CN115488639A - Intelligent numerical control multi-position processing machine for radiating fins - Google Patents

Abstract

The invention relates to the technical field of radiating fin processing equipment and discloses an intelligent numerical control multi-position processing machine for radiating fins, which comprises a working disc, a plurality of clamping modules and a control module, wherein the working disc is rotatably arranged inside a working table of the processing machine; multiunit station module, it is in to distribute the surface of workstation is located the workstation surface is close to the position of workstation side, this many processing machines of fin intelligence numerical control, design through workstation surface operation dish and the design of workstation surface multiunit station module, can realize the multiplex processing to the fin, guide rail one and X axle driver in the station module, guide rail two and Y axle driver and guide rail three with the design of Z axle driver, can regulate and control the position of processing head, thereby can realize carrying out the processing of different positions and different technologies to the surface of fin, the regional occupation space of fin surface machining is little, the processing equipment is few, be favorable to reducing the cost of equipment for fin surface machining.

Description

Intelligent numerical control multi-position processing machine for radiating fins

Technical Field

The invention relates to the technical field of radiating fin processing equipment, in particular to an intelligent numerical control multi-position processing machine for radiating fins.

Background

The radiator is a device or an instrument which transfers heat generated by mechanical equipment during operation so as to ensure normal operation of the mechanical equipment, the radiating fin is a heat transfer component in the radiator, and is often integrated in the radiator, so that the thermal contact area is increased, and when the radiating fin is produced, drilling, tapping and other processing are required to be carried out on the surface of the radiating fin for convenience of positioning and mounting of the radiating fin.

The existing machining of the surface of the radiating fin, such as drilling, tapping, chamfering and the like, is finished in a flow line operation mode, the radiating fin needs to be conveyed to equipment of multiple machining tools by an automatic production line, the machining of the surface of the radiating fin is realized by multiple machining equipment, the whole machining flow line of the radiating fin is long, the required machining equipment is more, the production space occupied by the machining of the radiating fin is large, and the cost of the machining equipment is high.

Disclosure of Invention

In order to solve the problems that the whole processing assembly line of the existing radiating fin is longer, more processing equipment is needed, the production space occupied by the processing of the radiating fin is larger, and the cost of the processing equipment is high, the invention is realized by the following technical scheme: an intelligent numerical control multi-position processing machine for radiating fins comprises,

the working disc is rotatably arranged inside the working table of the machining machine, a plurality of groups of clamping modules are arranged on the surface of the working table, each clamping module consists of two clamping blocks capable of moving horizontally, the internal threads of the two clamping blocks are connected with the same threaded rod piece, the threaded connection directions of the two clamping blocks and the threaded rod piece are opposite, and the two clamping blocks can move oppositely or reversely through the rotation of the threaded rod piece, so that the two clamping blocks are used for clamping and fixing the radiating fins;

multiunit station module distributes and is in the surface of workstation is located the workstation surface is close to the position of working disc side for carry out multiplex kind of processing to the surface of fin, including hitting some chamfer, drilling, attack tooth, fly plane and chamfer angle processing, the station module includes:

the surface of the first guide rail is provided with a base in a sliding mode, and an X-axis driver used for driving the base to move is arranged on the side face of the first guide rail;

the mounting plate is slidably mounted on the surface of the base through a second guide rail, the second guide rail is vertically distributed with the first guide rail, and a Y-axis driver for driving the mounting plate to move is arranged on the surface of the second guide rail;

the support plate is fixedly arranged on the surface of the mounting plate, and a third guide rail is arranged on the surface of one side, close to the working disc, of the support plate;

the machining head is vertically and slidably mounted on the surface of one side, close to the working disc, of the guide rail III, and a Z-axis driver used for driving the machining head to move is arranged inside the guide rail III.

Furthermore, the station modules are provided with seven groups, and the seven groups of station modules are uniformly distributed on the outer side of the working disc in an eight-position mode.

And the machining heads in the station modules comprise a dotting chamfering machine head, a drilling machine head, a tapping machine head, a plane flying machine head and a chamfering machine head, wherein the drilling machine head and the tapping machine head are respectively provided with two groups and are respectively used for dotting chamfering, drilling, tapping, plane flying and chamfering machining on the surface of the radiating fin.

Further, follow the direction of rotation of working disc, the distribution order of processing head is in proper order for dotting chamfer aircraft nose, drilling aircraft nose, attack the tooth aircraft nose, fly plane aircraft nose and chamfer aircraft nose.

Furthermore, the X-axis driver, the Y-axis driver and the Z-axis driver are all telescopic cylinders.

Further, the processing head lower part is close to one side of three guide rails is equipped with the outlet pipe, the outlet pipe is installed the inside of mounting panel, the play water end of outlet pipe is directional the surface of working disc for dispel the heat to the processing end of processing head, carry the piece that the processing produced simultaneously.

Furthermore, the surface of the working disc is provided with a plurality of flow guide discs, the flow guide discs correspond to the plurality of station modules, the flow guide discs extend obliquely downwards along the side edges of the working disc to the center direction of the working disc and are used for guiding cutting fluid, one side of each flow guide disc, which is far away from the outer side edge of the working disc, is provided with an annular throttling groove, and the cross section of each throttling groove is concave and is used for collecting chips.

Furthermore, the surface of the flow guide disc is provided with a chip collecting groove, and the surface of the flow guide disc extends downwards obliquely from two side edges in the width direction of the chip collecting groove to the chip collecting groove and is used for collecting chips.

Further, the surface of workstation is equipped with control center, control center is inside to include:

a programming system: the system is used for programming and controlling the working operation of the processing heads in the plurality of groups of processing modules;

a parameter setting module: the processing parameters of the radiating fins are set through a touch screen on the surface of the control center, and the parameter setting module is in digital communication connection with the programming system;

a PLC controller: and the programming systems are in electric signal connection and are used for controlling drivers in the multiple groups of station modules, and meanwhile, the programming systems are in electric signal connection with driving equipment of the working disc and are used for controlling the rotation of the working disc.

Further, the driver in the station module comprises a displacement driver and an operation driver for driving the processing head to operate, and the displacement driver comprises an X-axis driver, a Y-axis driver and a Z-axis driver.

Compared with the prior art, the invention has the following beneficial effects:

1. this many processing machines of fin intelligence numerical control, design through workstation surface working dish and the design of workstation surface multiunit station module, can realize the processing of many kinds of work to the fin, guide rail one and X axle driver in the station module, guide rail two and Y axle driver and guide rail three and the design of Z axle driver, can regulate and control the position of processing head, thereby can realize carrying out the processing of different positions and different technologies to the surface of fin, the regional occupation space of fin surface processing is little, processing equipment is few, be favorable to reducing the cost of the equipment for fin surface processing.

2. This many processing machines of fin intelligence numerical control, through the design of flow guide disc with throttle groove and the design of flow guide disc surface chip collecting groove, be convenient for retrieve the cutting fluid, be convenient for simultaneously collect the piece that processing produced.

Drawings

FIG. 1 is a top view of the heat sink processing apparatus according to the present invention;

FIG. 2 is a top view of the station module structure of the present invention;

FIG. 3 is a side view of a first exemplary station module configuration of the present invention;

FIG. 4 is a side view of a second exemplary station module configuration of the present invention;

FIG. 5 is a schematic view of the surface structure of the work plate according to the present invention;

fig. 6 is a schematic structural view of a flow guiding plate according to the present invention;

FIG. 7 is a schematic cross-sectional view of a throttle slot according to the present invention;

FIG. 8 is a schematic structural view of a clamping module according to the present invention;

FIG. 9 is a first flowchart of a system for processing heat sink fins according to the present invention;

fig. 10 is a flow chart of a second system of the heat sink processing apparatus of the present invention.

In the figure: 1. a work table; 2. a working plate; 3. clamping the module; 4. a station module; 41. a first guide rail; 411. an X-axis driver; 42. a base; 421. mounting a plate; 43. a second guide rail; 431. a Y-axis driver; 44. a support plate; 441. a third guide rail; 442. a Z-axis driver; 5. a machining head; 6. a water outlet pipe; 7. a flow guide disc; 71. a chip collecting groove; 8. a throttling groove.

Detailed Description

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

The radiator is a device or an instrument for transferring heat generated by mechanical equipment during operation so as to ensure normal operation of the mechanical equipment, the radiating fin is a heat transfer component in the radiator, and is often integrated in the radiator, so that the thermal contact area is increased, and in production, the surface of the radiating fin needs to be drilled, tapped and the like for convenience in positioning and mounting of the radiating fin.

The embodiment of the intelligent numerical control multi-position processing machine for the radiating fin is as follows:

the first embodiment is as follows:

referring to fig. 1-10, an intelligent numerical control multi-position processing machine for heat dissipation plate comprises,

the working disc 2 is rotatably installed inside the working table 1 of the machining machine, a plurality of groups of clamping modules 3 are arranged on the surface of the working table 1, each clamping module 3 consists of two clamping blocks capable of moving horizontally, the internal threads of the two clamping blocks are connected with the same threaded rod piece, the threaded connection directions of the two clamping blocks and the threaded rod piece are opposite, and the two clamping blocks can move oppositely or reversely through the rotation of the threaded rod piece, so that the two clamping blocks are used for clamping and fixing the radiating fins;

multiunit station module 4 distributes on the surface of workstation 1, is located the position that 2 sides of workstation 1 surface is close to the service disk for carry out multiplex kind of processing to the surface of fin, including dotting chamfer, drilling, attack the tooth, fly plane and chamfer angle processing, station module 4 includes:

the surface of the first guide rail 41 is provided with a base 42 in a sliding manner, and the side surface of the first guide rail 41 is provided with an X-axis driver 411 for driving the base 42 to move; the mounting plate 421 is slidably mounted on the surface of the base 42 through the second guide rail 43, the second guide rail 43 is vertically distributed with the first guide rail 41, and the surface of the second guide rail 43 is provided with a Y-axis driver 431 for driving the mounting plate 421 to move.

The support plate 44 is fixedly arranged on the surface of the mounting plate 421, and a guide rail III 441 is arranged on the surface of the support plate 44 close to one side of the working plate 2; the processing head 5 is vertically and slidably mounted on the surface of the guide rail three 441 close to one side of the working disc 2, a Z-axis driver 442 for driving the processing head 5 to move is arranged inside the guide rail three 441, and the X-axis driver 411, the Y-axis driver 431 and the Z-axis driver 442 are telescopic cylinders.

The surface of workstation 1 is equipped with control center, and control center is inside to include: programming a system: the system is used for carrying out programming control on the working operation of the processing heads 5 in the plurality of groups of processing modules 4; a parameter setting module: the processing parameters of the radiating fins are set through a touch screen on the surface of the control center, and the parameter setting module is in digital communication connection with the programming system; a PLC controller: the electric signal connection is arranged between the working disc and the programming system, and is used for controlling drivers in the plurality of groups of station modules 4, and simultaneously is connected with the driving equipment of the working disc 2 through the electric signal connection and is used for controlling the rotation of the working disc 2.

The drivers in the station module 4 include a displacement driver including an X-axis driver 411, a Y-axis driver 431, and a Z-axis driver 442, and an operation driver for driving the operation of the processing head 5.

Example two:

referring to fig. 1-10, an intelligent numerical control multi-position processing machine for heat dissipation plate comprises,

the working plate 2 is rotatably installed inside the working table 1 of the machining machine, a plurality of groups of clamping modules 3 are arranged on the surface of the working table 1, each clamping module 3 is composed of two clamping blocks capable of moving horizontally, the internal threads of the two clamping blocks are connected with the same threaded rod piece, the two clamping blocks are opposite to the threaded rod piece in threaded connection direction, and the two clamping blocks can move oppositely or reversely to the threaded rod piece to clamp and fix the radiating fins by utilizing the two clamping blocks.

Multiunit station module 4, the distribution is on the surface of workstation 1, is located the position that 2 sides of workstation 1 surface are close to the service disk for carry out multiplex kind of processing to the surface of fin, including hitting some chamfer, drilling, attacking the tooth, flying plane and chamfer angle processing, station module 4 includes:

the surface of the first guide rail 41 is provided with a base 42 in a sliding manner, and the side surface of the first guide rail 41 is provided with an X-axis driver 411 for driving the base 42 to move; the mounting plate 421 is slidably mounted on the surface of the base 42 through a second guide rail 43, the second guide rail 43 and the first guide rail 41 are vertically distributed, and a Y-axis driver 431 for driving the mounting plate 421 to move is arranged on the surface of the second guide rail 43; and the support plate 44 is fixedly arranged on the surface of the mounting plate 421, and the surface of the support plate 44 close to one side of the working plate 2 is provided with a guide rail three 441.

The machining head 5 is vertically and slidably installed on the surface of one side, close to the working disc 2, of the guide rail three 441, a Z-axis driver 442 used for driving the machining head 5 to move is arranged inside the guide rail three 441, seven groups of station modules 4 are arranged and evenly distributed on the outer side of the working disc 2 in eight-division mode, machining heads 5 in the seven groups of station modules 4 comprise a dotting chamfering machine head, a drilling machine head, a tapping machine head, a flying plane machine head and chamfering machine heads, wherein the two groups of drilling machine heads and the two groups of tapping machine heads are respectively used for dotting chamfering, drilling, tapping, flying plane machining and chamfering machining on the surface of a cooling fin, and the machining heads 5 sequentially comprise the dotting chamfering machine head, the drilling machine head, the tapping machine head, the flying plane machine head and the chamfering machine head along the rotation direction of the working disc 2.

Example three:

referring to fig. 1-10, an intelligent numerical control multi-position processing machine for heat dissipation plate comprises,

the working plate 2 is rotatably installed inside the working table 1 of the machining machine, a plurality of groups of clamping modules 3 are arranged on the surface of the working table 1, each clamping module 3 is composed of two clamping blocks capable of moving horizontally, the internal threads of the two clamping blocks are connected with the same threaded rod piece, the two clamping blocks are opposite to the threaded rod piece in threaded connection direction, and the two clamping blocks can move oppositely or reversely to the threaded rod piece to clamp and fix the radiating fins by utilizing the two clamping blocks.

Multiunit station module 4 distributes on the surface of workstation 1, is located the position that 2 sides of workstation 1 surface is close to the service disk for carry out multiplex kind of processing to the surface of fin, including dotting chamfer, drilling, attack the tooth, fly plane and chamfer angle processing, station module 4 includes:

the surface of the first guide rail 41 is provided with a base 42 in a sliding manner, and the side surface of the first guide rail 41 is provided with an X-axis driver 411 for driving the base 42 to move; the mounting plate 421 is slidably mounted on the surface of the base 42 through a second guide rail 43, the second guide rail 43 and the first guide rail 41 are vertically distributed, and a Y-axis driver 431 for driving the mounting plate 421 to move is arranged on the surface of the second guide rail 43; and the support plate 44 is fixedly arranged on the surface of the mounting plate 421, and the surface of the support plate 44 close to one side of the working plate 2 is provided with a guide rail three 441.

The machining head 5 is vertically slidably mounted on the surface of the guide rail third 441 on the side close to the work table 2, and a Z-axis actuator 442 for moving the machining head 5 is provided inside the guide rail third 441.

A water outlet pipe 6 is arranged on one side, close to the third guide rail 441, of the lower portion of the machining head 5, the water outlet pipe 6 is installed inside the installation plate 421, and a water outlet end of the water outlet pipe 6 points to the surface of the working disc 2 and is used for dissipating heat of the machining end of the machining head 5 and conveying scraps generated in machining.

The surface of working disc 2 is equipped with a plurality of flow guide discs 7, a plurality of flow guide discs 7 are corresponding with a plurality of station modules 4, flow guide disc 7 is along the side of working disc 2 to the central direction downwardly extending of working disc 2, be used for carrying out the water conservancy diversion to the cutting fluid, one side that the outer side limit of working disc 2 was kept away from to flow guide disc 7 is equipped with annular throttle groove 8, the cross section of throttle groove 8 is the spill, be used for clastic collection, chip collecting groove 71 has been seted up on the surface of flow guide disc 7, the surface of flow guide disc 7 is from the direction downwardly extending to chip collecting groove 71 from the both sides limit on the chip collecting groove 71 width direction, be used for collecting the piece, the inside in chip collecting groove 71 and throttle groove 8 all is equipped with the filter screen, the lower part is equipped with the header tank.

The working principle of processing the radiating fin by using the processing machine is as follows:

firstly, a cooling fin to be processed is placed on the surface of a working disc 2, the cooling fin is fixed by a clamping module 3, then processing parameters of the cooling fin are set by a parameter setting module on a touch screen of a control center, the processing parameters comprise processing hole position, processing hole position quantity and hole position chamfer, after the processing parameters are set, the equipment is started by the control center, at the moment, the working disc 2 starts to rotate and drives the cooling fin to move, and the cooling fin is moved to the position of a first station module 4.

At this time, the program system can transmit information to the PLC controller according to the processing parameters set by the parameter setting module, the PLC controller can control the driver in the first station module 4, the X-axis driver 411 can drive the mounting plate 421 to move, thereby driving the processing head 5 to move on the X axis, the Y-axis driver 431 can drive the support plate 44 to move on the Y axis, thereby driving the processing head 5 to move on the Y axis, the Z-axis driver 442 can drive the processing head 5 to move on the Z axis, the PLC controller can control the position of the processing head 5 by controlling the displacement driver in the first station module 4, thereby controlling the operation of the processing head 5, and the processing head 5 can process the surface of the heat sink.

According to the rotation direction of the working disc 2, the radiating fins can be subjected to dotting chamfering, drilling, tapping, plane milling and chamfering, meanwhile, according to the machining requirements of the radiating fins, machining parameters of the radiating fins can be set through the parameter setting module, and the radiating fins can be machined through the rotation of the working disc 2 and the machining head 5 in the corresponding station module 4 controlled by the PLC.

When the machining head 5 is used for machining the radiating fins, cutting fluid is sprayed to the machining position of the machining head 5 through the water outlet pipe 6, when the position of the machining head 5 is cooled, chips generated by machining can be conveyed into the flow guide disc 7, the cutting fluid containing the chips flows into the chip collecting groove 71 through the flow guide disc 7, part of the cutting fluid enters the throttling groove 8 through the flow guide disc 7, and therefore the chip collecting groove 71 and the throttling groove 8 are used for collecting the chips.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various 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 (10)

1. An intelligent numerical control multi-position processing machine for radiating fins comprises,

the working disc (2) is rotatably arranged inside the working table (1) of the processing machine, and a plurality of groups of clamping modules (3) are arranged on the surface of the working table (1);

multiunit station module (4), distribute and be in the surface of workstation (1) is located workstation (1) surface is close to the position of working disc (2) side, station module (4) include:

the device comprises a first guide rail (41), wherein a base (42) is installed on the surface of the first guide rail (41) in a sliding mode, and an X-axis driver (411) for driving the base (42) to move is arranged on the side surface of the first guide rail (41);

the mounting plate (421) is slidably mounted on the surface of the base (42) through a second guide rail (43), the second guide rail (43) and the first guide rail (41) are vertically distributed, and a Y-axis driver (431) for driving the mounting plate (421) to move is arranged on the surface of the second guide rail (43);

the support plate (44) is fixedly arranged on the surface of the mounting plate (421), and a third guide rail (441) is arranged on the surface of the support plate (44) close to one side of the working disc (2);

the machining head (5) is mounted on the surface of one side, close to the working disc (2), of the guide rail III (441) in a vertically sliding mode, and a Z-axis driver (442) used for driving the machining head (5) to move is arranged inside the guide rail III (441).

2. An intelligent, digitally controlled, multi-position converting machine for heat sinks according to claim 1, wherein said station modules (4) are in seven groups, said seven groups being evenly distributed in octants outside said work disc (2).

3. A fin intelligent numerical control multi-position processing machine according to claim 2, wherein the processing heads (5) of the seven groups of station modules (4) comprise a dotting chamfering head, a drilling head, a tapping head, a flying plane head, a chamfering head, wherein there are two groups of drilling heads and tapping heads.

4. An intelligent numerically controlled multi-position processor for cooling fins as claimed in claim 3, wherein the distribution of the processing heads (5) is in the order dotting, drilling, tapping, flying plane and chamfering heads, in the direction of rotation of the work disc (2).

5. A fin intelligent, digitally controlled multi-position processor according to any one of claims 1 to 4, wherein the X axis drive (411), Y axis drive (431) and Z axis drive (442) are telescopic cylinders.

6. An intelligent numerically controlled multi-position processing machine for cooling fins as claimed in any one of claims 1 to 4, wherein a water outlet pipe (6) is arranged on one side of the lower portion of the processing head (5) close to the third guide rail (441), the water outlet pipe (6) is installed inside the installation plate (421), and the water outlet end of the water outlet pipe (6) points to the surface of the working disk (2).

7. The fin intelligent numerical control multi-position processing machine according to claim 6, wherein a plurality of flow guide discs (7) are arranged on the surface of the working disc (2), a plurality of flow guide discs (7) correspond to a plurality of position modules (4), the flow guide discs (7) extend obliquely downwards along the side edges of the working disc (2) towards the center direction of the working disc (2), an annular throttling groove (8) is arranged on one side of the flow guide discs (7) far away from the outer side edges of the working disc (2), and the cross section of the throttling groove (8) is concave.

8. The fin intelligent numerical control multi-position processor according to claim 7, wherein the surface of the deflector (7) is provided with a chip collecting groove (71), and the surface of the deflector (7) extends obliquely downwards from two sides of the chip collecting groove (71) in the width direction to the direction of the chip collecting groove (71).

9. A fin smart numerically controlled multi-position processor according to any one of claims 1 to 4, wherein the surface of said table (1) is provided with a control centre internally comprising:

programming a system: the system is used for programming and controlling the working operation of the processing heads (5) in the plurality of groups of processing modules (4);

a parameter setting module: the processing parameters of the radiating fins are set through a touch screen on the surface of the control center, and the parameter setting module is in digital communication connection with the programming system;

a PLC controller: and the programming system is in electric signal connection and is used for controlling drivers in a plurality of groups of station modules (4).

10. A fin cnc multi-position processing machine as claimed in claim 9 wherein the drives in the station module (4) include a displacement drive and a run drive for driving operation of the processing head (5), the displacement drive including an X-axis drive (411), a Y-axis drive (431), and a Z-axis drive (442).

Images