CN111571221A - Aluminum alloy die casting treatment facility - Google Patents

Abstract

The invention discloses aluminum alloy die casting processing equipment which comprises an installation base and an installation main body fixedly arranged on the upper side of the installation base, wherein an operation space with a rightward opening is arranged in the installation main body, a power motor is fixedly arranged in the upper end wall of the operation space, a drilling tool and a chamfering tool are matched to complete drilling and chamfer a hole at the same time, so that burrs are removed, the subsequent process of independently processing the burrs is avoided, the working efficiency of a user is improved, the processing process of the whole production line is improved, the positioning of the drilling position is completed according to the descending height of a supporting arm and the gear ratio between gear sets, the preparation efficiency before drilling is improved, the workload of the user is reduced, the supporting arm is supported and damped by the pressure of hydraulic oil in the drilling process, and the possibility of damage to parts caused by vibration in the operation process of the equipment is reduced, the later maintenance cost is reduced.

Description

Aluminum alloy die casting treatment facility

Technical Field

The invention relates to the technical field of aluminum alloy die casting, in particular to aluminum alloy die casting processing equipment.

Background

The aluminum alloy die casting is widely evaluated due to the advantages of high performance, high precision, high toughness and the like in the use of mechanical parts, the aluminum alloy die casting is mostly required to be drilled in the processing at the present stage, a plurality of burrs are often generated due to heating, distortion, cutting angles and the like of a drill bit in the drilling process, the burrs are difficult to process in the drilling process in the traditional processing procedure, a procedure is added after the drilling is finished, the burrs are removed by friction, the processing which is greatly influenced is carried out, the workload of workers is increased, the working efficiency is extremely low, some existing drilling devices often require the workers to mark the drilling position negligence according to own experience or in advance, the drilling position is often deviated due to some reasons, the later-stage use is influenced, the quality of a final finished product is reduced, and meanwhile, great vibration is often generated in the drilling process, the possibility of damage of parts due to vibration is improved, and the later maintenance cost is increased.

Disclosure of Invention

The invention aims to provide aluminum alloy die casting processing equipment which is used for overcoming the defects in the prior art.

The aluminum alloy die casting processing equipment comprises a mounting base and a mounting main body fixedly arranged on the upper side of the mounting base, wherein an operation space with a rightward opening is formed in the mounting main body, a power motor is fixedly arranged in the upper end wall of the operation space, the lower end of the power motor is in power connection with a power shaft extending downwards, the lower end of the power shaft is in rotating fit connection with the upper end face of the mounting base, a mounting block is slidably arranged on the upper end face of the mounting base, the power shaft controls the mounting block to move through a cam group, a mounting groove with a rightward opening is formed in the mounting block, a drilling tool and a chamfering tool are arranged through a mounting rack, a supporting arm extending leftwards and rightwards is slidably arranged in the operation space, the supporting arm controls the mounting rack to lift through a gear rack assembly, a sliding groove penetrates between the upper end face and the lower end face, the power shaft penetrates through the sliding groove in a sliding mode, a matching groove is formed in the right end wall of the sliding groove in a communicated mode, a threaded block which is in threaded matching with the power shaft is arranged in the matching groove in a sliding mode, an aluminum alloy die casting is placed on the upper end face of the installation base, and the aluminum alloy die casting and a trapezoidal block set arranged in the lower end face of the supporting arm are controlled to move leftwards and rightwards and are in threaded matching with the power shaft in an extruding and pressing mode.

In a further technical scheme, a spring groove is arranged in the support arm, a first trapezoidal block is slidably arranged in the spring groove, a first spring is fixedly arranged between the right end surface of the first trapezoidal block and the right end wall of the spring groove, a sliding groove communicated with the outside is arranged in the lower end wall of the spring groove, a second trapezoidal block matched with the first trapezoidal block is slidably arranged in the sliding groove, a clamping groove is communicated and arranged in the left end wall of the spring groove, a clamping block is slidably arranged in the clamping groove, the right end of the clamping block is fixedly connected with the second trapezoidal block, a second spring is fixedly arranged between the upper end surface of the clamping block and the upper end wall of the clamping groove, a transmission pull wire is fixedly arranged on the left end surface of the first trapezoidal block, and one end of the transmission pull wire, which is far away from the first trapezoidal block, slidably extends into the matching groove and is fixedly connected with the right end surface of the threaded, and a third spring is fixedly arranged between the right end surface of the threaded block and the right end wall of the matching groove.

According to the technical scheme, a limiting groove is formed in the left end wall of the operation space in a communicated mode, a limiting block is arranged on the limiting groove in a sliding mode, the right end of the limiting block is fixedly connected with the supporting arm, a hydraulic groove is formed in the lower side of the limiting groove, a hydraulic block is arranged in the hydraulic groove in the sliding mode, a hydraulic rod extending upwards is fixedly connected to the upper end of the hydraulic block, the upper end of the hydraulic rod extends into the limiting groove in the sliding mode and is fixedly connected with the lower end face of the limiting block, a communicating groove extending leftwards is formed in the lower end of the hydraulic groove in a communicated mode, a hydraulic valve is fixedly mounted on the communicating groove, a sliding block is arranged in the communicating groove in the sliding mode, and a fourth spring is.

In a further technical scheme, a cam sleeved on the outer surface of the power shaft is arranged in the operation space, the right end face of the cam is abutted against the left end face of the mounting block, a support rod extending downwards is fixedly connected to the lower end face of the cam, a limit ring with an upward opening is arranged on the upper end face of the mounting base, a connecting block is slidably arranged in the limit ring, the upper end of the connecting block is fixedly connected with the support rod, an electromagnetic space is arranged in the cam, the power shaft slidably penetrates through the electromagnetic space, a friction block is slidably arranged in the electromagnetic space, a fifth spring is fixedly arranged between the left end face of the friction block and the left end wall of the electromagnetic space, a first electromagnet is fixedly arranged in the left end face of the friction block, and a second electromagnet matched with the first electromagnet is fixedly arranged in the left end wall of the electromagnetic space, the mounting base is internally provided with a reset groove with an upward opening, a reset block is arranged in the reset groove in a sliding mode, the upper end of the reset block is fixedly connected with the mounting block, and a sixth spring is fixedly arranged between the right end face of the reset block and the right end wall of the reset groove.

In a further technical scheme, a transmission groove with a downward opening is arranged on the lower end surface of the support arm, a transmission block is slidably arranged in the transmission groove, the lower end of the transmission block is fixedly connected with a transmission rack extending downwards, a rack cavity with an upward opening is arranged in the mounting block, the lower end of the transmission rack can slidably extend into the rack cavity, a seventh spring is fixedly arranged between the lower end surface of the rack cavity and the lower end wall of the rack cavity, a gear cavity is communicated and arranged between the gear cavity and the mounting groove, a transmission gear meshed with the transmission rack is rotatably arranged between the front end wall and the rear end wall of the gear cavity, a driven gear meshed with the transmission gear is rotatably arranged between the front end wall and the rear end wall of the gear cavity, an installation rack meshed with the driven gear is slidably arranged in the installation groove, and an eighth spring is fixedly arranged between the lower end face of the installation rack and the lower end wall of the installation groove.

In a further technical scheme, a rotating motor is fixedly arranged in the right end face of the installation rack, a drilling tool extending rightwards is in power connection with the right end of the rotating motor, a linkage space with an upward opening is arranged in the drilling tool, a third trapezoidal block is slidably arranged in the linkage space, a ninth spring is fixedly arranged between the lower end face of the third trapezoidal block and the lower end wall of the linkage space, mounting grooves with an upward opening are symmetrically arranged in the upper end face of the drilling tool, chamfering tools are rotatably arranged in the left mounting groove and the right mounting groove through torsion springs, first guide wheels are rotatably arranged in the left mounting groove and the right mounting groove, first guide wire spaces are respectively arranged at the lower sides of the left mounting groove and the right mounting groove, a second guide wheel is rotatably arranged in the first guide wire spaces, and a second guide wire space is arranged between the left first guide wheel and, rotationally be provided with bilateral symmetry's third wire wheel in the second wire space, two elasticity of the fixed bilateral symmetry that is provided with of terminal surface are acted as go-between under the third trapezoidal piece, and control two elasticity and act as go-between and keep away from the one end of third trapezoidal piece is walked around in proper order respectively the third wire wheel second wire wheel and behind the first wire wheel with terminal surface fixed connection under the chamfer cutter.

The invention has the beneficial effects that: the drilling tool chamfering device is simple in structure and convenient to operate, holes are chamfered while drilling is completed through the matching of the drilling tool and the chamfering tool, burrs are removed, the subsequent process of independently processing the burrs is avoided, the working efficiency of a user is improved, the processing process progress of the whole production line is improved, the drilling position is positioned according to the gear ratio between the descending height of the supporting arm and the gear set, the preparation efficiency before drilling is improved, the workload of the user is reduced, the supporting arm is supported and damped through the pressure of hydraulic oil in the drilling process, the possibility that parts are damaged by vibration in the equipment operation process is reduced, and the later maintenance cost is reduced.

Drawings

FIG. 1 is a schematic view of the internal overall structure of an aluminum alloy die casting processing device of the invention;

FIG. 2 is an enlarged, fragmentary, schematic view at A of FIG. 1 of the present invention;

fig. 3 is a partially enlarged view of B in fig. 2 according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-3, an aluminum alloy die casting processing device according to an embodiment of the present invention comprises a mounting base 100 and a mounting body 119 fixedly arranged on the upper side of the mounting base 100, wherein an operating space 124 with a right opening is arranged in the mounting body 119, a power motor 120 is fixedly arranged in the upper end wall of the operating space 124, a power shaft 118 extending downwards is connected to the lower end of the power motor 120 in a power connection manner, the lower end of the power shaft 118 is connected with the upper end surface of the mounting base 100 in a rotating fit manner, a mounting block 150 is slidably arranged on the upper end surface of the mounting base 100, the power shaft 118 controls the mounting block 150 to move through a cam set, a mounting groove 152 with a right opening is arranged in the mounting block 150 and is provided with a drilling and chamfering tool through a mounting rack 153, a supporting arm 117 extending left and right is slidably arranged in the operating space 124, the supporting arm 117 is controlled by a gear and rack assembly to lift the mounting rack 153, a sliding groove 116 penetrates through the upper end face and the lower end face of the supporting arm 117, the power shaft 118 slidably penetrates through the sliding groove 116, a matching groove 123 is communicated in the right end wall of the sliding groove 116, a threaded block 121 which is in threaded matching with the power shaft 118 is slidably arranged in the matching groove 123, an aluminum alloy die casting 101 is placed on the upper end face of the mounting base 100, and the aluminum alloy die casting 101 and a trapezoidal block set arranged in the lower end face of the supporting arm 117 are in extrusion press fit to control the threaded block 121 to move left and right to be in threaded matching with the power shaft 118.

Beneficially or exemplarily, a spring groove 127 is disposed in the support arm 117, a first trapezoidal block 126 is slidably disposed in the spring groove 127, a first spring 130 is fixedly disposed between a right end surface of the first trapezoidal block 126 and a right end wall of the spring groove 127, a sliding groove 131 communicated with the outside is disposed in a lower end wall of the spring groove 127, a second trapezoidal block 132 adapted to the first trapezoidal block 126 is slidably disposed in the sliding groove 131, a locking groove 135 is communicatively disposed in a left end wall of the spring groove 127, a locking block 133 is slidably disposed in the locking groove 135, a right end of the locking block 133 is fixedly connected to the second trapezoidal block 132, a second spring 134 is fixedly disposed between an upper end surface of the locking block 133 and an upper end wall of the locking groove 135, a transmission pull wire 125 is fixedly disposed on a left end surface of the first trapezoidal block 126, and one end of the transmission pull wire 125 far away from the first trapezoidal block 126 slidably extends into the matching groove 123 and is fixedly connected to a right side of the threaded block 121 The right end face of the thread block 121 is fixedly connected with the right end wall of the matching groove 123, a third spring 122 is fixedly arranged between the right end face of the thread block and the right end wall of the matching groove 123, the aluminum alloy die casting 101 drives the second trapezoidal block 132 to move upwards under the action of the elastic force of the second spring 134, the second trapezoidal block 132 drives the first trapezoidal block 126 to move rightwards under the action of the elastic force of the first spring 130, and the first trapezoidal block 126 drives the thread block 121 to move rightwards under the action of the elastic force of the third spring 122 through the transmission pull wire 125, so that the thread block 121 is driven to be disengaged from the power shaft 118.

Beneficially or exemplarily, a limiting groove 114 is communicated with and disposed in a left end wall of the operation space 124, a limiting block 115 is disposed in the limiting groove 114 in a sliding manner, a right end of the limiting block 115 is fixedly connected with the supporting arm 117, a hydraulic groove 111 is disposed at a lower side of the limiting groove 114, a hydraulic block 112 is disposed in the hydraulic groove 111 in a sliding manner, an upward extending hydraulic rod 113 is fixedly connected to an upper end of the hydraulic block 112, an upper end of the hydraulic rod 113 slidably extends into the limiting groove 114 and is fixedly connected with a lower end surface of the limiting block 115, a communicating groove 110 extending leftward is communicated with and is fixedly disposed at a lower end of the hydraulic groove 111, a sliding block 107 is slidably disposed in the communicating groove 110, a fourth spring 109 is fixedly disposed between a left end surface of the sliding block 107 and a left end wall of the communicating groove 110, and the hydraulic valve 106 is in an open state when the supporting arm 117, at this time, the limiting block 115 drives the hydraulic block 112 to move downward through the hydraulic rod 113, the hydraulic block 112 drives the slider 107 to move leftward under the action of the elastic force of the fourth spring 109 through the pressure of hydraulic oil, the hydraulic valve 106 is closed when the support arm 117 stops moving downward, and a supporting force is provided for the support arm 117 through the pressure of the hydraulic oil.

Beneficially or exemplarily, a cam 141 sleeved on the outer surface of the power shaft 118 is disposed in the operating space 124, a right end surface of the cam 141 abuts against a left end surface of the mounting block 150, a support rod 144 extending downward is fixedly connected to a lower end surface of the cam 141, a stop ring 104 having an upward opening is disposed on an upper end surface of the mounting base 100, a connecting block 105 is slidably disposed in the stop ring 104, an upper end of the connecting block 105 is fixedly connected to the support rod 144, an electromagnetic space 140 is disposed in the cam 141, the power shaft 118 slidably penetrates through the electromagnetic space 140, a friction block 146 is slidably disposed in the electromagnetic space 140, a fifth spring 143 is fixedly disposed between a left end surface of the friction block 146 and a left end wall of the electromagnetic space 140, and a first electromagnet 145 is fixedly disposed in a left end surface of the friction block 146, a second electromagnet 142 matched with the first electromagnet 145 is fixedly arranged in the left end wall of the electromagnetic space 140, a reset groove 102 with an upward opening is formed in the mounting base 100, a reset block 103 is slidably arranged in the reset groove 102, the upper end of the reset block 103 is fixedly connected with the mounting block 150, a sixth spring 108 is fixedly arranged between the right end face of the reset block 103 and the right end wall of the reset groove 102, when the support arm 117 descends to a proper height, the first electromagnet 145 and the second electromagnet 142 are opened, the friction block 146 is driven to move rightwards under the elastic force action of the fifth spring 143, the friction block 146 is made to cling to the power shaft 118, and at the moment, the power shaft 118 drives the cam 141 to rotate through the friction block 146, so that the mounting block 150 is driven to move leftwards and rightwards.

Beneficially or exemplarily, the lower end surface of the support arm 117 is provided with a transmission groove 136 with a downward opening, the transmission groove 136 is slidably provided with a transmission block 137, the lower end of the transmission block 137 is fixedly connected with a transmission rack 138 extending downward, the mounting block 150 is provided with a rack cavity 147 with an upward opening, the lower end of the transmission rack 138 slidably extends into the rack cavity 147, a seventh spring 148 is fixedly arranged between the lower end surface of the rack cavity 147 and the lower end wall of the rack cavity 147, a gear cavity 156 is arranged between the rack cavity 147 and the mounting groove 152 in a communicating manner, a transmission gear 157 engaged with the transmission rack 138 is rotatably arranged between the front end wall and the rear end wall of the gear cavity 156, a driven gear 154 engaged with the transmission gear 157 is rotatably arranged between the front end wall and the rear end wall of the gear cavity 156, a mounting rack 153 engaged with the driven gear 154 is slidably arranged in the mounting groove 152, an eighth spring 151 is fixedly arranged between the lower end face of the mounting rack 153 and the lower end wall of the mounting groove 152, the support arm 117 drives the transmission rack 138 to move downwards against the elastic force of the seventh spring 148 when descending, the transmission rack 138 drives the mounting rack 153 to move downwards against the elastic force of the eighth spring 151 through the meshing relationship among the transmission rack 138, the transmission gear 157 and the mounting rack 153, and the descending distance of the mounting rack 153 is controlled by changing the gear ratio among the gears and the racks.

Beneficially or exemplarily, a rotating motor 162 is fixedly arranged in the right end face of the mounting rack 153, a drilling tool 170 extending rightward is dynamically connected to the right end of the rotating motor 162, a linkage space 167 with an upward opening is arranged in the drilling tool 170, a third trapezoidal block 165 is slidably arranged in the linkage space 167, a ninth spring 166 is fixedly arranged between the lower end face of the third trapezoidal block 165 and the lower end wall of the linkage space 167, mounting grooves 169 with an upward opening are symmetrically arranged in the upper end face of the drilling tool 170, chamfering tools 168 are rotatably arranged in the left and right mounting grooves 169 through torsion springs 164, a first wire guide wheel 163 is rotatably arranged in the left and right mounting grooves 169, a first wire guide space 171 is arranged at the lower side of the left and right mounting grooves 169, and a second wire guide wheel 172 is rotatably arranged in the first wire guide space 171, a second wire space 174 is arranged between the left first wire space 171 and the right first wire space 171, a left third wire wheel 173 symmetrical to the left and the right is rotatably arranged in the second wire space 174, two elastic pull wires 175 symmetrical to the left and the right are fixedly arranged on the lower end surface of the third trapezoidal block 165, one ends of the left elastic pull wires 175 and the right elastic pull wires 175 far away from the third trapezoidal block 165 respectively and sequentially bypass the third wire wheel 173, the second wire wheel 172 and the first wire wheel 163 and then are fixedly connected with the lower end surface of the chamfering tool 168, when the mounting block 150 moves rightwards, the drilling tool 170 is driven to rotate by the rotating motor 162, the aluminum alloy die casting 101 is drilled by the drilling tool 170, and after the drilling is completed, the third trapezoidal block 165 is pushed to move downwards under the action of the elastic force of the ninth spring 166, and at this moment, the elastic pull wires 175 are in a relaxed state, releasing the torsion action of the torsion spring 164 drives the left chamfering cutter 168 and the right chamfering cutter 168 to rotate for a certain angle, slightly chamfering the surface of the hole, and removing burrs on the surface of the hole.

In an initial state, the supporting arm 117 slides upwards to the maximum extent in the operating space 124, the second trapezoidal block 132 is disengaged from the aluminum alloy die casting 101, the screw block 121 slides leftwards to the maximum extent under the left and right of the elastic force of the third spring 122 to be engaged with the power shaft 118, the hydraulic valve 106 is in a closed state, the slider 107 slides rightwards to the maximum extent under the elastic force of the fourth spring 109, the driving rack 138 moves upwards to the maximum extent in the rack cavity 147, the mounting rack 153 is at the highest point in the mounting groove 152, the second electromagnet 142 and the first electromagnet 145 are both in a closed state, the friction block 146 is disengaged from the power shaft 118 under the elastic force of the fifth spring 143, and the third trapezoidal block 165 moves upwards to the maximum extent under the elastic force of the ninth spring 166, the left and right chamfering tools 168 are both restrained in the mounting groove 169 by the elastic pull wire 175, and the torsion spring 164 is in a power accumulation state.

When the hydraulic valve is used, the hydraulic valve 106 is opened, the power motor 120 is started to rotate forward, the support arm 117 is driven to move downwards through the threaded fit between the power shaft 118 and the thread block 121, the second trapezoidal block 132 is driven to move upwards by being squeezed between the hydraulic valve and the aluminum alloy die casting 101 and overcome the elastic force of the second spring 134, when the lower end face of the second trapezoidal block 132 is flush with the lower end face of the support arm 117, the thread block 121 is separated from the power shaft 118, the hydraulic valve 106 is closed, the support effect is achieved through the pressure of hydraulic oil, meanwhile, the transmission rack 138 drives the drilling tool 170 to descend to a proper height through the meshing relation of the gear set diameters, at the moment, the second electromagnet 142 and the first electromagnet 145 are started to drive the friction block 146 to move rightwards by overcoming the elastic force of the fifth spring 143, the power shaft 118 drives the cam 141 to rotate through the friction block 146, drives the mounting block 150 to move rightwards, and simultaneously turns on the rotating motor 162, the aluminum alloy die casting 101 is drilled, after the drilling is finished, the third trapezoidal block 165 is pushed to move downwards under the action of the elastic force of the ninth spring 166, at the moment, the elastic pull wire 175 is in a relaxed state, the torsion force of the torsion spring 164 is released to drive the left chamfering cutter 168 and the right chamfering cutter 168 to rotate for a certain angle, slightly chamfering the surface of the formed hole, removing burrs on the surface of the formed hole, taking out the aluminum alloy die casting 101 after the working procedure is finished, the second trapezoidal block 132 is moved downward by the elastic force of the second spring 134, the thread block 121 is engaged with the power shaft 118 again under the action of elastic force, and at the moment, the power motor 120 rotates reversely, so that the device restores the initial position.

The invention has the beneficial effects that: the drilling tool chamfering device is simple in structure and convenient to operate, holes are chamfered while drilling is completed through the matching of the drilling tool and the chamfering tool, burrs are removed, the subsequent process of independently processing the burrs is avoided, the working efficiency of a user is improved, the processing process progress of the whole production line is improved, the drilling position is positioned according to the gear ratio between the descending height of the supporting arm and the gear set, the preparation efficiency before drilling is improved, the workload of the user is reduced, the supporting arm is supported and damped through the pressure of hydraulic oil in the drilling process, the possibility that parts are damaged by vibration in the equipment operation process is reduced, and the later maintenance cost is reduced.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims (6)

1. The utility model provides an aluminum alloy die casting treatment facility, is in including installation base and fixed the setting the installation main part of installation base upside, its characterized in that: an operation space with a right opening is arranged in the installation main body, a power motor is fixedly arranged in the upper end wall of the operation space, the lower end of the power motor is in power connection with a power shaft extending downwards, the lower end of the power shaft is in running fit connection with the upper end face of the installation base, an installation block is slidably arranged on the upper end face of the installation base, the power shaft controls the installation block to move through a cam group, an installation groove with a right opening is arranged in the installation block, a drilling tool and a chamfering tool are arranged through an installation rack, a support arm extending leftwards and rightwards is slidably arranged in the operation space, the support arm controls the installation rack to lift through a gear rack assembly, a sliding groove is arranged between the upper end face and the lower end face of the support arm in a penetrating manner, the power shaft slidably penetrates through the sliding groove, and a, the matching groove is slidably provided with a thread block in a thread matching relation with the power shaft, an aluminum alloy die casting is placed on the upper end face of the mounting base, and the left and right movement of the thread block is controlled to be in thread matching with the power shaft through the extrusion press fit of the aluminum alloy die casting and a trapezoid block set arranged in the lower end face of the supporting arm.

2. The aluminum alloy die casting processing apparatus according to claim 1, characterized in that: a spring groove is arranged in the supporting arm, a first trapezoidal block is slidably arranged in the spring groove, a first spring is fixedly arranged between the right end surface of the first trapezoidal block and the right end wall of the spring groove, a sliding groove communicated with the outside is arranged in the lower end wall of the spring groove, a second trapezoidal block matched with the first trapezoidal block is slidably arranged in the sliding groove, a clamping groove is communicated in the left end wall of the spring groove, a clamping block is slidably arranged in the clamping groove, the right end of the clamping block is fixedly connected with the second trapezoidal block, a second spring is fixedly arranged between the upper end surface of the clamping block and the upper end wall of the clamping groove, a transmission pull wire is fixedly arranged on the left end surface of the first trapezoidal block, and one end of the transmission pull wire, far away from the first trapezoidal block, slidably extends into the matching groove and is fixedly connected with the right end surface of the threaded block, and a third spring is fixedly arranged between the right end surface of the threaded block and the right end wall of the matching groove.

3. The aluminum alloy die casting processing apparatus according to claim 1, characterized in that: the operation space left end wall is provided with a limiting groove in a communicated mode, the limiting groove is provided with a limiting block in a sliding mode, the limiting block right end is fixedly connected with the supporting arm, a hydraulic groove is arranged on the lower side of the limiting groove, a hydraulic block is arranged in the hydraulic groove in the sliding mode, the upper end of the hydraulic block is fixedly connected with a hydraulic rod extending upwards, the upper end of the hydraulic rod extends into the limiting groove in the sliding mode and is fixedly connected with the lower end face of the limiting block, the lower end of the hydraulic groove is communicated with a communicated groove extending leftwards, a hydraulic valve is fixedly mounted in the communicated groove, a sliding block is arranged in the communicated groove in the sliding mode, and a fourth spring is fixedly arranged between the left end wall of.

4. The aluminum alloy die casting processing apparatus according to claim 1, characterized in that: a cam sleeved on the outer surface of the power shaft is arranged in the operation space, the right end face of the cam is abutted against the left end face of the mounting block, a support rod extending downwards is fixedly connected to the lower end face of the cam, a limiting ring with an upward opening is arranged on the upper end face of the mounting base, a connecting block is slidably arranged in the limiting ring, the upper end of the connecting block is fixedly connected with the support rod, an electromagnetic space is arranged in the cam, the power shaft slidably penetrates through the electromagnetic space, a friction block is slidably arranged in the electromagnetic space, a fifth spring is fixedly arranged between the left end face of the friction block and the left end wall of the electromagnetic space, a first electromagnet is fixedly arranged in the left end face of the friction block, and a second electromagnet matched with the first electromagnet is fixedly arranged in the left end wall of the electromagnetic space, the mounting base is internally provided with a reset groove with an upward opening, a reset block is arranged in the reset groove in a sliding mode, the upper end of the reset block is fixedly connected with the mounting block, and a sixth spring is fixedly arranged between the right end face of the reset block and the right end wall of the reset groove.

5. The aluminum alloy die casting processing apparatus according to claim 1, characterized in that: the lower end surface of the supporting arm is provided with a transmission groove with a downward opening, a transmission block is slidably arranged in the transmission groove, the lower end of the transmission block is fixedly connected with a transmission rack extending downwards, a rack cavity with an upward opening is arranged in the mounting block, the lower end of the transmission rack can slidably extend into the rack cavity, a seventh spring is fixedly arranged between the lower end surface of the rack cavity and the lower end wall of the rack cavity, a gear cavity is communicated and arranged between the gear cavity and the mounting groove, a transmission gear meshed with the transmission rack is rotatably arranged between the front end wall and the rear end wall of the gear cavity, a driven gear meshed with the transmission gear is rotatably arranged between the front end wall and the rear end wall of the gear cavity, an installation rack meshed with the driven gear is slidably arranged in the installation groove, and an eighth spring is fixedly arranged between the lower end face of the installation rack and the lower end wall of the installation groove.

6. The aluminum alloy die casting processing apparatus according to claim 1, characterized in that: a rotating motor is fixedly arranged in the right end face of the mounting rack, a drilling tool extending rightwards is in power connection with the right end of the rotating motor, a linkage space with an upward opening is arranged in the drilling tool, a third trapezoidal block is slidably arranged in the linkage space, a ninth spring is fixedly arranged between the lower end face of the third trapezoidal block and the lower end wall of the linkage space, mounting grooves with an upward opening are symmetrically arranged in the upper end face of the drilling tool leftwards and rightwards, chamfering tools are rotatably arranged in the left and right mounting grooves through torsion springs, first guide wheels are rotatably arranged in the left and right mounting grooves, first guide wire spaces are arranged at the lower sides of the left and right mounting grooves, a second guide wheel is rotatably arranged in the first guide wire spaces, a second guide wire space is arranged between the left and right first guide wire spaces, and a third guide wheel which is symmetrically arranged in the left and right guide wire spaces, the fixed two elasticity of bilateral symmetry of being provided with of terminal surface are acted as go-between under the third trapezoidal piece, and control two elasticity and act as go-between and keep away from the one end of third trapezoidal piece is walked around in proper order respectively the third wire wheel the second wire wheel and behind the first wire wheel with terminal surface fixed connection under the chamfer cutter.

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