CN220073296U - Inclined Y double-spindle double-Y-axis power turret numerical control lathe - Google Patents

Abstract

The utility model discloses a numerical control lathe with an inclined Y double-spindle double-Y-axis power turret, which comprises a machine table, a spindle device, a first power turret and a second power turret. The spindle device is arranged on the machine table and comprises a first spindle mechanism and a second spindle mechanism which are oppositely arranged, wherein the first spindle mechanism and the second spindle mechanism are used for clamping a workpiece; the first power turret is arranged on one side of the main shaft device and comprises a first motion assembly and a first turret assembly; the second power turret is arranged on the other side of the spindle device and comprises a second motion assembly and a second turret assembly. Therefore, the first power tool turret and the second power tool turret can move towards the first spindle mechanism and the second spindle mechanism, so that the two power tool turrets can process workpieces of the two spindle mechanisms, the processing efficiency is high, the heights of the two power tool turrets can be adjusted, and in addition, the moving directions are different, and more types of workpieces can be processed.

Description

Inclined Y double-spindle double-Y-axis power turret numerical control lathe

Technical Field

The utility model relates to the field of numerical control machine tools, in particular to an inclined Y double-spindle double-Y-axis power turret numerical control lathe.

Background

In order to improve the machining efficiency, a plurality of double-spindle power turret numerical control lathes appear on the market, two spindles can clamp two bars or pipes simultaneously, the power turrets can automatically switch corresponding cutters in the machining process, the cutters are not replaced by hands, and the degree of automation is high. However, the two turret of the lathe respectively process the workpieces of the two main shafts, the two turrets cannot process each other, the processing efficiency is low, the two turrets cannot move in the Y-axis direction, the processing range is limited, and some turrets can move in the Y-axis direction, but only one movement or movement is consistent, and the processing limitation exists.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems existing in the prior art. Therefore, the utility model provides the oblique Y double-spindle double-Y-axis power turret numerical control lathe, two turrets can process workpieces of two spindle mechanisms, the processing efficiency is high, and meanwhile, the two power turrets can move in the Y-axis direction and have different movement directions, so that more types of workpieces can be processed.

The technical scheme adopted for solving the technical problems is as follows:

a tilt Y double-spindle double-Y-axis power turret numerical control lathe comprises

A machine table;

the spindle device is arranged on the machine table and comprises a first spindle mechanism and a second spindle mechanism which are oppositely arranged, and the first spindle mechanism and the second spindle mechanism are used for clamping a workpiece;

the first power turret is arranged on one side of the main shaft device and comprises a first motion assembly and a first turret assembly, the first motion assembly comprises a first Z-axis linear guide rail parallel to the main shaft device and a first X-axis linear guide rail arranged on the first Z-axis linear guide rail, the first turret assembly comprises a first cutter head and a Y-axis lifting assembly, and the Y-axis lifting assembly is vertically arranged with the first X-axis linear guide rail and is used for driving the first cutter head to lift;

the second power turret is arranged on the other side of the main shaft device and comprises a second motion assembly and a second turret assembly, the second motion assembly comprises a second Z-axis linear guide rail parallel to the main shaft device, a second X-axis linear guide rail arranged on the second Z-axis linear guide rail and a Y-axis linear guide rail arranged on the second X-axis linear guide rail, the Y-axis linear guide rail and the second X-axis linear guide rail are arranged at an acute angle, the second turret assembly is arranged on the Y-axis linear guide rail, and the second turret assembly comprises a second cutter head.

According to the embodiment of the utility model, the inclined Y double-spindle double-Y-axis power turret numerical control lathe has at least the following beneficial effects: through set up first power sword tower and second power sword tower respectively in main shaft device both sides, because first power sword tower includes first Z axle linear guide and first X axle linear guide, the second power sword tower includes second Z axle linear guide and second X axle linear guide, so first power sword tower and second power sword tower all can be in the past first spindle unit and second spindle unit motion, consequently, two power sword towers can each other process two spindle unit's work piece, machining efficiency is high, because first power sword tower includes Y axle elevating system, Y axle elevating system sets up with first X axle linear guide is perpendicular, the second power sword tower includes Y axle linear guide, Y axle linear guide is the acute angle setting with second X axle linear guide, can adjust two power sword towers's height, moreover, the direction of motion is different, more types of work piece can be processed.

According to some embodiments of the utility model, the machine has an inclined surface, the first power turret is disposed at a lower portion of the inclined surface, and the second power turret is disposed at an upper portion of the inclined surface.

The beneficial effects are that: the board sets up to the inclined plane and is favorable to practicing thrift the space, also is favorable to the discharge of cutting fluid, and first power sword tower sets up the lower part at the inclined plane, and the second power sword tower sets up the upper portion at the inclined plane, and structural layout is reasonable.

According to some embodiments of the utility model, the Y-axis linear guide is perpendicular to the horizontal plane.

The beneficial effects are that: the arrangement ensures that the motion of the first turret on the Y-axis linear guide rail is vertical to the horizontal plane, and is convenient to adjust.

According to some embodiments of the utility model, the first spindle mechanism includes a fixed seat disposed on the inclined surface, and a first clamping assembly disposed on the fixed seat.

The beneficial effects are that: the first main shaft mechanism is arranged in such a way that the first clamping assembly can be stably installed, so that the workpiece is stably clamped, and the machining precision is ensured.

According to some embodiments of the utility model, the first clamping assembly is driven by an external motor, which is disposed at a side of the machine.

The beneficial effects are that: since the position of the first clamping mechanism is fixed, the arrangement saves space on the machine.

According to some embodiments of the utility model, the second spindle mechanism includes a spindle linear guide parallel to the first and second Z-axis linear guides, and a second clamp assembly mounted on the spindle linear guide.

The beneficial effects are that: the second spindle mechanism is arranged in such a way that the second clamping assembly moves along the linear spindle guide rail, and the machining position can be adjusted.

According to some embodiments of the utility model, the second clamping assembly is driven by an internal motor.

The beneficial effects are that: the use of a built-in motor does not affect the movement of the second clamping assembly.

According to some embodiments of the utility model, the Y-axis lifting assembly comprises a first mounting frame, a first lifting motor and a first screw, wherein the first cutterhead is mounted on the first mounting frame, and the first lifting motor drives the first cutterhead to lift through the first screw.

The beneficial effects are that: the Y-axis lifting assembly is connected with the first screw rod through the first lifting motor, so that the first screw rod drives the first cutter head to lift, and the transmission is stable and easy to control.

According to some embodiments of the utility model, the two sides of the machine are provided with the water flowing grooves.

The beneficial effects are that: and the two sides of the machine table are provided with the water flowing grooves, so that the cutting fluid can be discharged.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The foregoing and/or additional aspects and advantages of the utility model will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic diagram of an embodiment of the present utility model;

FIG. 2 is an enlarged view of FIG. 1 at A;

fig. 3 is an enlarged view at B in fig. 1.

Reference numerals: the machine platform 100, the first spindle mechanism 110, the second spindle mechanism 120, the first moving assembly 130, the first turret assembly 140, the first Z-axis linear guide 150, the first X-axis linear guide 160, the first cutterhead 170, the Y-axis lifting assembly 180, the second moving assembly 190, the second cutterhead 200, the second Z-axis linear guide 210, the second X-axis linear guide 220, the Y-axis linear guide 230, the inclined surface 240, the fixed seat 250, the first clamping assembly 260, the external motor 270, the spindle linear guide 280, the second clamping assembly 290, the first mounting frame 300, the first lifting motor 310, the first screw 320 and the water chute 330.

Detailed Description

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

In the description of the present utility model, it should be understood that references to orientation descriptions such as upper, lower, front, rear, left, right, etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of description of the present utility model and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, a number means one or more, a number means two or more, and greater than, less than, exceeding, etc. are understood to not include the present number, and above, below, within, etc. are understood to include the present number. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present utility model, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present utility model can be reasonably determined by a person skilled in the art in combination with the specific contents of the technical scheme.

A tilt Y double spindle double Y axis power turret numerically controlled lathe is described in detail below with reference to fig. 1-3 in one specific embodiment. It is to be understood that the following description is exemplary only and is not intended to limit the utility model in any way.

As shown in fig. 1-3, an oblique Y double-spindle double-Y-axis power turret numerically controlled lathe comprises a machine 100, a spindle device, a first power turret and a second power turret.

The spindle device is arranged on the machine table 100 and comprises a first spindle mechanism 110 and a second spindle mechanism 120 which are oppositely arranged, wherein the first spindle mechanism 110 and the second spindle mechanism 120 are used for clamping a workpiece; the first power turret is arranged on one side of the spindle device and comprises a first moving assembly 130 and a first turret assembly 140, wherein the first moving assembly 130 comprises a first Z-axis linear guide rail 150 parallel to the spindle device and a first X-axis linear guide rail 160 arranged on the first Z-axis linear guide rail 150, the first turret assembly 140 comprises a first cutter head 170 and a Y-axis lifting assembly 180, and the Y-axis lifting assembly 180 is arranged perpendicular to the first X-axis linear guide rail 160 and is used for driving the first cutter head 170 to lift; the second power turret is arranged on the other side of the spindle device and comprises a second motion assembly 190 and a second turret assembly, the second motion assembly 190 comprises a second Z-axis linear guide 210 parallel to the spindle device, a second X-axis linear guide 220 arranged on the second Z-axis linear guide 210, and a Y-axis linear guide 230 arranged on the second X-axis linear guide 220, the Y-axis linear guide 230 and the second X-axis linear guide 220 are arranged at an acute angle, the second turret assembly is arranged on the Y-axis linear guide 230, and the second turret assembly comprises a second cutter head 200.

By arranging the first power turret and the second power turret on two sides of the spindle device respectively, since the first power turret comprises the first Z-axis linear guide 150 and the first X-axis linear guide 160 and the second power turret comprises the second Z-axis linear guide 210 and the second X-axis linear guide 220, the first power turret and the second power turret can both move towards the first spindle mechanism 110 and the second spindle mechanism 120, so that the two power turrets can mutually process workpieces of the two spindle mechanisms, the processing efficiency is high, and since the first power turret comprises the Y-axis lifting assembly 180, the Y-axis lifting assembly 180 is vertically arranged with the first X-axis linear guide 160, the second power turret comprises the Y-axis linear guide 230, the Y-axis linear guide 230 and the second X-axis linear guide 220 are arranged at an acute angle, the heights of the two power turrets can be adjusted, and in addition, the moving directions are different, more types of workpieces can be processed.

As shown in fig. 1, the machine 100 has an inclined surface 240, a first power turret is provided at a lower portion of the inclined surface 240, and a second power turret is provided at an upper portion of the inclined surface 240. The machine 100 is provided with the inclined surface 240, which is favorable for saving space and discharging cutting fluid, the first power tool turret is arranged at the lower part of the inclined surface 240, and the second power tool turret is arranged at the upper part of the inclined surface 240, so that the structure layout is reasonable.

Specifically, the Y-axis linear guide 230 is perpendicular to the horizontal plane. This arrangement ensures that the motion of the first turret in the Y-axis linear guide 230 is perpendicular to the horizontal plane, facilitating adjustment.

As shown in fig. 2, the first spindle mechanism 110 includes a fixing base 250 disposed on the inclined surface 240, and a first clamping assembly 260 disposed on the fixing base 250. The first spindle mechanism 110 is configured to firmly mount the first clamping assembly 260, thereby stably clamping the workpiece and ensuring machining accuracy.

It should be noted that, the first clamping assembly 260 is driven by an external motor 270, and the external motor 270 is disposed at a side of the machine 100. This arrangement saves space on the machine 100 since the location of the first clamping mechanism is fixed.

As shown in fig. 3, the second spindle mechanism 120 includes a spindle linear guide 280 parallel to the first Z-axis linear guide 150 and the second Z-axis linear guide 210, and a second clamping assembly 290 mounted on the spindle linear guide 280. The second spindle mechanism 120 is configured to move the second clamping assembly 290 along the spindle linear guide 280 to adjust the machining position. The second clamping assembly 290 is driven by an internal motor. The use of an internal motor does not affect the movement of the second clamping assembly 290.

Specifically, the Y-axis lifting assembly 180 includes a first mounting frame 300, a first lifting motor 310 and a first screw 320, the first cutterhead 170 is mounted on the first mounting frame 300, and the first lifting motor 310 drives the first cutterhead 170 to lift through the first screw 320. The Y-axis lifting assembly 180 is connected with the first screw 320 through the first lifting motor 310, so that the first screw 320 drives the first cutterhead 170 to lift, and the transmission is stable and easy to control.

It should be noted that, the machine 100 is provided with a water flowing groove 330 at both sides. The water flowing grooves 330 are provided at both sides of the machine 100 to facilitate the discharge of the cutting fluid.

The embodiments of the present utility model have been described in detail with reference to the accompanying drawings, but the present utility model is not limited to the above embodiments, and various changes can be made within the knowledge of one of ordinary skill in the art without departing from the spirit of the present utility model.

Claims (9)

1. The utility model provides a two Y axle power sword tower numerical control lathe of oblique Y double spindle which characterized in that includes:

a machine (100);

the spindle device is arranged on the machine table (100) and comprises a first spindle mechanism (110) and a second spindle mechanism (120) which are oppositely arranged, and the first spindle mechanism (110) and the second spindle mechanism (120) are used for clamping a workpiece;

the first power turret is arranged on one side of the main shaft device and comprises a first moving assembly (130) and a first turret assembly (140), the first moving assembly (130) comprises a first Z-axis linear guide rail (150) parallel to the main shaft device and a first X-axis linear guide rail (160) arranged on the first Z-axis linear guide rail (150), the first turret assembly (140) comprises a first cutter head (170) and a Y-axis lifting assembly (180), and the Y-axis lifting assembly (180) is perpendicular to the first X-axis linear guide rail (160) and is used for driving the first cutter head (170) to lift;

the second power turret is arranged on the other side of the main shaft device and comprises a second motion assembly (190) and a second turret assembly, the second motion assembly (190) comprises a second Z-axis linear guide rail (210) parallel to the main shaft device, a second X-axis linear guide rail (220) arranged on the second Z-axis linear guide rail (210) and a Y-axis linear guide rail (230) arranged on the second X-axis linear guide rail (220), the Y-axis linear guide rail (230) and the second X-axis linear guide rail (220) are arranged at an acute angle, the second turret assembly is arranged on the Y-axis linear guide rail (230), and the second turret assembly comprises a second cutter disc (200).

2. The tilt-Y double spindle double Y-axis power turret numerically controlled lathe according to claim 1, wherein the machine (100) has an inclined surface (240), the first power turret is disposed at a lower portion of the inclined surface (240), and the second power turret is disposed at an upper portion of the inclined surface (240).

3. The tilt-Y double spindle double Y-axis power turret numerically controlled lathe of claim 2, wherein the Y-axis linear guide (230) is perpendicular to the horizontal.

4. The tilt-Y double spindle double Y-axis power turret numerically controlled lathe of claim 2, wherein the first spindle mechanism (110) comprises a fixed seat (250) disposed on the inclined surface (240), and a first clamping assembly (260) disposed on the fixed seat (250).

5. The tilt-Y double spindle double Y-axis power turret numerically controlled lathe of claim 4, wherein the first clamping assembly (260) is driven by an external motor (270), the external motor (270) being disposed on a side of the machine (100).

6. The tilt-Y double spindle double Y-axis power turret numerically controlled lathe of claim 1, wherein the second spindle mechanism (120) comprises a spindle linear guide (280) parallel to the first Z-axis linear guide (150) and the second Z-axis linear guide (210), and a second clamping assembly (290) mounted on the spindle linear guide (280).

7. The tilt-Y double spindle double Y-axis power turret numerically controlled lathe of claim 6, wherein the second clamp assembly (290) is driven by an internal motor.

8. The oblique-Y double-spindle double-Y-axis power turret numerical control lathe according to claim 1, wherein the Y-axis lifting assembly (180) comprises a first mounting frame (300), a first lifting motor (310) and a first screw (320), the first cutterhead (170) is mounted on the first mounting frame (300), and the first lifting motor (310) drives the first cutterhead (170) to lift through the first screw (320).

9. The numerical control lathe with the inclined Y double-spindle and double-Y-axis power turret according to claim 1, wherein the water flowing grooves (330) are formed in two sides of the machine table (100).