CN111300239A - Numerical control turning center based on flexible manufacturing - Google Patents

Abstract

The invention discloses a numerical control turning center based on flexible manufacturing. Has the advantages that: the invention utilizes the cleaning mechanism to prevent the polishing component from being stuck and rotating due to metal chips under the action of lubricating oil permeated by the permeation strip, and simultaneously, under the coordination action of the cleaning component between shafts, the invention effectively scrapes off the redundant metal chips attached to the surface of the polishing component generated by polishing so as to prevent the polishing component from having the rotating load due to the large attachment of the metal chips and oil stains and the polishing part from being widened due to the attachment, thereby causing the inaccurate phenomenon.

Description

Numerical control turning center based on flexible manufacturing

Technical Field

The invention relates to the field of numerical control equipment, in particular to a numerical control turning center based on flexible manufacturing.

Background

The application of mechanical equipment in each field is particularly extensive, the mechanical equipment provides efficient production function for each field, and the mechanical equipment is beneficial and has disadvantages, in the operation process, if the mechanical equipment part is not accurate enough, the whole equipment can be caused to break down, thereby causing unnecessary influence, so in the production of the mechanical equipment, the accurate data of each part needs to be strictly controlled, and when the numerical control turning center is used for production, the mechanical equipment has the following defects:

the oil gas that contains in its air in the workshop is heavier and easy direct attached to the subassembly surface of polishing to form the adhesion of greasy dirt, lead to appearing partial polishing subassembly when rotatory because of the separation of this greasy dirt and unable normal rotation, when it was polished simultaneously, the produced unnecessary metal fillings of part then can be attached to along with this greasy dirt, and the part is under the influence of this metal object, and the part precision that its polished out is inaccurate, leads to unable input into use.

The scraped metal chips are easily taken up again when the equipment is operated, so that the metal chips are attached again to influence the normal grinding of the grinding assembly.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a numerical control turning center based on flexible manufacturing, and aims to solve the problems that in the prior art, oil gas contained in air in a workshop is heavy and is easy to directly adhere to the surface of a grinding assembly, so that oil stains are adhered, the grinding assembly cannot normally rotate due to the obstruction of the oil stains when rotating, meanwhile, redundant metal scraps generated by a part can be adhered along with the oil stains when grinding, the precision of the part ground under the influence of a metal object is inaccurate, the part cannot be put into use, and the scraped metal scraps are easy to be taken up again when equipment runs, so that the adhesion is performed again, and the normal grinding of the grinding assembly is influenced.

In order to achieve the purpose, the invention is realized by the following technical scheme:

the utility model provides a numerical control turning center based on flexible manufacturing, its structure includes equipment main part, drive case, workstation, links up the dish, controller, processing subassembly, the drive case is installed in equipment main part upper surface and is connected through the electric welding, the workstation is installed in equipment main part upper surface middle part and is connected through the electric welding, it locates drive case middle part left side and is connected through the electric welding to link up the dish, the controller is installed on drive case front surface right side and is connected through the electric welding, the processing subassembly is located drive case middle part left side and is connected through the electric welding, the processing subassembly includes the dish of buckleing, the mechanism is stroked down with the fingers to the clear, the structure is received to the collection, the mechanism is located the dish of buckleing the outside and is connected through the electric welding to the clear structure of stroking with the fingers of mechanism and is.

As a further scheme of the invention, the cleaning mechanism comprises an adapter ring, a plurality of penetration strips and a shaft surface cleaning assembly, wherein the penetration strips are arranged on the inner side surface of the adapter ring and are respectively installed on the inner side surface of the adapter ring, the penetration strips are connected with the adapter ring in a penetrating manner through electric welding, twelve shaft surface cleaning assemblies are arranged on the inner side surface of the adapter ring and are respectively arranged above the penetration strips in a uniform and equidistant manner, and the shaft surface cleaning assembly is connected with the adapter ring through electric welding and is connected with the collecting structure.

As a further scheme of the invention, the connecting ring is internally provided with lubricating oil and is connected with the penetrating strip, so that the phenomena of clamping a shell and rotating and blocking a grinding assembly due to metal chips are avoided.

As a further scheme of the invention, the axial surface cleaning component comprises a connecting rod, movable buckles, arc-stroking knots and supporting wires, wherein the tail end of the connecting rod is connected with the collecting structure, the movable buckles are connected with the connecting rod in a sleeved mode, the two arc-stroking knots are respectively connected with the movable buckles in a symmetrical structure, the two supporting wires are respectively connected with the arc-stroking knots, the other end of each supporting wire is connected with the collecting structure, and therefore the axial surface cleaning component is beneficial to preventing a large number of solids from adhering to the surface of the polishing component and increasing the polishing operation load of the polishing component.

According to a further scheme of the invention, the connecting rods comprise a rotating disk, hollow rods and leakage frame magnetic rods, the rotating disk is connected with the collecting structure through electric welding, the hollow rods are arranged on the upper surface of the rotating disk and are connected through electric welding, the leakage frames are provided with five leakage frames which are uniformly and equidistantly arranged, the leakage frames and the hollow rods are of an integrated structure, and the magnetic rods are arranged inside the hollow rods and are connected with the collecting structure through electric welding.

As a further scheme of the invention, the surface of the arc smoothing knot is of a rough structure and is an insulator, so that metal chips and oil stains attached to the surface of a grinding component can be scraped, and grinding of enlarging and widening the grinding component caused by the solid is avoided.

According to a further scheme of the invention, the collecting and accommodating structure comprises a connecting frame, a shaking belt and a collecting and accommodating cavity, wherein the inner side surface of the connecting frame is connected with the rotating disk, the shaking belt is arranged inside the connecting frame, the surface of the shaking belt is connected with the magnetic rod through electric welding, and the collecting and accommodating cavity is arranged outside the inner side of the connecting frame and is of an integrated structure, so that the situation that metal chips do a shell clamping gap effect on the grinding assembly and further the normal operation cannot be carried out is favorably realized.

As a further scheme of the invention, the airflow in the collecting cavity is in an adsorption structure, which is beneficial to realizing the centralized treatment of the metal chips.

Advantageous effects of the invention

Compared with the traditional numerical control turning center based on flexible manufacturing, the invention has the following beneficial effects:

the invention utilizes the cleaning mechanism to be beneficial to avoiding the phenomenon that the grinding component is blocked and rotationally blocked due to metal chips under the action of lubricating oil permeated by the permeation strip, and effectively scrapes off the redundant metal chips attached to the surface of the grinding component under the coordination action of the cleaning component between the shafts so as to avoid the inaccurate phenomenon caused by the rotation load of the grinding component due to the large attachment of the metal chips and oil stains and the enlarged and widened grinding of grinding parts due to the attachment.

According to the invention, the collecting structure is adopted to further collect and treat the metal chips generated during polishing in a centralized manner, so that the metal chips are prevented from clamping the shell gap of the polishing assembly and further failing to operate normally.

Drawings

Other features, objects and advantages of the invention will become more apparent from a reading of the detailed description of non-limiting embodiments with reference to the attached drawings.

In the drawings:

FIG. 1 is a schematic structural diagram of a numerical control turning center based on flexible manufacturing.

FIG. 2 is a schematic front view of a processing assembly according to the present invention.

Fig. 3 is a front structural schematic view of the cleaning mechanism of the present invention.

FIG. 4 is an enlarged view of the axial cleaning assembly of the present invention.

FIG. 5 is a front view of the inner structure of the joint rod of the present invention.

FIG. 6 is a schematic view of the front view of the inner structure of the present invention.

In the figure: the device comprises a device body-1, a driving box-2, a workbench-3, a connecting disc-4, a controller-5, a processing assembly-6, a button disc-6 a, a clearing mechanism-6 b, a collecting structure-6 c, a connecting ring-6 b1, a penetrating strip-6 b2, a shaft surface cleaning assembly-6 b3, a connecting rod-6 b31, a movable button-6 b32, a smoothing arc knot-6 b33, a supporting line-6 b34, a rotating disc-g 1, a hollow rod-g 2, a leakage frame-g 3 magnetic rod-g 4, a connecting frame-6 c1, a shaking belt-6 c2 and a collecting cavity-6 c 3.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

The first embodiment:

as shown in fig. 1 to 5, the present invention provides a technical solution of a numerical control turning center based on flexible manufacturing:

as shown in fig. 1-2, a numerical control turning center based on flexible manufacturing comprises an apparatus body 1, a driving box 2, a workbench 3, a connecting disc 4, a controller 5, a processing assembly 6, the driving box 2 is arranged on the upper surface of the equipment main body 1 and is connected with the upper surface of the equipment main body 1 through electric welding, the workbench 3 is arranged in the middle of the upper surface of the equipment main body 1 and is connected with the upper surface of the equipment main body through electric welding, the connecting disc 4 is arranged on the left side of the middle part of the driving box 2 and is connected with the driving box by electric welding, the controller 5 is arranged on the right side of the front surface of the driving box 2 and is connected with the driving box by electric welding, the processing component 6 is arranged on the left side of the middle part of the driving box 2 and is connected with the driving box through electric welding, the processing component 6 comprises a buckle disc 6a, a cleaning mechanism 6b and a collecting structure 6c, the cleaning mechanism 6b is arranged on the outer side of the buckle disk 6a and connected through electric welding, and the collecting structure 6c is arranged on the outer surface of the cleaning mechanism 6b and connected through electric welding.

As shown in fig. 3, the cleaning mechanism 6b includes an adaptor ring 6b1, a penetration strip 6b2, and a shaft surface cleaning assembly 6b3, the penetration strip 6b2 is provided with a plurality of strips and is respectively installed on the inner side surface of the adaptor ring 6b1, the penetration strip 6b2 and the adaptor ring 6b1 are connected through electric welding, the shaft surface cleaning assembly 6b3 is provided with twelve strips and is respectively provided on the inner side surface of the adaptor ring 6b1 in a uniform and equidistant manner and is located above the penetration strip 6b2, and the shaft surface cleaning assembly 6b3 and the adaptor ring 6b1 are connected through electric welding and is connected with the collecting structure 6 c.

As shown in fig. 3, the inside of the joint ring 6b1 is provided with lubricating oil and connected with the penetrating strip 6b2, which is beneficial to preventing the grinding assembly from being jammed due to metal chips.

As shown in fig. 4, the axial surface cleaning assembly 6b3 includes an attachment rod 6b31, a movable buckle 6b32, an arc-smoothing knot 6b33, and a support wire 6b34, the end of the attachment rod 6b31 is connected to the collecting structure 6c, the movable buckle 6b32 is connected to the attachment rod 6b31 by means of a socket, two arc-smoothing knots 6b33 are provided and are respectively connected to the movable buckle 6b32 in a symmetrical structure, two support wires 6b34 are provided and are respectively connected to the arc-smoothing knot 6b33, and the other end of each support wire is connected to the collecting structure 6c, which is beneficial to preventing a large amount of solid objects from adhering to the surface of the polishing assembly and increasing the load of the polishing operation of the polishing assembly.

As shown in fig. 4-5, the joint rod 6b31 includes a rotating disk g1, a hollow rod g2, and a leakage frame g3 magnetic rod g4, the rotating disk g1 is connected with the collecting structure 6c by electric welding, the hollow rod g2 is disposed on the upper surface of the rotating disk g1 and connected by electric welding, the leakage frame g3 is provided with five frames and respectively installed in a uniform and equidistant manner, the leakage frame g3 and the hollow rod g2 are integrated, and the magnetic rod g4 is disposed inside the hollow rod g2 and connected with the collecting structure 6c by electric welding.

As shown in fig. 4, the surface of the arc smoothing knot 6b33 is a rough structure and is an insulator, which is beneficial to scraping metal chips and oil stains attached to the surface of the grinding component, and avoids grinding parts to be widened due to the solid.

In conclusion, the axial surface cleaning assembly 6b3 and the penetration strip 6b2 are matched with each other, so that oil stains and metal chips attached to the surface of the grinding assembly are scraped, the load force of the surface of the grinding assembly is reduced, and the grinding of the machined part with inaccurate precision is avoided.

The specific realization principle is as follows: when using, the oil gas that contains in its air in the workshop is heavier and easy direct attached to the subassembly surface of polishing to form the adhesion of greasy dirt, lead to appearing the subassembly of polishing of part and can't normal rotation because of the separation of this greasy dirt when rotatory, when it was polished simultaneously, the produced unnecessary metal fillings of part then can be attached to along with this greasy dirt, and the part is under the influence of this metallics, and the part precision that it was polished out is inaccurate, leads to unable input use.

Therefore, by means of the arranged smoothing-out knot 6b33 and the connection of the supporting wire 6b34 and the containing structure 6c, under the action of vibration, the supporting wire 6b34 pulls the smoothing-out knot 6b33 to stretch and contract, oil stains and metal objects attached to the surface of the grinding assembly are scraped, under the cooperation effect of the magnetic rod g4, the scraped metal objects are magnetically adsorbed on the surface of the magnetic rod g4 through the leakage frame g3, and the situation that the scraped metal objects are scattered for multiple times and affect the normal grinding treatment of the parts is avoided.

And because of its attached place still has the residue after the greasy dirt is scraped off, and the subassembly of polishing is when doing rotary motion, because of the difficult rotation that can rotate of attaching to of this greasy dirt to the rotational resistance effect has, so under the effect of infiltration strip 6b2, to this position input lubricating oil, and then its rotation action with higher speed, avoid having the phenomenon that the card is pause now.

The embodiment aims to solve the problems that oil gas contained in air in a workshop is heavy and is easy to directly adhere to the surface of a grinding assembly, so that oil stains are adhered to the surface of the grinding assembly, the grinding assembly cannot normally rotate due to the obstruction of the oil stains when rotating, and meanwhile, redundant metal chips generated by parts are adhered to the oil stains when grinding the parts, so that the parts cannot be put into use due to the fact that the precision of the ground parts is not accurate under the influence of the metal objects, so that the cleaning mechanism is utilized to effectively scrape the redundant metal chips adhered to the surface of the grinding assembly due to grinding under the action of lubricating oil permeated by a permeating strip, so that the grinding assembly is prevented from being stuck and blocked due to the metal chips, and the existing rotary load of the grinding assembly due to the adhesion of the metal chips and the oil stains is avoided, and polishing that causes enlargement and widening of a polished part due to the attachment, resulting in an inaccurate phenomenon.

Second embodiment:

as shown in fig. 1, 2 and 6, the invention provides a technical scheme of a numerical control turning center based on flexible manufacturing, which comprises the following steps:

as shown in fig. 1-2, a numerical control turning center based on flexible manufacturing comprises an apparatus body 1, a driving box 2, a workbench 3, a connecting disc 4, a controller 5, a processing assembly 6, the driving box 2 is arranged on the upper surface of the equipment main body 1 and is connected with the upper surface of the equipment main body 1 through electric welding, the workbench 3 is arranged in the middle of the upper surface of the equipment main body 1 and is connected with the upper surface of the equipment main body through electric welding, the connecting disc 4 is arranged on the left side of the middle part of the driving box 2 and is connected with the driving box by electric welding, the controller 5 is arranged on the right side of the front surface of the driving box 2 and is connected with the driving box by electric welding, the processing component 6 is arranged on the left side of the middle part of the driving box 2 and is connected with the driving box through electric welding, the processing component 6 comprises a buckle disc 6a, a cleaning mechanism 6b and a collecting structure 6c, the cleaning mechanism 6b is arranged on the outer side of the buckle disk 6a and connected through electric welding, and the collecting structure 6c is arranged on the outer surface of the cleaning mechanism 6b and connected through electric welding.

As shown in fig. 6, the storage structure 6c includes a connection frame 6c1, a shaking belt 6c2 and a storage cavity 6c3, the inner side surface of the connection frame 6c1 is connected with a rotation disc g1, the shaking belt 6c2 is arranged inside the connection frame 6c1, the surface of the shaking belt 6c2 is connected with the magnetic rod g4 through electric welding, and the storage cavity 6c3 is arranged outside the inner side of the connection frame 6c1 and is of an integrated structure, so that the situation that metal chips do not block a housing gap on the grinding assembly and normal operation cannot be performed is facilitated.

As shown in fig. 6, the air flow inside the collecting cavity 6c3 is in an adsorption structure, which is beneficial to the centralized treatment of the metal chips.

In conclusion, through the collection structure 6c that is equipped with, further concentrated collection processing is done to greasy dirt and the metal fillings after scraping to avoid it to cause the adnexed influence of card pause again to the subassembly of polishing.

The specific realization principle is as follows: the scraped metal chips are easily taken up again when the equipment is operated, so that the metal chips are attached again to influence the normal grinding of the grinding assembly.

Therefore, the collecting structure 6c is connected with the collecting cavity 6b3, so that the scraped metal chips are absorbed by the airflow in the collecting cavity 6b3 under the action of adsorption, and the scraped metal chips are collected and processed in a centralized manner.

In the embodiment, in order to solve the problem that the scraped metal chips are easily taken up again when equipment runs, so that the metal chips are attached again to influence the normal grinding of the grinding assembly, the metal chips generated during grinding are further collected and processed in a concentrated manner by utilizing the collecting and accommodating structure, and the situation that the metal chips clamp a shell gap of the grinding assembly and cannot run normally is avoided.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (8)

1. The utility model provides a numerical control turning machining center based on flexible manufacturing, its structure includes equipment main part (1), drive case (2), workstation (3), links up flange (4), controller (5), processing subassembly (6), its characterized in that: the driving box (2) is installed on the upper surface of the equipment main body (1) and connected through electric welding, the workbench (3) is installed in the middle of the upper surface of the equipment main body (1) and connected through electric welding, the connecting disc (4) is arranged on the left side of the middle of the driving box (2) and connected through electric welding, the controller (5) is installed on the right side of the front surface of the driving box (2) and connected through electric welding, and the machining assembly (6) is arranged on the left side of the middle of the driving box (2) and connected through electric welding;

the machining assembly (6) comprises a button disk (6a), a clearing mechanism (6b) and a collecting structure (6c), the clearing mechanism (6b) is arranged on the outer side of the button disk (6a) and connected through electric welding, and the collecting structure (6c) is installed on the outer surface of the clearing mechanism (6b) and connected through electric welding.

2. The numerical control turning center based on flexible manufacturing according to claim 1, characterized in that: clear with fingers mechanism (6b) including linking up ring (6b1), infiltration strip (6b2), clean subassembly of axial plane (6b3), infiltration strip (6b2) are equipped with a plurality of and install respectively in linking up ring (6b1) inboard surface, infiltration strip (6b2) and link up ring (6b1) are run through the electric welding and are connected, clean subassembly of axial plane (6b3) are equipped with twelve altogether and are even equidistance form respectively and locate linking up ring (6b1) inboard surface and lie in infiltration strip (6b2) top, clean subassembly of axial plane (6b3) is connected and is connected through the electric welding with linking up ring (6b1) and with collection and receive structure (6 c).

3. The numerical control turning center based on flexible manufacturing according to claim 2, characterized in that: the inside of the connecting ring (6b1) is provided with lubricating oil and is connected with the penetrating strip (6b 2).

4. The numerical control turning center based on flexible manufacturing according to claim 2, characterized in that: clean subassembly of axial plane (6b3) is detained (6b32), is smoothed out the arc including linking pole (6b31), activity and binds (6b33), support line (6b34), linking pole (6b31) end is connected with collection and receives structure (6c), activity is detained (6b32) and is connected through the registrate with linking pole (6b31), it is connected with activity knot (6b32) to smooth out the arc to bind (6b33) be equipped with two altogether and be the symmetric structure respectively and be connected, support line (6b34) are equipped with two altogether and are connected with smoothing out the arc respectively and bind (6b33) and the other end is connected with collection and receive structure (6 c).

5. The numerical control turning center based on flexible manufacturing according to claim 4, characterized in that: the joint rod (6b31) comprises a rotating disk (g1), a hollow rod (g2), a leakage frame (g3) and a magnetic rod (g4), the rotating disk (g1) is connected with the collecting structure (6c) through electric welding, the hollow rod (g2) is arranged on the upper surface of the rotating disk (g1) and connected through electric welding, the leakage frame (g3) is provided with five parts and is installed in an even and equidistant mode respectively, the leakage frame (g3) and the hollow rod (g2) are of an integrated structure, and the magnetic rod (g4) is arranged inside the hollow rod (g2) and is connected with the collecting structure (6c) through electric welding.

6. The numerical control turning center based on flexible manufacturing according to claim 4, characterized in that: the surface of the arc smoothing knot (6b33) is of a rough structure and is an insulator.

7. A numerically controlled turning center based on flexible manufacturing according to claim 1 or 5, characterized in that: the collecting structure (6c) comprises a connecting frame (6c1), a shaking belt (6c2) and a collecting cavity (6c3), wherein the inner side surface of the connecting frame (6c1) is connected with a rotating disk (g1), the shaking belt (6c2) is arranged inside the connecting frame (6c1), the surface of the shaking belt (6c2) is connected with a magnetic rod (g4) through electric welding, and the collecting cavity (6c3) is arranged on the inner outer side of the connecting frame (6c1) and is of an integrated structure.

8. The numerical control turning center based on flexible manufacturing according to claim 7, characterized in that: the air flow inside the collecting cavity (6c3) is in an adsorption structure.

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