CN114800680A

CN114800680A - Automatic pipe fitting machining equipment

Info

Publication number: CN114800680A
Application number: CN202210402953.5A
Authority: CN
Inventors: 王斌; 吴海军; 汪敏捷; 张福曦
Original assignee: Shanghai Ocean University
Current assignee: Shanghai Ocean University
Priority date: 2022-04-18
Filing date: 2022-04-18
Publication date: 2022-07-29
Anticipated expiration: 2042-04-18
Also published as: CN114800680B

Abstract

The invention provides automatic pipe fitting machining equipment which comprises a workbench, a blanking mechanism, a rotary platform, a safety partition plate, a conductive sliding ring, a mold core transmission mechanism, a positioning mechanism, a punching mechanism and a propelling mechanism, wherein the workbench is arranged on the workbench; the rotating platform is in transmission connection with the conductive sliding ring and is rotatably fixed above the working head through the conductive sliding ring; the safety partition plate is erected on the workbench and divides the space above the rotary platform into a first station, a second station, a third station and a fourth station sequentially and uniformly along the circumferential direction; the mold core transmission mechanisms are uniformly distributed and connected to the rotating platform along the circumferential direction; the positioning mechanism and the three stamping mechanisms are arranged at the second station; the other positioning mechanism and the three propelling mechanisms are arranged at a third station; the blanking mechanism is arranged at the fourth station. According to the automatic pipe fitting processing equipment, the wheel disc type processing structure is adopted, the pipe fitting placing, the pipe fitting positioning, the punching and the pattern knitting are carried out on the same equipment, and the automatic pipe fitting processing equipment is convenient, fast, efficient and automatic.

Description

Automatic pipe fitting machining equipment

Technical Field

The invention relates to the field of plastic pipe fitting processing, in particular to automatic pipe fitting processing equipment.

Background

In the process of processing the plastic pipe fitting, six inward clamping jaws are formed by stamping the outer part of a single-section pipe fitting, and the clamping jaws are pressed in sequence to form two flower-shaped inner decorations. The existing processing mode is manual processing, punching is carried out on an open type punching press machine by manpower, then pattern weaving operation is carried out by manual internal pressure, the mode is low in efficiency, large in manpower and material resource consumption, long in production period and incapable of meeting the efficiency requirement of order accumulation conditions. At present, the manual punching operation is carried out, an operator is required to manually fix the pipe fitting and rotate, the process has certain potential safety hazards, and certain guarantee is lacked for the safety of the operator. At present, the process of forming the pattern interior decoration by internal pressure needs to be outsourced to other personnel for operation, so that the production period is prolonged to a certain extent, and the requirements of enterprises are not met.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides the automatic pipe fitting processing equipment which adopts a wheel disc type processing structure, and the pipe fitting placing, the pipe fitting positioning, the punching and the flower arrangement are carried out on the same equipment, so that the automatic pipe fitting processing equipment is convenient, fast, efficient and automatic.

In order to achieve the aim, the invention provides automatic pipe machining equipment which comprises a workbench, a blanking mechanism, a rotating platform, a safety partition plate, a conductive sliding ring, a four-mold-core transmission mechanism, two positioning mechanisms, three stamping mechanisms and four pushing mechanisms, wherein the workbench is provided with a feeding mechanism; the rotating platform is in transmission connection with the conductive sliding ring and is rotatably fixed above the working head through the conductive sliding ring; the safety partition plate is erected on the workbench and divides the space above the rotary platform into a first station, a second station, a third station and a fourth station uniformly along the circumferential direction, and the safety partition plate forms four pipe fitting channels; the mold core transmission mechanisms are uniformly distributed and connected to the rotating platform along the circumferential direction; the positioning mechanism and the three stamping mechanisms are arranged at the second station; the other positioning mechanism and the three pushing mechanisms are arranged at the third station; the blanking mechanism is arranged at the fourth station.

Preferably, the blanking mechanism comprises a blanking groove, a plurality of material rack supporting rods, a material blocking supporting rod and a material blocking rod; the blanking groove is fixed on the workbench through the material rack supporting rod and is arranged beside the rotating platform; the material blocking rod is fixed on the workbench through the material blocking support rod and is arranged beside the blanking groove and close to one side of the first station; the material blocking rod is arc-shaped and extends to the upper part of the rotating platform.

Preferably, the rotating platform is uniformly distributed along the circumferential direction to form four mold core through holes; each mold core transmission mechanism comprises: the device comprises a mold core, an electric cylinder connecting plate, an electric cylinder mounting plate and a plurality of rubber gaskets; the bottom of the mold core is fixedly connected with the top of the electric cylinder connecting plate; the top of the telescopic rod of the electric cylinder is fixedly connected with the bottom of the electric cylinder connecting plate; the side surface of the electric cylinder mounting plate is connected with the electric cylinder; the top of the electric cylinder mounting plate is connected with the bottom of the rotating platform; the section of the mold core is in a shape of a rounded triangle, and two horizontal long grooves are formed on three side surfaces of the mold core respectively; the rubber gaskets are respectively fixed in the horizontal long grooves; the mold core receives the transmission of the electric cylinder and can extend out of the corresponding mold core through hole to the upper part of the rotating platform.

Preferably, each positioning mechanism comprises a clamping jaw movable frame, an air cylinder and an air cylinder fixing frame; the clamping jaw movable frame is fixed on the workbench; the cylinder is fixed on the clamping jaw movable frame through the cylinder fixing frame; and the pressure lever of the cylinder is vertically positioned right above the through hole of the mold core.

Preferably, each stamping mechanism comprises a cutter, a cutter head guide block, a cutter head pushing block and a hydraulic cylinder; the hydraulic cylinder is in transmission connection with the cutter through the cutter head propelling block; the cutter is arranged in the cutter head guide block in a penetrating way; the tool bit guide block and the hydraulic cylinder are fixed on the corresponding clamping jaw movable frame; thirdly, the punching mechanism is uniformly distributed along the circumferential direction and surrounds the periphery of the mold core through hole which is located at the second station at present, and the cutter of the punching mechanism faces the mold core through hole.

Preferably, the cutting head is arc-shaped.

Preferably, each propelling mechanism comprises a propelling head, a propelling head guide block, a propelling block, a cylinder head and a cylinder block; the cylinder block drives the cylinder head; the cylinder head is in transmission connection with the propelling head through the propelling block; the propelling head penetrates through the propelling head guide block; the pushing head guide block and the cylinder block are fixed on a corresponding clamping jaw movable frame; thirdly, the propelling mechanisms are uniformly distributed along the circumferential direction and surround one of the third station, the mold core through hole is arranged at the periphery, and the propelling heads of the propelling mechanisms face the mold core through hole.

Due to the adoption of the technical scheme, the invention has the following beneficial effects:

1. through adopting wheel disk processing equipment, divide four stations with each process and process on same equipment, reached that production efficiency improves and the effect of machine full automated production, solved manual operation and made production cycle lengthen, can not satisfy the problem of enterprise's production demand and the produced potential safety hazard of manual operation.

2. Through setting the mold core into the rounded triangle shape to be provided with six recesses, the inside fixed connection rubber gasket of recess, the mold core is removable and adopt electric jar control mold core stroke, has reached non-deformable and the pipe fitting is easily taken out after to the pipe fitting punching press, and equipment can be used to the effect of modular production, has solved and has leaded to the pipe fitting to take out the difficulty because of the mold core shape, and the punching press leads to the pipe fitting to warp, and the mold core can not be changed and can only produce the problem of the product size that the mold core corresponds.

3. Through adopting the pneumatic cylinder control tool bit to carry out the punching press simultaneously to set up the tool bit into the arc, reached six jack catchs of one shot forming, the jack catch edge is changeed and is peeled off pipe fitting and jack catch comparatively smooth all around, and effect that the size is similar basically has solved manual work and has leaded to process time long, and the jack catch leads to the shape of jack catch because of the atress is inhomogeneous, the size, the length difference leads to the problem that follow-up work is difficult to develop.

4. Six propulsion heads are respectively controlled by the three cylinders to press the clamping jaws in an inward differential sequence, so that the three clamping jaws in the same area are mutually fastened, the effect of automatic pattern weaving and forming of equipment is achieved, and the problem that the processing period is prolonged due to the fact that enterprises need to wrap patterns for weaving operation is solved.

Drawings

Fig. 1 is a schematic structural diagram of an automated pipe processing apparatus according to an embodiment of the present invention;

fig. 2 is a schematic view of an internal structure of the automatic pipe processing apparatus according to the embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a mold core transmission mechanism according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a punching mechanism according to an embodiment of the present invention;

fig. 5 and 6 are schematic views of the processing state of the three-punching mechanism according to the embodiment of the invention;

FIG. 7 is a schematic structural diagram of a propulsion mechanism according to an embodiment of the present invention;

FIGS. 8 and 9 are schematic views of the three-stage propulsion mechanism according to the embodiment of the present invention in a processing state;

FIG. 10 is a schematic structural diagram of a positioning mechanism according to an embodiment of the present invention;

FIG. 11 is a schematic structural view of a plastic pipe after the second station completes the processing according to the embodiment of the invention;

fig. 12 is a schematic structural diagram of the plastic pipe processed by the third station according to the embodiment of the present invention.

Detailed Description

The following description of the preferred embodiments of the present invention will be provided in conjunction with the accompanying drawings of fig. 1 to 12, and will make the functions and features of the present invention better understood.

Referring to fig. 1 to 12, an automatic pipe processing apparatus according to an embodiment of the present invention includes a worktable 1, a blanking mechanism, a rotary platform 6, a safety partition 7, a conductive slip ring 8, a four-mold-core transmission mechanism 12, two positioning mechanisms, three stamping mechanisms 13, and four pushing mechanisms 14; the rotating platform 6 is in transmission connection with the conductive sliding ring 8 and can be rotatably fixed above the working head through the conductive sliding ring 8; the safety partition plate 7 is erected on the workbench 1 and divides the space above the rotary platform 6 into a first station, a second station, a third station and a fourth station uniformly along the circumferential direction, and the safety partition plate 7 forms four pipe fitting channels; the mold core transmission mechanisms 12 are uniformly distributed and connected to the rotating platform 6 along the circumferential direction; the positioning mechanism and the three stamping mechanisms 13 are arranged at the second station; another positioning mechanism and a third pushing mechanism 14 are arranged at the third station; the blanking mechanism is arranged at the fourth station.

The blanking mechanism comprises a blanking groove 2, a plurality of blanking support rods 4, a material blocking support rod 3 and a material blocking rod 5; the blanking groove 2 is fixed on the workbench 1 through a material rack support rod 4 and is arranged beside the rotary platform 6; the material blocking rod 5 is fixed on the workbench 1 through the material blocking support rod 3 and is arranged beside the blanking groove 2 and close to one side of the first station; the material blocking rod 5 is arc-shaped and extends to the position above the rotating platform 6.

The rotary platforms 6 are uniformly distributed along the circumferential direction to form four mold core through holes; each of the core transmission mechanisms 12 includes: a mold core 1201, an electric cylinder 1202, an electric cylinder connecting plate 1203, an electric cylinder mounting plate 1204 and a plurality of rubber gaskets 1205; the bottom of the mold core 1201 is fixedly connected with the top of the electric cylinder connecting plate 1203; the top of the telescopic rod of the electric cylinder 1202 is fixedly connected with the bottom of the electric cylinder connecting plate 1203; the side surface of the electric cylinder mounting plate 1204 is connected with the electric cylinder 1202; the top of the electric cylinder mounting plate 1204 is connected with the bottom of the rotating platform 6; the section of the mold core 1201 is in a shape of a rounded triangle, and two horizontal long grooves are formed on three side surfaces of the mold core 1201 respectively; the rubber gaskets 1205 are respectively fixed in the horizontal long grooves; the mold core 1201 can extend out of the corresponding mold core through hole to the upper part of the rotary platform 6 by receiving the transmission of the electric cylinder 1202.

The mold core 1201 is in a rounded triangle shape (the deformation of a plastic pipe fitting during processing is better prevented), the rising position of the mold core 1201 can be controlled when the electric cylinder 1202 works, the position of the mold core 1201 meets the requirements of each station, six rubber gaskets 1205 are fixedly connected with six horizontal long grooves on three side surfaces of the mold core 1201, clamping jaws are easy to pop out after processing, and the loss of the mold core 1201 is reduced.

Each positioning mechanism comprises a clamping jaw movable frame 9, an air cylinder 10 and an air cylinder fixing frame 11; the clamping jaw movable frame 9 is fixed on the workbench 1; the cylinder 10 is fixed on the clamping jaw movable frame 9 through a cylinder fixing frame 11; and the pressure rod 1001 of the cylinder 10 is vertically positioned right above the mold core through hole.

When a workpiece to be machined moves below the apparatus, the air cylinder 10 causes the pressing rod 1001 to push down and press the plastic pipe, and then the machining at the second station or the third station is performed.

Each punching mechanism 13 comprises a cutter 1301, a cutter head guide block 1302, a cutter head propelling block 1303 and a hydraulic cylinder 1304; the hydraulic cylinder 1304 is in transmission connection with the cutter 1301 through a cutter head propelling block 1303; the cutter 1301 is arranged in the cutter head guide block 1302 in a penetrating mode; the cutter head guide block 1302 and the hydraulic cylinder 1304 are fixed on a corresponding clamping jaw movable frame 9; the three punching mechanisms 13 are uniformly distributed along the circumferential direction and surround the periphery of a mold core through hole which is located at the second station at present, and the cutter 1301 of the punching mechanism 13 is arranged towards the mold core through hole. The tool bit is arc-shaped.

During punching, the cutter 1301 punches the plastic pipe to be processed under the action of the hydraulic cylinder 1304. When the plastic pipe to be processed moves to the second station, the tools 1301 of the three punching mechanisms 13 punch the pipe to be processed simultaneously from three directions under the action of the hydraulic cylinders 1304, so that six jaws are formed.

Each propulsion mechanism 14 comprises a propulsion head 1401, a propulsion head guide block 1402, a propulsion block 1403, a cylinder head 1404 and a cylinder block 1405; cylinder block 1405 drives cylinder head 1404; the cylinder head 1404 is in transmission connection with the propulsion head 1401 through the propulsion block 1403; the propelling head 1401 is arranged in the propelling head guide block 1402 in a penetrating way; the pushing head guide block 1402 and the air cylinder block 1405 are fixed on a corresponding clamping jaw movable frame 9; the three propelling mechanisms 14 are uniformly distributed along the circumferential direction and surround the periphery of a mold core through hole which is currently positioned at the third station, and the propelling heads 1401 of the propelling mechanisms 14 are arranged towards the mold core through hole.

The pushing head 1401 is used for pressing the plastic pipe processed at the second station in a differential mode under the action of the air cylinder block 1405, so that six clamping jaws complete the braiding work, and finally the required plastic pipe is formed.

When the plastic pipe processed at the second station moves to the third station, the pushing head 1401 pushes the jaws under the pushing of the cylinder by the pushing mechanism 14 at the first position, then the pushing mechanism 14 at the second position drives the corresponding pushing head 1401 to push the corresponding jaws inwards, then the pushing mechanism 14 at the third position pushes the corresponding jaws inwards in the same way, and after the braiding, the three pushing mechanisms 14 return simultaneously.

The pipe fitting automatic processing equipment provided by the embodiment of the invention has the following working principle:

the mold core transmission mechanism 12 of the first station moves the mold core to the highest position under the action of the electric cylinder 1202, the plastic pipe to be processed is sleeved outside the mold core 1201, the plastic pipe to be processed is moved to the second station under the action of the rotary platform 6, the cylinder 10 of the second station pushes down the pressure lever 1001 to press the plastic pipe to be processed, then six cutters 1301 press the plastic pipe to be processed simultaneously under the action of three hydraulic cylinders 1304, the mold core 1201 rotates anticlockwise for a certain angle after the pressing is completed, so that six jaws on the pressed plastic pipe peel off the mold core 1201, the mold core 1201 moves downwards to just fix the plastic pipe axially, the pressure lever 1001 rises at the moment, the pressed plastic pipe moves to the third station under the drive of the rotary platform 6, the cylinder 10 of the third station pushes down the pressure lever 1001 to fix the pressed plastic pipe, the six pushing heads 1401 press the corresponding jaws differentially under the action of the three cylinder blocks 1405 respectively, the embossing process is completed, after the embossing process is completed, the pressure rod 1001 and the mold core 1201 are withdrawn simultaneously, the plastic pipe fitting after the embossing process is transferred to the fourth station under the movement of the rotary platform 6, and in the rotating process, the plastic pipe fitting after the embossing process slides into the blanking groove 2 under the action of the material blocking rod 5.

The plastic pipe processed in the second station is shown in fig. 11, and the plastic pipe processed in the third station is shown in fig. 12.

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

1. The utility model provides a pipe fitting automated processing equipment which characterized in that: the automatic blanking device comprises a workbench, a blanking mechanism, a rotary platform, a safety partition plate, a conductive slip ring, a four-mold-core transmission mechanism, two positioning mechanisms, three stamping mechanisms and four propelling mechanisms; the rotating platform is in transmission connection with the conductive sliding ring and is rotatably fixed above the working head through the conductive sliding ring; the safety partition plate is erected on the workbench and divides the space above the rotary platform into a first station, a second station, a third station and a fourth station uniformly along the circumferential direction, and the safety partition plate forms four pipe fitting channels; the mold core transmission mechanisms are uniformly distributed and connected to the rotating platform along the circumferential direction; the positioning mechanism and the three stamping mechanisms are arranged at the second station; the other positioning mechanism and the three pushing mechanisms are arranged at the third station; the blanking mechanism is arranged at the fourth station.

2. The automatic pipe machining equipment according to claim 1, wherein the blanking mechanism comprises a blanking groove, a plurality of material rack support rods, a material blocking support rod and a material blocking rod; the blanking groove is fixed on the workbench through the material rack supporting rod and is arranged beside the rotating platform; the material blocking rod is fixed on the workbench through the material blocking support rod and is arranged beside the blanking groove and close to one side of the first station; the material blocking rod is arc-shaped and extends to the upper part of the rotating platform.

3. The automated pipe machining apparatus of claim 2, wherein the rotary platform is circumferentially and evenly distributed to form four core through holes; each mold core transmission mechanism comprises: the device comprises a mold core, an electric cylinder connecting plate, an electric cylinder mounting plate and a plurality of rubber gaskets; the bottom of the mold core is fixedly connected with the top of the electric cylinder connecting plate; the top of the telescopic rod of the electric cylinder is fixedly connected with the bottom of the electric cylinder connecting plate; the side surface of the electric cylinder mounting plate is connected with the electric cylinder; the top of the electric cylinder mounting plate is connected with the bottom of the rotating platform; the section of the mold core is in a shape of a rounded triangle, and two horizontal long grooves are formed on three side surfaces of the mold core respectively; the rubber gaskets are respectively fixed in the horizontal long grooves; the mold core receives the transmission of the electric cylinder and can extend out of the corresponding mold core through hole to the upper part of the rotating platform.

4. The automated pipe machining apparatus of claim 3, wherein each of the positioning mechanisms comprises a movable jaw frame, a cylinder, and a cylinder holder; the clamping jaw movable frame is fixed on the workbench; the cylinder is fixed on the clamping jaw movable frame through the cylinder fixing frame; and the pressure lever of the cylinder is vertically positioned right above the through hole of the mold core.

5. The automated pipe machining apparatus of claim 4, wherein each of the stamping mechanisms includes a tool, a tool tip guide block, a tool tip pusher block, and a hydraulic cylinder; the hydraulic cylinder is in transmission connection with the cutter through the cutter head propelling block; the cutter is arranged in the cutter head guide block in a penetrating way; the tool bit guide block and the hydraulic cylinder are fixed on the corresponding clamping jaw movable frame; thirdly, the punching mechanism is uniformly distributed along the circumferential direction and surrounds the periphery of the mold core through hole which is located at the second station at present, and the cutter of the punching mechanism faces the mold core through hole.

6. The automated pipe machining apparatus of claim 5, wherein the tool bit is arcuate.

7. An automated pipe machining apparatus according to claim 6 wherein each said propulsion mechanism includes a propulsion head, a propulsion head guide block, a propulsion block, a cylinder head and a cylinder block; the cylinder block drives the cylinder head; the cylinder head is in transmission connection with the propelling head through the propelling block; the propelling head penetrates through the propelling head guide block; the pushing head guide block and the cylinder block are fixed on a corresponding clamping jaw movable frame; thirdly, the propelling mechanisms are uniformly distributed along the circumferential direction and surround one of the third station, the mold core through hole is arranged at the periphery, and the propelling heads of the propelling mechanisms face the mold core through hole.