CN112171289B - Grooving inserting plate type radiator manufacturing equipment - Google Patents

Abstract

The invention discloses a grooving inserting plate type radiator manufacturing device, wherein a grooving mechanism is provided with a grooving cutter for processing and forming a clamping groove on a radiator substrate, a fin pick-up mechanism is provided with a fin holder for inserting a radiating fin into the clamping groove of the radiator substrate, a riveting mechanism is provided with a fin squeezing device for deforming and clamping the clamping groove of the radiator substrate to fix the radiating fin, a station feeding mechanism for grooving station feeding of the radiator substrate is provided, a grooving inserting plate feeding mechanism for feeding a grooving inserting plate device is provided, a position separating mechanism for moving the grooving inserting plate device away from a working position and feeding the grooving inserting plate device into the working position is provided, the grooving cutter is arranged at a front corresponding position of the fin holder along the feeding direction of the grooving inserting plate feeding mechanism, and the fin squeezing device is arranged at a front position of the grooving cutter along the feeding direction of the station feeding mechanism.

Description

Grooving inserting plate type radiator manufacturing equipment

Technical Field

The invention relates to the field of radiator manufacturing equipment, in particular to grooving inserting plate type radiator manufacturing equipment.

Background

As shown in fig. 34, the heat sink includes a heat sink substrate 98 for contacting a device requiring heat dissipation and a heat sink 99 for increasing a heat dissipation area. The radiator is usually made of aluminum, and the current radiator manufacturing equipment forms the radiator structure by extruding a strip-shaped aluminum profile through a die and then cutting the strip-shaped aluminum profile. Some high-power devices or devices need a radiator with larger volume and large total radiating area, so that radiating fins of the radiator need to be set to be narrower and longer, the existing extrusion die cannot be used for manufacturing and forming the narrower and longer radiating fins due to the self structural strength, and a mode of cutting and forming the narrower and longer radiating fins by the whole aluminum block is adopted, so that a large amount of materials are wasted, the processing time is long, the efficiency is low, and the market is in urgent need for manufacturing equipment capable of manufacturing the radiator suitable for radiating the high-power device.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides a grooving inserting plate type radiator manufacturing device which is beneficial to manufacturing a radiator suitable for heat dissipation of a high-power device with low cost and high efficiency.

The aim of the invention is achieved by the following technical scheme.

The invention discloses a grooving inserting plate type radiator manufacturing device, which comprises a grooving inserting plate device, wherein the grooving inserting plate device is provided with a grooving mechanism, a plate picking mechanism and a riveting mechanism, the grooving mechanism is provided with a grooving cutter for processing and forming a clamping groove on a radiator substrate, the plate picking mechanism is provided with a plate holder for inserting a radiating plate into the clamping groove of the radiator substrate, and the riveting mechanism is provided with a plate squeezing device for deforming the clamping groove of the radiator substrate to clamp and fix the radiating plate; the heat radiator comprises a heat radiator substrate, and is characterized by further comprising a station feeding mechanism for feeding a grooving station of the heat radiator substrate, wherein the feeding direction of the station feeding mechanism is from front to back; the device also comprises a slot inserting sheet feeding mechanism for feeding the slot inserting sheet device and the slot extruder, wherein the feeding direction of the slot inserting sheet feeding mechanism is from right to left; the automatic cutting and inserting device also comprises a dislocation mechanism for moving the cutting and inserting device away from the working position and sending the cutting and inserting device into the working position, and the dislocation mechanism is arranged to be movable up and down; the grooving cutter is arranged at a corresponding position of the sheet holder in front of the feeding direction of the grooving inserting sheet feeding mechanism, and the groove squeezing device is arranged at a position of the grooving cutter in front of the feeding direction of the station feeding mechanism; the heat sink device further comprises a baffle mechanism for limiting the heat sink in the feeding direction of the grooving insert feeding mechanism, wherein the baffle mechanism comprises a heat sink stop block for contacting with the end face of the heat sink; the grooving inserting sheet device is provided with a pressing wheel mechanism, and the pressing wheel mechanism is provided with a positioning pressing wheel for applying pressure to the top ends of the radiating fins so that the radiating fins are positioned in the clamping grooves of the radiator substrate when the groove extruder works; the groove extruding device is set as a cutter wheel.

Preferably, the feeding device for feeding the cooling fins is further comprised, the feeding device comprises a pushing plate for pushing the stacked cooling fins, and the fin holder can move to a position corresponding to the pushing plate.

Preferably, the feeding device is provided with a retaining wall, the retaining wall and the pushing plate enclose a groove cavity for placing the stacked cooling fins, the feeding device is provided with a feeding spring for pushing the cooling fins along the stacking direction of the cooling fins, and the feeding spring is in driving connection with the pushing plate.

Preferably, the slot-cutting insert device is provided with a box seat, the slot-cutting tool is provided with a saw blade, the slot-cutting mechanism is provided with a saw blade motor, the saw blade motor is mounted on the box seat, and the saw blade motor is in driving connection with the slot-cutting tool.

Preferably, the slot inserting device is provided with a dust collection structure, the dust collection structure comprises a saw blade accommodating cavity, the slot cutting tool is arranged in the saw blade accommodating cavity, the box seat is provided with an air draft connecting pipe, and the air draft connecting pipe is communicated with the saw blade accommodating cavity.

Preferably, the wafer holder is provided with a sucking disc, and the wafer picking mechanism is provided with a first air cylinder which is in driving connection with the wafer holder.

Preferably, the riveting mechanism is provided with a connecting arm, a first positioning seat, a first base and a first positioning screw rod for adjusting the machining depth of the groove extruding device, the groove extruding device is rotationally connected with one end of the connecting arm, the first positioning seat is provided with a jack, the corresponding other end of the connecting arm is detachably and relatively fixedly inserted in the jack, the first positioning seat is in sliding connection with the first base, the first positioning screw rod is rotationally connected with the first base, and the first positioning screw rod is in threaded connection with the first positioning seat.

Compared with the prior art, the invention has the beneficial effects that: the radiator manufacturing device comprises a radiator base plate, a slot inserting device, a slot picking mechanism, a riveting mechanism, a slot inserting device and a slot cutter, wherein the slot picking mechanism is provided with a slot cutter used for processing and forming a clamping slot on the radiator base plate, the slot picking mechanism is provided with a slot holder used for inserting a radiating fin into the clamping slot of the radiator base plate, the riveting mechanism is provided with a slot extruding device used for deforming and clamping the radiating fin of the radiator base plate, the station feeding mechanism is provided with a slot station feeding mechanism used for feeding a slot inserting device, the slot inserting device is provided with a slot separating mechanism used for moving the slot inserting device away from a working position and feeding the slot inserting device into the working position, the slot cutter is arranged at a position in front of the slot cutter along the feeding direction of the station feeding mechanism, and the slot extruding device is arranged at a position in front of the slot cutter along the feeding direction of the station feeding mechanism.

Drawings

Fig. 1 is a schematic perspective view of a radiator manufacturing apparatus according to the present invention.

Fig. 2 is a schematic top view of a radiator manufacturing apparatus according to the present invention.

Fig. 3 is a schematic front view of the slot-inserting device of the present invention.

Fig. 4 is a schematic view of A-A cut-away perspective of fig. 3.

Fig. 5 is a schematic view of a partial structure at B of fig. 4.

Fig. 6 is a schematic left-hand view of the slot-and-tab apparatus of the present invention.

Fig. 7 is a schematic rear view of a slot-and-tab apparatus of the present invention.

Fig. 8 is a schematic cross-sectional view of the saw blade spindle of the present invention.

Fig. 9 is a schematic perspective view of a combined rear view of a slot cutting tool and blade receiving cavity according to the present invention.

Fig. 10 is a schematic perspective view of an exhaust connection pipe according to the present invention.

Fig. 11 is a schematic perspective view of a rear view of the film pick-up mechanism of the present invention.

Fig. 12 is a schematic rear view of a film pick-up mechanism according to the present invention.

Fig. 13 is a schematic view of the C-C cross-sectional structure of fig. 12.

Fig. 14 is a schematic perspective view of the front view of the film pick-up mechanism of the present invention.

Fig. 15 is a schematic left-hand structural view of the riveting mechanism of the present invention.

Fig. 16 is an exploded view of the riveting mechanism of the present invention.

Fig. 17 is a schematic perspective view of a station feed mechanism of the present invention.

Fig. 18 is a schematic rear view of the station feed mechanism of the present invention.

Fig. 19 is a schematic view of the D-D cross-sectional structure of fig. 18.

Fig. 20 is a schematic perspective view of a slot-and-tab feeding mechanism of the present invention.

Fig. 21 is a schematic right-side view of a slot-and-tab feeding mechanism of the present invention.

Fig. 22 is a schematic perspective view of the dislocation mechanism of the present invention.

Fig. 23 is a schematic perspective view of a loading device according to the present invention.

Fig. 24 is a schematic right-view structural diagram of a feeding device according to the present invention.

FIG. 25 is a schematic view of a pinch roller mechanism of the present invention in a left-view perspective.

Fig. 26 is a schematic view of the partial structure at E of fig. 25.

FIG. 27 is a schematic view of a partial top view of the puck mechanism of the present invention.

Fig. 28 is a schematic perspective view of a shutter mechanism according to the present invention.

Fig. 29 is a schematic diagram showing a state of the grooving tool according to the present invention in the front view of the clamping groove of the radiator substrate.

Fig. 30 is a schematic diagram showing a state in front view of a heat sink inserted into a clip groove of a heat sink base plate by a holder according to the present invention.

Fig. 31 is a schematic diagram showing a state in which a heat sink base plate and a positioning roller are pressed against the top of a heat sink by a slot extruder according to the present invention.

Fig. 32 is a schematic diagram showing the state in which the heat sink is relatively slid in the positioning guide groove of the present invention and the positioning roller is pressed against the top of the heat sink in the left-hand direction.

Fig. 33 is a schematic diagram showing a state in which the groove pressing machine of the present invention machines a left-hand view direction in which a radiator base plate and a positioning roller are pressed against a top of a fin.

Fig. 34 is a schematic structural diagram of a heat sink.

Description of the reference numerals: 1-a slot-and-tab device; 101-a box base; 11-a slotting mechanism; 111-saw blade spindle; 1111-a grooving tool; 1112-a support plate; 1113-platen; 1114-locking ram; 1115-a spindle; 112-a saw blade motor; 113-a drive belt; 12-a film picking mechanism; 121-a film holder; 1211-suction opening; 1212-flow channels; 1213-supporting the bumps; 1214-venting lumen; 1215-an inhalation connection tube; 122-connecting a support plate; 123-a first linear bearing; 124-a first optical axis; 125-a first cylinder mount; 126-first cylinder; 13-riveting mechanism; 131-a slot extruder; 132-a connecting arm; 133-a first positioning seat; 1331-jack; 134-a first base; 135-a first positioning screw; 136-a first hand wheel; 14-a pinch roller mechanism; 141-positioning the pinch roller; 142-floating mount; 143-a first spring; 144-a second positioning seat; 145-a second base; 146-a second positioning screw; 147-positioning guide grooves; 1471-a first guide tab; 1472-a second guide tab; 148-a second linear bearing; 15-a dust collection structure; 151-a saw blade receiving cavity; 152-saw blade cover plate; 153-air draft connecting pipe; 2-a feeding device; 21-retaining wall; 22-pushing plate; 221-a slide bar; 23-supporting the rod; 24-pressing plates; 25-a second cylinder; 26-a feeding base; 27-a feeding spring; 3-station feeding mechanism; 31-a workbench; 32-a base; 33-a first linear guide pair; 34-ball screw pair; 341-ball screw; 342-ball nut; 35-a first servo motor; 4-slot insert feeding mechanism; 41-a cross beam; 42-connecting seats; 43-a second linear guide pair; 44-racks; 45-gear; 46-a second servo motor; 5-a dislocation mechanism; 51-off-position cylinder; 52-unseating the cylinder block; 53-a third linear guide pair; 54-connecting blocks; 6-a baffle mechanism; 61-fin stopper; 62-positioning connection plates; 63-a third positioning seat; 64-a third base; 65-a third positioning screw; 7-stand columns; 8, a control box; 98-a heat sink substrate; 99-heat sink.

Detailed Description

The invention is further described below with reference to the accompanying drawings.

The radiator manufacturing apparatus of the present invention, as shown in fig. 1 and 2, includes a slot and insert device 1, and as shown in fig. 3, the slot and insert device 1 is provided with a slot mechanism 11, a pick-up mechanism 12 and a riveting mechanism 13. As shown in fig. 3 to 7, the grooving mechanism 11 is provided with a grooving tool 1111 for forming a clamping groove in the radiator base 98, the grooving tool 1111 may be a machining tool for forming a groove-like structure in the prior art such as an end mill, a planer tool or a broach, and the grooving mechanism 11 is provided with a driving structure corresponding to the type of the grooving tool 1111. The pick-up mechanism 12 is provided with a holder 121 for inserting the heat sink 99 into the clamping groove of the heat sink substrate 98, and in order to achieve the effect that the heat sink 99 and the holder 121 can be relatively fixed and separated, the holder 121 may be a clamping structure driven by a cylinder, and if the heat sink 99 is a carbon steel sheet, the holder 121 may be correspondingly provided as an electromagnet structure. The caulking mechanism 13 is provided with a groove squeezing device 131 for deforming the clamping groove of the radiator base plate 98 to clamp and fix the radiator fin 99, the groove squeezing device 131 can be a wheel with a cutting edge or a rod with a cutting edge, and the groove squeezing device 131 has the function of squeezing the radiator base plate 98 beside the clamping groove of the radiator base plate 98 in which the radiator fin 99 is already hidden, so that the clamping groove of the radiator base plate 98 is plastically deformed and narrowed toward the radiator fin 99 to clamp and fix the radiator fin 99 and form good contact.

As shown in fig. 1 and 2, the radiator manufacturing apparatus of the present invention further includes a station feed mechanism 3 for feeding the grooving station of the radiator substrate 98. As shown in fig. 34, a plurality of cooling fins 99 are inserted into one cooling fin 98, so after the cooling fin 98 is processed into one clamping groove and one cooling fin 99 is inserted, the cooling fin 98 and the slot-inserting device 1 are relatively moved to the position corresponding to the next clamping groove, wherein in the embodiment shown in fig. 1 and 2, the cooling fin 98 is connected with the station feeding mechanism 3, that is, the cooling fin 98 can be actively moved to the next processing station. In an embodiment, the heat sink substrate 98 may be fixed, and the station feeding mechanism 3 is configured to drive the slot-inserting device 1 to perform station feeding switching (note that, the corresponding structure of this embodiment is not shown in the drawings), for example, the upright post 7 in fig. 1 may be configured to be driven by the station feeding mechanism 3 to move back and forth. Fig. 17, 18 and 19 show an embodiment of the station feeding mechanism 3, the station feeding mechanism 3 includes a workbench 31, a base 32, a first linear guide pair 33, a ball screw pair 34 and a first servo motor 35, the base 32 can be placed on the ground, the workbench 31 is disposed on the upper side of the base 32, the workbench 31 and the base 32 are in linear sliding connection through the first linear guide pair 33, two ends of a ball screw 341 of the ball screw pair 34 are rotationally connected with the base 32, a ball nut 342 of the ball screw pair 34 is relatively and fixedly connected with the bottom of the workbench 31, the first servo motor 35 is connected with the end of the ball screw 341 through a coupler, so that the first servo motor 35 can drive the ball screw 341 to rotate, the ball nut 342 can drive the workbench 31 to translate, the extending direction of the guide rail of the first linear guide pair 33 is parallel to the feeding direction of the grooving station of the radiator base 98, and in fig. 1, the workbench 31 can move back and forth. As shown in fig. 2, the table 31 is used for fixing the radiator substrate 98, and a jig for fixing a plate-like workpiece of the prior art such as a flat tongs may be attached to the table 31 in order to facilitate fixing the radiator substrate 98.

As shown in fig. 1,2 and 20, the radiator manufacturing apparatus of the present invention further includes a slot and insert feeding mechanism 4 for feeding the slot and insert device 1, in other words, the slot and insert feeding mechanism 4 is used for feeding the slot cutter 1111 to process the radiator substrate 98, the slot and insert feeding mechanism 4 is used for driving the holder 121 to insert the radiator fin 99 into the clip groove formed by the slot cutter 1111, and the slot and insert feeding mechanism 4 is also used for feeding the slot extruder 131 to process the radiator substrate 98. Fig. 20 and 21 show an embodiment of the slot-and-insert feeding mechanism 4, the slot-and-insert feeding mechanism 4 includes a cross beam 41, a connecting seat 42, a second linear guide pair 43, a rack 44, a gear 45 and a second servo motor 46, the cross beam 41 is fixedly connected with the upper ends of the two upright posts 7, the upright posts 7 and the cross beam 41 form a gantry structure, a large-sized radiator workpiece (a combination of a radiator base 98 and a radiator fin 99) on the workbench 31 is facilitated to pass through, the cross beam 41 and the connecting seat 42 are in linear sliding connection through the second linear guide pair 43, the extending arrangement direction of the guide rails of the second linear guide pair 43 is parallel to the feeding direction of the slot-and-insert device 1, in fig. 1, the connecting seat 42 can move left and right, as shown in fig. 21, the top of the cross beam 41 is fixedly provided with the rack 44, the connecting seat 42 is fixedly provided with the second servo motor 46 relatively, the second servo motor 46 is connected with the gear 45 in a driving manner, and the gear 45 is meshed with the rack 44, and the second servo motor 46 can drive the connecting seat 42 to move left and right through the gear 45.

As shown in fig. 1 and 2, the radiator manufacturing apparatus of the present invention further includes a dislocating mechanism 5 for moving the slot-inserting device 1 away from the operating position and into the operating position, and when the radiator manufacturing apparatus of the present invention is configured to process the upper portion of the horizontally placed radiator substrate 98 with the slot and insert the heat sink 99, the dislocating mechanism 5 is configured to move up and down. To simplify the structure, the dislocating mechanism 5 is connected with the slot inserting sheet feeding mechanism 4, fig. 22 shows an embodiment of the dislocating mechanism 5, the dislocating mechanism 5 comprises an dislocating cylinder 51, an dislocating cylinder seat 52, a third linear guide pair 53 and a connecting block 54, as shown in fig. 20 and 21, the dislocating cylinder seat 52 is fixedly connected with the connecting seat 42 of the slot inserting sheet feeding mechanism 4 relatively, the dislocating cylinder 51 is arranged on the dislocating cylinder seat 52, the slot inserting sheet device 1 comprises a box seat 101, the box seat 101 is in linear sliding connection with the connecting seat 42 through the third linear guide pair 53, the guide rail of the third linear guide pair 53 is arranged along the up-down direction, the connecting block 54 is fixedly arranged on the rear side surface of the box seat 101 relatively, the connecting block 54 is fixedly connected with the piston rod of the dislocating cylinder 51 relatively, then the dislocating cylinder 51 can drive the slot inserting sheet device 1 to move up and down, and the second servo motor 46 can drive the slot inserting sheet device 1 to move left and right.

The station feeding mechanism 3, the slot inserting sheet feeding mechanism 4 and the off-position mechanism 5 are mainly used for realizing the shifting function, and the structure capable of realizing the shifting function in the prior art is not limited to the specific structural form shown in the drawings.

In the embodiment schematically illustrated in fig. 1 and 2, the feeding direction of the station feeding mechanism 3 is front to back, and the feeding direction of the slot blade feeding mechanism 4 is right to left, as shown in fig. 7, the slot cutter 1111 is provided at a front corresponding position of the blade holder 121 along the feeding direction of the slot blade feeding mechanism 4, and since fig. 7 is a rear view, the arrow direction in fig. 7 represents the feeding direction of the slot blade device 1. The slot extruder 131 is disposed at a position forward of the slot cutter 1111 in the feeding direction of the station feeding mechanism 3, and fig. 33 schematically shows the relative positional relationship of the slot cutter 1111 and the slot extruder 131, and since fig. 33 is a left side view, the arrow direction in fig. 33 represents the feeding direction of the station feeding mechanism 3.

The working principle of the radiator manufacturing apparatus of the present invention is briefly described as follows: as shown in fig. 29, the fin holder 121 fixes the fin 99 and the slot-inserting device 1 relatively, the slot-inserting feeding mechanism 4 drives the slot-inserting device 1 to move leftwards, the slot cutter 1111 processes the slot on the radiator base plate 98 to form a clamping slot, as shown in fig. 30, the slot cutter 1111 extends leftwards beyond the radiator base plate 98 after finishing the slot processing, in the process, the fin holder 121 inserts the fin 99 into the clamping slot of the radiator base plate 98, then the fin holder 121 releases the fin 99, the dislocating mechanism 5 lifts the slot-inserting device 1, Raising the slot die insert device 1 higher than the top ends of the heat sink fins 99 inserted into the radiator base plate 98 so as to avoid the slot die insert device 1 from colliding with the heat sink fins 99 inserted into the radiator base plate 98, then moving and resetting the slot die insert feeding mechanism 4 rightward, completing the rightwards resetting of the slot die insert feeding mechanism 4, lowering and resetting the slot die insert device 1 by the dislocating mechanism 5, moving the radiator base plate 98 backward to the position corresponding to the next station by the station feeding mechanism 3, simultaneously, fixing the second heat sink fins 99 and the slot die insert device 1 by the chip holder 121, moving and feeding the slot die insert feeding mechanism 4 leftward again as shown in fig. 31, As shown in fig. 33, since the slot extruder 131 is disposed at a position in front of the slot cutter 1111 in the feeding direction of the station feeding mechanism 3, then during the leftward movement of the slot cutter 1111 for feeding, the slot extruder 131 extrudes the radiator substrate 98 beside the clamping slot of the radiator substrate 98 in which the radiator substrate 99 has been hidden, so that the clamping slot of the radiator substrate 98 is narrowed down to the plastic deformation of the radiator substrate 99 to clamp the radiator substrate 99 and form a good contact, i.e., the clamping slot of the radiator substrate 98 is fixedly connected with the radiator substrate 99 in a rivet form, the holder 121 inserts the second radiator substrate 99 into the second clamping slot formed by the slot cutter 1111 processing the radiator substrate 98, the dislocating mechanism 5 again lifts the slot-and-tab apparatus 1 and the slot-and-tab feeding mechanism 4 is reset to the right, so that after the cyclic operation, the radiator base 98 and the heat sink 99 constitute a radiator structure as shown in fig. 34. In order to avoid the squeegees 131 from striking the heat sink 99 that has been inserted into the clip grooves of the heat sink base 98, as shown in fig. 30, the distance between the cutting edge of the squeegees 131 and the slotting cutter 1111 in the feeding direction along the station feeding mechanism 3 should be smaller than the pitch of the heat sink 99 in fig. 34. As can be seen from the above, since the radiator substrate 98 and the radiating fins 99 of the radiator manufactured by the radiator manufacturing apparatus of the present invention shown in fig. 34 are connected by riveting, the radiator manufacturing apparatus of the present invention does not need to cut a large amount of material compared with the prior art even if the height dimension of the radiating fins 99 is large, so that the radiator manufacturing apparatus of the present invention can save the material of the radiator, and the efficiency of manufacturing the radiator is high, which is beneficial to greatly reducing the manufacturing cost of the radiator; In addition, three main processes in the working process of the radiator manufacturing equipment of the invention are as follows: the radiator substrate 98 is provided with the clamping grooves, the radiator fins 99 are inserted into the radiator substrate 98 and the groove squeezing device 131 to fix the radiator fins 99 by riveting, and the three actions are realized in the same direction and in the same moving process of the grooving inserting device 1, so that the processing efficiency is high; furthermore, since the heat sink 99 of the heat sink manufactured by the heat sink manufacturing apparatus of the present invention is assembled in a tab type, the surface of the heat sink 99 may remain smooth, whereas the surface of the heat sink may be roughened by cutting directly on an aluminum block to form a heat sink structure in the prior art, and in some high voltage power apparatus application fields, the heat sink needs to be cleaned regularly, and the heat sink 99 having a smooth surface is convenient for blowing dust and sundries on the surface of the heat sink 99 by compressed air.

In some embodiments, the radiator manufacturing apparatus of the present invention further includes a feeding device 2 for feeding the cooling fins 99, the feeding device 2 includes a pushing plate 22 for pushing the stacked cooling fins 99, the holder 121 can be moved to a position corresponding to the pushing plate 22, specifically, as shown in fig. 24, the cooling fins 99 as assembly materials are stacked on the feeding device 2 vertically, and the pushing plate 22 can be driven by a servo motor in combination with a power source such as a screw pair, a cylinder or a spring. When the dislocating mechanism 5 moves down and resets the holder 121, the holder 121 corresponds to the position of the push plate 22, the holder 121 picks up the forefront heat sink 99 (leftmost heat sink 99 in fig. 24) placed on the loading device 2, after the holder 121 picks up the heat sink 99, the slot-and-tab feeding mechanism 4 drives the holder 121 to feed and insert the heat sink 99 into the heat sink substrate 98, and simultaneously, the push plate 22 pushes forward the heat sinks 99 stacked on the loading device 2, so that the holder 121 can pick up the next heat sink 99. By providing the above-mentioned loading device 2, compared with the way of putting the heat sink 99 on the holder 121 by hand, the working efficiency is improved and the labor intensity is reduced.

Further, as shown in fig. 24, the feeding device 2 is provided with a retaining wall 21, the retaining wall 21 and the pushing plate 22 enclose a groove cavity for placing the laminated cooling fins 99, and in fig. 24, the cooling fins 99 as the assembly raw material are vertically laminated and placed in the groove cavity, specifically, the feeding device 2 is provided with supporting rods 23 arranged at intervals, and the cooling fins 99 as the assembly raw material are supported by the supporting rods 23, so that resistance is reduced in the process of sliding the cooling fins 99 leftwards away from the feeding device 2. The feeding device 2 is provided with a feeding spring 27 for pushing the cooling fins 99 along the stacking direction of the cooling fins 99 (specifically, in the visual direction of fig. 24, the stacking direction is the leftward direction), in other words, the feeding spring 27 can push the stacked cooling fins 99 placed on the feeding device 2 at the same time, the feeding spring 27 drives and connects the push plate 22, specifically, four mutually parallel sliding rods 221 are fixedly connected to the rear side surface of the push plate 22 relatively, the sliding rods 221 are adapted to pass through the feeding base 26, the sliding rods 221 can move along the front and rear direction (seen from fig. 24, the sliding rods 221 can move left and right), the feeding spring 27 is sleeved on the sliding rods 221, the feeding spring 27 is arranged between the push plate 22 and the feeding base 26, the elastic force generated by the feeding spring 27 pushes the push plate 22, the feeding base 26 is fixedly connected with the upright post 7, then when the slot inserting sheet feeding mechanism 4 drives the cooling fins 99 placed on the feeding device 2 to move leftwards from the feeding device 2 relatively to the fixed cooling fins 99, the sliding plates 99 are relatively separated from the upright sliding plates 99 relatively to the upright device, the sliding plates 99 are relatively to be clamped to the sliding plates 99 relatively to the upright device, and then the cooling fins 99 are relatively assembled to the elastic device, the cooling fins are clamped by the sliding plate 99 are relatively arranged as a material holding device, and then the cooling fins are relatively clamped by the sliding plate 99, and the cooling fins are relatively arranged on the side of the lifting device, and the lifting device is relatively to be assembled, and the cooling fins are relatively separated, and the cooling fins are relatively separated, and the cooling plate is relatively by the radiator. In this embodiment, the retaining wall 21 and the push plate 22 enclose a groove cavity for placing the cooling fins 99, and the loading spring 27 drives the push plate 22, so that the structure is simple, the manufacturing is convenient, and the cost is low.

Further, as shown in fig. 1,2 and 28, the radiator manufacturing apparatus of the present invention further includes a shutter mechanism 6 for restricting the movement of the radiator 99 in the feeding direction of the slot-and-tab feeding mechanism 4, the shutter mechanism 6 including a radiator block 61 for contacting with the end face of the radiator 99. In the process of inserting the heat sink 99 into the clip groove of the heat sink base 98, as shown in fig. 30, when the left end face of the heat sink 99 is aligned with the left end face of the heat sink base 98, the left end face of the heat sink 99 is in contact with the heat sink stopper 61, so that the heat sink stopper 61 plays a role in restricting the heat sink 99, facilitating alignment of the heat sink 99 with the heat sink base 98 or alignment of the heat sinks 99 with each other, thereby facilitating improvement of the product quality of the heat sink. Specifically, as shown in fig. 28, the baffle mechanism 6 may further include a positioning connection plate 62, a third positioning seat 63, a third base 64, and a third positioning screw 65, wherein the third positioning seat 63 and the fin stopper 61 are respectively connected to the positioning connection plate 62 by bolts, wherein the bolts connected to the fin stopper 61 pass through long holes of the positioning connection plate 62 extending in the front-rear direction, and the bolts connected to the third positioning seat 63 pass through long holes of the positioning connection plate 62 extending in the left-right direction, so that the fin stopper 61 can adjust positions to accommodate manufacturing of heat sinks of different sizes, the third positioning seat 63 is slidably connected to the third base 64 by a dovetail groove structure, the third positioning seat 63 can move up and down relative to the third base 64, the third positioning screw 65 is screwed to the third positioning seat 63, an upper portion of the third positioning screw 65 is rotatably connected to the third base 64, the third base 64 can be fixedly mounted and connected to the stand 7, and the fin stopper 61 can be manufactured by rotating the third positioning screw 65 up and down to accommodate manufacturing of heat sinks of different sizes.

Further, as shown in fig. 1 and 2, the slot-and-tab apparatus 1 is provided with a pinch roller mechanism 14, and the pinch roller mechanism 14 is provided with a positioning pinch roller 141 for applying pressure to the tip of the heat sink 99 to position the heat sink 99 in the clip groove of the heat sink substrate 98 when the slot extruder 131 is in operation. As shown in fig. 31 and 33, when the slot-and-insert feeding mechanism 4 moves leftward and the slot extruder 131 extrudes the radiator substrate 98, the positioning press wheel 141 presses against the top end of the heat sink 99 which has been inserted into the slot of the radiator substrate 98, and the positioning press wheel 141 is driven by the slot-and-insert feeding mechanism 4 to move leftward, thereby avoiding displacement of the heat sink 99 when the slot extruder 131 extrudes the radiator substrate 98, and thus contributing to improvement of the product quality of the radiator. By providing the proper width dimension of the fin stopper 61 in the feeding direction of the station feeding mechanism 3, the fin stopper 61 can block both one fin 99 in the insertion process and an adjacent fin 99 already inserted on the radiator substrate 98, so that the positioning press wheel 141 does not push the fin 99 already inserted on the radiator substrate 98 when moving leftward. specifically, as shown in fig. 25 to 27, the pinch roller mechanism 14 may further include a floating base 142, a first spring 143, a second positioning base 144, a second base 145, a second positioning screw 146, and a positioning guide groove 147, the positioning pinch roller 141 is rotatably connected to the floating base 142, the floating base 142 is slidably connected to the second positioning base 144, the floating base 142 can move up and down relative to the second positioning base 144, the first spring 143 is disposed between the floating base 142 and the second positioning base 144, the first spring 143 can generate a downward force on the floating base 142, the second positioning base 144 is slidably connected to the second base 145 through two second linear bearings 148, The second positioning screw 146 is in screwed connection with the second positioning seat 144, the upper portion of the second positioning screw 146 is rotatably connected with the second base 145, as shown in fig. 1, the second base 145 is fixedly installed and connected with the box seat 101 relatively, specifically, the second base 145 is fixedly installed and connected with the left side surface of the box seat 101 relatively, and the positioning pressing wheel 141 can be disposed in front of the slot extruder 131 along the feeding direction of the slot inserting device 1. Then, the height position of the positioning press wheel 141 can be adjusted to adapt to the cooling fins 99 with different dimensions by rotating the second positioning screw 146, and by arranging the first spring 143, as shown in fig. 30 and 33, when the positioning press wheel 141 presses the top end of the cooling fin 99, the elastic force of the first spring 143 makes the positioning press wheel 141 press the top end of the cooling fin 99 downwards, which is beneficial to ensuring the positioning effect of the cooling fin 99, in addition, when the positioning press wheel 141 moves from right to left to the cooling fin 99, the positioning press wheel 141 can touch the upper right corner of the cooling fin 99, and at this time, the first spring 143 plays a role of buffering. Further, as shown in fig. 27, a positioning guide groove 147 is formed between a first guide plate 1471 of the pressing wheel mechanism 14 and a second guide plate 1472 of the pressing wheel mechanism 14, wherein one end of the second guide plate 1472 is suspended, the other end of the second guide plate 1472 is fixedly connected with the floating seat 142, the first guide plate 1471 is fixedly connected with the floating seat 142, the positioning guide groove 147 is arranged in front of the positioning pressing wheel 141 along the feeding direction of the slot inserting device 1, the positioning guide groove 147 is arranged at the left of the positioning pressing wheel 141 as seen in the visual direction of fig. 1, The positioning guide 147 and the positioning pinch roller 141 may be provided in two sets. as shown in fig. 32, the top ends of the heat sink 99 are inserted into the positioning guide grooves 147 relatively, so that the heat sink 99 is positioned in the front-rear direction, and then the positioning press wheel 141 presses the top ends of the heat sink 99, and an elastic structure is formed by suspending one end of the second guiding piece 1472, so that the heat sink 99 slides into the positioning guide grooves 147 relatively, and the first guiding piece 1471 and the second guiding piece 1472 can clamp the heat sink 99, further preventing the heat sink 99 from shifting.

Further, as shown in fig. 3 to 8, as shown above, the slot-cutting blade device 1 is provided with a box base 101, the box base 101, a slot cutter 1111 is provided as a saw blade, the slot cutting mechanism 11 is provided with a saw blade motor 112, the saw blade motor 112 is mounted on the box base 101, the saw blade motor 112 is in driving connection with the slot cutting cutter 1111, concretely, as shown in fig. 8, the slot cutting mechanism 11 is provided with a saw blade main shaft 111, wherein the saw blade main shaft 111 comprises the saw blade, the saw blade main shaft 111 further comprises a supporting disc 1112, a pressure disc 1113, a locking pressure head 1114 and a rotating shaft 1115, the locking pressure head 1114 is in threaded connection with the rotating shaft 1115, the locking pressure head 1114 generates pressure to enable the pressure disc 1113 and the supporting disc 1112 to clamp and fix the saw blade and the rear end of the rotating shaft 1115 relatively, a shell of the saw blade main shaft 111 is relatively fixedly mounted on the lower part of the box base 101, and the rotating shaft 1115 is connected with the shell of the saw blade main shaft 111 through a bearing. As shown in fig. 6, the front end of the rotation shaft 1115 of the saw blade main shaft 111 is connected to the saw blade motor 112 through a transmission belt 113. By setting the slotting cutter 1111 as a saw blade, the advantage of high efficiency of the saw blade slotting speed is utilized, thereby improving the efficiency of machining the clamping slot of the heat sink substrate 98.

As shown in fig. 7, the saw blades may be provided in three pieces, three saw blades are arranged at intervals along the feeding direction of the slot die insertion device 1, the saw blade main shaft 111 is correspondingly provided in three sets, and the height positions of the three saw blades (i.e., the slot cutting tool 1111 in fig. 7) are gradually raised along the feeding direction of the slot die insertion device 1 (i.e., the arrow direction in fig. 7), so that the three saw blades can progressively cut the radiator substrate 98, thereby slowing down the wear of the saw blades and also being beneficial to improving the cutting efficiency.

Further, as shown in fig. 3 to 5, the slot-cutting blade device 1 is provided with a dust-absorbing structure 15, the dust-absorbing structure 15 includes a blade accommodating cavity 151, as shown in fig. 9, a slot cutter 1111 is disposed in the blade accommodating cavity 151, i.e. the blade is disposed in the blade accommodating cavity 151, only the lower part of the blade is exposed in the blade accommodating cavity 151, and it should be noted that, as shown in fig. 5 and 7, a blade cover plate 152 is disposed at the rear side of the blade, and fig. 9 is a view after the blade cover plate 152 is removed. The box base 101 is provided with an air suction connecting pipe 153, fig. 10 shows the appearance of the air suction connecting pipe 153, as shown in fig. 5, the air suction connecting pipe 153 is communicated with the saw blade accommodating cavity 151, the air suction connecting pipe 153 is used for connecting an air suction inlet of a high-pressure fan which is independently arranged outside, and metal dust generated by cutting the radiator substrate 98 by the saw blade can be sucked away by the high-pressure fan, so that excessive accumulation of the metal dust between the radiator substrate 98 and the radiating fins 99 is avoided. By arranging the air draft connecting pipe 153, the radiator manufacturing equipment is convenient to connect with the high-pressure fan.

Further, as shown in fig. 11 to 14, the wafer holder 121 is provided as a suction cup, that is, the wafer holder 121 is provided to hold the heat sink 99 by suction force generated by negative pressure air, and the wafer pick-up mechanism 12 is provided with a first cylinder 126, and the first cylinder 126 is drivingly connected to the wafer holder 121. When the tab holder 121 is moved to a position corresponding to the push plate 22 by the combination of the slit tab feeding mechanism 4 and the dislocating mechanism, the tab holder 121 is moved backward to erect and stack the heat sink 99 placed on the loading device 2 by the first cylinder 126, then the tab holder 121 sucks the heat sink 99, after the tab holder 121 is relatively fixed to the sucked heat sink 99, the slit tab feeding mechanism 4 moves leftward to move the heat sink 99 away from the loading device 2, then the first cylinder 126 is reset, and the slit tab feeding mechanism 4 moves leftward to insert the heat sink 99 into the heat sink substrate 98. more specifically, the pick-up mechanism 12 further includes a connection support plate 122, a first linear bearing 123, a first optical axis 124, a first cylinder support 125 and a first cylinder 126, as shown in fig. 3, where the first linear bearing 123 is fixedly mounted on and connected with the bottom surface of the box base 101, the two first optical axes 124 are parallel to each other, the two first optical axes 124 are slidably connected with the first linear bearing 123, the rear end of the first optical axis 124 is fixedly connected with the connection support plate 122, the wafer holder 121 is fixedly mounted on the rear side surface of the connection support plate 122, the first cylinder support 125 is fixedly mounted on and connected with the bottom surface of the box base 101, As shown in fig. 14, the first cylinder 126 is mounted on the first cylinder support 125, a piston rod of the first cylinder 126 is relatively and fixedly connected with the connection support plate 122, as shown in fig. 12, the shape of the sheet holder 121 is rectangular, which is favorable for adapting to the shape of the heat sink 99, as shown in fig. 13, a ventilation cavity 1214 is formed inside the sheet holder 121, a suction port 1211 is formed on the rear side of the sheet holder 121, as shown in fig. 13 and 14, a suction connection pipe 1215 is provided on the front side of the sheet holder 121, both the suction connection pipe 1215 and the suction port 1211 are communicated with the ventilation cavity 1214, a support bump 1213 is formed on the front side of the sheet holder 121, The supporting projections 1213 are arranged in a rectangular array, air flow passages 1212 are formed between the supporting projections 1213, the air flow passages 1212 are communicated with the suction openings 1211, the suction connecting pipes 1215 are used for connecting an external independently configured vacuum pump, the supporting projections 1213 are abutted against the heat sink 99 when the heat sink 99 is sucked by the holder 121, the air flow passages 1212 are favorable for increasing the effective holding area, the suction openings 1211 in fig. 12 are arranged at intervals for making the holding force uniform, the number of the suction openings 1211 can be set to six, and the ventilation cavities 1214 are favorable for communicating the respective suction openings 1211. in order to make the above-mentioned chip holder 121 effectively hold the relatively fixed heat sink 99, as shown in fig. 23 and 24, the feeding device 2 is further provided with a pressing plate 24 and a second cylinder 25, the second cylinder 25 is fixedly mounted with the feeding base 26, a piston rod of the second cylinder 25 is fixedly connected with the rear side surface of the pressing plate 24, the front side surface of the pressing plate 24 can be in abutting connection with the rear side surface of the push plate 22, so that when the first cylinder 126 of the chip picking mechanism 12 moves the chip holder 121 backward towards the heat sink 99 placed on the feeding device 2, and the rear side surface of the chip holder 121 contacts with the heat sink 99, the second cylinder 25 presses the pressing plate 24 against the rear side surface of the push plate 22, The heat sink 99 is pressed against the rear side of the holder 121 in a forward driving manner, so that the holder 121 can hold the heat sink 99 relatively fixed, the second cylinder 25 is reset at any time after the heat sink 99 is pressed briefly by the second cylinder 25, and the slot insert feeding mechanism 4 drives the holder 121 to move leftwards.

Further, as shown in fig. 3,7, 15 and 16, the groove squeezing device 131 is a cutter wheel, and as shown in fig. 33, that is, the cutter wheel is a wheel with a cutting edge, the cutting edge of the cutter wheel is used for rolling and forming pits on the upper side surface of the radiator base plate 98, then the cutting edge of the cutter wheel is arranged on the material of the radiator base plate 98, the clamping groove of the radiator base plate 98 is plastically deformed and narrowed to clamp the radiating fin 99, in order to ensure the effect of the clamping groove of the radiator base plate 98 to be plastically deformed and narrowed, the included angle of the cutting edge section of the cutter wheel is preferably 35 ° to 40 °, and in order to reduce the impact load, the cutting edge of the cutter wheel is preferably arranged in a whole circle, by setting the groove squeezing device 131 as the cutter wheel, the structure is simple, the groove squeezing device 131 is easy to manufacture, scraps are not easy to form when the radiator base plate 98 is processed, and the resistance to be applied to the groove squeezing device 131 is small.

Further, as shown in fig. 15 and 16, the riveting mechanism 13 is provided with a connecting arm 132, a first positioning seat 133, a first base 134, and a first positioning screw 135 for adjusting the processing depth of the groove squeezing device 131, and the groove squeezing device 131 is rotatably connected to one end of the connecting arm 132 through a bearing; the first positioning seat 133 is formed with an insertion hole 1331, the other end corresponding to the connecting arm 132 is detachably and relatively fixedly inserted into the insertion hole 1331, specifically, the first positioning seat 133 is formed by connecting two parts through four screws, the upper part of the connecting arm 132 with a rectangular cross section is adaptively inserted into the rectangular insertion hole 1331, the end part of the connecting arm 132 is clamped and relatively fixed through the four screws, then after the four screws are loosened, the groove squeezing device 131 can move in the front-back direction to adjust the position so as to adapt to the distance between the radiating fins 99 on the radiator base plate 98, the first positioning seat 133 is slidably connected with the first base 134 through a dovetail groove structure, the first positioning screw 135 is rotationally connected with the first base 134, the first positioning screw 135 is in threaded connection with the first positioning seat 133, and then the relative position between the groove squeezing device 131 and the radiator base plate 98 in the upper-lower direction can be adjusted by rotating the first positioning screw 135, namely the processing depth of the groove squeezing device 131 can be adjusted. As shown in fig. 15, the upper end of the first positioning screw 135 may be relatively fixedly connected with a first hand wheel 136, so as to facilitate rotation of the first positioning screw 135.

As shown in fig. 1, the radiator manufacturing apparatus of the present invention further includes a control box 8, the control box 8 being connected to the top of the cross beam 41 through a pipe which is rotatably connected to the cross beam 41, i.e., the control box 8 is swingable in a horizontal plane, thereby facilitating the operation.

Claims (7)

1. A grooving inserting plate type radiator manufacturing device is characterized in that: the radiator comprises a grooving inserting device (1), wherein the grooving inserting device (1) is provided with a grooving mechanism (11), a piece picking mechanism (12) and a riveting mechanism (13), the grooving mechanism (11) is provided with a grooving cutter (1111) for forming a clamping groove on a radiator substrate (98), the piece picking mechanism (12) is provided with a piece holder (121) for inserting a radiating piece (99) into the clamping groove of the radiator substrate (98), and the riveting mechanism (13) is provided with a groove squeezing device (131) for deforming the clamping groove of the radiator substrate (98) to clamp and fix the radiating piece (99);

the heat radiator comprises a heat radiator substrate (98) and a station feeding mechanism (3) for feeding a grooving station of the heat radiator substrate, wherein the feeding direction of the station feeding mechanism (3) is from front to back;

the device further comprises a grooving insert feeding mechanism (4) for feeding the grooving insert device (1) and the groove extruder (131), wherein the feeding direction of the grooving insert feeding mechanism (4) is from right to left;

The automatic cutting and inserting device also comprises a dislocation mechanism (5) for moving the cutting and inserting device (1) away from the working position and sending the cutting and inserting device into the working position, wherein the dislocation mechanism (5) is arranged to move up and down;

The grooving cutter (1111) is arranged at a corresponding position in front of the chip holder (121) along the feeding direction of the grooving insert feeding mechanism (4), and the slot squeezing device (131) is arranged at a position in front of the grooving cutter (1111) along the feeding direction of the station feeding mechanism (3);

The device further comprises a baffle mechanism (6) for limiting the radiating fins (99) in the feeding direction of the grooving insert feeding mechanism (4), wherein the baffle mechanism (6) comprises radiating fin stoppers (61) for contacting with the end surfaces of the radiating fins (99);

The grooving inserting device (1) is provided with a pressing wheel mechanism (14), and the pressing wheel mechanism (14) is provided with a positioning pressing wheel (141) for applying pressure to the top end of the radiating fin (99) so that the radiating fin (99) is positioned in a clamping groove of the radiator substrate (98) when the groove extruder (131) works; the groove squeezing device (131) is arranged as a cutter wheel.

2. The apparatus for manufacturing a slot-and-insert radiator according to claim 1, wherein: the feeding device (2) is used for feeding the cooling fins (99), the feeding device (2) comprises a pushing plate (22) used for pushing the stacked cooling fins (99), and the fin holder (121) can move to a position corresponding to the pushing plate (22).

3. The apparatus for manufacturing a slot-and-insert radiator according to claim 2, wherein: the feeding device (2) is provided with a retaining wall (21), the retaining wall (21) and the pushing plate (22) enclose a groove cavity for placing laminated cooling fins (99), the feeding device (2) is provided with a feeding spring (27) for pushing the cooling fins (99) along the lamination direction of the cooling fins (99), and the feeding spring (27) is in driving connection with the pushing plate (22).

4. The apparatus for manufacturing a slot-and-insert radiator according to claim 1, wherein: the grooving insert device (1) is provided with a box seat (101), a grooving cutter (1111) is arranged as a saw blade, a grooving mechanism (11) is provided with a saw blade motor (112), the saw blade motor (112) is arranged on the box seat (101), and the saw blade motor (112) is in driving connection with the grooving cutter (1111).

5. The apparatus for manufacturing a slot-and-insert radiator according to claim 4, wherein: the grooving inserting sheet device (1) is provided with a dust collection structure (15), the dust collection structure (15) comprises a saw blade accommodating cavity (151), a grooving cutter (1111) is arranged in the saw blade accommodating cavity (151), an air draft connecting pipe (153) is arranged on the box base (101), and the air draft connecting pipe (153) is communicated with the saw blade accommodating cavity (151).

6. The apparatus for manufacturing a slot-and-insert radiator according to claim 1, wherein: the wafer holder (121) is provided with a sucker, the wafer picking mechanism (12) is provided with a first air cylinder (126), and the first air cylinder (126) is in driving connection with the wafer holder (121).

7. The apparatus for manufacturing a slot-and-insert radiator according to claim 1, wherein: the riveting mechanism (13) is provided with a connecting arm (132), a first positioning seat (133), a first base (134) and a first positioning screw rod (135) for adjusting the machining depth of the groove squeezing device (131), the groove squeezing device (131) is rotationally connected to one end of the connecting arm (132), the first positioning seat (133) is provided with an inserting hole (1331), the corresponding other end of the connecting arm (132) is detachably and fixedly inserted into the inserting hole (1331), the first positioning seat (133) is in sliding connection with the first base (134), the first positioning screw rod (135) is rotationally connected with the first base (134), and the first positioning screw rod (135) is in threaded connection with the first positioning seat (133).