CN218904538U - Numerical control lathe with piece collection device - Google Patents

Abstract

The utility model relates to a numerical control lathe with a chip collecting device, wherein a chip collecting channel is arranged on a chip collecting table and is positioned between a jig mounting base and two side spindle mounting bases, namely, the chip collecting channel is positioned right below a workpiece to be processed. During the use, the piece that first processing main shaft device and second processing main shaft device processed the product produced falls into the piece collection passageway under the effect of gravity, through advancing the mutual cooperation of piece opening, play piece opening and chip removal runner, can discharge the piece landing outside the piece collection platform again. Therefore, the utility model has good cleaning effect, is convenient for discharging the scraps out of the equipment in time, effectively prevents the scraps from being difficult to slide out of the lathe and accumulating in a large amount, is convenient for the smooth proceeding of the next procedure, and effectively improves the practicability of the device.

Description

Numerical control lathe with piece collection device

Technical Field

The utility model belongs to the technical field of numerically controlled lathes, and particularly relates to a numerically controlled lathe with a scrap collecting device.

Background

The numerical control machine tool is an electromechanical integrated product integrating a plurality of technologies such as high-performance machinery, electricity, transmission, hydraulic pressure, pneumatic and the like, is a machine tool with the advantages of high precision, high efficiency, high automation, high flexibility and the like in mechanical manufacturing equipment, and the precision and the processing speed of a processed workpiece are rapidly developed along with the use of the numerical control machine tool.

Currently, chinese patent with publication number CN201357230Y discloses a dual-system numerically controlled lathe, which comprises a frame, a clamp arranged on the frame and used for clamping a workpiece, a longitudinal sliding rail arranged on the frame, a large supporting plate slidingly connected on the longitudinal sliding rail, a transverse sliding rail arranged on the large supporting plate, and a small supporting plate slidingly connected on the transverse sliding rail, wherein a multi-station tool rest is arranged on the small supporting plate, and a tool used for turning the workpiece is arranged on the multi-station tool rest.

The prior art solutions described above have the following drawbacks: the numerical control lathe can produce a large amount of fragments when handling the steel, and the fragment falls in numerical control lathe below formation accumulation, and the joint is inside the numerical control lathe, and the workman need clear up the numerical control lathe below when clearing up the fragment, has increased the degree of difficulty when follow-up workman clear up the fragment to the time of workman's clearance fragment has been increased, has increased the manpower, has reduced production efficiency.

Disclosure of Invention

The utility model aims to provide a numerical control lathe with a scrap collecting device, and aims to solve the technical problem that a large amount of scraps are generated when the numerical control lathe in the prior art processes steel materials, and the time for cleaning scraps by workers is prolonged.

In order to achieve the above object, an embodiment of the present utility model provides a numerically controlled lathe with a chip collecting device, including:

the device comprises a chip collecting device, a jig mounting base and a spindle mounting base, wherein the jig mounting base is formed by upwards protruding along the middle part of the chip collecting table, and the spindle mounting base is formed by upwards protruding along the two sides of the chip collecting table;

the product fixing jig is arranged on the jig mounting base and is used for simultaneously fixing a plurality of products;

the first processing spindle device is arranged on the left spindle mounting base and is used for processing the left side surface of a product;

the second processing main shaft device is arranged on the main shaft installation base on the right side and is used for processing the right side surface of the product;

the chip collecting tables are respectively provided with a chip collecting channel between the jig mounting base and the spindle mounting bases at two sides and are used for collecting chips generated by processing products by the first processing spindle device and the second processing spindle device;

the chip collecting channel comprises a chip inlet opening, a chip outlet opening and a chip removing flow channel; the chip inlet opening penetrates through the upper surface of the chip collecting table, the chip outlet opening penetrates through the side surface of the chip collecting table, and two end parts of the chip discharging flow passage are communicated with the chip inlet opening and the chip outlet opening.

Optionally, the chip removal runner is "L" shape structure setting, including the blanking runner of vertical setting and the row material runner of level setting, the upper end of blanking runner with advance the bits opening and be linked together, the lower tip of blanking runner with the inner tip of row material runner is linked together, the outer tip of row material runner with it is linked together to go out the bits opening.

Optionally, the first processing spindle device and the second processing spindle device have the same structure, and each includes:

rotating the main shaft;

the rotary driving motor is connected with the rotary main shaft through a transmission belt so as to drive the rotary main shaft to synchronously rotate;

the feeding driving assembly is connected with the rotary main shaft and the rotary driving motor so as to drive the rotary main shaft and the rotary driving motor to horizontally move in the X-axis direction;

and the displacement driving assembly is connected with the feeding driving assembly to drive the feeding driving assembly, the rotating main shaft and the rotating driving motor to translate back and forth in the Y-axis direction.

Optionally, the displacement driving assembly comprises a displacement driving motor, a displacement screw rod, a displacement sliding rail and a displacement mounting platform; the shifting slide rail is paved on the main shaft installation base, the shifting installation platform is arranged on the shifting slide rail in a sliding mode and is connected with the feeding driving assembly, the shifting screw is arranged on the main shaft installation base in a rotating mode and is in transmission connection with the shifting installation platform, and the shifting driving motor is arranged on the main shaft installation base and is connected with the shifting screw.

Optionally, the feed driving assembly comprises a feed driving motor, a feed screw, a feed slide rail, a feed mounting platform and an output mounting seat; the feeding slide rail is paved on the displacement mounting platform, the feeding mounting platform is arranged on the feeding slide rail in a sliding manner and is connected with the output mounting seat, and the rotating main shaft and the rotating driving motor are both mounted on the output mounting seat; the feeding screw is rotatably arranged on the displacement mounting platform and is in transmission connection with the feeding mounting platform, and the feeding driving motor is arranged on the displacement mounting platform and is connected with the feeding screw.

Optionally, the output mounting seat is hollow and provided with a spindle mounting hole matched with the rotating spindle, and the rotating spindle is inserted and assembled in the output mounting seat through the spindle mounting hole.

Optionally, a motor mounting surface matched with the rotary driving motor is horizontally arranged at the top of the output mounting seat, and the rotary driving motor is fixedly assembled on the motor mounting surface through a plurality of screws.

Optionally, be provided with a plurality of product fixing stations on the product fixing jig, a plurality of product fixing stations are along Y axle direction evenly distributed and arrange in proper order.

The technical scheme of the numerical control lathe with the scrap collecting device provided by the embodiment of the utility model has at least one of the following technical effects: the numerical control lathe with the chip collecting device is characterized in that the chip collecting channel is arranged on the chip collecting table and is positioned between the jig mounting base and the spindle mounting bases at two sides, namely, the chip collecting channel is positioned right below a workpiece to be processed. During the use, the piece that first processing main shaft device and second processing main shaft device processed the product produced falls into the piece collection passageway under the effect of gravity, through advancing the mutual cooperation of piece opening, play piece opening and chip removal runner, can discharge the piece landing outside the piece collection platform again. Therefore, the utility model has good cleaning effect, is convenient for discharging the scraps out of the equipment in time, effectively prevents the scraps from being difficult to slide out of the lathe and accumulating in a large amount, is convenient for the smooth proceeding of the next procedure, and effectively improves the practicability of the device.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a perspective view of a numerically controlled lathe with a scrap collecting device according to an embodiment of the present utility model.

Fig. 2 is a top view of a numerically controlled lathe with a scrap collecting device according to an embodiment of the present utility model.

Fig. 3 isbase:Sub>A cross-sectional view alongbase:Sub>A-base:Sub>A in fig. 2.

Fig. 4 is a schematic structural diagram of a first processing spindle device and a second processing spindle device according to an embodiment of the present utility model.

Fig. 5 is a schematic structural diagram of an output mounting seat according to an embodiment of the present utility model.

Fig. 6 is a schematic structural diagram of a product fixing jig according to an embodiment of the present utility model.

Wherein, each reference sign in the figure:

100. a debris collection device; 110. a debris collection station; 111. a debris collection channel; 112. a chip inlet opening; 113. a chip outlet opening; 114. chip removal flow channel; 115. a blanking runner; 116. a discharge flow passage; 120. a jig mounting base; 130. a spindle mounting base;

200. a product fixing jig; 210. a product fixing station;

300. a first machining spindle device;

400. a second machining spindle device;

500. rotating the main shaft;

600. a rotary drive motor; 610. a drive belt;

700. a feed drive assembly; 710. a feed drive motor; 720. a feed screw; 730. a feed slide rail; 740. a feed mounting platform; 750. outputting a mounting seat; 751. a spindle mounting hole; 752. a motor mounting surface;

800. a displacement drive assembly; 810. a shift driving motor; 820. a displacement screw; 830. a shifting slide rail; 840. and (5) displacing the mounting platform.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are exemplary and intended to illustrate embodiments of the utility model and should not be construed as limiting the utility model.

In the description of the embodiments of the present utility model, it should be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate description of the embodiments of the present utility model and simplify description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the embodiments of the present utility model, the meaning of "plurality" is two or more, unless explicitly defined otherwise.

In the embodiments of the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured" and the like are to be construed broadly and include, for example, either permanently connected, removably connected, or integrally formed; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the embodiments of the present utility model will be understood by those of ordinary skill in the art according to specific circumstances.

In one embodiment of the present utility model, as shown in fig. 1 to 3, there is provided a numerically controlled lathe having a chip collecting device, comprising:

a debris collection apparatus 100, the debris collection apparatus 100 comprising a debris collection stage 110, a jig mounting base 120 formed to protrude upward along a middle portion of the debris collection stage 110, and a spindle mounting base 130 formed to protrude upward along both sides of the debris collection stage 110;

a product fixing jig 200, wherein the product fixing jig 200 is mounted on the jig mounting base 120, and is used for fixing a plurality of products at the same time;

a first machining spindle device 300, wherein the first machining spindle device 300 is mounted on the left spindle mounting base 130, and is used for machining the left side surface of a product;

a second machining spindle device 400, wherein the second machining spindle device 400 is mounted on the right spindle mounting base 130, and is used for machining the right side surface of the product;

wherein, the chip collecting table 110 is provided with a chip collecting channel 111 between the jig mounting base 120 and the spindle mounting bases 130 on both sides, respectively, for collecting chips generated by the processing products of the first processing spindle device 300 and the second processing spindle device 400;

the chip collection channel 111 includes a chip inlet opening 112, a chip outlet opening 113 and a chip removal flow channel 114; the chip inlet opening 112 is formed on the upper surface of the chip collecting table 110 in a penetrating manner, the chip outlet opening 113 is formed on the side surface of the chip collecting table 110 in a penetrating manner, and two ends of the chip discharging flow passage 114 are communicated with the chip inlet opening 112 and the chip outlet opening 113.

Specifically, in the present embodiment, the present utility model is achieved by providing the chip collecting channel 111 on the chip collecting table 110, and the chip collecting channel 111 is located between the jig mounting base 120 and the two-sided spindle mounting bases 130, i.e., the chip collecting channel 111 is located directly under the workpiece to be processed. In use, chips generated by machining products by the first machining spindle device 300 and the second machining spindle device 400 fall into the chip collecting channel 111 under the action of gravity, and the chips can be discharged out of the chip collecting table 110 in a sliding manner through the mutual cooperation of the chip inlet opening 112, the chip outlet opening 113 and the chip discharging flow channel 114. Therefore, the utility model has good cleaning effect, is convenient for discharging the scraps out of the equipment in time, effectively prevents the scraps from being difficult to slide out of the lathe and accumulating in a large amount, is convenient for the smooth proceeding of the next procedure, and effectively improves the practicability of the device.

In another embodiment of the present utility model, as shown in fig. 3, the chip removing flow channel 114 is configured in an "L" shape, and includes a vertically disposed blanking flow channel 115 and a horizontally disposed discharging flow channel 116, wherein an upper end portion of the blanking flow channel 115 is in communication with the chip inlet opening 112, a lower end portion of the blanking flow channel 115 is in communication with an inner end portion of the discharging flow channel 116, and an outer end portion of the discharging flow channel 116 is in communication with the chip outlet opening 113.

Specifically, in the present embodiment, the connection between the blanking runner 115 and the discharging runner 116 is an inclined transition, so that the chips directly fall down along the blanking runner 115 and then enter the discharging runner 116 through the inclined transition, and the impact of the chips on the discharging runner 116 caused by the direct falling down of the chips is effectively reduced by using the inclined transition, so that the movement of the chips in the blanking runner 115 and the discharging runner 116 is smoother.

In another embodiment of the present utility model, as shown in fig. 4, the first processing spindle device 300 and the second processing spindle device 400 have the same structure, and each includes:

rotating the spindle 500;

a rotary driving motor 600, wherein the rotary driving motor 600 is connected with the rotary main shaft 500 through a transmission belt 610 to drive the rotary main shaft 500 to rotate synchronously;

the feeding driving assembly 700 is connected with the rotating main shaft 500 and the rotating driving motor 600 to drive the rotating main shaft 500 and the rotating driving motor 600 to horizontally move in the X-axis direction;

the displacement driving assembly 800 is connected with the feeding driving assembly 700 to drive the feeding driving assembly 700, the rotating main shaft 500 and the rotating driving motor 600 to translate back and forth in the Y-axis direction.

Specifically, in the present embodiment, the working principles of the first machining spindle device 300 and the second machining spindle device 400 are the same, and when in operation, the rotary driving motor 600 drives the rotary spindle 500 to rotate synchronously, so as to provide the rotary spindle 500 with cutting power of the machined product; secondly, the feeding driving assembly 700 drives the rotary spindle 500 and the rotary driving motor 600 to horizontally move in the X-axis direction, so that the rotary spindle 500 can obtain the feeding amount required by the processed product; finally, the shift driving assembly 800 drives the feed driving assembly 700, the rotary spindle 500 and the rotary driving motor 600 to translate back and forth in the Y-axis direction, so that the rotary spindle 500 can obtain the lateral movement amount required by the processed product. As can be seen, the first and second processing spindle apparatuses 300 and 400 can improve the processing dimensional accuracy of the workpiece, improve productivity, reduce waste products, and save man-hours by the mutual cooperation among the rotary spindle 500, the rotary drive motor 600, the feed drive assembly 700, and the shift drive assembly 800.

In another embodiment of the present utility model, as shown in fig. 4, the displacement drive assembly 800 includes a displacement drive motor 810, a displacement screw 820, a displacement slide 830, and a displacement mounting platform 840; the shift sliding rail 830 is laid on the spindle mounting base 130, the shift mounting platform 840 is slidably disposed on the shift sliding rail 830 and connected with the feeding driving assembly 700, the shift screw 820 is rotatably disposed on the spindle mounting base 130 and is in transmission connection with the shift mounting platform 840, and the shift driving motor 810 is mounted on the spindle mounting base 130 and is connected with the shift screw 820.

Specifically, in this embodiment, the displacement mounting platform 840 carries the feeding driving assembly 700, the rotation driving motor 600 and the rotation spindle 500, when the displacement driving assembly 800 works, the displacement driving motor 810 drives the displacement screw 820 to rotate on the spindle mounting base 130, and the displacement mounting platform 840 is driven to slide back and forth on the displacement sliding rail 830 laid on the spindle mounting base 130 through the screw transmission of the displacement screw 820 and the displacement mounting platform 840, so that the feeding driving assembly 700, the rotation driving motor 600 and the rotation spindle 500 move synchronously along with the displacement mounting platform 840. Therefore, the shift driving assembly 800 can improve the accuracy of the lateral movement amount and the processing reliability of the rotating spindle 500 through the mutual cooperation among the shift driving motor 810, the shift screw 820, the shift sliding rail 830 and the shift mounting platform 840.

In another embodiment of the present utility model, as shown in fig. 4, the feed drive assembly 700 includes a feed drive motor 710, a feed screw 720, a feed slide 730, a feed mounting platform 740, and an output mount 750; the feeding slide rail 730 is laid on the displacement mounting platform 840, the feeding mounting platform 740 is slidably disposed on the feeding slide rail 730 and is connected to the output mounting seat 750, and the rotating main shaft 500 and the rotating driving motor 600 are both mounted on the output mounting seat 750; the feed screw 720 is rotatably disposed on the displacement mounting platform 840 and is in transmission connection with the feed mounting platform 740, and the feed driving motor 710 is mounted on the displacement mounting platform 840 and is connected with the feed screw 720.

Specifically, in this embodiment, the feeding mounting platform 740 carries the output mounting seat 750, the rotating main shaft 500 and the rotating driving motor 600, when the feeding driving assembly 700 works, the feeding driving motor 710 drives the feeding screw 720 to rotate on the shifting mounting platform 840, and the feeding mounting platform 740 is driven to slide left and right on the feeding sliding rail 730 laid on the shifting mounting platform 840 under the transmission of the screw 720 and the screw threads of the feeding mounting platform 740, so that the output mounting seat 750, the rotating main shaft 500 and the rotating driving motor 600 move synchronously along with the feeding mounting platform 740. It can be seen that the feeding driving assembly 700 can improve the feeding accuracy and the processing reliability of the rotary spindle 500 by the mutual cooperation of the feeding driving motor 710, the feeding screw 720, the feeding slide rail 730, the feeding mounting platform 740 and the output mounting seat 750.

In another embodiment of the present utility model, as shown in fig. 5, the output mounting seat 750 is hollow and formed with a spindle mounting hole 751 adapted to the rotary spindle 500, and the rotary spindle 500 is inserted into the output mounting seat 750 through the spindle mounting hole 751.

In particular, in the present embodiment, the assembly between the spin spindle 500 and the output mount 750 is simply inserted into each other through the spin spindle 500 and the spindle mounting hole 751, so that the assembly is fast, easy, and reliable, and the disassembly and maintenance between the spin spindle 500 and the output mount 750 are also flexible and convenient.

In another embodiment of the present utility model, as shown in fig. 5, the top of the output mounting seat 750 is horizontally provided with a motor mounting surface 752 adapted to the rotary driving motor 600, and the rotary driving motor 600 is fixedly mounted on the motor mounting surface 752 through a plurality of screws.

Specifically, in the present embodiment, the assembly between the rotary drive motor 600 and the output mount 750 can be quickly, easily, and reliably assembled by simply aligning the rotary drive motor 600 to the motor mounting surface 752 and then fixedly assembling the rotary drive motor 600 to the motor mounting surface 752 with a plurality of screws, and the disassembly and maintenance between the rotary drive motor 600 and the output mount 750 are also flexible and convenient.

In another embodiment of the present utility model, as shown in fig. 6, a plurality of product fixing stations 210 are disposed on the product fixing jig 200, and the plurality of product fixing stations 210 are uniformly distributed and sequentially arranged along the Y-axis direction.

Specifically, in this embodiment, the product fixing jig 200 can fix a plurality of products simultaneously through a plurality of product fixing stations 210, and then the first processing spindle device 300 and the second processing spindle device 400 perform cutting processing on the products on the plurality of product fixing stations 210 one by one, so that the processing of the plurality of products can be completed without multiple disassembly and assembly, and the production efficiency is greatly improved.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (8)

1. A numerically controlled lathe having a scrap collecting device, comprising:

the device comprises a chip collecting device, a jig mounting base and a spindle mounting base, wherein the jig mounting base is formed by upwards protruding along the middle part of the chip collecting table, and the spindle mounting base is formed by upwards protruding along the two sides of the chip collecting table;

the product fixing jig is arranged on the jig mounting base and is used for simultaneously fixing a plurality of products;

the first processing spindle device is arranged on the left spindle mounting base and is used for processing the left side surface of a product;

the second processing main shaft device is arranged on the main shaft installation base on the right side and is used for processing the right side surface of the product;

the chip collecting tables are respectively provided with a chip collecting channel between the jig mounting base and the spindle mounting bases at two sides and are used for collecting chips generated by processing products by the first processing spindle device and the second processing spindle device;

the chip collecting channel comprises a chip inlet opening, a chip outlet opening and a chip removing flow channel; the chip inlet opening penetrates through the upper surface of the chip collecting table, the chip outlet opening penetrates through the side surface of the chip collecting table, and two end parts of the chip discharging flow passage are communicated with the chip inlet opening and the chip outlet opening.

2. The numerically controlled lathe with scrap collecting device in accordance with claim 1, wherein: the chip removal runner is of an L-shaped structure and comprises a blanking runner which is vertically arranged and a discharging runner which is horizontally arranged, the upper end part of the blanking runner is communicated with the chip inlet opening, the lower end part of the blanking runner is communicated with the inner end part of the discharging runner, and the outer end part of the discharging runner is communicated with the chip outlet opening.

3. The numerically controlled lathe with scrap collecting device in accordance with claim 1, wherein: the first processing main shaft device and the second processing main shaft device have the same structure and both comprise:

rotating the main shaft;

the rotary driving motor is connected with the rotary main shaft through a transmission belt so as to drive the rotary main shaft to synchronously rotate;

the feeding driving assembly is connected with the rotary main shaft and the rotary driving motor so as to drive the rotary main shaft and the rotary driving motor to horizontally move in the X-axis direction;

and the displacement driving assembly is connected with the feeding driving assembly to drive the feeding driving assembly, the rotating main shaft and the rotating driving motor to translate back and forth in the Y-axis direction.

4. A numerically controlled lathe with a scrap collecting device in accordance with claim 3, wherein: the displacement driving assembly comprises a displacement driving motor, a displacement screw rod, a displacement sliding rail and a displacement mounting platform; the shifting slide rail is paved on the main shaft installation base, the shifting installation platform is arranged on the shifting slide rail in a sliding mode and is connected with the feeding driving assembly, the shifting screw is arranged on the main shaft installation base in a rotating mode and is in transmission connection with the shifting installation platform, and the shifting driving motor is arranged on the main shaft installation base and is connected with the shifting screw.

5. The numerically controlled lathe with scrap collecting apparatus in accordance with claim 4, wherein: the feeding driving assembly comprises a feeding driving motor, a feeding screw rod, a feeding sliding rail, a feeding mounting platform and an output mounting seat; the feeding slide rail is paved on the displacement mounting platform, the feeding mounting platform is arranged on the feeding slide rail in a sliding manner and is connected with the output mounting seat, and the rotating main shaft and the rotating driving motor are both mounted on the output mounting seat; the feeding screw is rotatably arranged on the displacement mounting platform and is in transmission connection with the feeding mounting platform, and the feeding driving motor is arranged on the displacement mounting platform and is connected with the feeding screw.

6. The numerically controlled lathe with scrap collecting apparatus in accordance with claim 5, wherein: the output mounting seat is hollow and provided with a main shaft mounting hole matched with the rotary main shaft, and the rotary main shaft is inserted and assembled in the output mounting seat through the main shaft mounting hole.

7. The numerically controlled lathe with scrap collecting apparatus in accordance with claim 6, wherein: the top of the output mounting seat is horizontally provided with a motor mounting surface matched with the rotary driving motor, and the rotary driving motor is fixedly assembled on the motor mounting surface through a plurality of screws.

8. The numerically controlled lathe with chip collection device according to any one of claims 1-7, wherein: the product fixing jig is provided with a plurality of product fixing stations, and the product fixing stations are uniformly distributed along the Y-axis direction and are sequentially arranged.

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