CN115464162A - Fixed end anchorage device extrusion sleeve processing device and processing technology thereof - Google Patents

Abstract

The invention discloses a fixed end anchorage device extrusion sleeve processing device which comprises a numerical control machine tool, a main shaft box arranged in the numerical control machine tool, a feeding mechanism, a main shaft arranged on the main shaft box and a tool rest arranged on the feeding mechanism, wherein the main shaft is arranged on the main shaft box; the automatic feeding mechanism is characterized by comprising an automatic feeding mechanism and a reversing feeding mechanism which are arranged in a numerical control machine; the automatic feeding mechanism comprises a feeding cylinder arranged in the numerical control machine tool, an ejection assembly connected with the feeding cylinder and a material receiving plate arranged on the ejection assembly; the reversing feeding mechanism comprises a rotary reversing assembly and a reversing feeding cylinder connected with the rotary reversing assembly. According to the automatic feeding device, the automatic feeding mechanism replaces manual work to carry out automatic feeding, so that the processing efficiency and the processing precision are improved, and the labor intensity of workers is reduced; the extrusion sleeve with the processed end is directly reversed by the reversing feeding mechanism to be processed continuously, so that the processing coaxiality of the extrusion sleeve is improved, and the processing time is shortened.

Description

Fixed end anchorage device extrusion sleeve processing device and processing technology thereof

Technical Field

The invention relates to the technical field of fixed end anchor extrusion sleeve processing, in particular to a fixed end anchor extrusion sleeve processing device and a processing technology thereof.

Background

A fixed-end anchor extruding sleeve is formed by generally cutting and machining a numerical control machine tool during machining, in the prior art, the fixed-end anchor extruding sleeve needs to be installed on a main shaft of the numerical control machine tool through manual work during machining, then the numerical control machine tool is machined through programming of the numerical control machine tool, manual clamping easily causes blank installation to be deviated, the quality of later-stage product machining is influenced, the numerical control machine tool needs to be shut down after one end of a product is machined, then the extruding sleeve with one end machined is disassembled from the main shaft through manual work, the extruding sleeve is replaced by one end and then fixedly installed on the main shaft continuously, the coaxiality of machining of two ends of the extruding sleeve is easily reduced through manual clamping, the machining time is prolonged, the labor intensity of workers and the quality of product machining are improved, and the production efficiency is reduced. Therefore, a fixed end anchorage device extrusion sleeve processing device and a processing technology thereof are provided.

Disclosure of Invention

The invention aims to solve the problems and provides a device and a process for processing an extrusion sleeve of a fixed end anchorage device.

In order to achieve the purpose, the invention provides the following technical scheme: a fixed end anchorage device extrusion sleeve processing device comprises a numerical control machine tool, a main shaft box arranged in the numerical control machine tool, a feeding mechanism, a main shaft arranged on the main shaft box and a tool rest arranged on the feeding mechanism; the automatic feeding mechanism is characterized by comprising an automatic feeding mechanism and a reversing feeding mechanism which are arranged in a numerical control machine; the automatic feeding mechanism comprises a feeding cylinder arranged in the numerical control machine tool, a material ejecting component connected with the feeding cylinder and a material receiving plate arranged on the material ejecting component; the reversing feeding mechanism comprises a rotary reversing assembly and a reversing feeding cylinder connected with the rotary reversing assembly.

Preferably, a feeding plate and a feeding fixing plate are further arranged in the numerical control machine; the feeding cylinder is arranged in the numerical control machine tool through a feeding fixing plate; the ejection assembly comprises an adjusting plate connected with the feeding cylinder and an ejection cylinder arranged on the adjusting plate; the material receiving plate is arranged on the adjusting plate.

Preferably, a material receiving groove is formed in the material receiving plate; the material ejecting cylinder is connected with a material ejecting block and penetrates through the material receiving plate to be installed in the material receiving groove.

Preferably, the adjusting plate is further provided with a plurality of guide rods; and the feeding fixing plate is provided with a guide sleeve matched with the guide rod.

Preferably, the rotary reversing assembly comprises a fixed plate arranged on the feeding mechanism, a rotary cylinder arranged on the fixed plate and a rotary reversing block connected with the rotary cylinder; the reversing feeding cylinder is installed on the fixing plate.

Preferably, the rotary reversing block is provided with a product reversing through hole; and the reversing ejection block matched with the product reversing through hole is connected to the reversing feeding cylinder.

Preferably, the main shaft is internally provided with an ejection rod; the ejection rod is connected with a product ejection cylinder arranged on the numerical control machine tool; and the feeding mechanism is also provided with a discharging plate.

A processing technology of a fixed end anchorage device extrusion sleeve processing device is characterized by comprising the following processing technology steps:

the first step is as follows: the blank of the extrusion sleeve rolls to the receiving plate through the feeding plate;

the second step is that: conveying the extrusion sleeve blank on the receiving plate to a main shaft of a numerical control lathe through a feeding cylinder and a material ejecting assembly, and fixing the extrusion sleeve blank by using the main shaft;

the third step: a feeding mechanism is used for driving a tool rest to process one end of the tool rest, and after the processing is finished, a product ejection cylinder is used for pushing an extrusion sleeve at the processed end to a reversing feeding mechanism;

the fourth step: a rotary reversing assembly of the reversing feeding mechanism reverses the extrusion sleeve and then is ejected onto the main shaft through a reversing feeding cylinder;

the fifth step: the feeding mechanism is utilized to drive the tool rest to process the other end of the tool rest, and after the processing is finished, the product ejection cylinder is utilized to push the processed extrusion sleeve to the discharge plate, and the extrusion sleeve rolls into the numerical control machine tool along the discharge plate.

The invention has the beneficial effects that: the automatic feeding mechanism replaces manual work to carry out automatic feeding, so that the processing efficiency and the processing precision are improved, and the labor intensity of workers is reduced;

the extrusion sleeve with the processed end is directly reversed by the reversing feeding mechanism to be processed continuously, so that the processing coaxiality of the extrusion sleeve is improved, and the processing time is shortened.

Drawings

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

Fig. 2 is a schematic structural diagram of the automatic feeding mechanism of the present invention.

Fig. 3 is a schematic structural diagram of the reversing feeding mechanism of the invention.

Fig. 4 is a schematic structural view in another aspect of the present invention.

Illustration of the drawings: 1, a numerical control machine tool; 101, a main spindle box; 102 a feeding mechanism; 103 a main shaft; 104 a tool post; 105 ejecting the rod; 106, ejecting a product out of a cylinder; 107 discharge plates; 2, an automatic feeding mechanism; 201 a feeding cylinder; 202 a topping assembly; 203 material receiving plate; 204 a feeding plate; 205 feeding a fixed plate; 206 adjusting plate; 207 a liftout cylinder; 208 receiving groove; 209 a top material block; 210 a guide rod; 211 a guide sleeve; 3, reversing the feeding mechanism; 301 rotating the reversing assembly; 302 reversing feeding cylinder; 303 fixing the plate; 304 a rotary cylinder; 305 rotating the reversing block; 306 product reversing through holes; 307 reversing the ejector block.

Detailed Description

The present invention will be further described with reference to the accompanying drawings.

Referring to fig. 1, the fixed end anchorage device extrusion sleeve processing device in the embodiment includes a numerically-controlled machine tool 1, a main spindle box 101 installed in the numerically-controlled machine tool 1, a feeding mechanism 102, a main spindle 103 installed on the main spindle box 101, and a tool rest 104 installed on the feeding mechanism 102; the automatic feeding device is characterized by comprising an automatic feeding mechanism 2 and a reversing feeding mechanism 3 which are arranged in a numerical control machine 1; the automatic feeding mechanism 2 comprises a feeding cylinder 201 installed in the numerical control machine tool 1, an ejection assembly 202 connected with the feeding cylinder 201 and a material receiving plate 203 installed on the ejection assembly 202; the reversing feeding mechanism 3 comprises a rotary reversing assembly 301 and a reversing feeding cylinder 302 connected with the rotary reversing assembly 301; the automatic feeding mechanism 2 replaces manual work to carry out automatic feeding, so that the processing efficiency and the processing precision are improved, and the labor intensity of workers is reduced; the extrusion sleeve with the processed end is directly reversed by the reversing feeding mechanism 3 to be processed continuously, so that the processing coaxiality of the extrusion sleeve is improved, and the processing time is shortened.

Referring to fig. 1-2, a feeding plate 204 and a feeding fixing plate 205 are further installed in the numerical control machine 1; the feeding cylinder 201 is arranged in the numerical control machine tool 1 through a feeding fixing plate 205; the material ejecting assembly 202 comprises an adjusting plate 206 connected with the feeding cylinder 201 and an ejecting cylinder 207 arranged on the adjusting plate 206; the material receiving plate 203 is arranged on the adjusting plate 206; a material receiving groove 208 is arranged on the material receiving plate 203; the material ejecting cylinder 207 is connected with a material ejecting block 209 and penetrates through the material receiving plate 203 to be installed in the material receiving groove 208; the adjusting plate 206 is also provided with a plurality of guide rods 210; the feeding fixing plate 205 is provided with a guide sleeve 211 matched with the guide rod 210; drive regulating plate 206 through feeding cylinder 201 and move, regulating plate 206 drives and connects flitch 203 and liftout cylinder 207 to move to main shaft 103 department along uide bushing 211 downstream, and liftout cylinder 207 promotes liftout piece 209 and moves, and liftout piece 209 promotes the extrusion cover that needs processing to main shaft 103 in, realizes replacing the manual work to carry out automatic feeding to improve the efficiency of production and processing and the quality of processing, reduce workman's intensity of labour.

Referring to fig. 1-4, the rotary reversing assembly 301 includes a fixing plate 303 mounted on the feeding mechanism 102, a rotary cylinder 304 mounted on the fixing plate 303, and a rotary reversing block 305 connected to the rotary cylinder 304; the reversing feeding cylinder 302 is arranged on the fixing plate 303; a product reversing through hole 306 is formed in the rotary reversing block 305; the reversing feeding cylinder 302 is connected with a reversing ejection block 307 matched with the product reversing through hole 306; an ejector rod 105 is further installed in the main shaft 103; the ejection rod 105 is connected with a product ejection cylinder 106 arranged on the numerical control machine tool 1; the feeding mechanism 102 is also provided with a discharging plate 107; the rotary cylinder 304 drives the rotary reversing block 305 to rotate, the machined workpiece is reversed, then the reversing feeding cylinder 302 pushes the reversing ejection block 307 to move, and the reversing ejection block 307 pushes the machined workpiece to move to the main shaft 103 along the product reversing through hole 306, so that the reversing of the machined product is facilitated, the continuous machining is realized, the machining time is shortened, and the machining coaxiality is improved.

During the working process of the invention, firstly, an extrusion sleeve blank to be processed rolls into a material receiving groove 208 on a material receiving plate 203 along a feeding plate 204, then a feeding cylinder 201 drives an adjusting plate 206 to move, the adjusting plate 206 drives the material receiving plate 203 and an ejection cylinder 207 to move downwards to a main shaft 103 along a guide sleeve 211, the ejection cylinder 207 pushes an ejection block 209 to move, the ejection block 209 pushes the extrusion sleeve to be processed into the main shaft 103, the main shaft 103 fixes the extrusion sleeve blank, then the numerical control machine 1 controls the main shaft 103 to rotate and a feeding mechanism 102 to move through programming, the feeding mechanism 102 drives a tool rest 104 to process one end of the extrusion sleeve blank, after the processing is finished, the feeding mechanism 102 drives a reversing feeding mechanism 3 to move to the opposite side of the main shaft 103, and then a product ejection cylinder 106 pushes an ejection rod 105 to move, the ejection rod 105 pushes the extrusion sleeve to move into a product reversing through hole 306 on the rotary reversing block 305, then the rotary cylinder 304 drives the rotary reversing block 305 to rotate, the machined extrusion sleeve is reversed, then the reversing feeding cylinder 302 pushes the reversing ejection block 307 to move, the reversing ejection block 307 pushes a machined workpiece to move onto the main shaft 103 along the product reversing through hole 306, the main shaft 103 fixes the extrusion sleeve again, then the numerical control machine tool 1 controls the main shaft 103 to rotate and the feeding mechanism 102 to move through programming, the feeding mechanism 102 drives the tool rest 104 to machine the other end of the extrusion sleeve blank, after machining is completed, the product ejection cylinder 106 pushes the ejection rod 105 to move, the ejection rod 105 pushes the extrusion sleeve to the discharge plate 107, and the machined extrusion sleeve rolls into the numerical control machine tool 1 along the discharge plate 107 to be collected.

The above embodiments are illustrative of the present invention, and are not intended to limit the present invention, and any simple modifications of the present invention are within the scope of the present invention.

Claims (8)

1. A fixed end anchorage device extrusion sleeve processing device comprises a numerical control machine tool (1), a main shaft box (101) arranged in the numerical control machine tool (1), a feeding mechanism (102), a main shaft (103) arranged on the main shaft box (101) and a tool rest (104) arranged on the feeding mechanism (102); the automatic feeding device is characterized by comprising an automatic feeding mechanism (2) and a reversing feeding mechanism (3) which are arranged in a numerical control machine tool (1); the automatic feeding mechanism (2) comprises a feeding cylinder (201) arranged in the numerical control machine tool (1), an ejection assembly (202) connected with the feeding cylinder (201), and a material receiving plate (203) arranged on the ejection assembly (202); the reversing feeding mechanism (3) comprises a rotary reversing assembly (301) and a reversing feeding cylinder (302) connected with the rotary reversing assembly (301).

2. The fixed end anchorage device extrusion sleeve processing device of claim 1, wherein: a feeding plate (204) and a feeding fixing plate (205) are further arranged in the numerical control machine tool (1); the feeding cylinder (201) is arranged in the numerical control machine tool (1) through a feeding fixing plate (205); the material ejecting assembly (202) comprises an adjusting plate (206) connected with the feeding cylinder (201) and an ejecting cylinder (207) arranged on the adjusting plate (206); the material receiving plate (203) is arranged on the adjusting plate (206).

3. The fixed end anchor extrusion sleeve processing device of claim 2, wherein: a material receiving groove (208) is arranged on the material receiving plate (203); the material ejecting cylinder (207) is connected with a material ejecting block (209) and penetrates through the material receiving plate (203) to be installed in the material receiving groove (208).

4. The fixed end anchor extrusion sleeve processing device of claim 2, wherein: the adjusting plate (206) is also provided with a plurality of guide rods (210); and a guide sleeve (211) matched with the guide rod (210) is arranged on the feeding fixing plate (205).

5. The fixed end anchorage device extrusion sleeve processing device of claim 1, wherein: the rotary reversing assembly (301) comprises a fixed plate (303) arranged on the feeding mechanism (102), a rotary cylinder (304) arranged on the fixed plate (303) and a rotary reversing block (305) connected with the rotary cylinder (304); the reversing feeding cylinder (302) is installed on the fixing plate (303).

6. The fixed end anchor extrusion sleeve processing device of claim 5, wherein: a product reversing through hole (306) is formed in the rotary reversing block (305); the reversing and feeding cylinder (302) is connected with a reversing ejection block (307) matched with the product reversing through hole (306).

7. The fixed end anchorage device extrusion sleeve processing device of claim 1, wherein: an ejector rod (105) is further installed in the main shaft (103); the ejection rod (105) is connected with a product ejection cylinder (106) arranged on the numerical control machine (1); the feeding mechanism (102) is also provided with a discharging plate (107).

8. The processing technique of the fixed end anchorage device extrusion sleeve processing device according to any one of claims 1 to 7, is characterized by comprising the following processing steps:

the first step is as follows: the blank of the extrusion sleeve rolls to a material receiving plate (203) through a feeding plate (204);

the second step is that: the extrusion sleeve blank on the material receiving plate (203) is conveyed to a main shaft (103) of the numerical control lathe (1) through a feeding cylinder (201) and a material ejecting assembly (202), and is fixed by the main shaft (103);

the third step: a feeding mechanism (102) is used for driving a tool rest (104) to process one end of the tool rest, and after the processing is finished, a product ejection cylinder (106) is used for pushing an extrusion sleeve at the processed end to a reversing feeding mechanism (3);

the fourth step: a rotary reversing assembly (301) of the reversing feeding mechanism (3) reverses the extrusion sleeve and then is ejected out of the main shaft (103) through a reversing feeding cylinder (302);

the fifth step: the feeding mechanism (102) is used for driving the tool rest (104) to process the other end of the tool rest, and after the processing is finished, the product ejection cylinder (106) is used for pushing the processed extrusion sleeve to the discharge plate (107), and the extrusion sleeve rolls into the numerical control machine tool (1) along the discharge plate (107).

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