CN216989690U - Heat pipe processing machine - Google Patents

Abstract

The utility model discloses a heat pipe processing machine, which comprises: the device comprises a machine table, a workbench, a copper pipe conveying mechanism, a plurality of groups of conveying mechanisms and a material pushing mechanism; the workbench is arranged on the machine table; the copper pipe conveying mechanism comprises a fixed table arranged on the machine table, the fixed table is in butt joint with the workbench, and the copper pipe conveying mechanism can convey copper pipes to the fixed table and fix the copper pipes; the plurality of groups of conveying mechanisms are all arranged on the machine table, and at least two groups of conveying mechanisms can respectively drive different materials to the workbench; the pushing mechanism is arranged on the machine table and can drive the material on the workbench to move and stretch into the copper pipe on the fixed table. The full-mechanical automatic processing can greatly increase the processing efficiency, and the multiple groups of conveying mechanisms can stably feed different materials, so that the problems of wrong loading and neglected loading can be effectively avoided.

Description

Heat pipe processing machine

Technical Field

The utility model relates to the field of heat pipes, in particular to a heat pipe processing machine.

Background

A heat pipe is a hollow pipe with liquid inside. When the temperature difference is generated at the two ends of the heat pipe, the liquid at one end of the heat pipe is quickly gasified and condensed at the other end, thereby realizing the effect of quickly reducing the temperature and dissipating the heat. To increase the velocity of the liquid flowing inside the heat pipe, a medium, such as a common wire or a metal mesh, is usually added inside the heat pipe. At present, in the process of manufacturing a heat pipe, materials such as a metal wire or a metal mesh are usually installed into a copper pipe with a small volume by hand. However, the manual processing has the disadvantages of low efficiency and high cost, and the problem of wrong assembly and missing assembly easily occurs in the manual operation in the process of installing various different materials into the copper pipe.

SUMMERY OF THE UTILITY MODEL

The present invention is directed to solving at least one of the problems of the prior art. Therefore, the utility model provides a heat pipe processing machine which can fully automatically insert materials into a copper pipe.

A heat pipe processing machine according to an embodiment of a first aspect of the present invention comprises: the device comprises a machine table, a workbench, a copper pipe conveying mechanism, a plurality of groups of conveying mechanisms and a material pushing mechanism; the workbench is arranged on the machine table; the copper pipe conveying mechanism comprises a fixed table arranged on the machine table, the fixed table is in butt joint with the workbench, and the copper pipe conveying mechanism can convey copper pipes to the fixed table and fix the copper pipes; the plurality of groups of conveying mechanisms are all arranged on the machine table, and at least two groups of conveying mechanisms can respectively drive different materials to the workbench; and the material pushing mechanism is arranged on the machine table and can drive the material on the workbench to move and stretch into the copper pipe on the fixed table.

The heat pipe processing machine according to the embodiment of the utility model at least has the following beneficial effects: the copper pipe conveying mechanism conveys the copper pipe to the fixed station and relatively fixes the copper pipe and the fixed station. Meanwhile, the conveying mechanism can drive different materials to the workbench respectively. And then, the pushing mechanism is started, all the materials on the workbench are pushed to move, and all the materials on the workbench are finally pushed into the materials fixed on the fixed table, so that the processing operation of the heat pipe is completed.

Through the combined action of the copper pipe conveying mechanism and the multiple groups of conveying mechanisms, the copper pipe and different materials can be automatically conveyed to a processing station, and the material pushing mechanism is used for pushing materials. The full-mechanical automatic processing can greatly increase the processing efficiency, and the multiple groups of conveying mechanisms can stably feed different materials, so that the problems of wrong loading and neglected loading can be effectively avoided.

According to some embodiments of the utility model, the copper pipe conveying mechanism further comprises a feeding material box, a feeding component and a discharging material box, wherein the feeding component can drive the copper pipe to move from the feeding material box to the fixed platform, and the feeding component can drive the copper pipe to move from the fixed platform to the discharging material box. The feeding material box can be used for storing copper pipes to be processed, and the discharging material box can receive the processed copper pipes.

According to some embodiments of the utility model, the feed assembly comprises: the device comprises a material ejecting part, a conveying cylinder, a connecting seat and a conveying seat; the ejection part is arranged in the feeding box, the machine table is provided with an ejection cylinder, and the ejection cylinder is connected with the ejection part and can drive the ejection cylinder to eject the copper pipe in the feeding box; the conveying cylinder is connected with the connecting seat and can drive the connecting seat to reciprocate between the feeding material box and the discharging material box, and a first lifting cylinder is arranged on the connecting seat and connected with the conveying seat.

According to some embodiments of the utility model, the transport mechanism comprises: the device comprises a driving wheel set, a material shearing assembly and a material conveying assembly; the driving wheel set can drive the material to move; the material shearing assembly is arranged on the machine table and positioned between the driving wheel set and the workbench, and can shear materials; the material transporting assembly is arranged on the machine table and can drive the material to move close to the end part of the workbench close to the fixed table.

According to some embodiments of the utility model, the conveying mechanism further comprises a shaping wheel set, the shaping wheel set is located between the material shearing assembly and the driving wheel set and can shape the material.

According to some embodiments of the utility model, the drive wheel set interfaces with the work bench through the trim assembly; the material conveying assembly comprises a third driving device arranged on the machine table, and the third driving device is connected with a sliding seat and can drive the sliding seat to move along the working table; the sliding seat is connected with a second lifting cylinder, and the second lifting cylinder is connected with a material pressing plate capable of pressing materials and driving the materials to move along the workbench.

According to some embodiments of the utility model, the material shearing assembly comprises a material shearing cylinder, and the material shearing cylinder is connected with a material shearing knife and can drive the material shearing knife to move close to or far away from the material.

According to some embodiments of the utility model, the transport mechanism comprises a transfer table, the drive wheel set is docked with the transfer table through the trim assembly; the material conveying assembly comprises a support frame configured on the transfer platform, a material conveying seat capable of reciprocating between the transfer platform and the workbench is movably connected to the support frame, and the material conveying seat is connected with a first driving device; the material conveying seat is provided with a third lifting cylinder, the third lifting cylinder is connected with a material clamping seat, and a cylinder clamping jaw is arranged on the material clamping seat.

According to some embodiments of the utility model, the table is provided with a chute, and the chute is butted with the fixed table; the material pushing mechanism comprises a supporting table arranged on the machine table, a material pushing seat capable of reciprocating along the length direction of the sliding groove is arranged on the supporting table, and the material pushing seat is connected with a second driving device; the material pushing device is characterized in that a material pushing cylinder is arranged on the material pushing seat and connected with a material pushing rod, and the material pushing rod can stretch into the sliding groove and push the material in the sliding groove to move and stretch into the copper pipe.

According to some embodiments of the utility model, a guide sleeve is arranged between the workbench and the fixed platform, a turnover cylinder is arranged on the workbench, the turnover cylinder is connected with a turnover block, and the turnover block can move through the chute and drive the material on the chute to be partially turned over; and a bending component is also arranged between the turning block and the guide sleeve.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is a schematic view of a heat pipe processing machine according to an embodiment of the present invention;

FIG. 2 is a schematic view of the structural profile of the heat pipe processor shown in FIG. 1;

FIG. 3 is a schematic view of the copper tube transport structure of the heat pipe processor shown in FIG. 1;

FIG. 4 is a schematic view of a transport configuration of the heat pipe processor shown in FIG. 1;

FIG. 5 is a schematic view of a table of the heat pipe processing machine shown in FIG. 1;

FIG. 6 is a schematic view of a press bending assembly of the heat pipe processing machine shown in FIG. 1;

FIG. 7 is a schematic view of a pusher mechanism of the heat pipe processing machine shown in FIG. 1;

FIG. 8 is a schematic view of another embodiment of a transport mechanism of the heat pipe processing machine shown in FIG. 1;

FIG. 9 is a schematic view of a material handling assembly of the heat pipe processing machine shown in FIG. 1.

Reference numerals: 100 is a machine table, which is a table,

200 is a copper pipe conveying mechanism, 210 is a feeding material box, 213 is a material ejecting cylinder, 215 is a material ejecting part, 230 is a feeding component, 231 is a conveying cylinder, 233 is a connecting seat, 235 is a material loading frame, 237 is a conveying seat, 239 is a first lifting cylinder, 250 is a fixing table, 251 is a sliding block, 253 is a fixing frame, 255 is a fixing cylinder, 270 is a clamping component, and 290 is a discharging material box;

300 is a workbench, 320 is a sliding chute, 330 is a turnover cylinder, 335 is a turnover block, 350 is a guide sleeve, 360 is a bending component, 361 is a bending cylinder, 365 is a bending wheel, 371 is a third driving device, 372 is a sliding seat, 375 is a pressure plate, 376 is a telescopic cylinder, 378 is a second lifting cylinder,

400 is a pushing mechanism, 410 is a support table, 420 is a second driving device, 430 is a pushing cylinder, 440 is a pushing clamping jaw, and 450 is a pushing rod;

500 is a conveying mechanism, 510 is a driving wheel group, 520 is a steering wheel, 530 is a shaping wheel group, 540 is a supporting wheel group, and 550 is a material pressing piece;

700 is a transfer table;

800 is a material shearing assembly, 810 is a material shearing cylinder, and 820 is a material shearing knife;

900 is the material transporting assembly, 910 is the supporting frame, 920 is the first driving device, 930 is the material transporting seat, 940 is the material clamping seat, 950 is the air cylinder clamping jaw, 980 is the third lifting air cylinder.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

In the description of the present invention, it should be understood that the orientation or positional relationship referred to in the description of the orientation, such as the upper, lower, front, rear, left, right, etc., is based on the orientation or positional relationship shown in the drawings, and is only for convenience of description and simplification of description, and does not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, the meaning of a plurality of means is one or more, the meaning of a plurality of means is two or more, and larger, smaller, larger, etc. are understood as excluding the number, and larger, smaller, inner, etc. are understood as including the number. If there is a description of first and second for the purpose of distinguishing technical features only, this is not to be understood as indicating or implying a relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of technical features indicated.

In the description of the present invention, unless otherwise specifically limited, terms such as set, installation, connection and the like should be understood in a broad sense, and those skilled in the art can reasonably determine the specific meanings of the above terms in the present invention by combining the specific contents of the technical solutions.

Referring to fig. 1, a heat pipe processing machine comprising: the device comprises a machine table 100, a workbench 300, a copper pipe conveying mechanism 200, a plurality of groups of conveying mechanisms 500 and a material pushing mechanism 400; the worktable 300 is disposed on the machine 100; the copper pipe conveying mechanism 200 comprises a fixed table 250 arranged on the machine table 100, the fixed table 250 is in butt joint with the workbench 300, and the copper pipe conveying mechanism 200 can convey copper pipes to the fixed table 250 and fix the copper pipes; the plurality of sets of conveying mechanisms 500 are all disposed on the machine platform 100, and at least two sets of conveying mechanisms 500 can respectively drive different materials to the workbench 300; the material pushing mechanism 400 is disposed on the machine platform 100, and the material pushing mechanism 400 can drive the material on the workbench 300 to move and stretch into the copper pipe on the fixing platform 250. The copper pipe conveying mechanism conveys the copper pipe to the fixing table 250 and relatively fixes the copper pipe and the fixing table 250. Meanwhile, the conveying mechanism 500 can drive different materials to the worktable 300 respectively. Subsequently, the pushing mechanism 400 is activated to push the materials on the worktable 300 to move, and finally, all the materials on the worktable 300 are pushed into the materials fixed on the fixing table 250, thereby completing the heat pipe processing operation. Through the combined action of the copper pipe conveying mechanism 200 and the multiple groups of conveying mechanisms 500, copper pipes and different materials can be automatically conveyed to a processing station, and the pushing mechanism 400 pushes materials. The full-mechanical automatic processing can greatly increase the processing efficiency, and the multiple groups of conveying mechanisms 500 can stably feed different materials, so that the problems of wrong loading and missing loading can be effectively avoided.

Specifically, the machine 100 has a slide block 251 and a clamping assembly 270, and the fixed table 250 is connected to the slide block 251. The fixing table 250 is provided with a fixing cylinder 255, and the fixing cylinder 255 can press the copper pipe to the clamping assembly 270.

Further, the clamping assembly 270 includes a clamping cylinder disposed above the junction of the stationary platen 250 and the work platen 300.

Further, the sliding block 251 is slidably mounted on the machine 100 through a fourth driving device.

In some embodiments, referring to fig. 2, the copper tube conveying mechanism 200 further comprises a feeding magazine 210, a feeding assembly 230 and a discharging magazine 290, wherein the feeding assembly 230 can drive the copper tube to move from the feeding magazine 210 to the fixing table 250, and the feeding assembly 230 can drive the copper tube to move from the fixing table 250 to the discharging magazine 290. The feed magazine 210 may be used to store copper tubes to be processed, while the discharge magazine 290 may receive processed copper tubes. The copper pipes before and after being processed are driven by the feeding assembly 230, so that the feeding and discharging processes of the copper pipes become more natural and ordered, and the operation efficiency can be greatly improved.

In certain embodiments, referring to fig. 3, the feed assembly 230 comprises: the ejector 215, the carrying cylinder 231, the attaching base 233, and the carrying base 237; the ejection part 215 is arranged in the feeding box 210, the machine table 100 is provided with an ejection cylinder 213, and the ejection cylinder 213 is connected with the ejection part 215 and can drive the ejection cylinder to eject the copper pipe in the feeding box 210; the conveying cylinder 231 is connected with the connecting seat 233 and can drive the connecting seat 233 to reciprocate between the feeding material box 210 and the discharging material box 290, a first lifting cylinder 239 is arranged on the connecting seat 233, and the first lifting cylinder 239 is connected with the conveying seat 237. After the ejector cylinder 213 drives the ejector 215 to move and the ejector 215 ejects the copper tube, the conveying cylinder 231 can drive the conveying seat 237 to move close to the feeding box 210 through the connecting seat 233, and then the first lifting cylinder 239 drives the conveying seat 237 to descend and take away the ejected copper tube. Subsequently, the transfer cylinder 231 moves the transfer base 237 again through the connection base 233, so that the transfer base 237 transfers the copper pipe to the fixing table 250. After the copper tube on the fixing table 250 is processed, the transporting seat 237 is lifted relative to the fixing seat again and the processed copper tube is taken away, and finally the copper tube is transported into the discharging box 290 to complete the discharging operation. The cooperation of the ejector 215 and the ejector cylinder 213 enables the copper tube to be ejected out of the feeding box 210 directly, thereby facilitating the copper tube to be taken away and processed; the cooperation of the conveying cylinder 231, the connecting seat 233 and the conveying seat 237 can drive the material to move from the material feeding box 210 to the fixing table 250 or the material discharging box 290, so that the processing process can be more automated, and the processing efficiency and accuracy can be improved.

Specifically, the ejector 215 is a thick ejector rod, such as a copper tube. Of course, the ejector 215 may also be composed of other components, such as a push rod (not shown). The specific implementation manner can be adjusted according to the actual situation, and is not limited herein.

Specifically, the carrier frame 235 is disposed on the carrying seat 237, two fixed carrier frames 253 are disposed on the fixed seat, and the carrying seat 237 moves between the two fixed carrier frames 253 on the fixed seat. Therefore, when the conveying seat 237 is lifted, the conveying seat passes through a material loading plane formed by the two fixed material racks 253 on the fixing seat, so that the effect of material taking or material placing is achieved.

In certain embodiments, referring to fig. 4, the transport mechanism 500 comprises: a driving wheel set 510, a material shearing assembly 800 and a feeding assembly; the driving wheel group 510 can drive the material to move; the material shearing assembly 800 is disposed on the machine 100 and located between the driving wheel set 510 and the workbench 300, and the material shearing assembly 800 can shear the material; the material transporting assembly 900 is disposed on the machine 100, and the material transporting assembly 900 can drive the material to move close to the junction between the working platform 300 and the fixed platform 250. A wire, strip, or mesh material may be wound around the drive wheel assembly 510. The driving wheel set 510 not only can provide a storage location for the material, but also can directly and effectively drive the material to move after the driving wheel set 510 rotates, thereby facilitating the material to be transported to the workbench 300 for processing. The cutting assembly 800 is capable of cutting filamentary, strip or web material to separate a portion of the stocked material required for a single operation to allow the portion to be processed. The material transporting assembly 900 can drive the portion cut by the material cutting assembly 800 to move to be close to the fixing table 250 relative to the workbench 300, so that the material pushing mechanism 400 can conveniently push materials.

Specifically, the conveyor 500 also includes a plurality of steerable wheels 520, with the material on the drive wheel set 510 passing through each steerable wheel 520 and ultimately parallel to the work platform 300.

In some embodiments, referring to fig. 4, the conveying mechanism 500 further includes a shaping wheel set 530, the shaping wheel set 530 being located between the trim assembly 800 and the drive wheel set 510 and being capable of shaping the material. The shaping wheel set 530 can extrude and shape the material, so that the material can move to the worktable 300 in a linear shape or a flat plate shape, and the process of the material entering the copper pipe is smoother.

In certain embodiments, referring to fig. 5, the drive wheel set 510 interfaces with the work table 300 through the trim assembly 800; the material conveying assembly 900 comprises a third driving device 371 arranged on the machine table 100, and the third driving device 371 is connected with a sliding seat 372 and can drive the sliding seat 372 to move along the workbench 300; the sliding seat 372 is connected with a second lifting cylinder 378, and the second lifting cylinder 378 is connected with a material pressing plate 375 which can press the material and drive the material to move along the workbench 300. After the third driving device 371 drives the pressing plate 375 to approach the workpiece through the sliding seat 372, the second lifting cylinder 378 will drive the pressing plate 375 to descend, so that the pressing plate 375 compresses the material on the workbench 300. Subsequently, the third driving device 371 operates again and moves the nip plate 375 close to the fixed platen 250. In the moving process of the material pressing plate 375, the material pressing plate 375 will drive the material to move along with the material pressing, so that the material is directly and effectively moved to the position close to the fixing table 250, so that the material pushing mechanism 400 can push the material into the copper pipe.

Further, be provided with telescopic cylinder 376 between sliding seat 372 and the second lift cylinder 378, telescopic cylinder 376 can drive second lift cylinder 378 and be close to or keep away from workstation 300 to realize pressing the material effect, perhaps avoid second lift cylinder 378 and pressure flitch 375 to cause the interference to the operation on workstation 300.

In certain embodiments, referring to fig. 8, the trim assembly 800 includes a trim cylinder 810, the trim cylinder 810 having a trim knife 820 coupled thereto and capable of driving the trim knife 820 to move toward or away from the material. After the material shearing cylinder 810 is started, the material shearing knife 820 is driven to move close to the material, so that the material is sheared, and the material shearing operation is completed. After the material shearing operation is finished, the material shearing cylinder 810 can drive the material shearing knife 820 to move and keep away from the material, so that the material in the conveying process is prevented from being additionally damaged by the material shearing knife 820.

In certain embodiments, referring to fig. 9, the transport mechanism 500 includes a transfer table 700 with the drive wheel set 510 interfaced with the transfer table 700 via a trim assembly 800; the material transporting assembly 900 comprises a supporting frame 910 arranged on the transfer platform 700, a material transporting seat 930 capable of reciprocating between the transfer platform 700 and the workbench 300 is movably connected to the supporting frame 910, and a first driving device 920 is connected to the material transporting seat 930; a third lifting cylinder 980 is arranged on the material conveying base 930, the third lifting cylinder 980 is connected with a material clamping base 940, and a cylinder clamping jaw 950 is arranged on the material clamping base 940. The transfer table 700 may be used for temporary storage of cut material to provide a prerequisite for the delivery of the material handling assembly 900. When the material conveying base 930 moves above the transfer platform 700, the third lifting cylinder 980 can drive the cylinder clamping jaw 950 to descend, so as to clamp the material on the transfer platform 700. Subsequently, the third lifting cylinder 980 drives the cylinder clamping jaw 950 to ascend again, the material conveying seat 930 drives the material to move above the workbench 300 through the cylinder clamping jaw 950, and the third lifting cylinder 980 drives the cylinder clamping jaw 950 to descend again, so that the material is placed on the workbench 300. Through the mutual cooperation among the transfer table 700, the material conveying seat 930 and the cylinder clamping jaw 950, the material can be effectively driven to move onto the workbench 300, so that the subsequent processing operation is facilitated.

Specifically, a support wheel set 540 is disposed between the relay stand 700 and the driving wheel set 510. The supporting wheel set 540 can prevent the material between the transferring table 700 and the driving wheel set 510 from falling down, so as to improve the integrity of the material before processing.

In some embodiments, referring to fig. 7, a chute 320 is disposed on the working platform 300, and the chute 320 is abutted with the fixing platform 250; the pushing mechanism 400 includes a supporting platform 410 disposed on the machine platform 100, a pushing seat capable of reciprocating along the length direction of the sliding chute 320 is disposed on the supporting platform 410, and the pushing seat is connected to a second driving device 420; the pushing cylinder 430 is arranged on the pushing seat, the pushing cylinder 430 is connected with a pushing rod 450, and the pushing rod 450 can extend into the chute 320 and push the material in the chute 320 to move and extend into the copper pipe. After the pushing cylinder 430 drives the pushing rod 450 to extend into the sliding groove 320, the second driving device 420 is started, and drives the pushing rod 450 to move along the sliding groove 320 through the pushing seat, so that the pushing rod 450 pokes the material into the copper rod, and the pushing operation is completed. The cooperation of the material pushing rod 450 and the material pushing seat can effectively drive the material to enter the copper pipe, thereby directly and effectively completing the material pushing operation.

Specifically, a material pushing clamping jaw 440 is arranged between the material pushing rod 450 and the material pushing cylinder 430, the material pushing cylinder 430 is connected with the material pushing clamping jaw 440, and the material pushing clamping jaw 440 clamps the material pushing rod 450 and can drive the material pushing rod to move.

In some embodiments, referring to fig. 6, a guide sleeve 350 is disposed between the worktable 300 and the fixed table 250, a turnover cylinder 330 is disposed on the worktable 300, the turnover cylinder 330 is connected to a turnover block 335, and the turnover block 335 can move through the chute 320 and drive the material on the chute 320 to be partially turned over; a press bending assembly 360 is also provided between the turnover block 335 and the guide sleeve 350. Activation of the tucker cylinder 330 will move the tucker block 335 through the chute 320. When the chute 320 contains material, the turning block 335 pushes the portion of the material and turns the portion. The flipped material more conveniently provides a force application point for the pusher bar 450, thereby ensuring that the pusher bar 450 can effectively push the material into the copper tube. And the subassembly 360 that bends can carry out preliminary bending with the material to make the material can adapt to the copper pipe and form the halfpipe form, and then ensure that the material can enter into the copper pipe smoothly.

Specifically, the bending assembly 360 includes a bending cylinder 361 disposed above the workbench 300, the bending cylinder 361 is connected with a bending wheel 365, and the bending cylinder 361 can drive the bending wheel 365 to descend and press the material in the chute 320.

Further, the bending wheel 365 is provided with an inner circular groove which can match with the sliding groove 320 to press the material into an approximate circular tube shape, so that the material pushing rod 450 can push the material into the copper tube conveniently.

Specifically, the first driving device 920, the second driving device 420, the third driving device 371, and the fourth driving device are all connected and combined by a motor and a belt transmission mechanism. Of course, the specific configuration of the first driving device 920, the second driving device 420, the third driving device 371 and the fourth driving device is not exclusive, and for example, the first driving device, the second driving device, the third driving device 371 and the fourth driving device may be replaced by a hydraulic cylinder (not shown). The specific configuration manners of the first driving device 920, the second driving device 420, the third driving device 371, and the fourth driving device may also be different, and the specific embodiments may be adjusted according to actual situations, which is not limited herein.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The embodiments of the present invention have been described in detail with reference to the drawings, but the present invention is not limited to the embodiments, and various changes can be made within the knowledge of those skilled in the art without departing from the gist of the present invention.

Claims (10)

1. A heat pipe processing machine, comprising:

a machine table (100);

a work table (300) disposed on the machine table (100);

the copper pipe conveying mechanism (200) comprises a fixed table (250) arranged on the machine table (100), the fixed table (250) is in butt joint with the workbench (300), and the copper pipe conveying mechanism (200) can convey a copper pipe onto the fixed table (250) and fix the copper pipe;

the plurality of groups of conveying mechanisms (500) are all arranged on the machine table (100), and at least two groups of conveying mechanisms (500) can respectively drive different materials to the workbench (300);

the pushing equipment (400) is arranged on the machine table (100), and the pushing equipment (400) can drive the material on the workbench (300) to move and stretch into the copper pipe on the fixed table (250).

2. A heat pipe processing machine as defined in claim 1, wherein:

the copper pipe conveying mechanism (200) further comprises a feeding box (210), a feeding assembly (230) and a discharging box (290), the feeding assembly (230) can drive the copper pipe to move from the feeding box (210) to the fixing table (250), and the feeding assembly (230) can drive the copper pipe to move from the fixing table (250) to the discharging box (290).

3. A machine as defined in claim 2, wherein:

the feed assembly (230) comprises:

the ejection part (215) is arranged in the feeding box (210), the machine table (100) is provided with an ejection cylinder (213), and the ejection cylinder (213) is connected with the ejection part (215) and can drive the ejection part to eject the copper pipe in the feeding box (210);

the conveying device comprises a conveying cylinder (231), a connecting seat (233) and a conveying seat (237), wherein the conveying cylinder (231) is connected with the connecting seat (233) and can drive the connecting seat (233) to reciprocate between the feeding material box (210) and the discharging material box (290), a first lifting cylinder (239) is arranged on the connecting seat (233), and the first lifting cylinder (239) is connected with the conveying seat (237).

4. A machine as defined in claim 1, wherein:

the transport mechanism (500) comprises:

the driving wheel set (510) can drive the material to move;

the material shearing assembly (800) is arranged on the machine table (100) and positioned between the driving wheel set (510) and the workbench (300), and the material shearing assembly (800) can shear materials;

the material conveying assembly (900) is arranged on the machine table (100), and the material conveying assembly (900) can drive materials to move close to the junction of the workbench (300) and the fixed table (250).

5. A machine as defined in claim 4, wherein:

the conveying mechanism (500) further comprises a shaping wheel set (530), and the shaping wheel set (530) is located between the material shearing assembly (800) and the driving wheel set (510) and can shape the material.

6. A machine as defined in claim 4, wherein:

the driving wheel set (510) is butted with the workbench (300) through the material shearing assembly (800);

the material conveying assembly (900) comprises a third driving device (371) arranged on the machine table (100), and the third driving device (371) is connected with a sliding seat (372) and can drive the sliding seat (372) to move along the workbench (300); the sliding seat (372) is connected with a second lifting cylinder (378), and the second lifting cylinder (378) is connected with a material pressing plate (375) capable of pressing materials and driving the materials to move along the workbench (300).

7. A heat pipe processing machine as defined in claim 4, wherein:

the material shearing assembly (800) comprises a material shearing cylinder (810), wherein the material shearing cylinder (810) is connected with a material shearing knife (820) and can drive the material shearing knife (820) to move close to or far away from a material.

8. A machine as defined in claim 4, wherein:

the conveying mechanism (500) comprises a transfer table (700), and the driving wheel set (510) is butted with the transfer table (700) through the material shearing assembly (800);

the material conveying assembly (900) comprises a supporting frame (910) arranged on the transfer table (700), a conveying seat (237) capable of reciprocating between the transfer table (700) and the workbench (300) is movably connected to the supporting frame (910), and a first driving device (920) is connected to the conveying seat (237); the conveying device is characterized in that a third lifting cylinder (980) is arranged on the conveying seat (237), the third lifting cylinder (980) is connected with a clamping seat (940), and a cylinder clamping jaw (950) is arranged on the clamping seat (940).

9. A machine as defined in claim 1, wherein:

a sliding groove (320) is formed in the workbench (300), and the sliding groove (320) is in butt joint with the fixing table (250);

the pushing mechanism (400) comprises a supporting table (410) arranged on the machine table (100), a pushing seat capable of reciprocating along the length direction of the chute (320) is arranged on the supporting table (410), and the pushing seat is connected with a second driving device (420); the material pushing device is characterized in that a material pushing cylinder (430) is arranged on the material pushing seat, the material pushing cylinder (430) is connected with a material pushing rod (450), and the material pushing rod (450) can stretch into the sliding groove (320) and push the material in the sliding groove (320) to move and stretch into the copper pipe.

10. A machine as defined in claim 9, wherein:

a guide sleeve (350) is arranged between the workbench (300) and the fixed table (250), a turnover cylinder (330) is arranged on the workbench (300), the turnover cylinder (330) is connected with a turnover block (335), and the turnover block (335) can move to penetrate through the chute (320) and drive the material on the chute (320) to be partially turned over; a bending component (360) is also arranged between the turning block (335) and the guide sleeve (350).

Images