CN211759775U - Numerical control drilling and tapping integrated machine tool for flange - Google Patents

Abstract

The utility model discloses an integrative lathe of numerical control drilling tapping for flange of machining technical field, include: a base; the first transmission assembly is mounted on a transverse moving plate assembly at the bottom of the right side of the base through a bolt, and the transverse moving plate assembly is mounted at the top of the base; a rotating disk mounted on top of the traverse plate assembly; the second transmission assembly is arranged at the top of the vertical plate through a bolt; the vertical moving frame assembly is arranged on the left side surface of the vertical plate; the drilling motor is installed at the top of the vertical moving frame assembly through a bolt; tapping motor, the tapping motor passes through the bolt and installs the bottom of vertical removal frame subassembly, the utility model discloses can do tapping processing to the hole in-process of doing spot facing work to the work piece, very big improvement work efficiency and machining precision.

Description

Numerical control drilling and tapping integrated machine tool for flange

Technical Field

The utility model relates to a machining technical field specifically is an integrative lathe of numerical control drilling tapping for flange.

Background

Machining refers to a process of changing the physical dimensions or properties of a workpiece by a mechanical device. The difference in the machining method can be divided into cutting machining and pressing machining.

In either machine, no holes are made. Screw holes, pin holes or rivet holes of various sizes are required for connecting parts; various mounting holes are required for fixing the transmission part; the machine parts themselves also have a variety of holes (e.g., oil holes, fabrication holes, lightening holes, etc.). The operation of machining a hole to make it desirable is called hole machining. The inner bore surface is one of the important surfaces that make up a mechanical part. In mechanical parts, the perforated parts generally account for 50% to 80% of the total number of parts. The type of hole is also various, and there are cylindrical hole, conical hole, threaded hole, shaped hole, and the like.

Need carry out spot facing work and the tapping to the flange in the production process of flange, present flange hole worker is mostly fixed the flange on anchor clamps, and the rethread drill carries out spot facing work to the flange, and rethread tap carries out the tapping to the flange after spot facing work is accomplished, need carry out the secondary centre gripping to the flange in the tapping process, very big influence the machining precision and need carry out the secondary centre gripping to the flange, operate too loaded down with trivial details to the production efficiency of flange has seriously been influenced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an integrative lathe of numerical control drilling tapping for flange, need carry out spot facing work and tapping to the flange in the production process of the flange that proposes in solving above-mentioned background art, present flange hole worker is mostly to fix the flange on anchor clamps, the rethread drill carries out spot facing work to the flange, rethread tap carries out the tapping to the flange after spot facing work is accomplished, need carry out the secondary centre gripping to the flange in the tapping process, very big influence the machining precision and need carry out the secondary centre gripping to the flange, the operation is too loaded down with trivial details, thereby the production efficiency's of flange problem has been seriously influenced.

In order to achieve the above object, the utility model provides a following technical scheme: a numerical control drilling and tapping integrated machine tool for flanges comprises:

a base;

a first transmission component installed at the bottom of the right side of the base through a bolt

The transverse moving plate assembly is mounted at the top of the base and is connected with the first transmission assembly;

a rotating disk mounted on top of the traverse plate assembly;

the vertical plate is arranged on the right side of the top of the base and corresponds to the transverse moving plate assembly;

the second transmission assembly is arranged at the top of the vertical plate through a bolt;

the vertical moving frame assembly is mounted on the left side face of the vertical plate and is connected with the second transmission assembly;

the drilling motor is installed at the top of the vertical moving frame assembly through a bolt, and an output shaft at the bottom of the drilling motor is inserted into the top of an inner cavity of the vertical moving frame assembly;

the tapping motor is installed at the bottom of the vertical moving frame assembly through a bolt, and an output shaft at the top of the tapping motor is inserted into the bottom of an inner cavity of the vertical moving frame assembly.

Preferably, the base includes:

a base body;

the two first sliding grooves are transversely arranged at the front end and the rear end of the top of the base body in tandem, and are parallel;

the first moving groove is transversely formed in the middle end of the top of the base body and is parallel to the first sliding groove.

Preferably, the first transmission assembly comprises:

a first motor;

and the first screw rod is installed on the left output shaft of the first motor through spline connection.

Preferably, the traverse plate assembly includes:

transversely moving the plate;

the two first sliding blocks are transversely arranged at the front end and the rear end of the bottom of the transverse moving plate in tandem, and are parallel;

the first moving block is transversely arranged at the middle end of the bottom of the transverse moving plate and is parallel to the first sliding block;

and the rotating motor is arranged at the middle end of the top of the transverse moving plate through a bolt.

Preferably, the rotating disk includes:

a rotating disk body;

the electromagnet is embedded on the front surface of the rotating disk body, and the front surface of the electromagnet is flush with the front surface of the rotating disk body.

Preferably, the riser includes:

a vertical plate body;

the two second sliding grooves are vertically arranged at the front end and the rear end of the top of the vertical plate body in tandem, and are parallel;

and the second moving groove is vertically arranged at the middle end of the top of the vertical plate body and is parallel to the second sliding groove.

Preferably, the second transmission assembly comprises:

a second motor;

and the second screw rod is connected and installed on the bottom output shaft of the second motor through a spline.

Preferably, the vertical moving frame assembly includes:

a vertical moving frame;

the two second sliding blocks are vertically arranged at the front end and the rear end of the right side of the vertical moving frame in tandem, and the two second sliding blocks are parallel;

the second moving block is vertically arranged at the right middle end of the vertical moving frame and is parallel to the second sliding block.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model can tap holes in the process of processing holes on a processed workpiece, greatly improves the working efficiency and the processing precision, the first moving block is matched with the first moving groove, the first moving block is inserted in the inner side of the first moving groove, the right side of the first moving block is provided with a threaded hole which runs through the left side surface of the first moving block, the threaded hole is matched with the first screw rod, the first moving block is arranged on the outer wall of the first screw rod through threaded connection, the first screw rod is driven to rotate through an output shaft on the first motor, the first moving block is driven to move transversely through the first screw rod (lead screw transmission principle), the transverse moving plate is driven to move transversely through the first moving block, the rotating motor is driven to move transversely through the transverse moving plate, the rotating motor is a stepping motor, and the rotating motor is connected with a driver and a PLC controller through a lead wire, the rotation angle of the rotating motor is controlled by the driver and the PLC, the flange can be rotated at equal angles, the second moving block is matched with the second moving groove and is inserted into the inner side of the second moving groove, the top of the second moving block is provided with a threaded hole which is matched with the second screw, the second moving block is installed on the outer wall of the second screw through threaded connection, the second screw is driven to rotate through an output shaft at the bottom of the second motor, the second moving block is driven to vertically move through the second screw (lead screw transmission principle), the vertical moving frame is driven to vertically move through the second moving block, the tapping motor and the drilling motor are coaxially arranged, the tapping motor and the drilling motor are driven to vertically move through the vertical moving frame, the flange is processed through the drilling motor, and after the hole processing is completed, the tapping motor is used for tapping the hole, the flange can be coaxially processed by hole processing and screw tapping, and the working efficiency and the processing precision are improved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the base structure of the present invention;

fig. 3 is a schematic structural view of the first transmission assembly of the present invention;

FIG. 4 is a schematic structural view of the lateral shifting plate assembly of the present invention;

FIG. 5 is a schematic view of a rotary disk structure of the present invention;

fig. 6 is a schematic structural view of the vertical plate of the present invention;

fig. 7 is a schematic structural view of a second transmission assembly of the present invention;

fig. 8 is the structural schematic diagram of the vertical moving frame assembly of the present invention.

In the figure: the drilling machine comprises a base 100, a base body 110, a first sliding groove 120, a first moving groove 130, a first transmission assembly 200, a first motor 210, a first screw 220, a transverse moving plate assembly 300, a transverse moving plate 310, a first sliding block 320, a first moving block 330, a rotary motor 340, a rotary disk 400, a rotary disk body 410, an electromagnet 420, a vertical plate 500, a vertical plate body 510, a second sliding groove 520, a second moving groove 530, a second transmission assembly 600, a second motor 610, a second screw 620, a vertical moving frame assembly 700, a vertical moving frame 710, a second sliding block 720, a second moving block 730, a drilling motor 800 and a tapping motor 900.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The utility model provides a numerical control drilling and tapping integrated machine tool for flange can do tapping to the hole in the process of doing the spot facing work to the work piece, very big improvement work efficiency and machining precision, please refer to fig. 1, base 100, first drive assembly 200, horizontal moving plate subassembly 300, rotary disk 400, riser 500, second drive assembly 600, vertical moving frame subassembly 700, drilling motor 800 and tapping motor 900;

referring to fig. 1 and 2, the base 100 includes:

a base body 110;

the two first sliding grooves 120 are transversely arranged at the front end and the rear end of the top of the base body 110 in tandem, and the two first sliding grooves 120 are parallel;

the first moving slot 130 is transversely arranged at the top middle end of the base body 110, and the first moving slot 130 is parallel to the first sliding slot 120;

referring to fig. 1-3, a first transmission assembly 200 is mounted on the bottom of the right side of the base 100 by bolts, the first transmission assembly 200 includes:

the first motor 210 is installed at the right middle end of the base body 110 through a bolt, and the first motor 210 corresponds to the first moving groove 130;

the first screw 220 is connected and installed on the left output shaft of the first motor 210 through a spline, the first screw 220 is transversely installed on the inner side of the first moving groove 130 through the first motor 210, and the output shaft of the first motor 210 drives the first screw 220 to rotate;

referring to fig. 1-4, the lateral moving plate assembly 300 is mounted on the top of the base 100, the lateral moving plate assembly 300 is connected to the first transmission assembly 200, and the lateral moving plate assembly 300 includes:

the bottom of the traverse plate 310 contacts the top of the base body 110;

the two first sliders 320 are transversely arranged at the front end and the rear end of the bottom of the transverse moving plate 310 in tandem, the two first sliders 320 are parallel, the first sliders 320 are matched with the first sliding grooves 120, the first sliders 320 are inserted into the inner sides of the first sliding grooves 120, the transverse moving plate 310 is arranged at the top of the base body 110 through the matching use of the first sliders 320 and the first sliding grooves 120, and the transverse moving plate 310 can transversely move at the top of the base body 110 through the matching use of the first sliders 320 and the first sliding grooves 120;

the first moving block 330 is transversely arranged at the middle end of the bottom of the transverse moving plate 310, the first moving block 330 is parallel to the first sliding block 320, the first moving block 330 is matched with the first moving groove 130, the first moving block 330 is inserted into the inner side of the first moving groove 130, a threaded hole is formed in the right side of the first moving block 330, the threaded hole penetrates through the left side surface of the first moving block 330, the threaded hole is matched with the first screw 220, the first moving block 330 is installed on the outer wall of the first screw 220 through threaded connection, the first screw 220 is driven to rotate through an output shaft on the first motor 210, the first moving block 330 is driven to transversely move through the first screw 220 (lead screw transmission principle), and the transverse moving plate 310 is driven to transversely move through the first moving block 330;

the rotating motor 340 is installed at the middle end of the top of the transverse moving plate 310 through a bolt, the transverse moving plate 310 drives the rotating motor 340 to transversely move, the rotating motor 340 is a stepping motor, the rotating motor 340 is connected with a driver and a PLC (programmable logic controller) through a wire, the driver and the PLC control are used for controlling the rotating angle of the rotating motor 340, and the flange can be rotated at equal angles;

referring to fig. 1 to 5, a rotating plate 400 is installed on the top of the transverse moving plate assembly 300, the rotating plate 400 including:

the rotating disc body 410 is connected and installed on the top output shaft of the rotating motor 340 through a spline, and the rotating disc body 410 is driven to rotate through the top output shaft of the rotating motor 340;

the electromagnet 420 is embedded on the front surface of the rotating disk body 410, the front surface of the electromagnet 420 is flush with the front surface of the rotating disk body 410, and the flange is adsorbed and fixed through the electromagnet 420;

referring to fig. 1, 2 and 6, the vertical plate 500 is installed on the right side of the top of the base 100, the vertical plate 500 corresponds to the lateral moving plate assembly 300, and the vertical plate 500 includes:

the vertical plate body 510 is mounted on the top of the base body 110 through bolts, and the right side surface of the vertical plate body 510 is flush with the right side surface of the base body 110;

the two second sliding grooves 520 are vertically arranged at the front end and the rear end of the top of the vertical plate body 510 in tandem, and the two second sliding grooves 520 are parallel;

the second moving groove 530 is vertically formed in the middle end of the top of the vertical plate body 510, and the second moving groove 530 is parallel to the second sliding groove 520;

referring to fig. 1 and 6 to 7, a second driving assembly 600 is mounted on the top of the vertical plate 500 by bolts, and the second driving assembly 600 includes:

the second motor 610 is installed at the top middle end of the riser body 510 through a bolt, and the second motor 610 corresponds to the second moving groove 530;

the second screw 620 is connected and installed on the output shaft at the bottom of the second motor 610 through a spline, the second screw 620 is vertically installed on the inner side of the second moving groove 530 through the second motor 610, and the second screw 620 is driven to rotate through the output shaft at the bottom of the second motor 610;

referring to fig. 1 and 6 to 8, the vertical moving frame assembly 700 is installed at the left side of the vertical plate 500, the vertical moving frame assembly 700 is connected to the second transmission assembly 600, and the vertical moving frame assembly 700 includes:

the right side of the vertical moving frame 710 is in contact with the left side surface of the vertical plate body 510;

the two second sliding blocks 720 are vertically arranged at the front end and the rear end of the right side of the vertical moving frame 710 in tandem, the two second sliding blocks 720 are parallel, the second sliding blocks 720 are matched with the second sliding groove 520, the second sliding blocks 720 are inserted into the inner side of the second sliding groove 520, the vertical moving frame 710 is arranged on the left side surface of the vertical plate body 510 through the matching use of the second sliding blocks 720 and the second sliding groove 520, and the vertical moving frame 710 can vertically move on the left side surface of the vertical plate body 510 through the matching use of the second sliding blocks 720 and the second sliding groove 520;

the second moving block 730 is vertically arranged at the right middle end of the vertical moving frame 710, the second moving block 730 is parallel to the second sliding block 720, the second moving block 730 is matched with the second moving groove 530, the second moving block 730 is inserted into the second moving groove 530, a threaded hole is formed in the top of the second moving block 730 and is matched with the second screw 620, the second moving block 730 is installed on the outer wall of the second screw 620 through threaded connection, the second screw 620 is driven to rotate through an output shaft at the bottom of the second motor 610, the second moving block 730 is driven to vertically move through the second screw 620 (a lead screw transmission principle), and the vertical moving frame 710 is driven to vertically move through the second moving block 730;

referring to fig. 1 and 8, a drilling motor 800 is mounted on the top of the vertical moving frame 710 through a bolt, an output shaft at the bottom of the drilling motor 800 is inserted into the top of an inner cavity of the vertical moving frame 710, and a drill bit is mounted on the output shaft at the bottom of the drilling motor 800;

referring to fig. 1 and 8, the tapping motor 900 is mounted at the bottom of the vertical moving frame 710 through a bolt, an output shaft at the top of the tapping motor 900 is inserted into the bottom of the inner cavity of the vertical moving frame 710, a tap is mounted on an output shaft at the bottom of the tapping motor 900, and the tapping motor 900 and the drilling motor 800 are coaxially arranged.

When the flange drilling machine is used specifically, an unprocessed flange is placed on the top of the rotating disk body 410, a power supply of the electromagnet 420 is switched on, the electromagnet 420 is electrified to generate magnetism to adsorb the flange on the top of the rotating disk body 410, the first motor 210 is started, the transverse moving plate 310 is driven to transversely move through the first motor 210, the rotating disk body 410 is driven to transversely move through the transverse moving plate 310, the flange is driven to transversely move through the rotating disk body 410 to be adjacent to the position of the vertical moving frame 710, then the second motor 610 is started, the vertical moving frame 710 is driven to vertically move through the second motor 610, the groove part on the left side of the vertical moving frame 710 corresponds to the flange, the flange is inserted into the inner side of the groove on the left side of the vertical moving frame 710 through the first motor 210, the drilling motor 800 and the tapping motor 900 are started between a drill bit and a tap, an output shaft, restart second motor 610, drive vertical removal frame 710 through second motor 610 and move down and drill to the flange, recycle second motor 610 and promote vertical removal frame 710, tap the flange through the tap at tapping motor 900 top, drive the angle of rotary disk body 410 swivelling movement through rotating electrical machines 340, action more than repeating once more, drill and the tapping to the flange, can carry out coaxial processing by the flange, improved production efficiency and machining precision.

While the invention has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, as long as there is no structural conflict, the various features of the disclosed embodiments of the present invention can be used in any combination with each other, and the description of such combinations is not exhaustive in the present specification only for the sake of brevity and resource conservation. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (8)

1. The utility model provides an integrative lathe of numerical control drilling tapping for flange which characterized in that: the method comprises the following steps:

a base (100);

a first transmission assembly (200), wherein the first transmission assembly (200) is installed at the bottom of the right side of the base (100) through a bolt;

a lateral movement plate assembly (300), the lateral movement plate assembly (300) being mounted on top of the base (100), the lateral movement plate assembly (300) being connected with the first transmission assembly (200);

a rotating disk (400), the rotating disk (400) being mounted on top of the traverse plate assembly (300);

the vertical plate (500), the vertical plate (500) is installed on the right side of the top of the base (100), and the vertical plate (500) corresponds to the transverse moving plate component (300);

the second transmission assembly (600), the second transmission assembly (600) is installed on the top of the vertical plate (500) through a bolt;

the vertical moving frame assembly (700), the vertical moving frame assembly (700) is installed on the left side surface of the vertical plate (500), and the vertical moving frame assembly (700) is connected with the second transmission assembly (600);

the drilling motor (800) is mounted at the top of the vertical moving frame assembly (700) through a bolt, and an output shaft at the bottom of the drilling motor (800) is inserted into the top of an inner cavity of the vertical moving frame assembly (700);

the tapping motor (900), the tapping motor (900) passes through the bolt and installs the bottom of vertical removal frame subassembly (700), the output shaft at tapping motor (900) top is pegged graft the inner chamber bottom of vertical removal frame subassembly (700).

2. The numerical control drilling and tapping integrated machine tool for the flange according to claim 1, characterized in that: the base (100) comprises:

a base body (110);

the two first sliding chutes (120) are transversely arranged at the front end and the rear end of the top of the base body (110) in tandem, and the two first sliding chutes (120) are parallel;

the first moving groove (130) is transversely formed in the middle end of the top of the base body (110), and the first moving groove (130) is parallel to the first sliding groove (120).

3. The numerical control drilling and tapping integrated machine tool for the flange according to claim 1, characterized in that: the first transmission assembly (200) comprises:

a first motor (210);

the first screw (220), the first screw (220) is installed on the left side output shaft of the first motor (210) through the spline connection.

4. The numerical control drilling and tapping integrated machine tool for the flange according to claim 1, characterized in that: the lateral movement plate assembly (300) includes:

a traverse plate (310);

the two first sliding blocks (320) are transversely arranged at the front end and the rear end of the bottom of the transverse moving plate (310) in tandem, and the two first sliding blocks (320) are parallel;

the first moving block (330), the first moving block (330) is transversely arranged at the middle end of the bottom of the transverse moving plate (310), and the first moving block (330) is parallel to the first sliding block (320);

a rotating motor (340), wherein the rotating motor (340) is installed at the top middle end of the transverse moving plate (310) through a bolt.

5. The numerical control drilling and tapping integrated machine tool for the flange according to claim 1, characterized in that: the rotating disk (400) comprises:

a rotating disk body (410);

the electromagnet (420) is embedded on the front surface of the rotating disk body (410), and the front surface of the electromagnet (420) is flush with the front surface of the rotating disk body (410).

6. The numerical control drilling and tapping integrated machine tool for the flange according to claim 1, characterized in that: the riser (500) includes:

a riser body (510);

the two second sliding grooves (520) are vertically arranged at the front end and the rear end of the top of the vertical plate body (510) in tandem, and the two second sliding grooves (520) are parallel;

the second moving groove (530) is vertically arranged at the middle end of the top of the vertical plate body (510), and the second moving groove (530) is parallel to the second sliding groove (520).

7. The numerical control drilling and tapping integrated machine tool for the flange according to claim 1, characterized in that: the second transmission assembly (600) comprises:

a second motor (610);

and the second screw (620), the second screw (620) is installed on the bottom output shaft of the second motor (610) through spline connection.

8. The numerical control drilling and tapping integrated machine tool for the flange according to claim 1, characterized in that: the vertical moving frame assembly (700) includes:

a vertical moving frame (710);

the two second sliding blocks (720) are vertically arranged at the front end and the rear end of the right side of the vertical moving frame (710) in tandem, and the two second sliding blocks (720) are parallel;

the second moving block (730), the second moving block (730) is vertically arranged at the right middle end of the vertical moving frame (710), and the second moving block (730) is parallel to the second sliding block (720).

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