CN219403470U - Bus type numerical control machining system - Google Patents

Abstract

The utility model discloses a bus type numerical control machining system, which relates to the field of numerical control machining equipment and comprises a movable base and an outer shell, wherein a scrap collecting box is slidably connected to the inner wall of the top of the movable base, a connecting support is fixedly connected to the top of the movable base, a fixing plate is fixedly arranged on the inner wall of the top of the connecting support, and a screw rod is rotatably connected to the inner wall of the fixing plate. This bus type numerical control system of processing, through sweeps collecting box and edulcoration mechanism that sets up for the edulcoration effect of the device is more good, thereby avoided processing equipment to produce when processing the part the metal waste material pile up the circumstances that causes the follow-up operation of equipment to receive the interference on the surface of workstation to take place, can provide convenient for staff's follow-up cleanness simultaneously, and through the air scoop that sets up, the conveyer pipe, the second air pump, dust collecting mechanism and third T shape draw runner, make the air purification effect of the device more good.

Description

Bus type numerical control machining system

Technical Field

The utility model relates to the field of numerical control machining equipment, in particular to a bus type numerical control machining system.

Background

Numerical control machining is generally a process method for machining parts on a numerical control machine tool, and the numerical control machine tool machining is consistent with the technical specifications of traditional machine tool machining, but is obviously changed, and the machining method for controlling the displacement of the parts and the cutters by using digital information is an effective way for solving the problems of changeable varieties of the parts, small batch, complex shape, high precision and the like and realizing efficient and automatic machining, and along with the high development of modern technology, the precision requirement of people on the parts is increased year by year, so that the application range of numerical control machining equipment is also increased year by year, wherein the application of bus type numerical control machining equipment is one of the most extensive numerical control machining equipment.

However, the existing numerical control processing equipment still has some defects, such as poor impurity removal effect of the existing numerical control processing equipment, so that metal waste generated by the processing equipment when processing parts is easily accumulated on the surface of a workbench, the accumulated waste is easy to interfere with subsequent operation of the equipment, the subsequent cleaning workload of workers is also easy to increase, the air evolution effect of the existing numerical control processing equipment is poor, dust or harmful gas residues are easy to exist in the equipment when processing the parts, and the situation that the inside of a body is irreversibly damaged due to the fact that the workers inhale the residual harmful gas or dust when taking the parts is easy to occur, so that certain use defects exist.

Therefore, the utility model provides a bus type numerical control processing system which aims at researching and improving the defects of the existing structure.

Disclosure of Invention

The utility model aims to provide a bus type numerical control machining system for solving the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a bus formula numerical control system of processing, includes removes base and shell body, remove the top inner wall sliding connection of base has the sweeps collecting box, and remove the top fixedly connected with linking bridge of base to linking bridge's top inner wall fixed mounting has the fixed plate, and the inside rotation of fixed plate is connected with the lead screw moreover, and the tip fixedly connected with motor of lead screw, sliding connection has a mechanism of placing around linking bridge's top, shell body fixed connection is at the top of linking bridge, and the inside of shell body is provided with transverse moving mechanism to transverse moving mechanism's avris swing joint has automatic processing mechanism, and automatic processing mechanism's bottom fixedly connected with edulcoration mechanism, and the top inner wall fixed mounting of shell body has the bucket of breathing in simultaneously, the top of the bucket of breathing in is inlayed and is equipped with the conveyer pipe, and the tip block of conveyer pipe is connected with the second air pump to the bottom of second air pump and the top fixedly connected with of shell body, and the inside sliding connection of shell body has dust collecting mechanism, the inside sliding connection of shell body has the third T shape draw runner, and the tip fixedly connected with air filter screen of third T shape draw runner.

Further, the placing mechanism comprises a part placing table, a cross-shaped sliding block, a connecting mechanism, a first T-shaped sliding bar and an electromagnet, wherein the cross-shaped sliding block is fixedly connected to the bottom of the part placing table, the connecting mechanism is fixedly arranged at the bottom of the cross-shaped sliding block, the inside of the connecting mechanism is movably connected with the side of the screw rod, the first T-shaped sliding bar is fixedly arranged at the bottom of the part placing table, and the electromagnet is embedded at the top of the part placing table.

Further, the number of the first T-shaped sliding strips is two, the two first T-shaped sliding strips are symmetrically arranged by taking the perpendicular bisector of the part placing table as a symmetry axis, and the part placing table forms a sliding structure with the connecting support through the first T-shaped sliding strips.

Further, the edulcoration mechanism includes the connecting rod, inhales hopper, telescopic connecting pipe and first air pump, and the bottom fixedly connected with of connecting rod inhale the hopper to inhale the avris of hopper and inlay and be equipped with telescopic connecting pipe, telescopic connecting pipe's tip block is connected with first air pump moreover, the bottom of first air pump and the top fixed connection of linking bridge simultaneously.

Further, the bottom of connecting rod and the top fixed connection of inhaling the hopper, and the top of connecting rod and the bottom fixed connection of automatic processing mechanism to inhale the hopper and constitute fixed knot through connecting rod and automatic processing mechanism and construct fixed knot.

Furthermore, the number of the air suction hoppers is two, the two air suction hoppers are symmetrically arranged by taking the perpendicular bisectors of the transverse moving mechanism as symmetry axes, and the air suction hoppers and the outer shell form a fixed structure.

Further, the dust collecting mechanism comprises a storage box, a second T-shaped slide bar, a metal filter screen and a sealing plate, wherein the second T-shaped slide bar is fixedly connected to the side of the storage box, the metal filter screen is embedded in the bottom of the storage box, and the sealing plate is fixedly mounted at the end part of the storage box.

Further, the number of the second T-shaped sliding strips is two, the two second T-shaped sliding strips are symmetrically arranged by taking the perpendicular bisector of the storage box as a symmetry axis, and the storage box and the outer shell form a sliding structure through the second T-shaped sliding strips.

The utility model provides a bus type numerical control machining system, which has the following beneficial effects: this bus type numerical control system of processing, through sweeps collecting box and edulcoration mechanism that sets up, make the edulcoration effect of the device more good, thereby avoided processing equipment to produce when processing the part the metal waste material pile up the circumstances that causes the follow-up operation of equipment to receive the interference at the surface of workstation and take place, can provide convenient for staff's follow-up cleanness simultaneously, and through the suction hopper that sets up, the conveyer pipe, the second air pump, dust collecting mechanism and third T shape draw runner, make the air purification effect of the device more good, thereby avoided equipment to process its inside dust or harmful gas to remain when processing the part and cause the staff to take the circumstances that the inside irreversible damage that receives of health that causes in the body with remaining harmful gas or dust to inhale the internal.

1. According to the utility model, a worker opens the first air pump through the controller, when the first air pump starts to operate, waste scraps produced by processing of the automatic processing mechanism are sucked into the waste scraps collecting box through the cooperation of the suction hopper and the telescopic connecting pipe, so that the aim of automatic impurity removal is achieved, and meanwhile, the suction hopper can synchronously move along with the movement of the automatic processing mechanism along with the cooperation of the connecting rod, so that the impurity removal effect of the improved device is better, and the condition that the subsequent operation of the device is disturbed due to the fact that metal waste scraps produced by processing equipment during processing of parts are accumulated on the surface of the workbench is avoided, and meanwhile, convenience is provided for the subsequent cleaning of the worker.

2. According to the utility model, a worker opens the second air pump through the controller, when the second air pump starts to operate, harmful gas in the outer shell is conveyed into the dust collecting mechanism and the air purifying filter screen through the cooperation of the suction hopper and the conveying pipe, and then dust and harmful gas in the air are filtered out completely through multiple filtration of the dust collecting mechanism and the air purifying filter screen, so that the air purifying effect of the improved device is better, and the situation that the inside of the body is irreversibly damaged due to dust or harmful gas residues in the device when the device processes parts is avoided, and the situation that the worker sucks the residual harmful gas or dust into the body when the worker takes the parts is avoided.

Drawings

FIG. 1 is a schematic diagram of a front view of a bus type numerical control machining system according to the present utility model;

FIG. 2 is a schematic diagram of a front cross-sectional structure of a bus type numerical control machining system according to the present utility model;

FIG. 3 is a schematic perspective view of a cross-shaped slide block, a part placement table of the bus type numerical control machining system;

fig. 4 is a schematic perspective view of a storage box-second T-shaped slide bar of the bus type numerical control machining system according to the present utility model.

In the figure: 1. a movable base; 2. a scrap collection box; 3. a connecting bracket; 4. a fixing plate; 5. a screw rod; 6. a motor; 7. a placement mechanism; 71. a part placement table; 72. a cross-shaped sliding block; 73. a connecting mechanism; 74. a first T-shaped slide; 75. an electromagnet; 8. an outer housing; 9. a lateral movement mechanism; 10. an automatic processing mechanism; 11. a impurity removing mechanism; 111. a connecting rod; 112. a suction hopper; 113. a telescopic connecting pipe; 114. a first air pump; 12. an air suction hopper; 13. a delivery tube; 14. a second air pump; 15. a dust collection mechanism; 151. a storage case; 152. a second T-shaped slide; 153. a metal filter screen; 154. a sealing plate; 16. a third T-shaped slide; 17. an air purifying filter screen.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples. The following examples are illustrative of the utility model but are not intended to limit the scope of the utility model.

As shown in fig. 1-3, a bus type numerical control machining system comprises a movable base 1 and an outer shell 8, wherein the inner wall of the top of the movable base 1 is slidably connected with a scrap collecting box 2, the top of the movable base 1 is fixedly connected with a connecting bracket 3, the inner wall of the top of the connecting bracket 3 is fixedly provided with a fixed plate 4, the inside of the fixed plate 4 is rotatably connected with a screw rod 5, meanwhile, the end part of the screw rod 5 is fixedly connected with a motor 6, the top of the connecting bracket 3 is slidably connected with a placing mechanism 7 back and forth, the placing mechanism 7 comprises a part placing table 71, a cross-shaped slide block 72, a connecting mechanism 73, a first T-shaped slide bar 74 and an electromagnet 75, the bottom of the part placing table 71 is fixedly connected with the cross-shaped slide block 72, the bottom of the cross-shaped slide block 72 is fixedly provided with the connecting mechanism 73, the inside of the connecting mechanism 73 is movably connected with the side of the screw rod 5, meanwhile, the bottom of the part placement table 71 is fixedly provided with first T-shaped sliding strips 74, the number of the first T-shaped sliding strips 74 is two, the two first T-shaped sliding strips 74 are symmetrically arranged by taking the perpendicular bisectors of the part placement table 71 as symmetry axes, the part placement table 71 and the connecting bracket 3 form a sliding structure through the first T-shaped sliding strips 74, the part placement table 71 and the connecting bracket 3 which are arranged into the sliding structure can prevent the part placement table 71 from shifting in position when moving, the top of the part placement table 71 is embedded with an electromagnet 75, the part placement table 71 can firmly fix the part to be processed through the arranged electromagnet 75, the outer shell 8 is fixedly connected with the top of the connecting bracket 3, the inside of the outer shell 8 is provided with a transverse moving mechanism 9, and the side of the transverse moving mechanism 9 is movably connected with an automatic processing mechanism 10, the bottom of the automatic processing mechanism 10 is fixedly connected with the impurity removing mechanism 11, the impurity removing mechanism 11 comprises a connecting rod 111, a suction hopper 112, a telescopic connecting pipe 113 and a first air pump 114, the bottom of the connecting rod 111 is fixedly connected with the suction hopper 112, the bottom of the connecting rod 111 is fixedly connected with the top of the suction hopper 112, the top of the connecting rod 111 is fixedly connected with the bottom of the automatic processing mechanism 10, the suction hopper 112 and the automatic processing mechanism 10 form a fixed structure through the connecting rod 111, the suction hopper 112 and the automatic processing mechanism 10 are arranged into the fixed structure, the automatic processing mechanism 10 can not fall off when the suction hopper 112 is driven to move, the telescopic connecting pipe 113 is embedded at the side of the suction hopper 112, the end part of the telescopic connecting pipe 113 is connected with the first air pump 114 in a clamping mode, meanwhile, the bottom of the first air pump 114 is fixedly connected with the top of the connecting bracket 3, and the suction hopper 112 can synchronously move when the automatic processing mechanism 10 moves through the connecting rod 111.

As shown in fig. 1, 2 and 4, the waste dust collecting box 2 is slidingly connected to the inner wall of the top of the mobile base 1, the connecting bracket 3 is fixedly connected to the top of the mobile base 1, the outer casing 8 is fixedly connected to the top of the connecting bracket 3, the suction hoppers 12 are fixedly mounted on the inner wall of the top of the outer casing 8, the number of the suction hoppers 12 is two, the two suction hoppers 12 are symmetrically arranged by taking the perpendicular bisectors of the transverse moving mechanism 9 as symmetry axes, the suction hoppers 12 and the outer casing 8 form a fixed structure, the suction hoppers 12 and the outer casing 8 are arranged into the fixed structure, so that the suction hoppers 12 cannot fall off during operation, the conveying pipe 13 is embedded in the top of the suction hoppers 12, the end part of the conveying pipe 13 is connected with the second air pump 14 in a clamping manner, the bottom of the second air pump 14 is fixedly connected with the top of the outer casing 8, and the dust collecting mechanism 15 is slidingly connected inside the outer casing 8, the dust collecting mechanism 15 comprises a storage box 151, a second T-shaped slide bar 152, a metal filter screen 153 and a sealing plate 154, the second T-shaped slide bar 152 is fixedly connected to the side of the storage box 151, the number of the second T-shaped slide bars 152 is two, the two second T-shaped slide bars 152 are symmetrically arranged by taking the perpendicular bisector of the storage box 151 as a symmetry axis, the storage box 151 and the outer shell 8 form a sliding structure through the second T-shaped slide bar 152, the storage box 151 is convenient for workers to take out from the outer shell 8 through the storage box 151 and the outer shell 8 which are arranged into the sliding structure, the metal filter screen 153 is embedded at the bottom of the storage box 151, the sealing plate 154 is fixedly arranged at the end part of the storage box 151, harmful gas in the outer shell 8 is not easy to overflow after the storage box 151 is closed through the sealing plate 154, the third T-shaped slide bar 16 is connected inside the outer shell 8 in a sliding way, and the end part of the third T-shaped slide bar 16 is fixedly connected with an air purifying filter screen 17.

In summary, the bus type numerical control machining system, firstly, according to the structure shown in fig. 1 to 4, the worker opens the protective door at the outer surface of the outer shell 8, then places the part to be machined on the top of the placing mechanism 7, then the part to be machined can be firmly fixed on the top of the part placing table 71 through the cooperation of the electromagnet 75, then the worker carries out machining route design through the controller, after the route design is finished, the equipment is started, at this time, the motor 6, the transverse moving mechanism 9 and the automatic machining mechanism 10 automatically run, when the motor 6 starts running, the lead screw 5 is driven to rotate in the interior of the fixed plate 4, then the part placing table 71 drives the part to be machined to move forwards and backwards through the connection of the connecting mechanism 73 and the sliding of the cross-shaped sliding block 72 and the first T-shaped sliding bar 74, so as to achieve the purpose of numerical control machining, then the worker opens the first air pump 114 through the controller, the automatic machining mechanism 10 is sucked into the waste air pump 12 through the cooperation of the suction hopper 112 and the telescopic hopper 113 when the first air pump 114 starts running, the waste dust collector 12 is sucked into the automatic machining mechanism 10 through the cooperation of the connecting pipe 12 and the second air pump 14 when the waste dust collector 12 is simultaneously opened through the connecting mechanism 14 and the connecting mechanism 13, the waste dust collector 12 is simultaneously matched with the automatic dust collector 12 is started, the dust and harmful gases in the air are then all filtered out by the multiple filtration of the dust collecting means 15 and the air cleaning filter 17, and finally the worker removes the finished parts from the top of the placement means 7, then grasps the sealing plate 154 and removes the storage case 151 from the inside of the outer case 8 by sliding the second T-shaped slide 152, then dumps out the dust accumulated in the storage case 151 and re-puts it into the inside of the outer case 8, and then removes and cleans or replaces the air cleaning filter 17 by sliding the third T-shaped slide 16 and re-puts it into the inside of the outer case 8, so that the subsequent air cleaning of the apparatus is not disturbed.

The embodiments of the utility model have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the utility model in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, and to enable others of ordinary skill in the art to understand the utility model for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (8)

1. The utility model provides a bus type numerical control machining system, includes mobile base (1) and shell body (8), a serial communication port, the top inner wall sliding connection of mobile base (1) has sweeps collecting box (2), and the top fixedly connected with linking bridge (3) of mobile base (1), and the top inner wall fixed mounting of linking bridge (3) has fixed plate (4), and the inside rotation of fixed plate (4) is connected with lead screw (5), the tip fixedly connected with motor (6) of lead screw (5) simultaneously, sliding connection has placing mechanism (7) around the top of linking bridge (3), shell body (8) fixed connection is at the top of linking bridge (3), and the inside of shell body (8) is provided with lateral shifting mechanism (9), and the avris swing joint of lateral shifting mechanism (9) has automatic processing mechanism (10), and the bottom fixedly connected with edulcoration mechanism (11) of automatic processing mechanism (10), the top inner wall fixed mounting of shell body (8) has suction hopper (12) simultaneously, the top of suction hopper (12) is inlayed and is equipped with conveyer pipe (13), and the bottom of second air pump (14) of conveyer pipe (13) and the top of second air pump (14) and the fixed connection of top body (14), and the inside sliding connection of shell body (8) has dust collection mechanism (15), the inside sliding connection of shell body (8) has third T shape draw runner (16), and the tip fixedly connected with air purification filter screen (17) of third T shape draw runner (16).

2. The bus type numerical control machining system according to claim 1, wherein the placement mechanism (7) comprises a part placement table (71), a cross-shaped sliding block (72), a connecting mechanism (73), a first T-shaped sliding bar (74) and an electromagnet (75), the bottom of the part placement table (71) is fixedly connected with the cross-shaped sliding block (72), the connecting mechanism (73) is fixedly arranged at the bottom of the cross-shaped sliding block (72), the inside of the connecting mechanism (73) is movably connected with the side of the screw rod (5), the first T-shaped sliding bar (74) is fixedly arranged at the bottom of the part placement table (71), and the electromagnet (75) is embedded at the top of the part placement table (71).

3. The bus type numerical control machining system according to claim 2, wherein the number of the first T-shaped sliding strips (74) is two, the two first T-shaped sliding strips (74) are symmetrically arranged by taking a perpendicular bisector of the part placement table (71) as a symmetry axis, and the part placement table (71) and the connecting bracket (3) form a sliding structure through the first T-shaped sliding strips (74).

4. The bus type numerical control machining system according to claim 1, wherein the impurity removing mechanism (11) comprises a connecting rod (111), a suction hopper (112), a telescopic connecting pipe (113) and a first air pump (114), the bottom of the connecting rod (111) is fixedly connected with the suction hopper (112), the telescopic connecting pipe (113) is embedded at the side of the suction hopper (112), the first air pump (114) is connected with the end part of the telescopic connecting pipe (113) in a clamping manner, and meanwhile, the bottom of the first air pump (114) is fixedly connected with the top of the connecting bracket (3).

5. The bus type numerical control machining system according to claim 4, wherein the bottom of the connecting rod (111) is fixedly connected with the top of the suction hopper (112), the top of the connecting rod (111) is fixedly connected with the bottom of the automatic machining mechanism (10), and the suction hopper (112) and the automatic machining mechanism (10) form a fixed structure through the connecting rod (111).

6. The bus type numerical control machining system according to claim 1, wherein the number of the suction hoppers (12) is two, the two suction hoppers (12) are symmetrically arranged with the center vertical line of the transverse moving mechanism (9) as a symmetry axis, and the suction hoppers (12) and the outer casing (8) form a fixed structure.

7. The bus type numerical control machining system according to claim 1, wherein the dust collecting mechanism (15) comprises a storage box (151), a second T-shaped sliding strip (152), a metal filter screen (153) and a sealing plate (154), the second T-shaped sliding strip (152) is fixedly connected to the side of the storage box (151), the metal filter screen (153) is embedded in the bottom of the storage box (151), and the sealing plate (154) is fixedly installed at the end of the storage box (151).

8. The bus type numerical control machining system according to claim 7, wherein the number of the second T-shaped sliding strips (152) is two, the two second T-shaped sliding strips (152) are symmetrically arranged with a perpendicular bisector of the storage box (151) as a symmetry axis, and the storage box (151) and the outer shell (8) form a sliding structure through the second T-shaped sliding strips (152).