CN223277232U - Saw cutting machine milling structure - Google Patents

Abstract

The utility model relates to a sawing machine milling structure, belonging to the field of sawing machines. The sawing machine milling structure includes: a first support member; a first movable assembly, the first movable assembly is arranged on the first support member, and the first movable assembly is at least partially movable relative to the first support member in a first direction and a second direction, the first direction and the second direction being opposite; a second movable assembly, the second movable assembly is arranged on the first movable assembly, and the second movable assembly is at least partially movable relative to the first movable assembly in a third direction and a fourth direction, the third direction and the fourth direction being opposite; a milling assembly, the milling assembly is arranged on the second movable assembly, and the milling assembly is used for milling profiles. The sawing machine milling structure disclosed in this application enables precise movement in multiple directions through the arrangement of the first movable assembly and the second movable assembly, thereby meeting the complex processing requirements of profiles.

Description

Milling structure of sawing machine

Technical Field

The utility model relates to the field of sawing machines, in particular to a sawing machine milling structure.

Background

In modern manufacturing industry, sawing machine is a common and important mechanical device and is widely applied to the fields of metal processing, profile processing and the like. The milling structure is an important component part of the sawing machine and can mill the section bar. However, the conventional milling structure is not flexible enough, so that the milling cutter of the milling structure is limited in movement in certain directions, and the requirement of complex processing cannot be met.

Disclosure of utility model

Based on this, it is necessary to provide a sawing machine milling structure for the problem that the milling cutter of the conventional milling structure is limited in movement in certain directions and cannot meet the requirement of complex machining.

The sawing machine milling structure comprises a first supporting piece, a first moving component and a milling component, wherein the first moving component is arranged on the first supporting piece and can move at least partially towards a first direction and a second direction relative to the first supporting piece, the first direction is opposite to the second direction, the second moving component is arranged on the first moving component and can move at least partially towards a third direction and a fourth direction relative to the first moving component, the third direction is opposite to the fourth direction, the milling component is arranged on the second moving component, and the milling component is used for milling materials of profiles.

The application discloses a sawing machine milling structure, which enables the product to accurately move in multiple directions through the arrangement of a first moving assembly and a second moving assembly. The design greatly improves the flexibility and the positioning precision in the processing process, ensures the accuracy of milling operation, and can meet the complex processing requirement of the profile. And the independent control of the first moving assembly and the second moving assembly enables the milling assembly to process curves or other complex shapes on the profile, so that high-precision processing is realized. The sawing machine milling structure disclosed by the application is not only suitable for processing the sectional materials with standard shapes, but also suitable for workpieces with various complex shapes and non-standard sizes by automatically adjusting the moving path and the speed, and is worthy of popularization.

In one embodiment, the first moving component comprises a first driving piece, a first moving piece and a second supporting piece, the first driving piece is arranged on the first supporting piece, the first moving piece is movably arranged on the first supporting piece, the first moving piece is in transmission connection with the first driving piece, the first driving piece can drive the first moving piece to move towards the first direction and the second direction relative to the first supporting piece, the second supporting piece is arranged on the first moving piece, and the second moving component is arranged on the second supporting piece. The second support member is arranged on the first movable member, so that stable support is provided for the second movable assembly. This design enables the second moving assembly to slide stably along a predetermined direction. The power of the first driving piece can be timely transmitted to the first movable piece through the transmission connection between the first driving piece and the first movable piece, so that the efficiency and the response speed of power transmission are improved, the first movable piece can rapidly move, and meanwhile, the accuracy and the stability of movement are guaranteed.

In one embodiment, the first driving member includes a first driving motor, a coupling, a first rotating shaft and a first screw nut, the first driving motor is disposed on the first supporting member, the coupling is connected with an output shaft of the first driving motor and the first rotating shaft respectively, the first driving motor can drive the first rotating shaft to rotate relative to the first supporting member, the first screw nut is movably sleeved on the first rotating shaft, the first screw nut can move relative to the first rotating shaft, and the first screw nut is connected with the first movable member. The rotation of the first driving motor can be accurately controlled to convert rotary motion into linear motion, so that the first screw nut can be stably and accurately moved, the first movable piece is controlled to accurately move, and the stability and the accuracy of the machining process are ensured. The output shaft of the first motor and the first rotating shaft are more firmly and stably connected through the arrangement of the coupler.

In one embodiment, the first movable member includes a first movable plate and a plurality of sliders, the first movable plate is connected with the first driving member, the plurality of sliders are all disposed on the first movable plate and located on the same side of the first movable plate, the plurality of sliders are all movably connected with the first supporting member, and the first driving member can drive the first movable plate and the plurality of sliders to move relative to the first supporting member in the first direction and the second direction. And a plurality of sliding blocks form multipoint contact between the first movable plate and the first supporting piece, so that the load is effectively dispersed, and the stability and the precision of movement are improved. And the sliding block is tightly matched with the first supporting piece, so that derailment caused by unexpected conditions is effectively prevented, and the safety of equipment is improved.

In one embodiment, the second supporting member includes a second supporting frame and a second sliding rail, the second supporting frame is disposed on the first movable member, the number of the second sliding rails is multiple, the multiple second sliding rails are all disposed on the second supporting frame and located on the same side of the second supporting frame, and the second moving component is movably disposed on the second sliding rail and can slide on the second sliding rail. The second movable assembly is provided with stable support through the arrangement of the second supporting frame. The second moving assembly can stably slide on the second sliding rail through the arrangement of the second sliding rails, so that friction resistance in a moving process is reduced, stability and efficiency of movement are improved, and maintenance frequency and cost are reduced.

In one embodiment, the second moving component includes a second driving element and a second moving element, the second driving element is disposed on the first moving component, the second moving element is movably disposed on the first moving component, the second moving element is in transmission connection with the second driving element, and the second driving element can drive the second moving element to move towards the third direction and the fourth direction relative to the first moving component. The second movable part can be driven to move in the third direction and the fourth direction through the arrangement of the second driving part, and the milling component is more flexible in the processing process due to the bidirectional movement capability, so that the milling component can meet various complex processing requirements.

In one embodiment, the second driving part comprises a power source part, a second rotating shaft and a second screw nut, the power source part is arranged on the first moving assembly, the second rotating shaft is in transmission connection with the power source part, the power source part can drive the second rotating shaft to rotate relative to the first moving assembly, the second screw nut is movably sleeved on the second rotating shaft, the second screw nut can move relative to the second rotating shaft, and the second screw nut is connected with the second moving part. The second rotating shaft is directly driven by the power source part, so that intermediate transmission links are reduced, and the efficiency and response speed of power transmission are improved. And the stable and accurate movement of the second screw nut can be realized, so that the accurate movement of the second movable part is controlled, and the stability and the accuracy of the milling component in the processing process are ensured.

In one embodiment, the power source piece comprises a first supporting seat, a second driving motor, a driving wheel, a driven wheel, a connecting belt and a belt cover, wherein the first supporting seat is arranged on the first moving assembly, the second driving motor and the driving wheel are both arranged on the first supporting seat, an output shaft of the second driving motor penetrates through the first supporting seat and then is in transmission connection with the driving wheel, the driven wheel is in transmission connection with the second rotating shaft, the connecting belt is wound on the driving wheel and the driven wheel, the belt cover is arranged on the first supporting seat and is positioned on the side part of the first supporting seat, and the driving wheel, the driven wheel and the connecting belt are positioned in a space formed by encircling the belt cover and the first supporting seat. The driving wheel is directly driven by the second driving motor, power is transmitted to the driven wheel by the connecting belt, and the second rotating shaft is driven, so that the accuracy and stability of power transmission can be effectively improved. The second driving motor is stably supported through the arrangement of the first supporting seat. Through the arrangement of the belt cover, operators are effectively prevented from contacting with the transmission part which runs at high speed, potential safety hazards are reduced, and safety of equipment is improved.

In one embodiment, the device further comprises a second supporting seat, the second supporting seat is arranged on the first moving assembly, the second rotating shaft penetrates through the second supporting seat, and the second rotating shaft penetrates through the second supporting seat and then is connected with the power source part. The second supporting seat provides an additional supporting point for the second rotating shaft, so that the stability of the whole transmission system is enhanced.

In one embodiment, the milling component comprises a third driving piece, a milling piece and a connecting rod component, the third driving piece and the milling piece are both arranged on the second moving component, the third driving piece and the milling piece are respectively positioned on two sides of the second moving component, the milling piece can rotate relative to the second moving component, the second moving component is provided with a first perforation, the connecting rod component is arranged in the first perforation in a penetrating way, the connecting rod component can move at the first perforation, and two ends of the connecting rod component are respectively connected with the third driving piece and the milling piece. The connecting rod assembly can be driven to move at the first perforation through the third driving piece, so that the milling piece rotates relative to the second moving assembly, the milling angle is adjusted, and the power transmission efficiency is high. The milling part can rotate relative to the second moving assembly, so that multi-angle and multi-azimuth accurate milling of the workpiece is realized, and the processing flexibility is greatly improved. The milling part can process curves or other complex shapes on the profile, and the applicability of the equipment is improved.

In one embodiment, the first perforation is arcuate. The first through hole is arc-shaped, so that the connecting rod assembly moves along a fixed track, the milling part can freely rotate in a larger angle range, the precise milling of multiple angles and complex shapes of a workpiece is realized, and the processing flexibility is remarkably improved.

In one embodiment, the second moving assembly is provided with a second through hole, and the milling part is matched with the second through hole. Through milling material spare and the adaptation of second perforation, the fastness of milling material spare assembly is good. And milling material spare rotates in a flexible way at different angles, adapts to the processing demand of complicated shape and multi-angle, has shown the flexibility that has promoted processing.

In one embodiment, the third driving member includes a supporting plate, a rotating cylinder and a first connecting shaft, the supporting plate is disposed on the second moving assembly, the rotating cylinder is located between the supporting plate and the second moving assembly, the first connecting shaft penetrates through the supporting plate and the rotating cylinder, and the first connecting shaft penetrates through the supporting plate and the rotating cylinder in sequence and then is connected with the second moving assembly. The rotary cylinder is penetrated through the first connecting shaft, and the rotary cylinder can be supported by the first connecting shaft, so that the rotary cylinder rotates by taking the first connecting shaft as the center, and the rotary cylinder rotates more stably.

In one embodiment, the milling part comprises a milling part body, a support plate and a second connecting shaft, the second connecting shaft penetrates through the second moving assembly, the support plate is arranged on the second connecting shaft and is connected with the connecting rod assembly, the connecting rod assembly drives the support plate to rotate relative to the second moving assembly, and the milling part body is arranged on the support plate. The support plate is driven to rotate through the connecting rod assembly, accurate control of the milling part body is achieved, and stability and accuracy of a machining process are guaranteed. The second through hole of second movable assembly is worn to locate through the second connecting axle to provide stable support basis for milling material piece body.

In one embodiment, the connecting rod assembly comprises a first connecting rod and a second connecting rod, the first connecting rod is connected with the third driving piece and the second connecting rod respectively, and the second connecting rod is connected with the milling piece. The relative positions between the first connecting rod and the second connecting rod are adjusted through the third driving piece, so that machining of milling pieces at different angles can be realized, and the flexibility of the equipment is enhanced.

In one embodiment, the first supporting member includes a first supporting frame and a first sliding rail, the number of the first sliding rails is multiple, the multiple first sliding rails are all disposed on the first supporting frame and located on the same side of the first supporting frame, and the first moving component is at least partially movably disposed on the first sliding rail and can slide on the first sliding rail. The first movable assembly is provided with stable support through the arrangement of the first supporting frame. The first moving assembly can stably slide on the first sliding rail through the arrangement of the plurality of first sliding rails, so that friction resistance in a moving process is reduced, stability and efficiency of movement are improved, and maintenance frequency and cost are reduced.

Drawings

FIG. 1 is a first perspective view of a sawing machine milling structure;

FIG. 2 is a second perspective view of a saw milling structure;

FIG. 3 is an exploded view of a saw cutting machine milling structure;

FIG. 4 is a first perspective view of the first mobile assembly;

FIG. 5 is a second perspective view of the first mobile assembly;

FIG. 6 is an exploded view of the first mobile assembly;

FIG. 7 is a perspective view of a second movement assembly;

FIG. 8 is an exploded view of the second mobile assembly;

FIG. 9 is an exploded view of the second driver;

FIG. 10 is an exploded view of the milling assembly;

fig. 11 is a perspective view of the first support.

Wherein, the correspondence between the reference numerals and the component names is:

1a first supporting piece, 11 a first supporting frame and 12 a first sliding rail;

The first moving assembly comprises a first moving assembly, a first driving piece, a first driving motor, a coupling, a first rotating shaft, a first screw nut, a first moving piece, a first movable plate, a first sliding block, a second supporting piece, a second supporting frame and a second sliding rail, wherein the first moving assembly, the first driving piece, the first driving motor, the coupling, the first rotating shaft, the first screw nut, the first moving piece, the first movable plate, the first sliding block, the second supporting piece, the second supporting frame and the second sliding rail are respectively arranged;

The second moving assembly comprises a second moving assembly, a second driving piece 31, a power source piece 311, a first support seat 3111, a second driving motor 3112, a driving wheel 3113, a driven wheel 3114, a connecting belt 3115, a belt cover 3116, a second support seat 3117, a second rotating shaft 312, a second lead screw nut 313, a second movable piece 32, a first through hole 301 and a second through hole 302;

4 mill material subassembly, 41 third driving piece, 411 supporting plate piece, 412 revolving cylinder, 413 first connecting axle, 42 mill material piece, 421 mill material piece body, 422 backup pad, 423 second connecting axle, 43 connecting rod subassembly, 431 first connecting rod, 432 second connecting rod.

Detailed Description

In order that the above-recited objects, features and advantages of the present utility model will be more clearly understood, a more particular description of the utility model will be rendered by reference to the appended drawings and appended detailed description. It should be noted that, without conflict, the embodiments of the present utility model and features in the embodiments may be combined with each other.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present utility model, but the present utility model may be practiced in other ways than those described herein, and therefore the scope of the present utility model is not limited to the specific embodiments disclosed below.

As shown in fig. 1-3, the embodiment discloses a sawing machine milling structure, which comprises a first supporting piece 1, a first moving component 2, a milling component 4 and a second moving component 3, wherein the first moving component 2 is arranged on the first supporting piece 1, the first moving component 2 can move at least partially towards a first direction and a second direction relative to the first supporting piece 1, the first direction is opposite to the second direction, the second moving component 3 is arranged on the first moving component 2, the second moving component 3 can move at least partially towards a third direction and a fourth direction relative to the first moving component 2, the third direction is opposite to the fourth direction, and the milling component 4 is arranged on the second moving component 3, and is used for milling materials of profiles.

The application discloses a sawing machine milling structure, which enables the product to realize accurate movement in multiple directions through the arrangement of a first moving assembly 2 and a second moving assembly 3. The design greatly improves the flexibility and the positioning precision in the processing process, ensures the accuracy of milling operation, and can meet the complex processing requirement of the profile. The independent control of the first moving assembly 2 and the second moving assembly 3 enables the milling assembly 4 to process curves or other complex shapes on the profile, so that high-precision processing is realized. The sawing machine milling structure disclosed by the application is not only suitable for processing the sectional materials with standard shapes, but also suitable for workpieces with various complex shapes and non-standard sizes by automatically adjusting the moving path and the speed, and is worthy of popularization.

As shown in fig. 4 and 5, in addition to the features of the above embodiment, the present embodiment further defines that the first moving assembly 2 includes a first driving member 21, a first movable member 22 and a second supporting member 23, the first driving member 21 is disposed on the first supporting member 1, the first movable member 22 is movably disposed on the first supporting member 1, the first movable member 22 is in driving connection with the first driving member 21, the first driving member 21 is capable of driving the first movable member 22 to move relative to the first supporting member 1 in the first direction and the second direction, the second supporting member 23 is disposed on the first movable member 22, and the second moving assembly 3 is disposed on the second supporting member 23. The second moving assembly 3 is provided with a stable support by providing the second support 23 on the first movable member 22. This design enables a stable sliding of the second moving assembly 3 along a predetermined direction. The power of the first driving piece 21 can be timely transmitted to the first movable piece 22 through the transmission connection between the first driving piece 21 and the first movable piece 22, so that the efficiency and the response speed of power transmission are improved, the first movable piece 22 can rapidly move, and meanwhile, the accuracy and the stability of movement are ensured.

As shown in fig. 6, in addition to the features of the foregoing embodiment, the present embodiment further defines that the first driving member 21 includes a first driving motor 211, a coupling 212, a first shaft 213, and a first screw nut 214, where the first driving motor 211 is disposed on the first supporting member 1, the coupling 212 is respectively connected to an output shaft of the first driving motor 211 and the first shaft 213, the first driving motor 211 can drive the first shaft 213 to rotate relative to the first supporting member 1, the first screw nut 214 is movably sleeved on the first shaft 213, the first screw nut 214 can move relative to the first shaft 213, and the first screw nut 214 is connected to the first movable member 22. The rotation motion can be converted into the linear motion by precisely controlling the rotation of the first driving motor 211, so that the stable and precise movement of the first screw nut 214 is realized, thereby controlling the precise movement of the first movable member 22, and ensuring the stability and precision of the processing process. The output shaft of the first motor and the first rotation shaft 213 are more firmly and stably connected by the coupling 212.

As shown in fig. 6, in addition to the features of the foregoing embodiment, the present embodiment further defines that the first movable member 22 includes a first movable plate 221 and a plurality of sliders 222, the first movable plate 221 is connected to the first driving member 21, the plurality of sliders 222 are disposed on the first movable plate 221 and located on the same side of the first movable plate 221, the plurality of sliders 222 are movably connected to the first supporting member 1, and the first driving member 21 is capable of driving the first movable plate 221 and the plurality of sliders 222 to move in the first direction and the second direction relative to the first supporting member 1. By the plurality of sliders 222 forming multipoint contact between the first movable plate 221 and the first support 1, the load is effectively dispersed, thereby improving the smoothness and accuracy of movement. And the sliding block 222 is tightly matched with the first supporting piece 1, so that derailment caused by unexpected situations is effectively prevented, and the safety of equipment is improved.

As shown in fig. 6, in addition to the features of the foregoing embodiment, the present embodiment further defines that the second supporting member 23 includes a second supporting frame 231 and a second sliding rail 232, the second supporting frame 231 is disposed on the first movable member 22, the number of the second sliding rails 232 is plural, the plural second sliding rails 232 are disposed on the second supporting frame 231 and located on the same side of the second supporting frame 231, and the second moving assembly 3 is movably disposed on the second sliding rail 232 and capable of sliding on the second sliding rail 232. The second moving assembly 3 is provided with stable support by the provision of the second supporting frame 231. The second moving assembly 3 can stably slide on the second sliding rail 232 through the arrangement of the second sliding rails 232, so that friction resistance in the moving process is reduced, the stability and efficiency of movement are improved, and the maintenance frequency and cost are reduced.

As shown in fig. 7 and 8, in addition to the features of the above embodiment, the present embodiment further defines that the second moving assembly 3 includes a second driving member 31 and a second movable member 32, where the second driving member 31 is disposed on the first moving assembly 2, the second movable member 32 is movably disposed on the first moving assembly 2, the second movable member 32 is in driving connection with the second driving member 31, and the second driving member 31 is capable of driving the second movable member 32 to move relative to the first moving assembly 2 in the third direction and the fourth direction. The second driving part 31 can drive the second movable part 32 to move in the third direction and the fourth direction, and the two-way movement capability enables the milling assembly 4 to be more flexible in the processing process and can adapt to various complex processing requirements.

As shown in fig. 8, in addition to the features of the foregoing embodiment, the present embodiment further defines that the second driving member 31 includes a power source member 311, a second rotating shaft 312 and a second screw nut 313, where the power source member 311 is disposed on the first moving assembly 2, the second rotating shaft 312 is in transmission connection with the power source member 311, the power source member 311 can drive the second rotating shaft 312 to rotate relative to the first moving assembly 2, the second screw nut 313 is movably sleeved on the second rotating shaft 312, the second screw nut 313 can move relative to the second rotating shaft 312, and the second screw nut 313 is connected with the second moving member 32. The second rotating shaft 312 is directly driven by the power source part 311, so that intermediate transmission links are reduced, and the power transmission efficiency and response speed are improved. And the stable and accurate movement of the second screw nut can be realized, so that the accurate movement of the second movable piece 32 is controlled, and the stability and the accuracy of the milling component 4 in the processing process are ensured.

As shown in fig. 9, in addition to the features of the foregoing embodiment, the power source 311 further includes a first support base 3111, a second driving motor 3112, a driving wheel 3113, a driven wheel 3114, a connection belt 3115 and a belt cover 3116, the first support base 3111 is disposed on the first moving assembly 2, the second driving motor 3112 and the driving wheel 3113 are disposed on the first support base 3111, an output shaft of the second driving motor 3112 is disposed through the first support base 3111, an output shaft of the second driving motor 3112 is in driving connection with the driving wheel 3113 after passing through the first support base 3111, the driven wheel 3114 is in driving connection with the second rotation shaft 312, the connection belt 3115 is wound on the driving wheel 3113 and the driven wheel 3114, the belt cover 3116 is disposed on the first support base 3111 and is located on a side portion of the first support base 3111, and the driving wheel 3113, the driven wheel 3114 and the connection belt 3115 and the belt cover 3116 are located in the support base 3111. The driving wheel 3113 is directly driven by the second driving motor 3112, and power is transmitted to the driven wheel 3114 through the connection belt 3115, so that the second rotating shaft 312 is driven, and accuracy and stability of power transmission can be effectively improved. The second driving motor 3112 is provided with stable support by the arrangement of the first support base 3111. The belt cover 3116 effectively prevents operators from contacting with the transmission components running at high speed, reduces potential safety hazards and improves safety of equipment.

As shown in fig. 9, in addition to the features of the foregoing embodiment, the present embodiment further includes a second support base 3117, where the second support base 3117 is disposed on the first moving assembly 2, the second rotating shaft 312 is disposed through the second support base 3117, and the second rotating shaft 312 is connected to the power source 311 after passing through the second support base 3117. The provision of the second support base 3117 provides an additional support point for the second rotating shaft 312, thereby enhancing the stability of the entire transmission system.

As shown in fig. 2, 7, 8 and 10, in addition to the features of the foregoing embodiment, the present embodiment further defines that the milling assembly 4 includes a third driving member 41, a milling member 42 and a connecting rod assembly 43, where the third driving member 41 and the milling member 42 are disposed on the second moving assembly 3, the third driving member 41 and the milling member 42 are respectively located on two sides of the second moving assembly 3, the milling member 42 can rotate relative to the second moving assembly 3, the second moving assembly 3 is provided with a first through hole 301, the connecting rod assembly 43 is disposed through the first through hole 301, the connecting rod assembly 43 can move at the first through hole 301, and two ends of the connecting rod assembly 43 are respectively connected with the third driving member 41 and the milling member 42. The third driving piece 41 can drive the connecting rod assembly 43 to move at the first perforation 301, so that the milling piece 42 rotates relative to the second moving assembly 3, the milling angle is adjusted, and the power transmission efficiency is high. The milling part 42 can rotate relative to the second moving assembly 3, so that multi-angle and multi-azimuth accurate milling of the workpiece is realized, and the processing flexibility is greatly improved. This design allows the milling member 42 to perform curved or other complex shape processing on the profile material, improving the applicability of the apparatus.

As shown in fig. 7 and 8, this embodiment further defines, in addition to the features of the above-described embodiment, that the first through hole 301 has an arc shape. The first through hole 301 is arc-shaped, so that the connecting rod assembly 43 moves along a fixed track, the milling part 42 can freely rotate in a larger angle range, precise milling of multiple angles and complex shapes of a workpiece is realized, and the processing flexibility is remarkably improved.

As shown in fig. 2, 7, 8 and 10, this embodiment further defines, in addition to the features of the above-described embodiments, that the second moving assembly 3 is provided with a second perforation 302, the milling member 42 being adapted to the second perforation 302. By adapting the milling member 42 to the second through hole 302, the firmness of the assembly of the milling member 42 is good. And the milling part 42 flexibly rotates at different angles, so that the machining requirements of complex shapes and multiple angles are met, and the machining flexibility is remarkably improved.

As shown in fig. 10, in addition to the features of the foregoing embodiment, the present embodiment further defines that the third driving member 41 includes a support plate 411, a rotary cylinder 412, and a first connection shaft 413, where the support plate 411 is disposed on the second moving assembly 3, the rotary cylinder 412 is located between the support plate 411 and the second moving assembly 3, the first connection shaft 413 is disposed through the support plate 411 and the rotary cylinder 412, and the first connection shaft 413 is connected to the second moving assembly 3 after sequentially passing through the support plate 411 and the rotary cylinder 412. Through the first connecting shaft 413 penetrating the rotary cylinder 412, the first connecting shaft 413 can support the rotary cylinder 412, so that the rotary cylinder 412 rotates around the first connecting shaft 413, and the rotary cylinder 412 rotates more stably.

As shown in fig. 10, in addition to the features of the foregoing embodiment, the present embodiment further defines that the milling part 42 includes a milling part body 421, a support plate 422, and a second connecting shaft 423, where the second connecting shaft 423 is disposed through the second moving assembly 3, the support plate 422 is disposed on the second connecting shaft 423, the support plate 422 is connected to the connecting rod assembly 43, the connecting rod assembly 43 drives the support plate 422 to rotate relative to the second moving assembly 3, and the milling part body 421 is disposed on the support plate 422. The support plate 422 is driven to rotate through the connecting rod assembly 43, so that accurate control of the milling part body 421 is achieved, and stability and accuracy of a machining process are guaranteed. The second connecting shaft 423 penetrates through the second through hole 302 of the second moving assembly 3, so that a stable supporting base is provided for the milling part body 421.

As shown in fig. 10, in addition to the features of the above embodiment, the present embodiment further defines that the connecting rod assembly 43 includes a first connecting rod 431 and a second connecting rod 432, the first connecting rod 431 is connected to the third driving member 41 and the second connecting rod 432, respectively, and the second connecting rod 432 is connected to the milling member 42. By adjusting the relative position between the first connecting rod 431 and the second connecting rod 432 by the third driving member 41, the milling member 42 can be processed at different angles, and the flexibility of the device is enhanced.

As shown in fig. 11, in addition to the features of the foregoing embodiment, the present embodiment further defines that the first support 1 includes a first support frame 11 and a first slide rail 12, where the number of the first slide rails 12 is plural, and plural first slide rails 12 are disposed on the first support frame 11 and located on the same side of the first support frame 11, and the first moving assembly 2 is at least partially movably disposed on the first slide rail 12 and capable of sliding on the first slide rail 12. The first moving assembly 2 is provided with stable support by the arrangement of the first support frame 11. The first moving assembly 2 can stably slide on the first sliding rail 12 through the arrangement of the plurality of first sliding rails 12, so that friction resistance in a moving process is reduced, the stability and efficiency of movement are improved, and maintenance frequency and cost are reduced.

The foregoing examples illustrate only a few embodiments of the utility model, which are described in detail and are not to be construed as limiting the scope of the utility model. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model. Accordingly, the scope of protection of the present utility model is to be determined by the appended claims.

Claims (10)

1. The utility model provides a saw cuts quick-witted milling material structure which characterized in that includes:

a first support (1);

-a first movement assembly (2), the first movement assembly (2) being arranged on the first support (1), the first movement assembly (2) being at least partially movable with respect to the first support (1) towards a first direction and a second direction, the first direction and the second direction being opposite;

-a second movement assembly (3), the second movement assembly (3) being arranged on the first movement assembly (2), the second movement assembly (3) being at least partially movable with respect to the first movement assembly (2) towards a third direction and a fourth direction, the third direction and the fourth direction being opposite;

Milling material subassembly (4), mill material subassembly (4) setting and be in on second movable assembly (3), mill material subassembly (4) are used for milling the material processing to the section bar.

2. Sawing machine milling structure according to claim 1, characterized in that the first moving assembly (2) comprises a first driving element (21), a first moving element (22) and a second supporting element (23), the first driving element (21) is arranged on the first supporting element (1), the first moving element (22) is movably arranged on the first supporting element (1), the first moving element (22) is in transmission connection with the first driving element (21), the first driving element (21) can drive the first moving element (22) to move towards the first direction and the second direction relative to the first supporting element (1), the second supporting element (23) is arranged on the first moving element (22), and the second moving assembly (3) is arranged on the second supporting element (23).

3. The sawing machine milling structure as claimed in claim 2, wherein,

The first driving piece (21) comprises a first driving motor (211), a coupler (212), a first rotating shaft (213) and a first screw nut (214), wherein the first driving motor (211) is arranged on the first supporting piece (1), the coupler (212) is respectively connected with an output shaft of the first driving motor (211) and the first rotating shaft (213), the first driving motor (211) can drive the first rotating shaft (213) to rotate relative to the first supporting piece (1), the first screw nut (214) is movably sleeved on the first rotating shaft (213), the first screw nut (214) can move relative to the first rotating shaft (213), and the first screw nut (214) is connected with the first movable piece (22);

And/or the first movable part (22) comprises a first movable plate (221) and a sliding block (222), the first movable plate (221) is connected with the first driving part (21), the sliding blocks (222) are multiple, the sliding blocks (222) are arranged on the first movable plate (221) and are positioned on the same side of the first movable plate (221), the sliding blocks (222) are movably connected with the first supporting part (1), and the first driving part (21) can drive the first movable plate (221) and the sliding blocks (222) to move towards the first direction and the second direction relative to the first supporting part (1);

And/or second support piece (23) include second support frame (231) and second slide rail (232), second support frame (231) set up on first movable part (22), the quantity of second slide rail (232) is a plurality of, and a plurality of second slide rail (232) all set up on second support frame (231) and be located the same side of second support frame (231), second remove subassembly (3) activity setting is in on second slide rail (232) and can be in slide on second slide rail (232).

4. Sawing machine milling structure according to claim 1, wherein the second moving assembly (3) comprises a second driving element (31) and a second moving element (32), wherein the second driving element (31) is arranged on the first moving assembly (2), the second moving element (32) is movably arranged on the first moving assembly (2), the second moving element (32) is in transmission connection with the second driving element (31), and the second driving element (31) can drive the second moving element (32) to move towards the third direction and the fourth direction relative to the first moving assembly (2).

5. The sawing machine milling structure according to claim 4, wherein the second driving member (31) comprises a power source member (311), a second rotating shaft (312) and a second screw nut (313), the power source member (311) is arranged on the first moving assembly (2), the second rotating shaft (312) is in transmission connection with the power source member (311), the power source member (311) can drive the second rotating shaft (312) to rotate relative to the first moving assembly (2), the second screw nut (313) is movably sleeved on the second rotating shaft (312), the second screw nut (313) can move relative to the second rotating shaft (312), and the second screw nut (313) is connected with the second moving member (32).

6. The sawing machine milling structure as claimed in claim 5, wherein,

The power source piece (311) comprises a first supporting seat (3111), a second driving motor (3112), a driving wheel (3113), a driven wheel (3114), a connecting belt (3115) and a belt cover (3116), wherein the first supporting seat (3111) is arranged on the first moving assembly (2), the second driving motor (3112) and the driving wheel (3113) are both arranged on the first supporting seat (3111), an output shaft of the second driving motor (3112) penetrates through the first supporting seat (3111), the output shaft of the second driving motor (3112) penetrates through the first supporting seat (3111) and is in transmission connection with the driving wheel (3113), the driven wheel (3114) is in transmission connection with the second rotating shaft (312), the connecting belt (3115) is wound on the driving wheel (3113) and the driven wheel (3114), the belt cover (3116) is arranged on the first supporting seat (3111) and is located on the side portion of the first supporting seat (3111), and the driven wheel (3114) is located in the space (3113) and the driving wheel (3114) is formed in the connecting seat (3111).

And/or further comprise a second supporting seat (3117), the second supporting seat (3117) is arranged on the first moving assembly (2), the second rotating shaft (312) is arranged on the second supporting seat (3117) in a penetrating mode, and the second rotating shaft (312) is connected with the power source element (311) after penetrating through the second supporting seat (3117).

7. Sawing machine milling structure according to claim 1, characterized in that the milling assembly (4) comprises a third driving member (41), a milling member (42) and a connecting rod assembly (43), the third driving member (41) and the milling member (42) are both arranged on the second moving assembly (3), the third driving member (41) and the milling member (42) are respectively arranged at two sides of the second moving assembly (3), the milling member (42) can rotate relative to the second moving assembly (3), the second moving assembly (3) is provided with a first perforation (301), the connecting rod assembly (43) is arranged in the first perforation (301) in a penetrating manner, the connecting rod assembly (43) can move at the first perforation (301), and two ends of the connecting rod assembly (43) are respectively connected with the third driving member (41) and the milling member (42).

8. The sawing machine milling structure as claimed in claim 7, wherein,

The first perforation (301) is arc-shaped;

And/or the second moving assembly (3) is provided with a second through hole (302), and the milling part (42) is matched with the second through hole (302).

9. The sawing machine milling structure as claimed in claim 7, wherein,

The third driving piece (41) comprises a supporting plate block (411), a rotary air cylinder (412) and a first connecting shaft (413), the supporting plate block (411) is arranged on the second moving assembly (3), the rotary air cylinder (412) is positioned between the supporting plate block (411) and the second moving assembly (3), the first connecting shaft (413) penetrates through the supporting plate block (411) and the rotary air cylinder (412), and the first connecting shaft (413) sequentially penetrates through the supporting plate block (411) and the rotary air cylinder (412) and then is connected with the second moving assembly (3);

And/or the milling part (42) comprises a milling part body (421), a supporting plate (422) and a second connecting shaft (423), wherein the second connecting shaft (423) penetrates through the second moving assembly (3), the supporting plate (422) is arranged on the second connecting shaft (423), the supporting plate (422) is connected with the connecting rod assembly (43), the connecting rod assembly (43) drives the supporting plate (422) to rotate relative to the second moving assembly (3), and the milling part body (421) is arranged on the supporting plate (422);

And/or the connecting rod assembly (43) comprises a first connecting rod (431) and a second connecting rod (432), wherein the first connecting rod (431) is respectively connected with the third driving piece (41) and the second connecting rod (432), and the second connecting rod (432) is connected with the milling piece (42).

10. Sawing machine milling structure according to claim 1, characterized in that the first support (1) comprises a first support frame (11) and a first slide rail (12), the number of the first slide rails (12) is a plurality, a plurality of the first slide rails (12) are all arranged on the first support frame (11) and are positioned on the same side of the first support frame (11), and the first moving assembly (2) is at least partially movably arranged on the first slide rail (12) and can slide on the first slide rail (12).