CN222957983U - A processing equipment for shock absorber aluminum cylinder - Google Patents

Abstract

The utility model discloses a processing device, belongs to the technical field of shock absorber aluminum cylinder processing, and specifically relates to a shock absorber aluminum cylinder processing device, comprising: a frame, a driving mechanism, a turntable mechanism, a cutting mechanism, a reaming mechanism, a pore mechanism, a hydraulic station and a cover shell; the driving mechanism drives the turntable mechanism to rotate, the cutting mechanism, the reaming mechanism and the pore mechanism are all installed on the frame and docked with the turntable mechanism to perform cutting, reaming and pore work of the shock absorber aluminum cylinder; the hydraulic station is respectively connected to the turntable mechanism, the cutting mechanism, the reaming mechanism and the pore mechanism to provide power for them. The utility model combines the original three processing devices into one processing device, saves costs, reduces the floor space, greatly improves the conversion speed between various processes, and is more efficient.

Description

Processing equipment of shock absorber aluminum cylinder

Technical Field

The utility model discloses processing equipment, belongs to the technical field of processing of shock absorber aluminum barrels, and particularly relates to processing equipment of shock absorber aluminum barrels.

Background

The shock absorber aluminum cylinder refers to a part for installing an electric vehicle on the shock absorber and is usually made of aluminum alloy. The main function of the shock absorber aluminum cylinder is to serve as a shell of the shock absorber, and is used for accommodating components such as a piston, a valve, oil liquid and the like in the shock absorber and bearing the force and pressure generated when a vehicle or equipment runs.

In the automotive industry and other mechanical devices, the design and manufacture of the shock absorber aluminum cylinder is to ensure that the shock absorber can effectively reduce the shock and impact generated by uneven road surfaces of vehicles or devices in the running process, and improve the driving comfort and safety.

The current market of the battery car is huge, wherein the demand of the shock absorber aluminum cylinder of the battery car is considerable, cutting, reaming and pore opening are arranged in the production process of the shock absorber aluminum cylinder before, each process needs a processing device, the occupied area is large, and the materials between each process also need manual circulation, so that a lot of manpower and material resources can be consumed. In order to solve such a problem, an integrated processing apparatus of the damper aluminum cylinder is required.

Disclosure of utility model

The utility model aims to provide processing equipment for the shock absorber aluminum cylinder, which solves the problems.

The technical scheme is that the processing equipment of the shock absorber aluminum cylinder comprises a frame, a driving mechanism, a turntable mechanism, a cutting mechanism, a reaming mechanism, a pore opening mechanism, a hydraulic station and a housing;

The hydraulic device comprises a frame, a rotary table mechanism, a cutting mechanism, a reaming mechanism, a pore mechanism, a hydraulic station, a rotary table mechanism, a cutting mechanism, a reaming mechanism, a hydraulic station and a shell, wherein the driving mechanism is arranged on the frame, the rotary table mechanism is arranged on the driving mechanism to rotate along with the driving mechanism, the cutting mechanism, the reaming mechanism and the pore mechanism are all arranged on the frame and are in butt joint with the rotary table mechanism to cut, ream and pore the shock absorber aluminum cylinder, the hydraulic station is fixedly arranged in the shell and is respectively connected with the rotary table mechanism, the cutting mechanism, the reaming mechanism and the pore mechanism to supply power for the rotary table mechanism, the reaming mechanism and the pore mechanism, and the shell is fixedly arranged on the frame and forms an installation cavity with the frame.

In a further embodiment, the driving mechanism comprises a main shaft wallboard fixedly arranged on one side of the frame, a bracket seat fixedly arranged on one side of the main shaft wallboard, a speed reducer fixedly arranged on the bracket seat, a first motor arranged on the speed reducer, a driving shaft, a positioning disc, a thin cylinder, a positioning pin shaft, a first sensor fixedly arranged on the thin cylinder, a first sensing piece fixedly arranged on the positioning disc, a rotary joint and a driving shaft, wherein the rotating shaft is connected with one end of the speed reducer through a bearing seat and is arranged on the main shaft wallboard, one end of the driving shaft is connected with the other end of the speed reducer through a flange so as to rotate along with the speed reducer, the positioning disc is sleeved on the driving shaft, the thin cylinder is fixedly arranged at two ends of the bracket seat, the positioning pin shaft is fixedly arranged on the thin cylinder and matched with an upper positioning hole of the positioning disc, the first sensor is fixedly arranged on the thin cylinder, the first sensing piece is fixedly arranged on the positioning disc, and the rotary joint is fixedly arranged on the other end of the driving shaft.

In a further embodiment, the turntable mechanism comprises a tool square box, an aluminum cylinder placement tool, a pressing oil cylinder assembly, a fixed shaft, a main shaft center column and a main shaft center column, wherein one end of the tool square box is connected with the driving shaft through a flange to follow the driving shaft, the aluminum cylinder placement tool is provided with four groups and is fixedly installed at four corners of the tool square box in a circumferential rotation array mode, the pressing oil cylinder assembly is provided with four groups and is fixedly installed on the tool square box corresponding to the aluminum cylinder placement tool, one end of the fixed shaft is fixedly installed on the other side of the tool square box through a ball bearing seat, and the fixed shaft center column is fixedly installed on the frame and is fixedly connected with the main shaft center column.

In a further embodiment, the cutting mechanism comprises a column wallboard fixedly arranged on the frame, a cutting platform fixedly arranged on the column wallboard and the main shaft center post, a first guide rail fixedly arranged on the cutting platform, a first sliding block slidably arranged on the first guide rail, a cutting sliding plate fixedly arranged on the first sliding block, a cutting oil cylinder fixedly arranged on the cutting platform, a cutting motor fixedly arranged on the cutting sliding plate, a cutting blade sleeved on a rotating shaft of the cutting motor, a material sliding groove fixedly arranged on the cutting sliding plate and positioned below the cutting blade, a second sensor fixedly arranged on the cutting sliding plate, and a second sensing piece fixedly arranged on the cutting platform.

In a further embodiment, the reaming mechanism comprises a second guide rail fixedly arranged on the frame, a second sliding block which is slidably arranged on the second guide rail, a second sliding plate fixedly arranged on the second sliding block, a second oil cylinder fixedly arranged on the frame, a telescopic rod fixedly connected with one side of the second sliding plate so as to drive the second sliding plate to move, a rack fixedly arranged on one side of the second sliding plate, a pore encoder fixedly arranged on the frame through a bracket, a gear sleeved on the pore encoder and meshed with the rack, a double-shaft drilling machine power head fixedly arranged on the second sliding plate, a pore adjusting plate fixedly arranged on the second sliding plate through an adjusting screw rod, a second motor pore adjusting plate, a driving belt pulley sleeved on a rotating shaft of the second motor, a driven belt pulley sleeved on one end of the rotating shaft of the double-shaft drilling machine power head, the driving belt pulley and the driven belt pulley connected with the pore encoder through a belt, and a double-shaft drilling machine power head fixedly sleeved on the other end of the double-shaft drilling machine power head.

In a further embodiment, the pore opening mechanism is structurally identical to the reaming mechanism.

In a further embodiment, the aluminum cylinder placement tool comprises a clamp seat fixedly arranged on the tool square box, a base bottom plate fixedly arranged on the clamp seat, a tool assembly body adjustably arranged on the base bottom plate, and a positioning seat fixedly arranged on one side of the base bottom plate.

In a further embodiment, the compression oil cylinder assembly comprises a cylinder seat fixedly arranged on the tool square box, a supporting seat fixedly arranged on one side of the cylinder seat, a clamping arm, a compression oil cylinder and a pressing block, wherein the middle part of the clamping arm is rotatably arranged on the supporting seat, the compression oil cylinder is arranged in the tool square box through a TC frame, the telescopic rod and one end of the clamping arm are arranged on the other end of the clamping arm, and the pressing block is fixedly arranged on the other end of the clamping arm.

The hydraulic station is respectively connected with the turntable mechanism, the cutting mechanism, the reaming mechanism and the pore mechanism to provide power for the turntable mechanism, and the original three processing devices are combined into one processing device, so that the cost is saved, the conversion speed between the various processes of the occupied area is reduced, the conversion speed is greatly improved, and the efficiency is higher.

Drawings

Fig. 1 is a schematic diagram of the present utility model.

Fig. 2 is an isometric view of the present utility model.

Fig. 3 is a schematic view of the drive mechanism and turntable mechanism of the present utility model.

Fig. 4 is a front view of the drive mechanism and turntable mechanism of the present utility model.

Fig. 5 is an isometric view of a cutting mechanism of the present utility model.

Fig. 6 is a front view of the cutting mechanism of the present utility model.

Fig. 7 is a schematic view of the reaming mechanism and pore mechanism of the present utility model.

Fig. 8 is an isometric view of the reaming mechanism and pore mechanism of the present utility model.

Fig. 9 is a front view of the reaming mechanism and pore mechanism of the present utility model.

Fig. 10 is an isometric view of the turntable mechanism of the present utility model.

The numerical control machine comprises a frame 1, a driving mechanism 2, a turntable mechanism 3, a cutting mechanism 4, a reaming mechanism 5, a pore opening mechanism 6, a hydraulic station 7, a housing 8, a spindle wallboard 9, a bracket seat 10, a speed reducer 11, a first motor 12, a driving shaft 13, a positioning disk 14, a thin cylinder 15, a positioning pin 16, a first sensor 17, a first sensing piece 18, a rotary joint 19, a tooling square box 20, an aluminum cylinder placement tooling 21, a compression cylinder assembly 22, a fixed shaft 23, a spindle center post 24, a column wallboard 25, a cutting platform 26, a first guide rail 27, a first slide 28, a cutting slide 29, a cutting cylinder 30, a cutting motor 31, a cutting blade 32, a chute 33, a second sensor 34, a second sensing piece 35, a second guide rail 36, a second slide 37, a second slide 38, a second cylinder 39, a rack 40, a pore encoder 41, a gear 42, a double-spindle power head 43, an adjusting plate 44, a second motor 45, a driving pulley 46, a driven pulley 47, a drill bit 48, a clamp seat 49, a base bottom plate 50, an assembly body 51, a positioning cylinder seat 52, a support cylinder seat 53, a clamp cylinder seat 57, and a compression cylinder seat 57.

Detailed Description

The following description of the embodiments of the present utility model will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the utility model are shown. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present utility model, unless explicitly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, mechanically connected, electrically connected, directly connected, indirectly connected via an intervening medium, or in communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art. In addition, the technical features of the different embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other.

The processing equipment of the shock absorber aluminum cylinder comprises a frame 1, a driving mechanism 2, a turntable mechanism 3, a cutting mechanism 4, a reaming mechanism 5, a pore opening mechanism 6, a hydraulic station 7 and a housing 8, as shown in fig. 1 and 2.

In one embodiment, as shown in fig. 1 and 2, the driving mechanism 2 is mounted on the frame 1, the turntable mechanism 3 is mounted on the driving mechanism 2 to rotate along with the driving mechanism 2, the cutting mechanism 4, the reaming mechanism 5 and the pore mechanism 6 are mounted on the frame 1 and are in butt joint with the turntable mechanism 3 to cut, ream and pore the shock absorber aluminum cylinder, the hydraulic station 7 is fixedly mounted in the housing 8 and is respectively connected with the turntable mechanism 3, the cutting mechanism 4, the reaming mechanism 5 and the pore mechanism 6 to provide power for the turntable mechanism, and the housing 8 is fixedly mounted on the frame 1 and forms a mounting cavity with the frame 1.

In one embodiment, as shown in fig. 3 and 4, the driving mechanism 2 includes a main shaft wall plate 9 fixedly installed on one side of the frame 1, a bracket base 10 fixedly installed on one side of the main shaft wall plate 9, a speed reducer 11 fixedly installed on the bracket base 10, a first motor 12 installed on the speed reducer 11 and having a rotating shaft connected with one end of the speed reducer 11 to rotate, a driving shaft 13 installed on the main shaft wall plate 9 through a bearing seat and having one end connected with the other end of the speed reducer 11 through a flange to rotate along with the speed reducer 11, a positioning disk 14 sleeved on the driving shaft 13, a thin cylinder 15 fixedly installed on both ends of the bracket base 10, a positioning pin 16 fixedly installed on the thin cylinder 15 and engaged with an upper positioning hole of the positioning disk 14, a first sensor 17 fixedly installed on the thin cylinder 15, a first sensing piece 18 fixedly installed on the positioning disk 14, and a rotary joint 19 fixedly installed on the other end of the driving shaft 13.

In one embodiment, as shown in fig. 3 and 4, the turntable mechanism comprises a tooling square box 20, a test flange and a test shaft 13, wherein the test flange is connected with the drive shaft 13 to follow the drive shaft 13; the aluminum tube placing tool 21 is provided with four groups and is fixedly arranged at four corners of the tool square box 20 in a circumferential rotation array mode, the compression oil cylinder assembly 22 is provided with four groups and is fixedly arranged on the tool square box 20 corresponding to the aluminum tube placing tool 21, one end of a fixed shaft 23 is fixedly arranged on the other side of the tool square box 20 through a ball bearing seat, a main shaft center column 24 is fixedly arranged on the frame 1, and the fixed shaft 23 is fixedly connected with the main shaft center column 24.

In one embodiment, as shown in fig. 5 and 6, the cutting mechanism 4 comprises a column wall plate 25 fixedly mounted on the frame 1, a cutting platform 26 fixedly mounted on the column wall plate 25 and the main shaft center post 24, a first guide rail 27 fixedly mounted on the cutting platform 26, a first sliding block 28 slidably mounted on the first guide rail 27, a cutting slide plate 29 fixedly mounted on the first sliding block 28, a cutting cylinder 30 fixedly mounted on the cutting platform 26 and connected with the bottom of the cutting slide plate 29 by a telescopic rod to drive the cutting slide plate 29 to move, a cutting motor 31 fixedly mounted on the cutting slide plate 29, a cutting blade 32 sleeved on a rotating shaft of the cutting motor 31, a sliding groove 33 fixedly mounted on the cutting slide plate 29 and positioned below the cutting blade 32, a second sensor 34 fixedly mounted on the cutting slide plate 29, and a second sensor 35 fixedly mounted on the cutting platform 26.

In one embodiment, the reaming mechanism 5 comprises a second guide rail 36 fixedly installed on the frame 1, a second sliding block 37 slidably installed on the second guide rail 36, a second sliding plate 38 fixedly installed on the second sliding block 37, a second oil cylinder 39 fixedly installed on the frame 1 and fixedly connected with one side of the second sliding plate 38 through a telescopic rod so as to drive the second sliding plate 38 to move, a rack 40 fixedly installed on one side of the second sliding plate 38, a pore encoder 41 fixedly installed on the frame 1 through a bracket, a gear 42 sleeved on the pore encoder 41 and meshed with the rack 40, a double-shaft drilling machine power head 43 fixedly installed on the second sliding plate 38, an adjusting plate 44 fixedly installed on the second sliding plate 38 through an adjusting screw, a second motor 45 fixedly installed on the pore adjusting plate 44, a driving pulley 46 sleeved on a rotating shaft of the second motor 45, a driven pulley 47 sleeved on the driven pulley, the driven pulley 47 sleeved on the driven pulley 43 and connected with one end of the driving pulley 43 through a double-shaft belt, and the driven pulley 46 is fixedly sleeved on the driven pulley 43 and the other end of the driven pulley 43 is rotatably connected with the driven pulley 43 through the driving pulley.

In one embodiment, as shown in fig. 7 to 9, the pore opening mechanism 6 is identical in structure to the reaming mechanism 5.

In one embodiment, as shown in fig. 10, the aluminum cylinder placement tool 21 includes a fixture base 49 fixedly mounted on the tool square box 20, a base bottom plate 50 fixedly mounted on the fixture base 49, a tool assembly 51 adjustably mounted on the base bottom plate 50, and a positioning base 52 fixedly mounted on one side of the base bottom plate 50.

In one embodiment, as shown in fig. 10, the pressing cylinder assembly 22 includes a cylinder base 53 fixedly installed on the tool square box 20, a support base 54 fixedly installed on one side of the cylinder base 53, a clamping arm 55 rotatably installed in the middle of the support base 54, a pressing cylinder 56 installed in the tool square box 20 through a TC frame and having one end of a telescopic rod and the clamping arm 55, and a pressing block 57 fixedly installed on the other end of the clamping arm 55.

The working principle of the shock absorber aluminum tube machining equipment comprises the steps of firstly adjusting the position of an adjusting nut according to the type of an aluminum tube to be machined by an aluminum tube placing tool 21 of a rotary table mechanism 3, placing the aluminum tube to be machined on the aluminum tube placing tool 21, pressing a tightening button, pressing the aluminum tube to be machined by a pressing oil cylinder assembly 22, pressing a starting button, rotating the rotary table mechanism 3, enabling the aluminum tube to a cutting station, enabling the cutting machine to act, enabling the cutting machine to reach a working position through a linear guide rail by the oil cylinder, cutting the aluminum tube, enabling the cutting machine to return after cutting, enabling the cut stub bar to slide into a waste box through a stub bar chute 33, enabling the cut aluminum scraps to directly fall into an aluminum scraps box below, enabling the rotary table mechanism 3 to rotate the aluminum tube to a reaming station, enabling a three-phase asynchronous motor to drive a double-shaft drilling machine 43 through the pulley mechanism, enabling the oil cylinder to act through the oil cylinder to finish reaming depth through an encoder and a gear 42, enabling the rotary table mechanism 3 to rotate the aluminum tube to a pore, enabling the rotary table mechanism to rotate the double-shaft drilling machine 48, enabling the rotary table to act through the gear 40, enabling the rotary table mechanism to complete reaming to complete the reaming, enabling the reaming to act through the gear 40 to complete the reaming, enabling the reaming machine to complete after the reaming, and the reaming is completed according to the four steps when the four times when the working depth is completed, and the four times that the working is completely and the full.

Specifically, the workflow of the present utility model is divided into the following:

And (3) charging flow:

Firstly, placing an aluminum cylinder of a shock absorber on an aluminum cylinder placing tool 21 of a turntable mechanism 3 and fixing the aluminum cylinder by a compression oil cylinder assembly 22, firstly, placing the aluminum cylinder of the shock absorber on a workpiece assembly, positioning a positioning seat 52 at the same time, further, working a compression oil cylinder 56, and driving a clamping arm 55 to rotate on a supporting seat 54 so that a pressing block 57 presses the aluminum cylinder of the shock absorber to realize fixation;

The rotation flow is as follows:

The driving mechanism 2 works, the first motor 12 rotates to drive the driving shaft 13 to rotate through the speed reducer 11, so that the driving shaft 13 drives the tooling square box 20 in the turntable mechanism 3 to rotate through the flange, the tooling square box 20 drives the shock absorber aluminum cylinder on the aluminum cylinder placing tooling 21 to rotate, when a working station is reached, the first motor 12 stops working, the thin cylinder 15 works, and the positioning pin shaft 16 is driven to be inserted into the positioning hole of the positioning disc 14, so that the positioning of the tooling square box 20 is realized;

Cutting flow:

When the cutting station is reached, the cutting cylinder 30 works, drives the cutting slide plate 29 to move through the first guide rail 27 and the first slide block 28, and then stops when moving to a designated position, and further the cutting motor 31 works, drives the cutting blade 32 to cut the shock absorber aluminum cylinder, and the crushed aggregates flow away through the slide groove 33;

Pore expanding flow:

When the reaming mechanism 5 and the pore mechanism 6 are reached, the second oil cylinder 39 works first, the second sliding plate 38 is driven to move through the second guide rail 36 and the second sliding block 37, so that the double-shaft drilling machine power head 43 and the second motor 45 are driven to move, meanwhile, the pore encoder 41 works to calculate the depth of the reamed pore along with the meshing of the gear 42 and the rack 40 of the second sliding block 37, so that the second motor 45 rotates, the driving pulley 46 rotates, the driven pulley 47 rotates through a belt, the double-shaft drilling machine power head 43 rotates, the double-shaft drilling machine power head 43 drives the drill bit 48 to rotate, and the pore of the shock absorber aluminum cylinder is reamed.

And after the process is finished, the processed aluminum cylinder is taken out manually, then the aluminum cylinder to be processed is put into the aluminum cylinder, and the movement process is repeated.

It is apparent that the above examples are given by way of illustration only and are not limiting of the embodiments. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. While still being apparent from variations or modifications that may be made by those skilled in the art are within the scope of the utility model.

Claims (8)

1. The processing equipment of the shock absorber aluminum cylinder is characterized by comprising a frame, a driving mechanism, a turntable mechanism, a cutting mechanism, a reaming mechanism, a pore opening mechanism, a hydraulic station and a housing;

The hydraulic device comprises a frame, a rotary table mechanism, a cutting mechanism, a reaming mechanism, a pore mechanism, a hydraulic station, a rotary table mechanism, a cutting mechanism, a reaming mechanism, a hydraulic station and a shell, wherein the driving mechanism is arranged on the frame, the rotary table mechanism is arranged on the driving mechanism to rotate along with the driving mechanism, the cutting mechanism, the reaming mechanism and the pore mechanism are all arranged on the frame and are in butt joint with the rotary table mechanism to cut, ream and pore the shock absorber aluminum cylinder, the hydraulic station is fixedly arranged in the shell and is respectively connected with the rotary table mechanism, the cutting mechanism, the reaming mechanism and the pore mechanism to supply power for the rotary table mechanism, the reaming mechanism and the pore mechanism, and the shell is fixedly arranged on the frame and forms an installation cavity with the frame.

2. The processing equipment for the shock absorber aluminum cylinder according to claim 1, wherein the driving mechanism comprises a main shaft wallboard fixedly arranged on one side of the frame, a support seat fixedly arranged on one side of the main shaft wallboard, a speed reducer fixedly arranged on the support seat, a first motor arranged on the speed reducer, a driving shaft arranged on the main shaft wallboard through a bearing seat, one end of the driving shaft is connected with the other end of the speed reducer through a flange to rotate along with the speed reducer, a positioning disc sleeved on the driving shaft, a thin cylinder fixedly arranged on two ends of the support seat, positioning pins fixedly arranged on the thin cylinder and matched with upper positioning holes of the positioning disc, a first sensor fixedly arranged on the thin cylinder, a first sensing piece fixedly arranged on the positioning disc, and a rotary joint fixedly arranged on the other end of the driving shaft.

3. The processing equipment for the aluminum cylinder of the shock absorber is characterized in that the turntable mechanism comprises a tool square box, an aluminum cylinder placing tool, a pressing oil cylinder assembly, a fixed shaft, a main shaft center column and a main shaft center column, wherein one end of the tool square box is connected with the driving shaft through a flange to follow the driving shaft, the four sets of aluminum cylinder placing tools are fixedly installed at four corners of the tool square box in a circumferential rotation array mode, the four sets of pressing oil cylinder assembly are fixedly installed on the tool square box corresponding to the aluminum cylinder placing tools, one end of the fixed shaft is fixedly installed on the other side of the tool square box through a ball bearing seat, the main shaft center column is fixedly installed on the frame, and the fixed shaft is fixedly connected with the main shaft center column.

4. The device for machining the shock absorber aluminum cylinder according to claim 3, wherein the cutting mechanism comprises a column wallboard fixedly arranged on the frame, a cutting platform fixedly arranged on the column wallboard and the main shaft center post, a first guide rail fixedly arranged on the cutting platform, a first sliding block slidably arranged on the first guide rail, a cutting sliding plate fixedly arranged on the first sliding block, a cutting oil cylinder fixedly arranged on the cutting platform, a telescopic rod connected with the bottom of the cutting sliding plate for driving the cutting sliding plate to move, a cutting motor fixedly arranged on the cutting sliding plate, a cutting blade sleeved on a rotating shaft of the cutting motor, a sliding groove fixedly arranged on the cutting sliding plate and positioned below the cutting blade, a second sensor fixedly arranged on the cutting sliding plate, and a second sensing piece fixedly arranged on the cutting platform.

5. The device for machining the aluminum cylinder of the shock absorber according to claim 1, wherein the reaming mechanism comprises a second guide rail fixedly arranged on the frame, a second sliding block slidably arranged on the second guide rail, a second sliding plate fixedly arranged on the second sliding block, a second oil cylinder fixedly arranged on the frame, a telescopic rod fixedly connected with one side of the second sliding plate so as to drive the second sliding plate to move, a rack fixedly arranged on one side of the second sliding plate, a pore encoder fixedly arranged on the frame through a bracket, a gear sleeved on the encoder and meshed with the rack, a double-shaft drilling machine power head fixedly arranged on the second sliding plate, a pore adjusting plate fixedly arranged on the second sliding plate through an adjusting screw and positioned on the double-shaft drilling machine power head, a second motor fixedly arranged on the pore adjusting plate, a belt pulley sleeved on a rotating shaft of the second sliding plate, a driven belt sleeved on one end of the double-shaft drilling machine power head, a driving belt pulley sleeved on the driven belt pulley and connected with the driving belt pulley through the driven belt pulley to the rotating shaft drilling machine power head.

6. The apparatus for machining an aluminum cylinder of a shock absorber according to claim 5, wherein said pore-forming means is identical in structure to said reaming means.

7. The processing equipment for the aluminum cylinder of the shock absorber according to claim 3, wherein the aluminum cylinder placing tool comprises a clamp seat fixedly arranged on the tool square box, a base bottom plate fixedly arranged on the clamp seat, a tool assembly body adjustably arranged on the base bottom plate, and a positioning seat fixedly arranged on one side of the base bottom plate.

8. The device for machining the aluminum cylinder of the shock absorber according to claim 7, wherein the compression oil cylinder assembly comprises a cylinder seat fixedly installed on the tool square box, a supporting seat fixedly installed on one side of the cylinder seat, a clamping arm rotatably installed on the supporting seat in the middle, a compression oil cylinder installed in the tool square box through a TC frame and on one end of a telescopic rod and one end of the clamping arm, and a pressing block fixedly installed on the other end of the clamping arm.