CN211052655U - Heavy milling machine ray apparatus structure - Google Patents

Abstract

The utility model relates to a heavy milling processing ray apparatus structure, include: the upper side of the base is provided with a workbench; two Y-axis sliding tables are arranged, and the two Y-axis sliding tables are oppositely arranged on two sides of the workbench; the movable beam is arranged between the two Y-axis sliding tables, two ends of the movable beam are respectively connected with the Y-axis sliding tables in a sliding manner, and the movable beam is provided with an X-axis transmission assembly; the milling assembly is arranged on the movable beam, one side of the milling assembly is connected with the movable beam in a sliding mode, and the output end of the X-axis transmission assembly is in transmission connection with the milling assembly. The utility model discloses set up Y axle slip table in the side of workstation to on will milling the subassembly and installing the walking beam, can more urgently need the adjustment to mill the position of subassembly, process large-scale or heavy part, machining efficiency is high.

Description

Heavy milling machine ray apparatus structure

Technical Field

The utility model relates to a heavy lathe processing technology field especially relates to a heavy milling processing ray apparatus structure.

Background

At present, along with the increasing and wider demands of various large and heavy parts at home and abroad, when the parts are machined, not only can the excircle, the end face and the inner hole of the part be machined, but also the part needs to be milled, and during milling, the machined point position needs to be positioned, the part is usually moved to a milling cutter and is milled, so that the cost of the machine tool is higher, the occupied area of a heavy lathe is large during milling, the heavy type connection is milled, the lathe is easy to vibrate due to heavy type milling, and the machining precision is lower.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a solve above-mentioned technical problem and provide a well xing milling processing ray apparatus structure that simple structure, machining efficiency are high to solve above-mentioned at least one technical problem.

The utility model provides an above-mentioned technical problem's technical scheme as follows:

a heavy duty milling light engine structure comprising:

the upper side of the base is provided with a workbench;

two Y-axis sliding tables are arranged, and the two Y-axis sliding tables are oppositely arranged on two sides of the workbench;

the movable beam is arranged between the two Y-axis sliding tables, two ends of the movable beam are respectively connected with the Y-axis sliding tables in a sliding mode, and an X-axis transmission assembly is arranged on the movable beam;

the milling assembly is arranged on the movable beam, one side of the milling assembly is connected with the movable beam in a sliding mode, and the output end of the X-axis transmission assembly is in transmission connection with the milling assembly.

The utility model has the advantages that: the utility model discloses set up Y axle slip table in the side of workstation to on will milling the subassembly and installing the walking beam, can more urgently need the adjustment to mill the position of subassembly, process large-scale or heavy part, machining efficiency is high.

On the basis of the technical scheme, the utility model discloses can also do following improvement.

Further, every Y axle slip table with all be equipped with a plurality of stands between the base, the lower extreme of stand with the base passes through bolt fixed connection, the upper end of stand with Y axle slip table fixed connection.

The beneficial effect of adopting the further scheme is that: the stand can play the supporting role to Y axle slip table, can reduce the whole weight of lathe simultaneously, promotes the anti-seismic performance of lathe.

Furthermore, the bottom of walking beam is equipped with the reinforcing plate, the both ends of reinforcing plate with Y axle slip table sliding connection, the walking beam is fixed in on the reinforcing plate.

The beneficial effect of adopting the further scheme is that: the movable beam is arranged on the reinforcing plate, so that the sliding stability of the milling assembly on the movable beam can be ensured, and the stability of the milling assembly during machining is improved.

Furthermore, the movable beam and the Y-axis sliding table are both made of granite.

The beneficial effect of adopting the further scheme is that: granite is nonmagnetic, and has good anti-plastic deformation, and can effectively avoid machining dimension errors.

Further, every the equal parallel two Y guide rails that are provided with of the side wall on the upside of Y axle slip table, the one end of reinforcing plate all with Y guide rail sliding connection.

The beneficial effect of adopting the further scheme is that: two Y guide rails can be to the stability of guaranteeing to lead between the reinforcing plate.

Further, two be equipped with the rack between the Y guide rail, the rack with Y guide rail parallel arrangement, all be equipped with Y axle motor on the both ends of reinforcing plate, be equipped with on the output of Y axle motor with rack toothing's gear, Y axle motor passes through the gear with rack transmission is connected.

The beneficial effect of adopting the further scheme is that: set up the action rack that Y axle motor passes through the gear on the reinforcing plate, can drive the reinforcing plate and slide along the extending direction of Y guide rail, stability when can keeping the reinforcing plate to remove.

Furthermore, one side of the movable beam is provided with two first X guide rails in parallel, and one side of the milling assembly is connected with the first X guide rails in a sliding mode.

The beneficial effect of adopting the further scheme is that: the first X guide rail arranged on the side face can play a role in guiding and keeps the stability of the milling assembly.

Furthermore, a mounting groove is formed in the movable beam between the two first X guide rails, and the X-axis transmission assembly is arranged in the mounting groove and is in transmission connection with the milling assembly.

The beneficial effect of adopting the further scheme is that: an X-axis transmission assembly is arranged in the mounting groove, and the milling assembly can be effectively driven to slide along the movable beam.

Furthermore, the X-axis transmission assembly comprises a transmission screw rod and a driving motor, the output end of the driving motor is in transmission connection with one end of the transmission screw rod, and the transmission screw rod is in transmission connection with the milling assembly screw rod.

The beneficial effect of adopting the further scheme is that: the screw rod transmission has good stability and can realize better positioning.

Furthermore, a second X guide rail is arranged on the top surface of the movable beam, the second X guide rail is parallel to the first X guide rail, and the upper end side of the milling structure is connected with the second X guide rail in a sliding mode.

The beneficial effect of adopting the further scheme is that: the second guide rail is connected with the upper end side of the milling assembly in a sliding mode, the milling assembly can be subjected to bearing and guiding effects, and the influence of the dead weight of the milling assembly on the first X guide rail is reduced.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

1. y axle slip table, 2, walking beam, 3, mill the subassembly, 4, stand, 5, base, 6, reinforcing plate, 7, Y axle motor, 8, workstation, 9, driving motor, 10, transmission lead screw, 11, Y guide rail, 12, rack, 13, first X guide rail, 14, second X guide rail, 15, mounting groove.

Detailed Description

The principles and features of the present invention are described below in conjunction with the following drawings, the examples given are only intended to illustrate the present invention and are not intended to limit the scope of the present invention.

Examples

As shown in fig. 1, the utility model discloses a heavy milling machine ray apparatus structure, include: a base 5, wherein a workbench 8 is arranged on the upper side of the base 5; two Y-axis sliding tables 1 are arranged, and the two Y-axis sliding tables 1 are oppositely arranged on two sides of the workbench 8; the movable beam 2 is arranged between the two Y-axis sliding tables 1, two ends of the movable beam 2 are respectively connected with the Y-axis sliding tables 1 in a sliding manner, and the movable beam 2 is provided with an X-axis transmission assembly; the milling assembly 3 is arranged on the movable beam 2, one side of the milling assembly 3 is connected with the movable beam 2 in a sliding mode, and the output end of the X-axis transmission assembly is in transmission connection with the milling assembly 3.

A plurality of upright posts 4 are arranged between each Y-axis sliding table 1 and the base 5, the lower ends of the upright posts 4 are fixedly connected with the base 5 through bolts, and the upper ends of the upright posts 4 are fixedly connected with the Y-axis sliding tables 1; the upper end of stand 4 is equipped with four adjusting nut, and adjusting nut and Y axle slip table 1 fixed connection are passed through to the upper end of stand 4, can adjust Y axle slip table 1's levelness through adjusting nut like this, avoid reducing machining dimension error.

The bottom of walking beam 2 is equipped with reinforcing plate 6, and the both ends and the 1 sliding connection of Y axle slip table of reinforcing plate 6, walking beam 2 is fixed in on reinforcing plate 6.

The movable beam 2 and the Y-axis sliding table 1 are both made of granite.

The upper side wall surface of each Y-axis sliding table 1 is provided with two Y guide rails 11 in parallel, and one end of each reinforcing plate 6 is connected with the Y guide rails 11 in a sliding manner; a rack 12 is arranged between the two Y guide rails 11, the rack 12 is arranged in parallel with the Y guide rails 11, two ends of the reinforcing plate 6 are respectively provided with a Y-axis motor 7, the output end of the Y-axis motor 7 is provided with a gear meshed with the rack 12, and the Y-axis motor 7 is in transmission connection with the rack 12 through the gear; the side of the rack 12 is provided with a insection meshed with the gear, the gear is driven to rotate by the Y-axis motor 7, and the gear moves along the length direction of the rack 12 relative to the rack 12, so that the reinforcing plate 6 can be driven to slide along the Y-axis sliding table 1, and the movable beam 2 reaches a processing position.

Two first X guide rails 13 are arranged on one side of the movable beam 2 in parallel, and one side of the milling assembly 3 is connected with the first X guide rails 13 in a sliding mode.

And a mounting groove 15 is formed in the movable beam 2 between the two first X guide rails 13, and the X-axis transmission assembly is arranged in the mounting groove 15 and is in transmission connection with the milling assembly 3.

The X-axis transmission assembly comprises a transmission screw rod 10 and a driving motor 9, the output end of the driving motor 9 is in transmission connection with one end of the transmission screw rod 10, and the transmission screw rod 10 is in transmission connection with the milling assembly 3.

A second X guide rail 14 is arranged on the top surface of the movable beam 2, the second X guide rail 14 is arranged in parallel with the first X guide rail 13, and the upper end side of the milling assembly 3 is connected with the second X guide rail 14 in a sliding manner; milling assembly 3 includes a mount pad, a Z axle drive assembly and mills the tool bit structure in this application, and the tool bit structure that mills slides and sets up on the mount pad, and Z axle drive assembly is connected with milling tool bit structure transmission, treats that the processing part locates between workstation 8 and milling assembly 3, and milling assembly 3 removes the back that targets in place, carries out milling process.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the present invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included within the protection scope of the present invention.

Claims (10)

1. A heavy milling light machine structure, comprising:

the device comprises a base (5), wherein a workbench (8) is arranged on the upper side of the base (5);

the two Y-axis sliding tables (1) are arranged, and the two Y-axis sliding tables (1) are oppositely arranged on two sides of the workbench (8);

the movable beam (2) is arranged between the two Y-axis sliding tables (1), two ends of the movable beam (2) are respectively connected with the Y-axis sliding tables (1) in a sliding mode, and an X-axis transmission assembly is arranged on the movable beam (2);

the milling assembly (3), the milling assembly (3) is arranged on the movable beam (2), one side of the milling assembly (3) is connected with the movable beam (2) in a sliding mode, and the output end of the X-axis transmission assembly is in transmission connection with the milling assembly (3).

2. The heavy type milling machine structure according to claim 1, wherein a plurality of upright columns (4) are arranged between each Y-axis sliding table (1) and the base (5), the lower ends of the upright columns (4) are fixedly connected with the base (5) through bolts, and the upper ends of the upright columns (4) are fixedly connected with the Y-axis sliding table (1).

3. The heavy milling machine tool structure according to claim 2, characterized in that a reinforcing plate (6) is arranged at the bottom of the movable beam (2), two ends of the reinforcing plate (6) are slidably connected with the Y-axis sliding table (1), and the movable beam (2) is fixed on the reinforcing plate (6).

4. A heavy duty milling machine structure according to claim 3 characterized in that the material of the walking beam (2) and the Y-axis slipway (1) is granite.

5. The heavy milling machine optical-mechanical structure as claimed in claim 3, characterized in that the upper side wall surface of each Y-axis sliding table (1) is provided with two Y-shaped guide rails (11) in parallel, and one end of the reinforcing plate (6) is slidably connected with the Y-shaped guide rails (11).

6. The heavy type milling optical-mechanical structure according to claim 5, characterized in that a rack (12) is arranged between two Y guide rails (11), the rack (12) is arranged in parallel with the Y guide rails (11), two ends of the reinforcing plate (6) are respectively provided with a Y-axis motor (7), the output end of the Y-axis motor (7) is provided with a gear meshed with the rack (12), and the Y-axis motor (7) is in transmission connection with the rack (12) through the gear.

7. A heavy duty milling machine bare engine structure according to any of the claims 1-6, characterized in that two first X guide rails (13) are provided in parallel on one side of the movable beam (2), and one side of the milling assembly (3) is slidably connected to the first X guide rails (13).

8. The heavy milling machine tool structure according to claim 7, characterized in that a mounting groove (15) is provided on the walking beam (2) between the two first X guide rails (13), and the X-axis transmission component is disposed in the mounting groove (15) and is in transmission connection with the milling component (3).

9. The heavy milling machine bare engine structure according to claim 8, wherein the X-axis transmission assembly comprises a transmission screw (10) and a driving motor (9), an output end of the driving motor (9) is in transmission connection with one end of the transmission screw (10), and the transmission screw (10) is in transmission connection with the milling assembly (3).

10. The heavy milling machine tool structure according to claim 7, characterized in that a second X guide rail (14) is arranged on the top surface of the movable beam (2), the second X guide rail (14) is arranged in parallel with the first X guide rail (13), and the upper end side of the milling assembly (3) is connected with the second X guide rail (14) in a sliding manner.

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