CN218591846U - Cutter for processing deep hole boring cutter - Google Patents

Abstract

The utility model discloses a cutter for processing a deep hole boring cutter, which comprises a cutter body, wherein the cutter body is provided with a first cooling hole, a second cooling hole, a third cooling hole and a fourth cooling hole, and the number of the first cooling holes is two; two chip grooves are symmetrically arranged at one end of the cutter body, and the depth directions of the chip grooves extend from the top end of the cutter body to the outer wall; a first blade is arranged on each chip groove; the upper side of the cutter body is provided with a first blade, a pressing block, a screw and an adjusting screw. This processing deep hole boring cutter utensil discharges the aluminium bits of cutting rapidly to play the effect of cooling down to work piece, part, guarantee the stability of second blade in the course of working, thereby make the dimensional accuracy who the cutter processed improve, and adopt module handle of a knife connected mode through connecting cutter body department, make the beating of detecting ring department reduce to minimum through adjusting module handle of a knife connected screw, and then reduce the transfer range of cutter when adding man-hour.

Description

Cutter for processing deep hole boring cutter

Technical Field

The utility model relates to a mechanical tool technical field specifically is a processing deep hole boring cutter.

Background

Aiming at the difficult point of the workpiece, the processing of large parts often has deeper holes and requires more precise size to be combined for operation. However, the size of the deep hole is often more difficult to machine and guarantee, and the boring cutter is generally used on boring machines, machining centers and combined machines, and is mainly used for machining cylindrical holes, threaded holes, grooves in the holes and end faces on boxes, brackets and shells.

This prior art solution also presents the following problems when in use: the aluminum scraps which are cut can not be rapidly discharged, so that the aluminum scraps are accumulated together, the aluminum scraps are heated, the heat dissipation effect of a workpiece and a part is poor, the heat of the cutter is high, the adjusting strength of the cutter is high, and the cutter is easy to damage.

Improvements are needed to address the above issues to meet market demands.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a processing deep hole boring cutter to propose in solving above-mentioned background art and can not discharge rapidly the aluminium bits of cutting, lead to the aluminium bits to pile up together, aluminium bits self just has the heat degree, makes the radiating effect of work piece and part relatively poor, leads to the heat degree of cutter great, and the intensity of transferring of cutter is higher, leads to the problem that the cutter damaged easily.

In order to achieve the above purpose, the utility model provides a following technical scheme: a cutter for machining a deep hole boring cutter comprises a cutter body, wherein a first cooling hole, a second cooling hole, a third cooling hole and a fourth cooling hole are formed in the cutter body, and the number of the first cooling holes is two;

one end of the cutter body is symmetrically provided with two chip grooves;

the depth direction of the chip groove extends from the top end of the cutter body to the outer wall;

a first blade is arranged on each chip groove;

the upper side of the cutter body is provided with a first blade, a pressing block, a screw and an adjusting screw;

a first water tank is arranged on the lower side of the cutter body, and a first water tank pressing plate is arranged on the first water tank;

one end of the cutter body is provided with a first blade, a pressing block and two adjusting screws;

four first water tanks are arranged at the bottom of the cutter body.

The front end of the cutter body is provided with four asymmetric first guide bars, and the rear part of the cutter body is provided with six symmetric second guide bars;

the cutter body is characterized in that a second guide strip is installed at the center of the cutter body, a second water tank and a third water tank are arranged on the side wall of the second guide strip, one end of the first water tank is communicated with a first water tank pressing plate, one end of the second water tank is communicated with a second water tank pressing plate, and the third water tank is communicated with a third water tank pressing plate.

Preferably, the cutter body material is 42CrMo.

Preferably, the materials of the first blade and the second blade are hard alloy and diamond.

Preferably, the first blade and the second blade are both fixed by screws.

Preferably, the first blade performs rough machining on the workpiece.

Preferably, the second blade is used for finishing the workpiece, and the size of the workpiece can be adjusted by adjusting a screw.

Compared with the prior art, the beneficial effects of the utility model are that: the front end of the deep hole boring cutter is used for removing large blank allowance through the first blade, a small amount of aluminum scraps which are used for finish machining are reserved for the second blade, the first guide strip and the second guide strip play a supporting role, and then the second blade, the third water tank, the first cooling hole, the second cooling hole, the third cooling hole and the fourth cooling hole are used for rapidly discharging the cut aluminum scraps, so that the workpiece and part cooling effect is achieved, the stability of the second blade in the machining process is guaranteed, the size precision of the cutter machined is improved, a module cutter handle connecting mode is adopted at the cutter body, the jumping of a detection ring is reduced to the minimum by adjusting a screw at the connection position of the module cutter handle, and the moving amplitude of the cutter during machining is reduced.

Drawings

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

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

FIG. 3 is a schematic view of the end structure of the knife body of the present invention;

FIG. 4 is a schematic view of a partially enlarged structure of the cutter body of the present invention;

FIG. 5 is a schematic view of a first blade according to the present invention;

fig. 6 is a schematic view of the side-view enlarged structure of the adjusting screw of the present invention.

In the figure: 101. a cutter body; 1011. a detection ring; 1021. a chip groove; 1031. a first cooling hole; 1032. a second cooling hole; 1033. a third cooling hole; 1034. a fourth cooling hole; 1201. a first blade; 1202. a second blade; 1213. a screw; 1231. pressing into blocks; 1241. adjusting screws; 1221. a first conducting bar; 1222. a second conducting bar; 1041. a first water tank; 1042. a second water tank; 1043. a third water tank; 1251. a first sink platen; 1252. a second water tank pressing plate; 1253. and a third water tank pressing plate.

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.

Referring to fig. 1-6, the present invention provides a technical solution: a cutter for machining a deep hole and boring a cutter comprises a cutter body 101, wherein two first cooling holes 1031, two second cooling holes 1032, two third cooling holes 1033, two fourth cooling holes 1034 and two first cooling holes 1031 are formed in the cutter body 101;

one end of the cutter body 101 is symmetrically provided with two chip grooves 1021;

the depth direction of the chip grooves 1021 extends from the top end of the cutter body 101 to the outer wall;

a first blade 1201 is mounted on each chip groove 1021;

the upper side of the cutter body 101 is provided with a first blade 1201, a pressing block 1231, a screw 1213 and an adjusting screw 1241;

a first water tank 1041 is formed in the lower side of the cutter body 101, and a first water tank pressing plate 1251 is mounted on the first water tank 1041;

one end of the cutter body 101 is provided with a first blade 1201, a pressing block 1231 and a screw 1213, and two adjusting screws 1241;

the bottom of the cutter body 101 is provided with four first water tanks 1041;

the front end of the cutter body 101 is provided with four asymmetric first conducting bars 1221, and the rear part of the cutter body is provided with six symmetric second conducting bars 1222;

the cutter body 101 is provided with a second guide bar 1222 at the center, a second water tank 1042 and a third water tank 1043 are arranged on the side wall of the second guide bar 1222, one end of the first water tank 1041 is communicated with a first water tank pressing plate 1251, one end of the second water tank 1042 is communicated with a second water tank pressing plate 1252, and the third water tank 1043 is communicated with a third water tank pressing plate 1253.

The cutter body 101 is made of 42CrMo;

the first blade 1201 and the second blade 1202 are made of cemented carbide plus diamond, and the first blade 1201 and the second blade 1202 are made of cemented carbide plus diamond, so that the first blade 1201 and the second blade 1202 have stronger toughness;

the first blade 1201 and the second blade 1202 are both fixed by screws, and the screws are butted with the first blade 1201 and the second blade 1202 to mount the first blade 1201 and the second blade 1202 together;

the first blade 1201 roughens the workpiece, and by using the rough machining of the first blade 1201, the first blade 1201 has a stronger tough condition.

The second blade 1202 performs finish machining on the workpiece, and the size of the workpiece can be adjusted by the adjusting screw 1241, the tool is taken by hand, the adjusting screw 1241 is rotated by the tool, and the adjusting pin hole can be adjusted by the adjusting screw 1241.

In summary, the following steps: as shown in fig. 1-6, when the tool is used for machining the deep hole boring cutter, firstly, the deep hole boring cutter is subjected to rough and fine machining, the first blade 1201 is used for removing a large blank allowance at the front end, a small amount of second blade 1202 is left for fine machining, the cutting amount of the second blade 1202 is ensured not to be too large, meanwhile, the first guide bar 1221 and the second guide bar 1222 play a supporting role, the first water tank 1041, the second water tank 1042, the third water tank 1043, the first cooling hole 1031, the second cooling hole 1032, the third cooling hole 1033 and the fourth cooling hole 1034 are added to rapidly discharge cut aluminum scraps, the workpiece and parts are cooled, the stability of the second blade 1202 in the machining process is ensured, the dimensional accuracy of the tool machined is improved, the module connecting mode is adopted at the tool shank connecting position 101, the screw at the detecting ring 1011 is reduced to the minimum by adjusting, the tool jump in the machining process is optimized, the tool shank is subjected to the increase in the machining precision of the tool shank, and the workpiece machined by the highest module jump is the tool.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a processing deep hole boring cutter, includes cutter body (101), its characterized in that: the cutter body (101) is provided with a first cooling hole (1031), a second cooling hole (1032), a third cooling hole (1033) and a fourth cooling hole (1034), and the number of the first cooling holes (1031) is two;

one end of the cutter body (101) is symmetrically provided with two chip grooves (1021);

the depth direction of the chip groove (1021) extends from the top end of the cutter body (101) to the outer wall;

a first blade (1201) is arranged on each chip groove (1021);

the upper side of the cutter body (101) is provided with a first blade (1201), a pressing block (1231), a screw (1213) and an adjusting screw (1241);

a first water tank (1041) is formed in the lower side of the cutter body (101), and a first water tank pressing plate (1251) is mounted on the first water tank (1041);

one end of the cutter body (101) is provided with a first blade (1201), a pressing block (1231) and a screw (1213), and the number of the adjusting screws (1241) is two;

the bottom of the cutter body (101) is provided with four first water tanks (1041);

the front end of the cutter body (101) is provided with four asymmetric first guide bars (1221), and the rear part of the cutter body is provided with six symmetric second guide bars (1222);

the cutter body (101) is provided with a second guide bar (1222) at the center, a second water tank (1042) and a third water tank (1043) are arranged on the side wall of the second guide bar (1222), one end of the first water tank (1041) is communicated with a first water tank pressing plate (1251), one end of the second water tank (1042) is communicated with a second water tank pressing plate (1252), and the third water tank (1043) is communicated with a third water tank pressing plate (1253).

2. The tool for machining deep holes and boring tools according to claim 1, wherein: the cutter body (101) is made of 42CrMo.

3. The tool for machining a deep hole boring cutter according to claim 1, wherein: the first blade (1201) and the second blade (1202) are made of hard alloy and diamond.

4. The tool for machining deep holes and boring tools according to claim 1, wherein: the first blade (1201) and the second blade (1202) are fixed by screws.

5. The tool for machining deep holes and boring tools according to claim 1, wherein: the first blade (1201) performs roughing on a workpiece.

6. The tool for machining deep holes and boring tools according to claim 4, wherein: the second blade (1202) performs finish machining on the workpiece, and the size of the workpiece can be adjusted through an adjusting screw (1241).

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