The present disclosure relates to the field of spraying tool technology, and more particularly, to a spherical core spraying tool.
When spherical cores with a small aperture are sprayed, because an inner hole the spherical cores is small, there are stricter requirements for dimension and coaxiality, thus the spherical cores can be individually sprayed only by using an expanding core axis, and efficiency will be extremely low. The present disclosure provides a tool that can simultaneously spray a plurality of spherical cores.
The technical problem to be solved by the present disclosure is to provide a tool that can simultaneously spray a plurality of spherical cores, in order to solve the problem in existing technology that spherical cores having a small aperture can only be individually sprayed by adopting an expanding core axis, and efficiency is extremely low.
The technical solution adopted by the present disclosure to solve the technical problem is as follows: a spherical core spraying tool includes: a spraying spindle and a connecting rod, wherein the spraying spindle is provided with a number of protruding rings in a circumferential direction, and is provided with a strip-shaped groove in an axial direction, the connecting rod is disposed in the groove, a power input end is provided at one end of the spraying spindle, and a locking sleeve is provided at the other end of the spraying spindle, and the groove penetrates through the protruding rings (2). Before a spherical core is fixed to the spraying spindle, spot-welding of a steel ball in an inner hole of the spherical core is required to be performed for the purpose of positioning. A positioning core axis, which is provided with an open slot at the top and a base at the bottom, is inserted into the spherical core, and the bottom of the spherical core comes into contact with the base, and because a height of the positioning core axis is smaller than a height of the spherical core, the positioning core axis is completely accommodated in the inner hole of the spherical core. The steel ball is then placed in the open slot of the positioning core axis, the steel ball is in contact with a wall of the inner hole of the spherical core, and then the steel ball is spot-welded to the wall of the inner hole of the spherical core, in such a manner that a position of the steel ball in the inner hole of each of the spherical cores is identical. The positioning core axis is taken out of the spherical core, and then the spherical core, to which the steel ball is welded, is fitted to the protruding rings on the spraying spindle, so that the steel ball is stuck in the groove of the spraying spindle, the wall of the inner hole of the spherical core is attached to the protruding ring, and then one of the connecting rods is placed in the groove to tighten the steel ball in abutting-against fashion, in this way, the spherical core is fixed on the spraying spindle. After the spherical cores, a number of which is the same as that of the protruding rings, are fixed on the spraying spindle according to the above-described steps, the last connecting rod is fastened with the locking sleeve.
The protruding rings are equally spaced and distributed on the spraying spindle so that the spherical cores fixed on the spraying spindle are equally spaced apart from each other. The spherical cores are sprayed by using an automatic spraying device, it is only required that a spraying procedure is set to be equally spaced or at equal time intervals, thus processes can be simplified, and spraying efficiency is improved.
The spherical core is fitted to the first protruding ring near the power input end, and one side of the steel ball inside the spherical core abuts against an end portion of the groove, and the other side of the steel ball is tightened by means of one end of a connecting rod in abutting-against fashion, and the steel ball of the spherical core fitted to the second protruding ring is tightened and positioned between the other end of the connecting rod and one end of another connecting rod in abutting-against fashion, and a connecting rod close to the locking sleeve is fastened by the locking sleeve, that is, each of the spherical cores corresponds to one of the connecting rods, so the number of the connecting rods is equal to the number of the protruding rings.
The wall of the inner hole of the spherical core is fitted to the protruding ring, and the connecting rod is connected between two spherical cores. A length of the connecting rod is equal to a distance between two adjacent protruding rings. A cross-section of the power input end of the spraying spindle is a polygonal, and the power input end and a driving device form molded surface connection, strength of which is high, and no stress concentration is caused, in this way, large torque can be transmitted, high efficiency can be obtained, and impact load can be withstood.
The advantageous effects of the present disclosure are as follows: by spot-welding the steel ball in the inner hole of the spherical core and fitting the spherical core to the spraying spindle, the steel ball is stuck in the groove of the spraying spindle, and both sides of the steel ball are tightened by means of the connecting rods in abutting-against fashion, so that the plurality of spherical cores are fixed to the spraying spindle, and can be sprayed simultaneously, thereby improving the efficiency.
Hereinafter, the present disclosure will be further described in conjunction with the accompanying drawings and embodiments.
In the drawings: 1.spraying spindle; 2.protruding ring; 3.groove; 4.power input end; 5.locking sleeve; 6.connecting rod; 7.spherical core; 8.base; 9.positioning core axis; 10.open slot; 11.steel ball.
The present disclosure will now be further described in detail with reference to the accompanying drawings. The drawings are simplified schematic diagrams, and are only illustrative of a basic structure of the present disclosure schematically, thus only configurations related to the present disclosure are shown.
As shown in
Before a spherical core 7 is fixed to the spraying spindle 1, spot-welding of a steel ball 11 in an inner hole of the spherical core 7 is required to be performed for the purpose of positioning. As shown in
In view of the above-described embodiments of the present disclosure, various changes and modifications can be made by those skilled in the art without departing from the scope of the technical idea of the present disclosure. The technical scope of the present disclosure is not limited to the contents of the specification, and the technical scope thereof must be determined according to the scope of the claims.
Number | Date | Country | Kind |
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201610180589.7 | Mar 2016 | CN | national |
The present application is a national phase application of International patent application PCT/CN2016/112246 filed Dec. 27, 2016, which claims priority to Chinese patent application 201610180589.7 filed Mar. 28, 2016, all of which are incorporated by reference herein in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/CN2016/112246 | 12/27/2016 | WO | 00 |