CN211892042U - Hot melt nut embedding device - Google Patents

Abstract

The utility model relates to a hot melt nut embedding device, which relates to the technical field of nut embedding application, and comprises a machine cabinet, a vibration feeder arranged above the machine cabinet for conveying nuts in a vibration mode and a machine head connected with the vibration feeder through an electric heating conduit, wherein a first driving component for driving the machine head to move along the Z-axis direction is arranged on the side wall of the machine head, the bottom of the first driving component is fixedly connected with a fixed seat, the bottom of the fixed seat is provided with a second driving component for driving the machine head to move along the X-axis direction, the bottom of the second driving component is provided with a third driving component for driving the machine head to move along the Y-axis direction, an air duct is arranged under the third driving component, the bottom of the air duct is vertically provided with a plurality of air outlet ducts corresponding to embedding positions, so that after the nut is embedded, a first servo motor drives a workpiece to move under the air outlet duct, and the air outlet, the nut and the plastic workpiece are cooled, so that the nut can be rapidly cooled.

Description

Hot melt nut embedding device

Technical Field

The utility model relates to a nut buries plants application technical field, concretely relates to hot melt nut buries device.

Background

With the requirements of factory labor cost and production efficiency being higher and higher, automatic production is more widely applied, compared with manual assembly, the hot-melt nut embedding device has the advantages of being free from influences of personnel change, proficiency of operators and the like when the nuts are embedded, automatic installation, simple in operation and operation of workers and free from special skilled personnel.

However, the existing hot-melt nut embedding device still has certain defects when in use, the existing nut embedding device can not quickly dissipate heat of the nut after the heated nut is embedded into a workpiece, if the nut can not be quickly cooled down, the high-temperature threads can continuously melt the plastic workpiece, and the position of the nut deviates from the position of the nut during embedding, so that the embedding accuracy is influenced. Therefore, it is necessary to provide a hot-melt nut implanting device for overcoming the disadvantages of the prior art.

Disclosure of Invention

In order to overcome the not enough among the prior art, the utility model discloses a hot melt nut implants device, it can cool off the nut, improves the embedded accuracy nature of nut.

In order to achieve the above object, the utility model discloses a hot melt nut embedding device, which comprises a cabinet, a vibration feeder arranged above the cabinet for conveying the nuts in a vibration mode and a machine head connected with the vibration feeder through an electric heating conduit, wherein a first driving component for driving the machine head to move along the Z-axis direction is arranged on the side wall of the machine head, a fixed seat is fixedly connected with the bottom of the first driving component, a second driving component for driving the machine head to move along the X-axis direction is arranged at the bottom of the fixed seat, a third driving component for driving the machine head to move along the Y-axis direction is arranged at the bottom of the second driving component, a fixed groove is concavely arranged at the top of the cabinet, a workpiece table is connected in a sliding mode inside the fixed groove, a first slide block is convexly arranged at the middle position at the bottom of the workpiece table, a first lead screw penetrates through the middle part of the first slide block, the first slide block is connected with the, a first servo motor is fixed on the rear side wall of the cabinet, and an output shaft of the first servo motor is connected with the end part of the first screw rod.

The bottom of the third driving assembly is provided with an exhaust pipe along the Y-axis direction through a clamping seat, the exhaust pipes are arranged above the fixing grooves in parallel, the bottom of each exhaust pipe is vertically downwards provided with a plurality of exhaust pipes corresponding to the embedding positions, and the end parts of the exhaust pipes are connected with an air pump through air guide pipes.

Preferably, the first driving assembly, the second driving assembly and the third driving assembly comprise a second servo motor, a second screw rod connected with the second servo motor and a second sliding block screwed with the second screw rod through threads, wherein the first driving assembly is arranged along the Z-axis direction, the second driving assembly is arranged along the X-axis direction, and the third driving assembly is arranged along the Y-axis direction.

Preferably, the top of work piece platform is concave to be established and is used for placing the rectangle standing groove of work piece, and the equal protruding guide rail that is bar structure of establishing of the left and right sides wall of work piece platform, the equal concave spout of establishing of two inside walls about the fixed slot, the guide rail block slides in the spout and along the spout.

Preferably, the clamping seats are arranged at two ends of the bottom of the third driving assembly, the clamping grooves in the arc-shaped structures are arranged at the bottom of the clamping seats, and two ends of the exhaust pipe are clamped in the two clamping grooves respectively.

Preferably, two baffles are symmetrically arranged at two ends of the top of the cabinet, a plurality of fixing frames are connected between the tops of the two baffles, the vibration feeder is arranged in the middle of each fixing frame, and two ends of the third driving assembly are respectively fixedly connected with the two baffles.

The utility model discloses following beneficial effect has:

the air guide pipe is arranged right below the third driving assembly, and the bottom of the air guide pipe is vertically provided with a plurality of air outlet pipes corresponding to the embedding positions, so that after the nut is embedded, the first servo motor drives the workpiece to move right below the air outlet pipes, the air outlet pipes lead air in the air outlet pipes to blow the embedding positions, the nut and the plastic workpiece are cooled, the nut can be rapidly cooled down and the position is fixed, and the embedding accuracy is improved.

Drawings

The invention will be further described and illustrated with reference to the accompanying drawings.

Fig. 1 is a schematic view of the overall structure of a hot-melt nut implanting device.

Fig. 2 is a side view of the table and exhaust stack assembly of the hot-melt nut implanting apparatus of fig. 1.

Fig. 3 is a schematic view of the mounting structure of the clamping seat and the exhaust pipe of the hot-melt nut embedding device in fig. 1.

Reference numerals: 1. a cabinet; 2. a vibration feeder; 3. an electrically heated conduit; 4. a machine head; 5. a first drive assembly; 6. a fixed seat; 7. a second drive assembly; 8. a third drive assembly; 9. a baffle plate; 10. a fixed mount; 11. fixing grooves; 12. a workpiece stage; 13. a guide rail; 14. a chute; 15. a first slider; 16. a first lead screw; 17. a first servo motor; 18. a card holder; 19. an exhaust pipe; 20. an air duct; 21. an air pump; 22. a card slot; 23. and an air outlet pipe.

Detailed Description

The technical solution of the present invention will be more clearly and completely explained by the description of the preferred embodiments of the present invention with reference to the accompanying drawings.

Examples

As shown in figure 1, the hot-melt nut embedding device comprises a cabinet 1, a vibration feeder 2 arranged above the cabinet 1 and used for conveying nuts in a vibration mode and a machine head 4 connected with the vibration feeder 2 through an electric heating conduit 3, a first driving assembly 5 used for driving the machine head 4 to move along the Z-axis direction is installed on the side wall of the machine head 4, a fixed seat 6 is fixedly connected to the bottom of the first driving assembly 5, a second driving assembly 7 used for driving the machine head 4 to move along the X-axis direction is arranged at the bottom of the fixed seat 6, a third driving assembly 8 used for driving the machine head 4 to move along the Y-axis direction is arranged at the bottom of the second driving assembly 7, the vibration feeder 2 sequentially feeds nuts into the electric heating conduit 3 through vibration, the electric heating conduit 3 preheats the nuts, the preheated nuts enter the machine head 4, clamping assemblies inside the machine head 4 clamp the nuts, and then the nuts are clamped through, The second driving assembly 7 and the third driving assembly 8 adjust the position of the machine head 4, so that the machine head 4 is opposite to the plastic workpiece needing to embed the nut, and then the clamping assembly inside the machine head 4 sequentially embeds the nut into the plastic workpiece.

As shown in fig. 1 and 2, a fixing groove 11 is concavely formed in the top of the cabinet 1, a workpiece table 12 is slidably connected to the inner side of the fixing groove 11, a first slider 15 is convexly arranged at the middle position of the bottom of the workpiece table 12, a first lead screw 16 penetrates through the middle part of the first slider 15, the first slider 15 is screwed with the first lead screw 16 in a threaded manner, two ends of the first lead screw 16 are fixed on the cabinet 1 along the X-axis direction through a bearing, a first servo motor 17 is fixed on the rear side wall of the cabinet 1, an output shaft of the first servo motor 17 is connected with the end part of the first lead screw 16, and the workpiece table 12 is used for placing and fixing plastic workpieces, meanwhile, the first servo motor 17 can drive the first lead screw 16 to rotate, and the first slider 15 on the first lead screw 16 can drive the workpiece table 12 to move along.

As shown in fig. 2 and 3, an exhaust pipe 19 is arranged at the bottom of the third driving assembly 8 along the Y-axis direction through a clamping seat 18, the exhaust pipe 19 is arranged above the fixing groove 11 in parallel, a plurality of air outlet pipes 23 corresponding to the embedding positions are vertically arranged at the bottom of the exhaust pipe 19 downwards, the end part of the exhaust pipe 19 is connected with an air pump 21 through air guide pipes 20, the air pump 21 can pump air outside the cabinet 1 and enter the exhaust pipe 19 through the air guide pipes 20, and the air outlet pipes 23 at the bottom of the exhaust pipe 19 are arranged to the embedding positions of the nuts, so that the nuts and the plastic workpieces can be rapidly cooled down.

As a technical optimization scheme of the utility model, first drive assembly 5, second drive assembly 7 and third drive assembly 8 all include second servo motor, the second lead screw of being connected with second servo motor and connect the second slider of second lead screw soon through the screw thread, and wherein first drive assembly 5 sets up along Z axle direction, and second drive assembly 7 sets up along X axle direction, and third drive assembly 8 sets up along Y axle direction.

Through adopting above-mentioned technical scheme to can utilize first drive assembly 5 to drive aircraft nose 4 along Z axle direction adjustment position, utilize second drive assembly 7 to drive aircraft nose 4 along X axle direction adjustment position, utilize third drive assembly 8 to drive aircraft nose 4 along Y axle direction adjustment position.

As a technical optimization scheme of the utility model, the concave rectangle standing groove that is used for placing the work piece that establishes in the top of work piece platform 12, the equal protruding guide rail 13 that is bar structure of establishing of the left and right sides wall of work piece platform 12, fixed slot 11 left and right sides both inside walls are all concave establishes spout 14, and guide rail 13 block slides in spout 14 and along spout 14.

By adopting the technical scheme, the guide rail 13 can slide along the sliding groove 14, and the workpiece table 12 can be kept stable when moving.

As a technical optimization scheme of the utility model, cassette 18 sets up the both ends in the 8 bottoms of third drive assembly, and the bottom of cassette 18 sets up the draw-in groove 22 that is convex structure, and blast pipe 19's both ends block respectively in two draw-in grooves 22.

Through adopting above-mentioned technical scheme to can utilize circular arc draw-in groove 22 block fixed blast pipe 19, guarantee that blast pipe 19 can set up along third drive assembly 8 bottom length direction.

As the utility model discloses a technical optimization scheme, the top both ends symmetry of rack 1 sets up two baffles 9, connects a plurality of mounts 10 between two baffles 9 tops, and wherein vibration feeder 2 sets up at the middle part of mount 10, two baffles 9 of the both ends difference fixed connection of third drive assembly 8.

By adopting the technical scheme, the third driving assembly 8 is supported and fixed by the baffle plate 9, and the vibration feeder 2 is fixedly supported by the fixing frame 10.

The working principle of the utility model is that plastic workpieces are placed and fixed on a workpiece table 12 in rows, a nut is fed into an electric heating conduit 3 of a vibration feeding machine 2 in sequence through vibration, the electric heating conduit 3 preheats the nut, the preheated nut enters a machine head 4, the nut is clamped by a clamping component in the machine head 4, then the position of the machine head 4 is adjusted through a first driving component 5, a second driving component 7 and a third driving component 8, so that the machine head 4 is just opposite to the plastic workpiece needing to be embedded with the nut, then the nut is embedded into the plastic workpiece by the clamping component in the machine head 4 in sequence, after all the plastic workpieces in the row are embedded with the nut, a first servo motor 17 drives a first screw rod 16 to rotate, a first slide block 15 on the first screw rod 16 can drive the workpiece table 12 to move along the X-axis negative direction, so that the plastic workpiece embedded with the nut is positioned under an air outlet pipe 23, the air pump 21 pumps air outside the cabinet 1, and the air enters the exhaust pipe 19 through the air duct 20 and is exhausted to the nut embedding position through the air outlet pipe 23 at the bottom of the exhaust pipe 19, so that the nut and the plastic workpiece can be rapidly cooled down.

The above detailed description merely describes the preferred embodiments of the present invention and does not limit the scope of the present invention. Without departing from the design concept and spirit scope of the present invention, the ordinary skilled in the art should belong to the protection scope of the present invention according to the present invention provides the text description and drawings to the various modifications, replacements and improvements made by the technical solution of the present invention. The scope of protection of the present invention is determined by the claims.

Claims (5)

1. The utility model provides a hot melt nut device of burying, includes the rack, sets up the vibration feeder of conveying the nut in rack top vibration and the aircraft nose of being connected with the vibration feeder through the electric heat pipe, the first drive assembly that the lateral wall installation drive aircraft nose of aircraft nose removed along Z axle direction, first drive assembly's bottom fixed connection fixing base, the bottom of fixing base sets up the second drive assembly that the drive aircraft nose removed along X axle direction, the bottom of second drive assembly sets up the third drive assembly that the drive aircraft nose removed along Y axle direction, its characterized in that: a fixed groove is concavely arranged at the top of the cabinet, the inner side of the fixed groove is connected with a workpiece table in a sliding manner, a first sliding block is convexly arranged at the middle position of the bottom of the workpiece table, a first lead screw penetrates through the middle part of the first sliding block, the first sliding block is screwed with the first lead screw in a threaded manner, two ends of the first lead screw are fixed on the cabinet along the X-axis direction through a bearing, a first servo motor is fixed on the rear side wall of the cabinet, and an output shaft of the first servo motor is connected with the end part of the first lead screw;

the bottom of the third driving assembly is provided with an exhaust pipe along the Y-axis direction through a clamping seat, the exhaust pipes are arranged above the fixing grooves in parallel, the bottom of each exhaust pipe is vertically downwards provided with a plurality of exhaust pipes corresponding to the embedding positions, and the end part of each exhaust pipe is connected with an air pump through an air guide pipe.

2. The hot-melt nut embedding device as claimed in claim 1, wherein: first drive assembly, second drive assembly and third drive assembly all include second servo motor, the second lead screw of being connected with second servo motor and connect the second slider of second lead screw soon through the screw thread, wherein first drive assembly sets up along Z axle direction, second drive assembly sets up along X axle direction, third drive assembly sets up along Y axle direction.

3. The hot-melt nut embedding device as claimed in claim 1, wherein: the top of work piece platform is concave establishes the rectangle standing groove that is used for placing the work piece, the equal protruding guide rail that is bar structure of establishing of the left and right sides wall of work piece platform, the equal concave spout of establishing of two inside walls about the fixed slot, the guide rail block is in the spout and follows the spout slides.

4. The hot-melt nut embedding device as claimed in claim 1, wherein: the clamping seats are arranged at two ends of the bottom of the third driving component, clamping grooves in arc-shaped structures are arranged at the bottom of the clamping seats, and two ends of the exhaust pipe are clamped in the two clamping grooves respectively.

5. The hot-melt nut embedding device as claimed in claim 1, wherein: two baffles are symmetrically arranged at two ends of the top of the cabinet, a plurality of fixing frames are connected between the tops of the baffles, the vibration feeder is arranged in the middle of each fixing frame, and two ends of the third driving assembly are respectively fixedly connected with the two baffles.

Images