CN111644884A - Machine tool structure for optimizing blanking space - Google Patents

Abstract

The invention relates to a machine tool structure for optimizing blanking space, which comprises a machine tool body and an auxiliary shaft mechanism arranged on the machine tool body, and is characterized in that: the lathe bed is further provided with a mounting seat opposite to the auxiliary shaft mechanism, the mounting seat is provided with a power device, the power device is provided with a plurality of cutters, a discharging mechanism is arranged at the position, located on one side of the auxiliary shaft mechanism, of the lathe bed, the discharging mechanism comprises a material guide piece and a transmission mechanism, the material guide piece is rotatably connected to the lathe bed, the transmission mechanism is connected to the lathe bed and located below the material guide piece, the bottom end of the material guide piece is connected with a linkage piece, and the linkage piece is intermittently abutted to the auxiliary. The invention has the effects of more reasonable space layout of the machine tool and higher space utilization rate in the machine tool.

Description

Machine tool structure for optimizing blanking space

Technical Field

The invention relates to the technical field of machine tools, in particular to a machine tool structure for optimizing blanking space.

Background

Machine tools play an increasingly important role in modern machine manufacturing, but parts with high precision requirements and fine surface roughness requirements generally need to be machined finally by cutting on the machine tool. With the development of industrial technology, the requirement on the machining capacity of the machine tool is higher and higher, so that the types and the number of the tools in the machine tool can be increased in order to enrich the functions of the machine tool and improve the machining efficiency, but the tools are increased while the available space in the machine tool is occupied.

For example, chinese patent publication No. CN206550360U discloses an automatic loading and unloading device for processing disc parts, which includes a rack, a slope slide, a loading cylinder, a pushing cylinder, a discharging cylinder, and a receiving cylinder. The material pushing cylinder and the blanking cylinder are arranged on the X direction of the rack oppositely. The slope slideway comprises an inlet and an outlet, the inlet of the slope slideway is used for placing blanks, the outlet of the slope slideway is aligned to the blanking cylinder, and a chuck is fixedly arranged between the blanking cylinder and the outlet of the slope slideway. And a feeding cylinder is fixedly arranged on the Y direction of the rack and used for pushing the slope slideway to translate along the Y direction of the rack. The material receiving cylinder fixed on the rack is further arranged below the discharging cylinder, and the material receiving cylinder is connected with a material receiving disc.

The above prior art solutions have the following drawbacks: the blanking device occupies the processing space in the machine tool, so that the processing range of the machine tool is reduced, and the spatial arrangement is unreasonable.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a machine tool structure for optimizing blanking space, which has the advantage of optimizing blanking space.

The above object of the present invention is achieved by the following technical solutions: the utility model provides a machine tool structure of optimizing unloading space, includes the lathe bed, sets up in the countershaft mechanism of lathe bed, the lathe bed still is provided with the mount pad relative with countershaft mechanism, the mount pad is provided with power device, power device is provided with a plurality of cutters, the position that the lathe bed is located countershaft mechanism one side is provided with unloading mechanism, unloading mechanism is including rotating the guide piece of connecting in the lathe bed, connecting in the lathe bed and being located the transmission mechanism of guide piece below, guide piece bottom is connected with the linkage, the linkage is contradicted with countershaft mechanism intermittent type.

Through adopting above-mentioned technical scheme, but countershaft mechanism centre gripping work piece removes, at first countershaft mechanism drives the work piece and processes on the cutter on power device, the guide spare is outside upset state this moment, when needs unloading, countershaft mechanism drives the work piece and removes towards guide spare direction, when work piece diameter is great, countershaft mechanism conflicts the linkage piece and continues to promote the linkage piece and rotate, thereby it continues to rotate towards countershaft mechanism to drive guide spare upper end, thereby make the feed inlet of guide spare and countershaft mechanism just in time align, and the guide spare does not collide with the cutter that is close to the guide spare this moment, realize the optimal utilization in space.

The present invention in a preferred example may be further configured to: the material guide piece comprises a material guide cylinder with the bottom end rotatably connected to the lathe bed, the material guide cylinder is in a cylindrical shape and penetrates up and down, a feed inlet is formed in the top of the material guide cylinder, the opening direction of the feed inlet faces to the auxiliary shaft, and the lower end opening of the material guide cylinder is communicated with the transmission mechanism.

By adopting the technical scheme, after the auxiliary shaft mechanism drives the workpiece to be conveyed to the feeding hole, the auxiliary shaft mechanism is moved away, and the material guiding piece is turned outwards again, so that the workpiece falls to the transmission mechanism through the feeding hole and the material guiding barrel and is driven by the transmission mechanism to be conveyed out.

The present invention in a preferred example may be further configured to: the linkage piece is rod-shaped, one end of the linkage piece is connected to the side wall of the guide cylinder, the other end of the linkage piece extends towards the auxiliary shaft mechanism and can be abutted against the auxiliary shaft mechanism, and the lathe bed is connected with a reset piece for resetting the guide cylinder.

Through adopting above-mentioned technical scheme, when countershaft mechanism remove and with the linkage butt towards the linkage, can promote the linkage and rotate downwards, because linkage and guide cylinder fixed connection, and then can drive the guide cylinder and rotate towards countershaft mechanism direction to make the work piece of feed inlet and countershaft mechanism align, the unloading of being convenient for.

The present invention in a preferred example may be further configured to: the guide cylinder side wall is connected with the installation piece, linkage tip rotates to be connected in the installation piece, curved adjustment tank has been seted up to the installation piece, the linkage passes through the bolt and screws up in the adjustment tank, the arc wall uses the center of rotation of linkage as the centre of a circle.

By adopting the technical scheme, when the size of a workpiece to be processed changes, the bolt is unscrewed and the linkage piece is rotated, when the linkage piece rotates downwards, the auxiliary shaft mechanism pushes the linkage piece to rotate in a reduced amplitude, so that the guide cylinder swings towards the auxiliary shaft mechanism in a reduced amplitude, and further adapts to workpiece blanking.

The present invention in a preferred example may be further configured to: the reset piece comprises a spring, one end of the spring is connected to the side wall of the bed body, and the other end of the spring is connected to the top end of the outer wall of the material guide cylinder and applies outward rotating force to the material guide cylinder.

By adopting the technical scheme, when the auxiliary shaft mechanism abuts against the material guide cylinder tightly and pushes the material guide cylinder to rotate towards the auxiliary shaft mechanism, the spring is in a stretching state, when the auxiliary shaft mechanism is moved away, the material guide cylinder can be pulled to rotate and reset under the reset action of the spring, and the limitation is realized by the power device, so that the material guide cylinder is prevented from being excessively turned outwards.

The present invention in a preferred example may be further configured to: the power device comprises a power seat fixedly connected to the mounting seat, four tool apron used for mounting the power head are mounted on one side, facing the auxiliary shaft, of the power seat, the power seat is connected with a driving motor, and the driving motor is located on one side, deviating from the auxiliary shaft mechanism, of the material guide cylinder.

Through adopting above-mentioned technical scheme, blade holder one end is stretched into in the power seat and is connected with the gear, and the other end of blade holder stretches out the power seat and is used for installing the cutter, and driving motor passes through gear structure drive blade holder and drives the cutter and rotate, can cartridge the cutter of different styles on the blade holder, like drill bit, milling cutter etc to make work piece processing more diversified, adaptability is stronger.

The present invention in a preferred example may be further configured to: the auxiliary shaft mechanism comprises a base connected to the lathe bed in a sliding mode, and an auxiliary shaft is connected to the base.

Through adopting above-mentioned technical scheme, the butt plate uses with the linkage cooperation to drive the butt plate and remove for the linkage when the base removes, and promote the linkage and rotate downwards, and then drive the guide cylinder and rotate.

The present invention in a preferred example may be further configured to: the conveying mechanism comprises a conveying belt arranged on the lathe bed, the feeding end of the conveying belt is located below the opening of the guide cylinder, and the discharging end of the conveying belt extends out of the machine.

Through adopting above-mentioned technical scheme, the work piece that the processing was accomplished is by the downward landing of guide cylinder, drops on the conveyer belt and outwards see off by the conveyer belt, realizes the autoloading of work piece, and the unloading is more convenient laborsaving, and efficiency is higher.

The present invention in a preferred example may be further configured to: the mounting groove has been seted up to the lathe bed side, guide cylinder bottom articulates in the mounting groove inner wall, and the mounting groove lateral wall is fixed with proximity sensor, and the proximity sensor level sets up, the bottom of guide cylinder is fixed with the detection piece, and when the guide cylinder resets, proximity sensor detectable detects the detection piece.

Through adopting above-mentioned technical scheme, when connecing the material, push the linkage piece and rotate and drive the guide cylinder and rotate under the butt effect of butt board, the guide cylinder is in the material receiving state and detects piece and proximity sensor separation this moment, when the countershaft withdraws from, the guide cylinder resets under reset spring's effect, it rotates to being close to proximity sensor to detect the piece this moment, it is normal to show operating condition, if proximity sensor does not detect the signal that detects the piece this moment, it does not rotate to primitive state to show the guide cylinder, proximity sensor sends the detected signal to control system, control system control reports to the police, trapezoidal operator has debris card this moment between guide cylinder and the driving motor and goes into, need in time to clear up the adjustment, the risk that the processing brought has been avoided at guide cylinder card dead state.

In summary, the invention includes at least one of the following beneficial technical effects:

the auxiliary shaft mechanism can clamp a workpiece to move, firstly the auxiliary shaft mechanism drives the workpiece to process on a cutter on the power device, the material guiding piece is in an outward turning state at the moment, when blanking is needed, the auxiliary shaft mechanism drives the workpiece to move towards the direction of the material guiding piece, when the diameter of the workpiece is larger, the auxiliary shaft mechanism is abutted against the linkage piece and continuously pushes the linkage piece to rotate, so that the upper end of the material guiding piece is driven to continuously rotate towards the auxiliary shaft mechanism, a feeding hole of the material guiding piece can be aligned with the auxiliary shaft mechanism, and the material guiding piece does not collide with the cutter close to the material guiding piece at the moment, so that the optimal utilization of space;

when the size of a workpiece to be machined changes, the bolt is unscrewed and the linkage piece is rotated, when the linkage piece rotates downwards, the auxiliary shaft mechanism pushes the linkage piece to rotate in a reduced amplitude, so that the amplitude of the guide cylinder swinging towards the auxiliary shaft mechanism is reduced, the workpiece is adaptive to workpiece blanking, and when the linkage piece rotates upwards, the auxiliary shaft mechanism pushes the linkage piece to rotate in an increased amplitude, so that the amplitude of the guide cylinder swinging towards the auxiliary shaft mechanism is increased, and the workpiece is adaptive to workpiece blanking with a large diameter.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic structural view of the material guide member of the present invention.

In the figure, 1, a lathe bed; 2. a counter shaft mechanism; 3. a mounting seat; 4. a power plant; 5. a cutter; 6. a blanking mechanism; 7. a material guide member; 8. a transport mechanism; 9. a linkage member; 10. a material guide cylinder; 11. a feed inlet; 12. a reset member; 13. mounting blocks; 14. an adjustment groove; 15. a power base; 16. a tool apron; 17. a drive motor; 18. a base; 19. a counter shaft; 20. a conveyor belt; 21. a butt joint plate; 22. a proximity sensor; 23. and (6) detecting the sheet.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1 and 2, the machine tool structure for optimizing blanking space disclosed by the invention comprises a machine tool body 1 and an auxiliary shaft mechanism 2 arranged on the machine tool body 1, wherein the machine tool body 1 is further provided with an installation seat 3 opposite to the auxiliary shaft mechanism 2, the installation seat 3 is provided with a power device 4, the power device 4 is provided with a plurality of cutters 5, the machine tool body 1 is provided with a blanking mechanism 6 at one side of the auxiliary shaft mechanism 2, the blanking mechanism 6 comprises a material guide member 7 rotatably connected to the machine tool body 1 and a transmission mechanism 8 connected to the machine tool body 1 and positioned below the material guide member 7, the bottom end of the material guide member 7 is connected with a linkage member 9, the linkage member 9 is intermittently abutted against the auxiliary shaft mechanism 2, and when the linkage member 9 is abutted against the auxiliary shaft mechanism 2, the distance between the top end of the material guide; the auxiliary shaft mechanism 2 can clamp a workpiece to move, firstly, the auxiliary shaft mechanism 2 drives the workpiece to process on a cutter 5 on the power device 4, at the moment, the material guiding piece 7 is in an outward turning state, when blanking is needed, the auxiliary shaft mechanism 2 drives the workpiece to move towards the direction of the material guiding piece 7, when the diameter of the workpiece is large, the auxiliary shaft mechanism 2 is abutted to the linkage piece 9 and continues to push the linkage piece 9 to rotate, so that the upper end of the material guiding piece 7 is driven to continue to rotate towards the auxiliary shaft mechanism 2, a feeding hole 11 of the material guiding piece 7 can be just aligned with the auxiliary shaft mechanism 2, at the moment, the material guiding piece 7 does not collide with the cutter 5 close to the material guiding piece 7.

The material guiding piece 7 comprises a material guiding cylinder 10, the bottom end of the material guiding cylinder is hinged to the lathe bed 1 through a rotating shaft, the material guiding cylinder 10 is arranged in a cylindrical shape penetrating from top to bottom, a feeding hole 11 is formed in the top of the material guiding cylinder 10, the opening direction of the feeding hole 11 is horizontal and faces an auxiliary shaft 19, and the lower end opening of the material guiding cylinder 10 is communicated with the transmission mechanism 8; after the auxiliary shaft mechanism 2 drives the workpiece to be sent to the feeding hole 11, the auxiliary shaft mechanism 2 is moved away, the material guiding piece 7 is turned outwards again, and therefore the workpiece falls to the transmission mechanism 8 through the feeding hole 11 and the material guiding cylinder 10 and is driven by the transmission mechanism 8 to be sent out.

As shown in fig. 1 and 2, the linkage member 9 is provided in a rod shape, one end of the linkage member 9 is connected to a side wall of the material guiding cylinder 10, the other end of the linkage member 9 extends toward the auxiliary shaft mechanism 2 and can abut against the auxiliary shaft mechanism 2, and the bed body 1 is connected with a resetting member 12 for resetting the material guiding cylinder 10; when the auxiliary shaft mechanism 2 moves towards the linkage piece 9 and abuts against the linkage piece 9, the linkage piece 9 can be pushed to rotate downwards, and the linkage piece 9 is fixedly connected with the guide cylinder 10, so that the guide cylinder 10 can be driven to rotate towards the auxiliary shaft mechanism 2, the feed inlet 11 is aligned with a workpiece of the auxiliary shaft mechanism 2, and blanking is facilitated.

As shown in fig. 1 and 2, the side wall of the guide cylinder 10 is connected with an installation block 13, the end of the linkage member 9 is rotatably connected to the installation block 13, the installation block 13 is provided with an arc-shaped adjustment groove 14, the linkage member 9 is screwed on the adjustment groove 14 through a bolt, and the arc-shaped groove takes the rotation center of the linkage member 9 as the center of a circle; when the size of a workpiece needing to be machined changes, the bolt is unscrewed and the linkage piece 9 is rotated, when the linkage piece 9 rotates downwards, the auxiliary shaft mechanism 2 pushes the linkage piece 9 to rotate in a reduced range, so that the swing range of the guide cylinder 10 towards the auxiliary shaft mechanism 2 is reduced, the workpiece is adaptive to blanking, when the linkage piece 9 rotates upwards, the auxiliary shaft mechanism 2 pushes the linkage piece 9 to rotate in an increased range, so that the swing range of the guide cylinder 10 towards the auxiliary shaft mechanism 2 is increased, and the workpiece is adaptive to blanking with a large diameter.

As shown in fig. 1 and 2, the reset element 12 may be a spring, one end of which is connected to the side wall of the bed 1, and the other end of which is connected to the top end of the outer wall of the material guiding drum 10 and applies an outward rotating force to the material guiding drum 10; when the auxiliary shaft mechanism 2 abuts against the material guide cylinder 10 and pushes the material guide cylinder 10 to rotate towards the auxiliary shaft mechanism 2, the spring is in a stretching state, when the auxiliary shaft mechanism 2 is moved away, the material guide cylinder 10 can be pulled to rotate and reset under the reset action of the spring, and the limiting is realized through the power device 4, so that the material guide cylinder 10 is prevented from being excessively turned outwards.

As shown in fig. 1 and 2, the power device 4 includes a power base 15 fixedly connected to the mounting base 3, one side of the power base 15 facing the auxiliary shaft 19 is provided with four tool holders 16 for mounting the power heads, a tool 5 is inserted into the tool holders 16, the power base 15 is connected with a driving motor 17, and the driving motor 17 is located on one side of the material guiding cylinder 10 facing away from the auxiliary shaft mechanism 2; tool apron 16 one end stretches into in the power seat 15 and is connected with the gear, and the other end of tool apron 16 stretches out power seat 15 and is used for installing cutter 5, and driving motor 17 passes through gear structure drive tool apron 16 and drives cutter 5 and rotate, can cartridge the cutter 5 of different styles on tool apron 16, like drill bit, milling cutter etc. to make the work piece processing more diversified, the adaptability is stronger.

As shown in fig. 1 and 2, the auxiliary shaft mechanism 2 includes a base 18 connected to the bed 1 in a sliding manner through lead screws, two sets of lead screws arranged perpendicular to each other drive the base 18 to realize movement of the X axis and the Y axis, an auxiliary shaft 19 is connected to the base 18, a butt plate 21 is further arranged on the base 18, and the butt plate 21 can butt against the linkage 9 and push the linkage 9 to rotate; the abutting plate 21 is matched with the linkage member 9, so that when the base 18 moves, the abutting plate 21 is driven to move relative to the linkage member 9, the linkage member 9 is pushed to rotate downwards, and the guide cylinder 10 is driven to rotate.

The conveying mechanism 8 comprises a conveying belt 20 arranged on the lathe bed 1, the feeding end of the conveying belt 20 is positioned below the opening of the guide cylinder 10, and the discharging end of the conveying belt 20 extends out of the machine; the processed workpiece slides downwards from the material guide cylinder 10, falls onto the conveyor belt 20 and is sent out from the conveyor belt 20, so that the workpiece is automatically fed, the blanking is more convenient and labor-saving, and the efficiency is higher.

As shown in fig. 1 and 2, a mounting groove is formed in a side edge of the bed body 1, a bottom end of the guide cylinder 10 is hinged to an inner wall of the mounting groove, a proximity sensor 22 is fixed to a side wall of the mounting groove, the proximity sensor 22 is horizontally arranged, a detection piece 23 is fixed to the bottom of the guide cylinder 10, and when the guide cylinder 10 is reset, the proximity sensor 22 can detect the detection piece 23; when receiving materials, the linkage part 9 is pushed to rotate under the abutting effect of the abutting plate 21 and the guide cylinder 10 is driven to rotate, at the moment, the guide cylinder 10 is in a material receiving state, the detection sheet is separated from the proximity sensor 22, when the auxiliary shaft 19 is moved away, and the guide cylinder 10 is reset under the action of the reset spring, the detection sheet 23 rotates to be close to the proximity sensor 22, at the moment, the proximity sensor 22 can detect the detection sheet 23, the working state is normal, if the proximity sensor 22 does not detect a signal of the detection sheet 23 at the moment, the guide cylinder 10 does not rotate to the original state, the proximity sensor 22 sends a detection signal to a control system, the control system controls and gives an alarm, an operator is reminded that sundries can be clamped between the guide cylinder 10 and the driving motor 17 at the moment, the timely cleaning and adjustment are needed, and the risk caused by continuous.

The implementation principle of the embodiment is as follows: the auxiliary shaft 19 clamps a workpiece on the corresponding cutter 5 for processing, when blanking is needed, the base 18 moves to drive the workpiece to move towards the direction of the material guide cylinder 10, meanwhile, the abutting plate 21 abuts against the linkage piece 9 and pushes the linkage piece 9 to rotate downwards, and then the upper end of the material guide cylinder 10 is driven to rotate towards the auxiliary shaft 19 until the feed port 11 of the material guide cylinder 10 is aligned with the auxiliary shaft 19, the workpiece on the auxiliary shaft 19 falls on the conveyor belt 20 through the feed port 11 and the material guide cylinder 10, blanking is achieved, and automatic blanking is completed.

The embodiments of the present invention are preferred embodiments of the present invention, and the scope of the present invention is not limited by these embodiments, so: all equivalent changes made according to the structure, shape and principle of the invention are covered by the protection scope of the invention.

Claims (9)

1. The utility model provides an optimize lathe structure in unloading space, includes lathe bed (1), sets up in countershaft mechanism (2) of lathe bed (1), its characterized in that: the automatic blanking machine is characterized in that the machine body (1) is further provided with a mounting seat (3) opposite to the auxiliary shaft mechanism (2), the mounting seat (3) is provided with a power device (4), the power device (4) is provided with a plurality of cutters (5), a blanking mechanism (6) is arranged at the position, located on one side of the auxiliary shaft mechanism (2), of the machine body (1), the blanking mechanism (6) comprises a material guide piece (7) rotatably connected to the machine body (1) and a transmission mechanism (8) connected to the machine body (1) and located below the material guide piece (7), a linkage piece (9) is connected to the bottom end of the material guide piece (7), and the linkage piece (9) is intermittently abutted against the auxiliary shaft mechanism (2).

2. The machine tool structure for optimizing blanking space of claim 1, wherein: the material guide piece (7) comprises a material guide cylinder (10) with the bottom end rotatably connected to the lathe bed (1), the material guide cylinder (10) is arranged in a cylindrical shape and penetrates through the material guide cylinder from top to bottom, a feed port (11) is formed in the top of the material guide cylinder (10), the opening direction of the feed port (11) faces to an auxiliary shaft (19), and the lower end opening of the material guide cylinder (10) is communicated with a transmission mechanism (8).

3. The machine tool structure for optimizing blanking space of claim 2, wherein: the material guide device is characterized in that the linkage piece (9) is in a rod-shaped arrangement, one end of the linkage piece (9) is connected to the side wall of the material guide cylinder (10), the other end of the linkage piece (9) extends towards the auxiliary shaft mechanism (2) and can be abutted against the auxiliary shaft mechanism (2), and the machine body (1) is connected with a reset piece (12) for resetting the material guide cylinder (10).

4. The machine tool structure for optimizing blanking space of claim 3, wherein: the guide cylinder (10) side wall is connected with installation piece (13), linkage (9) tip rotates to be connected in installation piece (13), curved adjustment tank (14) have been seted up in installation piece (13), linkage (9) are screwed up in adjustment tank (14) through the bolt, the arc wall uses the center of rotation of linkage (9) as the centre of a circle.

5. The machine tool structure for optimizing blanking space of claim 3, wherein: the reset piece (12) comprises a spring, one end of the spring is connected to the side wall of the bed body (1), and the other end of the spring is connected to the top end of the outer wall of the material guide cylinder (10) and applies outward rotating force to the material guide cylinder (10).

6. The machine tool structure for optimizing blanking space of claim 1, wherein: the power device (4) comprises a power seat (15) fixedly connected to the mounting seat (3), four tool apron (16) used for installing the power head are installed on one side, facing the auxiliary shaft (19), of the power seat (15), the power seat (15) is connected with a driving motor (17), and the driving motor (17) is located on one side, away from the auxiliary shaft mechanism (2), of the material guide cylinder (10).

7. The machine tool structure for optimizing blanking space of claim 1, wherein: the auxiliary shaft mechanism (2) comprises a base (18) connected to the lathe bed (1) in a sliding mode, and an auxiliary shaft (19) is connected to the base (18).

8. The machine tool structure for optimizing blanking space of claim 2, wherein: the conveying mechanism (8) comprises a conveying belt (20) arranged on the lathe bed (1), the feeding end of the conveying belt (20) is located below the opening of the guide cylinder (10), and the discharging end of the conveying belt (20) extends out of the machine.

9. The machine tool structure for optimizing blanking space of claim 1, wherein: the mounting groove has been seted up to lathe bed (1) side, guide cylinder (10) bottom articulates in the mounting groove inner wall, and the mounting groove lateral wall is fixed with proximity sensor (22), and proximity sensor (22) level sets up, the bottom of guide cylinder (10) is fixed with detects piece (23), and when guide cylinder (10) reset, proximity sensor (22) detectable detects piece (23).

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