Lathe Chuck for Aluminum Alloy Hubs

Abstract

A lathe chuck for aluminum alloy hubs, including a base plate, a base, a slide plate, positioning posts, etc. The base plate is connected together with the base by screws, forming a body of the lathe chuck for hubs; a tapered mounting hole is provided under the base plate so as to fit with a machine tool; the upper and lower ends of the positioning posts are mounted on the base plate and the base by screws respectively, which can increase mounting strength of the base plate and the base; the slide plate is in sliding fit with the positioning posts by copper sleeves, and may slide upwards and downwards along the positioning posts; the large pull rod is fixed on the slide plate by screws and may drive the slide plate to move upwards and downwards.

Claims

1. A lathe chuck for aluminum alloy hubs, comprising: a base plate, a base, a slide plate, positioning posts, a large pull rod, a small pull rod, a hydraulic power collet, a lateral pull rod, positioning blocks, a slide carriage, press claws and press claw shafts, wherein the base plate is connected together with the base by screws, forming a body of the lathe chuck for hubs; a tapered mounting hole is provided under the base plate so as to fit with a machine tool; upper and lower ends of the positioning posts are mounted on the base plate and the base by screws respectively; the slide plate is in a sliding fit with the positioning posts by copper sleeves to slide upwards and downwards along the positioning posts; the large pull rod is fixed on the slide plate by screws to drive the slide plate to move upwards and downwards; the small pull rod is coupled with the hydraulic power collet, which is fixed on the base plate by a gland to drive the slide carriage to move leftward and rightward by the lateral pull rod and screws under a driving of the small pull rod; the positioning blocks are mounted on the slide carriage; the press claws are coupled together with the press claw shafts by screws; the press claw shafts slide upwards and downwards and rotate in the slide carriage; and lower ends of the press claw shafts are mounted on the slide plate.

2. The lathe chuck for aluminum alloy hubs according to claim 1, wherein upper planes and inclined sides of the positioning blocks in contact with a hub blank provide end face positioning and radial positioning for the blank respectively.

3. The lathe chuck for aluminum alloy hubs according to claim 1, wherein the positioning blocks, the press claws and the press claw shafts move along when the hydraulic power collet drives the slide carriage to move leftward and rightward by the lateral pull rod, so that the chuck is adapted to hub blanks of different sizes; three sets of positioning blocks, press claw shafts and press claws are provided and are uniformly distributed in a circumferential direction.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] The invention will be further explained below with reference to the drawings and embodiments.

[0014] FIG. 1 is a front view of a lathe chuck for aluminum alloy hubs of the invention.

[0015] FIG. 2 is a front view of a lathe chuck for aluminum alloy hubs of the invention clamping a hub blank of other size.

[0016] FIG. 3 is a front view of a lathe chuck for aluminum alloy hubs of the invention connected with a cylinder of a machine tool.

DETAILED DESCRIPTION OF THE INVENTION

[0017] Details and operations of specific devices provided according to the invention will be explained in detail below with reference to the drawings.

[0018] A lathe chuck for aluminum alloy hubs comprises a base plate 1, a base 3, a slide plate 4, positioning posts 6, a large pull rod 10, a small pull rod 11, a hydraulic power collet 13, a lateral pull rod 15, positioning blocks 18, a slide carriage 17, press claws 21, press claw shafts 19, etc. The base plate 1 is connected together with the base 3 by screws 2, forming a body of the lathe chuck for hubs; a tapered mounting hole is provided under the base plate 1 so as to fit with a machine tool; the upper and lower ends of the positioning posts 6 are mounted on the base plate 1 and the base 3 by screws 5 respectively, which can increase mounting strength of the base plate 1 and the base 3; the slide plate 4 is in sliding fit with the positioning posts 6 by copper sleeves 7, and may slide upwards and downwards along the positioning posts 6; the large pull rod 10 is fixed on the slide plate 4 by screws 12 and may drive the slide plate 4 to move upwards and downwards; the small pull rod 11 is coupled with the hydraulic power collet 13, which is fixed on the base plate 1 by a gland 9 and may drive the slide carriage 17 to move leftward and rightward by the lateral pull rod 15 and screws 16 under the driving of the small pull rod 11; the positioning blocks 18 are mounted on the slide carriage 17; the press claws 21 are coupled together with the press claw shafts 19 by screws 20; the press claw shafts 19 may slide upwards and downwards and rotate in the slide carriage 17; the lower ends of the press claw shafts 19 are mounted on the slide plate 4.

[0019] Upper planes and inclined sides of the positioning blocks 18 in contact with the hub blank 22 provide end face positioning and radial positioning for the blank 22 respectively so as to ensure correct positioning of the blank.

[0020] The positioning blocks 18, the press claws 21 and the press claw shafts 19 move along when the hydraulic power collet 13 drives the slide carriage 17 to move leftward and rightward by the lateral pull rod 15, so that the chuck may be adapted to hub blanks of different sizes; three sets of positioning blocks 18, press claw shafts 19 and press claws 21 are provided and are uniformly distributed in a circumferential direction.

[0021] When the slide plate 4 moves downwards, it pulls the press claw shafts 19 to move down; as spiral grooves are provided at fitting portions of the press claw shafts 19 and the slide carriage 17, the press claw shafts 19 and press claws 21 rotate by 90 degrees, thus finishing rotating and pressing operations.

[0022] The slide plate 4 is provided with elongated slots at its outer side, in which the press claw shafts 19 may slide from side to side.

[0023] The large pull rod 10 and the small pull rod 11 are respectively connected with a double-rod cylinder 26 at the rear of a lathe spindle by a hollow shaft 25 and a solid shaft 24 and respectively operate under the driving of the cylinder 26.

[0024] Prior to operation, the large pull rod 10 and the small pull rod 11 are both at the uppermost end, where the large pull rod 10 allows the press claw shafts 19 and the press claws 21 opened by the slide plate 4, and the small pull rod 11 allows the slide carriage 17, the press claw shafts 19, the press claws 21 and the positioning blocks 18 at the outermost position, i.e., the largest diameter position, by the hydraulic power collet 13 and the lateral pull rod 15.

[0025] During operation, an aluminum alloy hub blank 22 is placed at first, an outer end face portion of the blank 22 is naturally placed on the positioning blocks 18 so as to finish end face positioning; an outer peripheral portion of the blank 22 is placed at the inner sides of the inclined sides of the positioning blocks 18; then the small pull rod 11 drives the hydraulic power collet 13 and the lateral pull rod 15 to drive the slide carriage 17, the positioning blocks 18, the press claw shafts 19 and the press claws 21 to move towards the center of circle until they abut against the outer peripheral portion of the blank 22, thus the end face positioning and radial positioning are finished.

[0026] Then the large pull rod 10 drives the slide plate 4 to move downwards, the slide plate 4 pulls the press claw shafts 19 to move downwards so as to finish the actions of rotating and pressing the blank, thus the end face positioning, radial positioning and pressing operations for the aluminum alloy hub blank are finished.

[0027] As hydraulic power collet 13 has a large stroke, the positioning blocks 18, the slide carriage 17, the press claw shafts 19 and the press claws 21 can move in a large range, so that compatibility with aluminum alloy hub blanks of different sizes can be provided. FIG. 2 is the state when a small-sized hub blank 23 is clamped.