshed with the lifting gear 54, the separating block 13 is located at the lower side position, the steering spring 40 is in a relaxed state, the pull rope 48 pulls the filter plate push plate 45 to the left limit position in the spring cavity 47, the through cavity 14 is in a communicated state, the filter plate spring 46 is in a tightened state, and the cutting fluid in the chip cavity 12 does not pass through the separating block 13.

Chips generated by the numerical control machine tool can fall downwards into the chip cavity 12, so that the chips made of lighter materials such as plastics and wood can float on the upper side of the separation block 13 through the buoyancy of cutting fluid, heavier chips such as metal can fall downwards into the lower wall of the chip cavity 12 through the through cavity 14, at the moment, the steering motor 32 is started to drive the steering shaft 33 to rotate, the steering bevel gear 34 is driven to rotate through the rotation of the steering shaft 33, the electromagnets 41 on the upper side and the lower side are alternately started to alternately adsorb the magnetic blocks 42 when the steering motor 32 is started, so that the steering spring 40 is alternately tightened to drive the steering shaft 33 to intermittently reciprocate up and down, the steering bevel gear 34 and the lower bevel gear 35 are driven to be meshed through the vertical reciprocating motion of the steering shaft 33, the upper bevel gear 36 is meshed to drive the main shaft 15 to alternately rotate forward and backward, thereby driving the swinging ring 16 to alternately rotate forward and backward, and, the pushing cavity 19 is pushed to drive the sliding block 18 to slide in a left-right reciprocating manner, the stirring motor 22 is started to drive the motor shaft 23 to rotate, the front stirring wheel 24 and the rear stirring wheel 24 are driven to rotate to stir and disperse the chips which are wound together, the spindle 15 rotates and simultaneously drives the threaded connecting block 26 to reciprocate up and down through threaded connection and sliding guide of the left wall and the right wall of the sliding guide cavity 27, when the threaded connecting block 26 moves downwards, the water drainage cavity 68 is sealed so that water in the chip cavity 12 can be sucked downwards, when the threaded connecting block slides into the communicating cavity 28, the water drainage cavity 68 is communicated with the communicating cavity 28 so that cutting fluid in the chip cavity 12 is flushed into the communicating cavity 28 through the water drainage cavity 68 and is recycled through the circulating cavity 29, when the threaded connecting block 26 moves upwards, the water drainage cavity 68 is sealed so that the cutting fluid on the upper side of the sliding guide cavity 27 is upwards extruded into the chip cavity 12 through pressure, thereby preventing the blocking of the blocking filter plate 25.

After the cutting is finished, the lifting motor 58 is started to drive the lifting gear shaft 56 to rotate, the driving belt 55 is driven to rotate through the rotation of the lifting gear shaft 56, so that the driving shaft 57 is driven to rotate, the lifting gears 54 on the upper side and the lower side are driven to rotate through the rotation of the lifting gear shaft 56, so that the rack 51 is driven to move upwards through meshing, the separation block 13 is driven to move upwards, the top plate 52 is driven to push the top block 59 upwards through the upward movement of the rack 51, so that the sealing plate 60 is driven to slide in the sealed guide sliding cavity 62, so that the cutting cavity 12 is communicated with the fan cavity 61, at the moment, the pull rope 48 is not tensioned through the upward movement of the separation block 13, the separation filter plate 44 is driven to move rightwards through the thrust of the filter plate spring 46, so that the through cavity 14 is sealed, and the mechanism light cutting is left on the, and the cutting fluid flows downwards to the lower side of the separating block 13 through the filtering of the separating filtering plate 44, and then the fan motor 66 is started to drive the fan shaft 65 to rotate, so that the fan 64 is driven to rotate to generate wind power to the right, and therefore light cuttings can be sucked to the right into the fan cavity 61 to be collected.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. The utility model provides a device is stirred in smear metal separation of digit control machine tool, includes the smear metal case, its characterized in that: the cutting box is internally provided with a cutting cavity with an upward opening, the lower wall of the cutting cavity is connected with a sliding block in a left-right sliding mode and is symmetrical in front and back, a pushing cavity which is through is arranged in the sliding block in front and back, the lower wall of the cutting cavity is communicated with a guiding sliding cavity, the lower side of the guiding sliding cavity is provided with a transmission cavity, the lower wall of the transmission cavity is connected with a rotating shaft which runs through the guiding sliding cavity and extends to the main shaft in the cutting cavity in front and back, the main shaft is located on one side of the cutting cavity, an outer circular surface fixedly connected with oscillating ring is arranged on the oscillating ring in front and back, the pushing cavity extends to the front side and the back side respectively, swinging rods on the front side and the back side of the sliding block are arranged, the main shaft is located on one side of the guiding sliding cavity, the upper end face of the threaded connecting block is communicated with downward extending The device comprises communicated symmetrical drainage cavities, the left side and the right side of a sliding guide cavity are communicated and provided with communicated cavities, the rear wall of the communicated cavity is communicated and provided with a circulating cavity extending backwards, the upper wall and the lower wall of a transmission cavity are fixedly connected with steering blocks, the steering blocks are internally provided with steering cavities communicated left and right, a steering mechanism is arranged in the transmission cavity, the left wall of a cutting cavity is connected with a separation block in an up-and-down sliding manner, the separation block is internally provided with a through cavity communicated with a filter plate cavity, the right end face of the separation block is fixedly connected with a rack which is connected with the right wall of the cutting cavity in an up-and-down sliding manner, the top end of the front end face of the rack is fixedly connected with a top plate, the right wall of the cutting cavity is provided with a gear cavity, the right wall of the cutting cavity is communicated and provided with a fan cavity positioned on the upper side of the gear cavity, the upper, the gear intracavity is equipped with upwards to extend to the suction mechanism of fan intracavity, smear metal chamber left wall intercommunication is equipped with the stay cord and connects the chamber, stay cord connection chamber left side intercommunication is equipped with the stay cord chamber.

2. The chip separating and dispersing device of the numerical control machine tool as claimed in claim 1, wherein: reciprocating mechanism includes the motor chamber that is equipped with in the sliding block, motor chamber upper wall is equipped with stirs the motor, it has upwards to extend to stir motor up end power connection to stir the motor shaft of sliding block upside, motor shaft top end fixedly connected with stirs scattered wheel.

3. The chip separating and dispersing device of the numerical control machine tool as claimed in claim 1, wherein: the steering mechanism comprises a motor base which is vertically and slidably connected with the left wall of the transmission cavity, the right end face of the motor base is fixedly connected with a steering motor, the right end face of the steering motor is in power connection with a steering shaft which penetrates through the steering cavity and extends to the right side of the steering block, one outer circular face of one side of the steering shaft, which is positioned in the steering cavity, is rotatably connected with a steering block which is vertically and slidably connected with the steering cavity, steering springs are fixedly connected between the upper end face and the lower end face of the steering block and the upper wall and the lower wall of the steering cavity, the right ends of the upper end face and the lower end face of the steering block are fixedly connected with magnetic blocks, electromagnets corresponding to the magnetic blocks are arranged on the upper wall and the lower wall of the steering cavity, one outer circular face of the main shaft, which is positioned in the transmission cavity, is, and the outer circular surface of the tail end of the right side of the steering shaft is fixedly connected with a steering bevel gear which can be meshed with the lower bevel gear and the upper bevel gear.

4. The chip separating and dispersing device of the numerical control machine tool as claimed in claim 1, wherein: the suction mechanism comprises a lifting motor arranged on the rear wall of the gear cavity, the front end face of the lifting motor is in power connection with a lifting gear shaft which is in rotary connection with the front wall of the gear cavity, the front and rear walls of the gear cavity are in rotary connection with a transmission shaft which is arranged on the lower side of the lifting gear shaft, a transmission belt is in power connection between the lifting gear shaft and the transmission shaft, the lifting gear shaft and the outer circular surface of the transmission shaft are fixedly connected with a lifting gear which is arranged on the rear side of the transmission belt and meshed with the rack, the fan cavity is vertically and slidably connected with a sealing plate which can extend into the sealing and sliding guide cavity, the bottom end of the left end face of the sealing plate is fixedly connected with a top block, a fan block cavity is arranged in the fan block, the right wall of the fan block cavity is provided with, and the outer circular surface of the tail end of the left side of the fan shaft is fixedly connected with a fan.

5. The chip separating and dispersing device of the numerical control machine tool as claimed in claim 1, wherein: the novel filter plate is characterized in that the top end of the guide sliding cavity is fixedly connected with a material blocking filter plate penetrated by the main shaft, the filter plate cavity is connected with a filter plate push plate in a left-right sliding mode, the right end face of the filter plate push plate is fixedly connected with a separation filter plate, the left end face of the filter plate push plate is fixedly connected with a pull rope connecting cavity penetrated by the pull rope connecting cavity and extends leftwards to a pull rope fixedly connected with the top end of the left wall of the pull rope cavity, and a filter plate spring positioned on the upper side of the pull rope is fixedly connected between the left.