Sawing device
By designing a sawing device with cross-clamping force and automated control, the problem of insufficient material stability in traditional sawing devices is solved, achieving an efficient and safe cutting process that can stably clamp and cut different material specifications.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUANGDONG COMIMAN INTELLIGENT EQUIPMENT CO LTD
- Filing Date
- 2025-07-29
- Publication Date
- 2026-06-23
AI Technical Summary
The limitations of the clamping structure of traditional sawing devices result in insufficient stability of materials during the cutting process, affecting processing accuracy and efficiency. In particular, uneven force during the cutting process can easily cause material to shift or loosen, posing a safety hazard.
The first and second clamping components move in intersecting directions to form a cross clamping force. Combined with the multi-position movement design of the sawing component, this ensures that the material remains stable during the cutting process, and the drive component enables automated control.
It significantly improves clamping reliability, extends the service life of the sawing assembly, adapts to materials of different sizes and shapes, ensures a stable cutting path, avoids cutting deviation and material splashing, and improves cutting efficiency and safety.
Smart Images

Figure CN224390105U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of sawing equipment, and in particular to a sawing device. Background Technology
[0002] In traditional sawing equipment, the limitations of the clamping structure often lead to insufficient stability of the material during cutting, affecting processing accuracy and efficiency. Traditional sawing equipment uses only a single-direction clamping structure or relies solely on a fixed clamping structure, making it difficult to adapt to the stable fixation requirements of materials of different sizes or shapes. Especially during the cutting process, when the saw blade applies cutting force, traditional clamping methods are prone to material displacement or loosening due to uneven force distribution, which in turn affects the cut quality and may even cause safety hazards. Utility Model Content
[0003] Therefore, it is necessary to provide a sawing device that addresses the problem that traditional sawing devices, which only employ a unidirectional clamping structure or rely solely on a fixed clamping structure, are unable to meet the stable fixing requirements of materials of different sizes or shapes.
[0004] A sawing device includes: a support assembly having a first cutting space; a first clamping assembly disposed on the support assembly and capable of moving relative to the support assembly in a first direction; a second clamping assembly disposed on the support assembly, wherein a portion of the second clamping assembly for clamping material is capable of moving relative to the support assembly in a second direction, the second direction intersecting the first direction; and a sawing assembly disposed on the support assembly and capable of moving relative to the support assembly, the sawing assembly having at least a first position and a second position relative to the support assembly, wherein when the sawing assembly is in the first position, it passes through the first cutting space, and when the sawing assembly is in the second position, it exits the first cutting space.
[0005] This application discloses a sawing device. By moving a first clamping component and a second clamping component along intersecting directions, a cross-clamping force is formed, clamping the material from different directions. This effectively prevents the material from shifting or loosening during cutting, significantly improving clamping reliability. This design ensures the material remains stable during cutting, effectively preventing the problem of scrap material splattering and extending the service life of the sawing component by 30%, making it highly practical. Furthermore, the independent movement of the two clamping components allows it to adapt to materials of different sizes and shapes, ensuring stable clamping for materials of various specifications, thus having a wide range of applications. The design of the sawing component precisely passing through the first cutting space in the first position ensures a stable cutting path and avoids cut deviations caused by unstable clamping. The sawing component can smoothly switch between the first and second positions, ensuring correct saw blade positioning during cutting and allowing it to completely retract from the cutting space when not in operation, reducing the risk of accidental contact.
[0006] In one embodiment, the first clamping assembly has a second cutting space, which is opposite to the first cutting space. When the sawing assembly is in the first position, it is located in the second cutting space. By providing a second cutting space opposite to the first cutting space in the first clamping assembly, it is ensured that the sawing assembly completely passes through the clamping area in the first position, avoiding collision or friction with the first clamping assembly and improving the service life of the sawing assembly. The first clamping assembly simultaneously clamps both parts of the material being cut, keeping the material stable during sawing and preventing offset or vibration caused by unilateral clamping, ensuring a smooth cut. The sawing assembly passes through the middle of the two parts of the material, ensuring accurate cutting trajectory and avoiding interference from the clamping structure that affects cutting accuracy. This design effectively improves the smoothness of the cut surface and prevents material from splashing during cutting.
[0007] In one embodiment, there are two second clamping components, both of which are mounted on the support component. The two second clamping components clamp the material on the same side, forming a third cutting space between them. This third cutting space is opposite to the first cutting space. When the sawing component is in the first position, it passes through the third cutting space. By using two second clamping components to clamp the material on the same side, multi-point fixation is achieved, effectively preventing material deflection or loosening during cutting and improving clamping reliability. The third cutting space formed between the two second clamping components is aligned with the first cutting space, ensuring the sawing component can accurately pass through in the first position, avoiding interference with the clamping structure and guaranteeing the accuracy of the cutting trajectory. This design allows the sawing component to completely pass through the clamping area during operation, reducing the risk of contact with the clamping components and lowering the possibility of accidental damage.
[0008] In one embodiment, a first driving member is further included. The first driving member is disposed on the support assembly and is pulsatorically connected to the first clamping assembly. The first driving member can drive the first clamping assembly to move relative to the support assembly. Through the pulsatorically connected to the first clamping assembly, the moving position and clamping force of the first clamping assembly can be precisely controlled, ensuring that the material is stably clamped. The first driving member automates the clamping operation, eliminating the need for manual adjustment and significantly improving work efficiency and ease of operation.
[0009] In one embodiment, the second clamping assembly includes a second driving member and a clamping component. The second driving member is disposed on the support assembly, and the clamping component is pulsatorically connected to the second driving member. The clamping component is capable of moving relative to the support assembly under the control of the second driving member. Through the pulsatorically connected to the clamping component, the second clamping assembly can be precisely moved independently of the first clamping assembly, achieving multi-directional collaborative clamping. The adjustability of the clamping component under the control of the second driving member allows it to adapt to the clamping requirements of materials of different shapes and sizes, improving the versatility of the device. The controllable driving force provided by the second driving member ensures that the clamping component maintains a stable clamping state under different working conditions, effectively preventing material displacement during processing.
[0010] In one embodiment, a third driving member is further included. The third driving member is disposed on the support assembly and is driveably connected to the sawing assembly. The third driving member can drive the sawing assembly to move relative to the support assembly. Through the drive connection between the third driving member and the sawing assembly, the movement position and cutting stroke of the sawing assembly can be precisely controlled, ensuring the stability and accuracy of the cutting process. The third driving member automates the movement of the sawing assembly, eliminating the need for manual operation and significantly improving the efficiency of the cutting operation.
[0011] In one embodiment, the sawing assembly includes a slider and a sawing component. The slider is movably mounted on the support assembly and is drive-connected to the third drive component. The slider can move relative to the support assembly under the control of the third drive component, and the sawing component is mounted on the slider. The drive-connection between the slider and the third drive component allows the sawing component to move precisely along a predetermined trajectory, ensuring the accuracy of the cutting path. The movable mounting of the slider on the support assembly ensures both the smoothness of the sawing component's movement and enhances the rigidity of the overall structure.
[0012] In one embodiment, the sliding member includes a slide block and a connecting member. The slide block is movably disposed on the support assembly, and the connecting member is connected to both the slide block and the third driving member. The movable arrangement of the slide block on the support assembly provides stable motion guidance, ensuring that the sawing component moves smoothly along a predetermined trajectory. The connecting member, acting as a transmission intermediary between the slide block and the third driving member, effectively transmits driving force, enabling the sawing component to move stably up and down.
[0013] In one embodiment, the sawing component includes a first drive motor and a saw blade structure. The first drive motor is mounted on the sliding member, and the saw blade structure is drive-connected to the first drive motor. The saw blade structure can pass through the first cutting space. The first drive motor directly drives the saw blade structure, ensuring efficient transmission of cutting power and improving cutting speed and work efficiency.
[0014] In one embodiment, the support assembly includes a base assembly, a bracket assembly, a support plate, and a slide rail. The bracket assembly is disposed on the base assembly. Both the first clamping assembly and the second clamping assembly are disposed on the bracket assembly. The support plate and the slide rail are both disposed on the bracket assembly. The support plate has a first cutting space. The sawing assembly is movably disposed on the slide rail and can slide on the slide rail. The combined arrangement of the base assembly and bracket assembly provides a stable mounting foundation for the clamping assembly and the sawing assembly, ensuring the rigid support of the entire device. The slide rail allows the sawing assembly to slide smoothly along a predetermined trajectory, ensuring the accuracy of the cutting path and avoiding movement deviation. The first cutting space on the support plate allows the sawing assembly to pass through the center of the support plate to cut the material, resulting in better cutting performance.
[0015] In one embodiment, the support assembly includes a first support plate, a bearing assembly, and a second support plate. The bearing assembly is disposed on the first support plate, the second support plate is disposed on the bearing assembly, and the bracket assembly is disposed on the second support plate. It also includes a fourth driving member disposed on the second support plate and pulsatorically connected to the bearing assembly. Through the cooperation of the bearing assembly and the fourth driving member, the support assembly can rotate as a whole, flexibly adjusting the material conveying angle and cutting angle to adapt to different processing requirements. This design allows materials to be positioned and cut at the optimal angle, improving processing compatibility with materials of different shapes or sizes.
[0016] In one embodiment, the fourth driving component includes a support block, a second drive motor, and a gear. The support block is mounted on the second support plate, and the second drive motor is mounted on the support block and passes through the second support plate. After passing through the second support plate, the second drive motor engages with the gear, which in turn engages with the bearing assembly. Through the engagement of the gear and the bearing assembly, the second drive motor can precisely control the rotation angle of the support assembly, ensuring accurate material positioning. This design effectively improves the adjustment of the material conveying and cutting angles, ensuring cutting effect and efficiency, making the cutting process more stable, and avoiding or reducing material splashing.
[0017] In one embodiment, the bearing assembly includes an outer ring structure and an inner ring structure. The outer ring structure is connected to the first support plate, and the inner ring structure is connected to the second support plate. The inner ring structure is in transmission engagement with the fourth driving component, and the inner ring structure and the second support plate can rotate together relative to the first support plate. The fixed connection between the outer ring structure and the first support plate, and the fixed connection between the inner ring structure and the second support plate, forms a reliable rotational support structure, ensuring smooth rotation. The direct transmission engagement between the inner ring structure and the fourth driving component makes the driving force transmission path more direct and efficient, reducing intermediate energy loss.
[0018] In one embodiment, the first clamping component and the second clamping component are used to clamp the adjacent sides of the material. By clamping the adjacent sides of the material with the first clamping component and the second clamping component respectively, a multi-directional constraint is formed, which effectively prevents the material from shifting or rotating during the cutting process and improves the clamping reliability.
[0019] In one embodiment, a blade guard assembly is also included, which surrounds the saw assembly. The blade guard assembly surrounds the saw assembly, effectively isolating the high-speed rotating saw blade structure, preventing accidental contact by operators, and reducing the risk of workplace injuries. Attached Figure Description
[0020] Figure 1 This is a first perspective view of the sawing device;
[0021] Figure 2 This is a second perspective view of the sawing device;
[0022] Figure 3 This is the first exploded view of the sawing device;
[0023] Figure 4 This is the second exploded view of the sawing device;
[0024] Figure 5 This is the third exploded view of the sawing device;
[0025] Figure 6 This is the fourth exploded view of the sawing device;
[0026] Figure 7 A perspective view of the support assembly, the first clamping assembly, the second clamping assembly, the sawing assembly, the first drive component, the third drive component, and the fourth drive component;
[0027] Figure 8 A perspective view of the saw assembly and the third drive component;
[0028] Figure 9 First exploded view of the saw assembly and the third drive component;
[0029] Figure 10 A second exploded view of the saw assembly and the third drive component;
[0030] Figure 11 A first perspective view of the support assembly and the fourth drive component;
[0031] Figure 12 A second perspective view of the support assembly and the fourth drive component;
[0032] Figure 13 Exploded view of the support assembly and the fourth drive component;
[0033] Figure 14 A perspective view of the support component, the first clamping component, the second clamping component, and the first driving component;
[0034] Figure 15 An exploded view of the support component, the first clamping component, the second clamping component, and the first driving component.
[0035] The correspondence between the reference numerals and the component names is as follows:
[0036] 1 Support assembly, 11 Support assembly, 111 First support plate, 112 Bearing assembly, 1121 Outer ring structure, 1122 Inner ring structure, 113 Second support plate, 12 Bracket assembly, 13 Support plate, 14 Slide rail, 101 First tool passage space;
[0037] 2 First clamping component, 201 Second tool passage space;
[0038] 3 Second clamping assembly, 31 Second driving member, 32 Clamping component, 301 Third tool passage space;
[0039] 4. Saw assembly, 41. Sliding component, 411. Slide block, 412. Connecting component, 42. Saw component, 421. First drive motor, 422. Saw blade structure;
[0040] 5. First driving component;
[0041] 6. Third driving component;
[0042] 7 Fourth driving component, 71 Support block, 72 Second driving motor, 73 Gear;
[0043] 8-blade shield assembly. Detailed Implementation
[0044] To better understand the above-mentioned objectives, features, and advantages of this utility model, the present utility model will be further described in detail below with reference to the accompanying drawings and specific embodiments. It should be noted that, unless otherwise specified, the embodiments and features described in these embodiments can be combined with each other.
[0045] Many specific details are set forth in the following description in order to provide a full understanding of the present invention. However, the present invention may also be implemented in other ways different from those described herein. Therefore, the scope of protection of the present invention is not limited to the specific embodiments disclosed below.
[0046] like Figure 1-15 As shown, this embodiment discloses a sawing device, including: a support component 1, the support component 1 having a first cutting space 101; a first clamping component 2, the first clamping component 2 being disposed on the support component 1, the first clamping component 2 being at least movable relative to the support component 1 in a first direction; a second clamping component 3, the second clamping component 3 being disposed on the support component 1, the portion of the second clamping component 3 used for clamping material being at least movable relative to the support component 1 in a second direction, the second direction intersecting the first direction; and a sawing component 4, the sawing component 4 being disposed on the support component 1, the sawing component 4 being movable relative to the support component 1, the sawing component 4 having at least a first position and a second position relative to the support component 1, the sawing component 4 being in the first position passing through the first cutting space 101, and the sawing component 4 being in the second position withdrawing from the first cutting space 101.
[0047] This application discloses a sawing device. By moving the first clamping component 2 and the second clamping component 3 along intersecting directions, a cross-clamping force is formed, clamping the material from different directions. This effectively prevents the material from shifting or loosening during cutting, significantly improving clamping reliability. This design ensures the material remains stable when the sawing component 4 cuts, effectively preventing the problem of residual material splattering and extending the service life of the sawing component 4 by 30%, making it highly practical. Furthermore, the independent movement of the two clamping components allows it to adapt to materials of different sizes and shapes, ensuring stable clamping for materials of various specifications, thus having a wide range of applications. The design of the sawing component 4 precisely passing through the first cutting space 101 in the first position ensures a stable cutting path and avoids cut deviations caused by unstable clamping. The sawing component 4 can smoothly switch between the first and second positions, ensuring correct saw blade positioning during cutting and allowing it to completely retract from the cutting space when not in operation, reducing the risk of accidental contact.
[0048] like Figure 3 and Figure 7 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the first clamping component 2 is provided with a second through space 201, the second through space 201 is arranged opposite to the first through space 101, and the sawing component 4 is located at the second through space 201 when the sawing component 4 is in the first position. By providing a second through space 201 opposite to the first through space 101 in the first clamping component 2, it is ensured that the sawing component 4 completely passes through the clamping area in the first position, avoiding collision or friction with the first clamping component 2, and improving the service life of the sawing component 4. The first clamping component 2 clamps both parts of the material being cut at the same time, keeping the material stable during the sawing process, preventing displacement or vibration caused by unilateral clamping, and ensuring a smooth cut. The sawing component 4 passes through the middle of the two parts of the material, ensuring accurate cutting trajectory and avoiding interference from the clamping structure that affects cutting accuracy. This design can effectively improve the smoothness of the cutting surface and avoid material splashing during cutting.
[0049] like Figure 3 and Figure 7As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the number of second clamping components 3 is two, both second clamping components 3 are disposed on the support component 1, the two second clamping components 3 are used to clamp the same side of the material, a third cutting space 301 is formed between the two second clamping components 3, the third cutting space 301 is disposed opposite to the first cutting space 101, and the sawing component 4 passes through the third cutting space 301 when the sawing component 4 is in the first position. By setting two second clamping components 3 to clamp the same side of the material together, multi-point fixation is formed, effectively preventing the material from deflecting or loosening during the cutting process, and improving the clamping reliability. The third cutting space 301 formed between the two second clamping components 3 is aligned with the first cutting space 101 to ensure that the sawing component 4 can accurately pass through when in the first position, avoiding interference with the clamping structure and ensuring the accuracy of the cutting trajectory. This design allows the sawing component 4 to completely pass through the clamping area during operation, reducing the risk of contact with the clamping components and reducing the possibility of accidental damage.
[0050] like Figure 14 and Figure 15 As shown, in addition to the features of the above embodiments, this embodiment further includes a first driving member 5, which is disposed on the support assembly 1 and is driveably connected to the first clamping assembly 2. The first driving member 5 can drive the first clamping assembly 2 to move relative to the support assembly 1. Through the drive connection between the first driving member 5 and the first clamping assembly 2, the moving position and clamping force of the first clamping assembly 2 can be precisely controlled, ensuring that the material is stably clamped. The first driving member 5 automates the clamping operation, eliminating the need for manual adjustment and significantly improving work efficiency and operational convenience.
[0051] like Figure 14 and Figure 15 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the second clamping assembly 3 includes a second driving member 31 and a clamping component 32. The second driving member 31 is disposed on the support assembly 1, and the clamping component 32 is convexly connected to the second driving member 31. The clamping component 32 can move relative to the support assembly 1 under the control of the second driving member 31. Through the convex connection between the second driving member 31 and the clamping component 32, the second clamping assembly 3 can be precisely moved independently of the first clamping assembly 2, realizing multi-directional collaborative clamping. The adjustability of the clamping component 32 under the control of the second driving member 31 allows it to adapt to the clamping requirements of materials of different shapes and sizes, improving the versatility of the device. The controllable driving force provided by the second driving member 31 ensures that the clamping component 32 maintains a stable clamping state under different working conditions, effectively preventing material displacement during processing.
[0052] like Figure 6-10 As shown, in addition to the features of the above embodiments, this embodiment further includes a third driving member 6, which is disposed on the support assembly 1 and is driveably connected to the sawing assembly 4. The third driving member 6 can drive the sawing assembly 4 to move relative to the support assembly 1. Through the drive connection between the third driving member 6 and the sawing assembly 4, the moving position and cutting stroke of the sawing assembly 4 can be precisely controlled, ensuring the stability and accuracy of the cutting process. The third driving member 6 enables automated control of the movement of the sawing assembly 4, eliminating the need for manual operation and significantly improving the efficiency of the cutting operation.
[0053] like Figure 6-10 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the sawing assembly 4 includes a sliding member 41 and a sawing member 42. The sliding member 41 is movably disposed on the support assembly 1. The sliding member 41 is drive-connected to the third driving member 6. The sliding member 41 can move relative to the support assembly 1 under the control of the third driving member 6. The sawing member 42 is disposed on the sliding member 41. Through the drive-connection between the sliding member 41 and the third driving member 6, the sawing member 42 can move precisely along a predetermined trajectory, ensuring the accuracy of the cutting path. The movable arrangement of the sliding member 41 on the support assembly 1 ensures both the smoothness of the movement of the sawing member 42 and enhances the rigidity of the overall structure.
[0054] like Figure 6-10 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the sliding member 41 includes a slide base 411 and a connecting member 412. The slide base 411 is movably disposed on the support assembly 1, and the connecting member 412 is connected to the slide base 411 and the third driving member 6 respectively. The movable arrangement of the slide base 411 on the support assembly 1 provides stable motion guidance, ensuring that the sawing member 42 moves smoothly along a predetermined trajectory. The connecting member 412, as a transmission intermediary between the slide base 411 and the third driving member 6, effectively transmits driving force, enabling the sawing assembly 42 to move stably up and down.
[0055] like Figure 6-10 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the sawing component 42 includes a first drive motor 421 and a saw blade structure 422. The first drive motor 421 is disposed on the sliding member 41, and the saw blade structure 422 is driveably connected to the first drive motor 421. The saw blade structure 422 can pass through the first cutting space 101. The first drive motor 421 directly drives the saw blade structure 422, ensuring efficient transmission of cutting power and improving cutting speed and work efficiency.
[0056] like Figure 7 and Figure 11-15 As shown, in addition to the features of the above embodiments, this embodiment further defines the following: the support assembly 1 includes a support assembly 11, a bracket assembly 12, a support plate 13, and a slide rail 14. The bracket assembly 12 is disposed on the support assembly 11, the first clamping assembly 2 and the second clamping assembly 3 are both disposed on the bracket assembly 12, the support plate 13 and the slide rail 14 are both disposed on the bracket assembly 12, the support plate 13 is provided with a first cutting space 101, and the sawing assembly 4 is movably disposed on the slide rail 14, allowing the sawing assembly 4 to slide on the slide rail 14. The combined arrangement of the support assembly 11 and the bracket assembly 12 provides a stable mounting foundation for the clamping assembly and the sawing assembly 4, ensuring the rigid support of the entire device. The slide rail 14 allows the sawing assembly 4 to slide smoothly along a predetermined trajectory, ensuring the accuracy of the cutting path and avoiding movement deviation. The first cutting space 101 provided in the support plate 13 allows the sawing assembly 4 to pass through the middle of the support plate 13 to cut the material, resulting in better cutting performance.
[0057] like Figure 11-13 As shown, in addition to the features of the above embodiments, this embodiment further defines the following: the support assembly 11 includes a first support plate 111, a bearing assembly 112, and a second support plate 113. The bearing assembly 112 is disposed on the first support plate 111, the second support plate 113 is disposed on the bearing assembly 112, the bracket assembly 12 is disposed on the second support plate 113, and a fourth driving member 7 is also included. The fourth driving member 7 is disposed on the second support plate 113 and is drively connected to the bearing assembly 112. Through the cooperation of the bearing assembly 112 and the fourth driving member 7, the support assembly 11 can rotate as a whole, flexibly adjusting the material conveying angle and cutting angle to adapt to different processing requirements. This design allows the material to be positioned and cut at the optimal angle, improving the processing compatibility of materials of different shapes or sizes.
[0058] like Figure 11-13As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the fourth driving component 7 includes a support block 71, a second driving motor 72, and a gear 73. The support block 71 is disposed on the second support plate 113, and the second driving motor 72 is disposed on the support block 71. The second driving motor 72 passes through the second support plate 113 and engages with the gear 73 after passing through the second support plate 113. The gear 73 engages with the bearing assembly 112 in a transmission manner. Through the transmission engagement between the gear 73 and the bearing assembly 112, the second driving motor 72 can precisely control the rotation angle of the support assembly 11, ensuring the accuracy of material positioning. This design can effectively improve the adjustment of the material conveying angle and cutting angle, ensuring the cutting effect and cutting efficiency, making the cutting process more stable, and avoiding or reducing material splashing.
[0059] like Figure 11-13 As shown, in addition to the features of the above embodiments, this embodiment further specifies that: the bearing assembly 112 includes an outer ring structure 1121 and an inner ring structure 1122. The outer ring structure 1121 is connected to the first support plate 111, and the inner ring structure 1122 is connected to the second support plate 113. The inner ring structure 1122 is in a transmission engagement with the fourth driving member 7. The inner ring structure 1122 and the second support plate 113 can rotate together relative to the first support plate 111. The fixed connection between the outer ring structure 1121 and the first support plate 111, and the fixed connection between the inner ring structure 1122 and the second support plate 113, forms a reliable rotational support structure, ensuring the smoothness of the rotation process. The direct transmission engagement between the inner ring structure 1122 and the fourth driving member 7 makes the driving force transmission path more direct and efficient, reducing intermediate energy loss.
[0060] In addition to the features of the above embodiments, this embodiment further specifies that: the first clamping component 2 and the second clamping component 3 are used to clamp the adjacent sides of the material. By clamping the adjacent sides of the material by the first clamping component 2 and the second clamping component 3 respectively, multi-directional constraints are formed, effectively preventing the material from shifting or rotating during the cutting process and improving clamping reliability.
[0061] like Figure 1-5 As shown, in addition to the features of the above embodiments, this embodiment further includes a blade cover assembly 8, which surrounds the saw assembly 4. The blade cover assembly 8 surrounds the saw assembly 4, effectively isolating the high-speed rotating saw blade structure 422, preventing accidental contact by operators, and reducing the risk of workplace injuries.
[0062] The above embodiments only illustrate several implementation methods of this utility model, and their descriptions are relatively specific and detailed, but they should not be construed as limiting the scope of the utility model patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this utility model, and these all fall within the protection scope of this utility model. Therefore, the protection scope of this utility model patent should be determined by the appended claims.
Claims
1. A sawing device, characterized in that, include: Support component (1), the support component (1) is provided with a first through space (101); A first clamping component (2) is disposed on the support component (1) and the first clamping component (2) is at least movable relative to the support component (1) in a first direction; A second clamping component (3) is disposed on the support component (1). The portion of the second clamping component (3) used to clamp the material is at least movable relative to the support component (1) toward a second direction, which intersects with the first direction. A sawing assembly (4) is disposed on the support assembly (1). The sawing assembly (4) is movable relative to the support assembly (1). The sawing assembly (4) has at least a first position and a second position relative to the support assembly (1). When the sawing assembly (4) is in the first position, it passes through the first cutting space (101). When the sawing assembly (4) is in the second position, it exits from the first cutting space (101).
2. The sawing device according to claim 1, characterized in that, The first clamping component (2) is provided with a second cutting space (201), which is arranged opposite to the first cutting space (101). When the sawing component (4) is in the first position, the sawing component (4) is located in the second cutting space (201). And / or the number of the second clamping components (3) is two, both of the second clamping components (3) are disposed on the support component (1), the two second clamping components (3) are used to clamp the material on the same side, a third cutting space (301) is formed between the two second clamping components (3), the third cutting space (301) is disposed opposite to the first cutting space (101), and when the sawing component (4) is in the first position, the sawing component (4) passes through the third cutting space (301).
3. The sawing device according to claim 1, characterized in that, It also includes a first driving member (5), which is disposed on the support assembly (1). The first driving member (5) is connected to the first clamping assembly (2) in a transmission manner. The first driving member (5) can drive the first clamping assembly (2) to move relative to the support assembly (1). And / or the second clamping assembly (3) includes a second drive member (31) and a clamping member (32), the second drive member (31) being disposed on the support assembly (1), the clamping member (32) being tractively connected to the second drive member (31), and the clamping member (32) being movable relative to the support assembly (1) under the control of the second drive member (31).
4. The sawing device according to claim 1, characterized in that, It also includes a third driving member (6), which is disposed on the support assembly (1). The third driving member (6) is connected to the sawing assembly (4) in a transmission manner. The third driving member (6) can drive the sawing assembly (4) to move relative to the support assembly (1).
5. The sawing device according to claim 4, characterized in that, The sawing assembly (4) includes a sliding member (41) and a sawing member (42). The sliding member (41) is movably disposed on the support assembly (1). The sliding member (41) is connected to the third driving member (6) in a transmission manner. The sliding member (41) can move relative to the support assembly (1) under the control of the third driving member (6). The sawing member (42) is disposed on the sliding member (41).
6. The sawing device according to claim 5, characterized in that, The sliding member (41) includes a slide block (411) and a connector (412). The slide block (411) is movably disposed on the support assembly (1), and the connector (412) is connected to the slide block (411) and the third driving member (6) respectively. And / or the sawing component (42) includes a first drive motor (421) and a saw blade structure (422), the first drive motor (421) is disposed on the sliding member (41), the saw blade structure (422) is connected to the first drive motor (421) in a transmission manner, and the saw blade structure (422) can pass through the first cutting space (101).
7. The sawing device according to claim 1, characterized in that, The support assembly (1) includes a support assembly (11), a bracket assembly (12), a support plate (13), and a slide rail (14). The bracket assembly (12) is disposed on the support assembly (11). The first clamping assembly (2) and the second clamping assembly (3) are both disposed on the bracket assembly (12). The support plate (13) and the slide rail (14) are both disposed on the bracket assembly (12). The support plate (13) is provided with the first cutting space (101). The sawing assembly (4) is movably disposed on the slide rail (14) and can slide on the slide rail (14).
8. The sawing device according to claim 7, characterized in that, The support assembly (11) includes a first support plate (111), a bearing assembly (112), and a second support plate (113). The bearing assembly (112) is disposed on the first support plate (111), the second support plate (113) is disposed on the bearing assembly (112), and the bracket assembly (12) is disposed on the second support plate (113). It also includes a fourth driving member (7), which is disposed on the second support plate (113) and is connected to the bearing assembly (112) in a transmission manner.
9. The sawing device according to claim 8, characterized in that, The fourth driving component (7) includes a support block (71), a second driving motor (72), and a gear (73). The support block (71) is disposed on the second support plate (113), and the second driving motor (72) is disposed on the support block (71). The second driving motor (72) passes through the second support plate (113) and engages with the gear (73) after passing through the second support plate (113). The gear (73) engages with the bearing assembly (112) in a transmission relationship. And / or the bearing assembly (112) includes an outer ring structure (1121) and an inner ring structure (1122), the outer ring structure (1121) being connected to the first support plate (111), the inner ring structure (1122) being connected to the second support plate (113), the inner ring structure (1122) being in transmission engagement with the fourth drive member (7), and the inner ring structure (1122) and the second support plate (113) being able to rotate together relative to the first support plate (111).
10. The sawing device according to claim 1, characterized in that, The first clamping assembly (2) and the second clamping assembly (3) are used to clamp the adjacent sides of the material; And / or may also include a blade cover assembly (8) disposed around the saw assembly (4).