CN113714600A - Automatic welding equipment for industrial fan mesh enclosure - Google Patents

Abstract

The invention discloses automatic welding equipment for an industrial fan mesh enclosure, and relates to the technical field of fan spare and accessory part processing. The invention comprises a working bottom plate, a transmission frame and a conveying arm, wherein a conveying rail frame and a supporting table are arranged between the working bottom plate and the conveying arm. According to the invention, the feeding box, the conveying rail frame and the supporting table are arranged, the feeding box, the conveying rail frame and the supporting table are communicated with each other and are sequentially arranged along the same direction, so that raw materials such as spokes or iron wires can be directly conveyed to a welding station, and the track deviation cannot occur in the conveying process; the rotary welding press plate and the plurality of welding grooves on the surface of the rotary welding press plate are arranged, and the gear linkage structure with a fixed radius ratio is arranged, so that the welding groove station switching of the rotary welding press plate can be strictly controlled, the rotary welding press plate and the material placing groove of the support table can accurately correspond to each other, and the material conveying accuracy is greatly improved; through setting up electrode bolt and electric welding electrode, can utilize spoke or iron wire whereabouts accurate control weldment work's opportunity to cooperate with foretell transport material process, realize continuous automation work.

Description

Automatic welding equipment for industrial fan mesh enclosure

Technical Field

The invention belongs to the technical field of fan spare and accessory part machining, and particularly relates to automatic welding equipment for an industrial fan mesh enclosure.

Background

The industrial fan is commonly used in the operations of ventilation, heat dissipation, ventilation, temperature reduction and the like in a building site or an industrial factory building, so the application range of the industrial fan is wide; one part of the industrial fan, which can obviously show the product quality in the use process, is a mesh enclosure, and the firmness degree of the mesh enclosure of the fan can directly reflect the safety performance of the industrial fan; therefore, the welding processing work of the industrial fan mesh enclosure is relatively important; in the prior art, an automatic welding device special for a fan mesh enclosure has been disclosed, for example, an automatic welding device for an industrial fan mesh enclosure disclosed in the invention patent (CN 111515506A), which mainly comprises an internal transmission linkage structure formed by a plurality of screws and bevel gears, and realizes a process of automatically arranging iron wires by matching a conveying belt with a preset iron wire groove; however, in the technical characteristics, the related transmission linkage structure is complicated, and if an iron wire is conveyed into a corresponding iron wire groove, the error is usually large, the iron wire is easy to deviate from a preset position, so that the welding efficiency is reduced; therefore, in order to improve the problems, an automatic welding device for the industrial fan guard is designed.

Disclosure of Invention

The invention aims to provide automatic welding equipment for an industrial fan mesh enclosure, which solves the problems that the existing welding equipment for the fan mesh enclosure is complicated in structure, large in spoke arrangement or iron wire arrangement error and easy to reduce the welding work efficiency.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to automatic welding equipment for an industrial fan mesh enclosure, which comprises a working bottom plate, a transmission frame and a conveying arm, wherein the working bottom plate is connected with the conveying arm through the transmission frame; a support table is welded on the upper surface of the working bottom plate, a feeding box is bolted on the upper surface of the conveying arm, a conveying rail frame is welded on the lower surface of the conveying arm, and the support table, the feeding box and the conveying rail frame are in corresponding positions; the feeding box is communicated with the conveying rail frame and is arranged above the supporting table; a gap exists between the supporting table and the conveying rail frame, a communicating rotary groove is formed in the transmission frame, and the communicating rotary groove is communicated with the gap; when the welding equipment works, the feeding box receives and cuts the iron wires, and after temporary storage, the iron wires are discharged to the supporting table by the conveying rail frame to participate in welding work;

a clamping shaft is arranged on one surface of the conveying arm, and the clamping shaft is in sliding fit with the conveying arm; the lower end face of the clamping shaft is clamped with a spin welding pressing plate, and the spin welding pressing plate is used for fixing a base steel ring of the clamping mesh enclosure; the rotary welding pressing plate is of a hollow structure, and a plurality of electric welding electrodes are arranged in the rotary welding pressing plate; the peripheral side surface of the spin welding pressing plate is provided with a plurality of welding grooves, and electric welding electrodes extend into the welding grooves; when the welding groove is screwed to a support table for placing the iron wire, the electric welding electrode is started and the iron wire is welded with the steel ring of the base;

a control power supply is arranged in the spin welding pressure plate, and a plurality of welding electrodes are electrically connected with the control power supply; a material placing groove is formed in the upper surface of the support table, two electrode bolts are mounted on the inner surface of the material placing groove, and the two electrode bolts are electrically connected with each other; the electrode bolt is electrically connected with a control power supply; when the iron wire is conveyed to the support table, the two electrode bolts are simultaneously contacted with the iron wire to form a conductive path, and the control power supply controls the electrode to start welding.

Preferably, the upper surface of the working bottom plate is connected with a supporting plate in a shaft mode, the supporting plate corresponds to the position of the spin-welding pressing plate in size, and the supporting plate and the spin-welding pressing plate are matched with each other to fix the clamping base steel ring.

Preferably, the rotating shaft of the supporting plate extends to the lower part of the working bottom plate, and a driven gear is welded on the circumferential side surface of the rotating shaft of the supporting plate; the lower surface of the working bottom plate is bolted with a driving motor, a driving gear is welded on the peripheral side face of an output shaft of the driving motor, the driving gear is meshed with a driven gear, the driving motor is used for driving the supporting plate to rotate, and the supporting plate and the rotary welding pressing plate are matched to rotate and weld the steel ring of the base.

Preferably, a tangent cutter head is clamped in the feeding box, and a reset spring is welded between the tangent cutter head and the inner wall of the feeding box; the inner surface of the feeding box is elastically hinged with a supporting plate, and the supporting plate is arranged below the cutting head; the periphery of the feeding box is bolted with a plurality of feeding frames, and a plurality of feeding shafts are connected between the two feeding frames through shafts; feeding cam is welded on the circumferential side of the feeding shaft, protruding teeth of the feeding cam are in contact with the tangent tool bit, and the feeding cam can be used for extruding the tangent tool bit to cut off an iron wire conveyed to the feeding box in a rotating mode.

Preferably, a transmission gear is welded on one end face of the feeding shaft, and the two transmission gears are meshed with each other; the upper surface of the transmission frame is in shaft connection with a worm, and the worm is meshed with the transmission gear; the upper surface of the working bottom plate is in shaft connection with a linkage shaft, and the linkage shaft and the worm are in meshed linkage through the arrangement of clamping teeth; one end of the linkage shaft extends to the lower part of the working bottom plate; the linkage gear is connected to the lower surface of the working bottom plate in a shaft coupling mode, a linkage belt is installed between a rotary shaft of the linkage gear and the linkage shaft, the linkage gear is meshed with the driving gear, and the driving motor can be synchronously utilized to drive the cutting line to work periodically.

Preferably, the driving gear is subjected to semicircular tooth punching, and simultaneously, each time the driving gear rotates for one circle, the rotary welding pressing plate rotates for one welding groove station, the semicircular tooth punching gear structure can ensure that the linkage gear is in an idle running state and the tangent line work stops when the linkage gear is meshed with the driven gear to rotate; on the contrary, when the tangent line work is carried out, the rotary welding pressure plate stops rotating to start the welding work; the lower surface of the rotary welding pressure plate is as high as the communicating rotary groove, and the rotary welding pressure plate can rotate to the next station after welding one spoke.

Preferably, the upper surface of the conveying arm is clamped with an adjusting cap, and a screw structure is formed between the adjusting cap and the clamping shaft by arranging threads; the control power supply, the electrode bolt and the driving motor are electrically connected with each other.

The invention has the following beneficial effects:

according to the invention, the feeding box, the conveying rail frame and the supporting table are arranged, the feeding box, the conveying rail frame and the supporting table are communicated with each other and are sequentially arranged along the same direction, so that raw materials such as spokes or iron wires can be directly conveyed to a welding station, and the track deviation cannot occur in the conveying process; the rotary welding press plate and the plurality of welding grooves on the surface of the rotary welding press plate are arranged, and the gear linkage structure with a fixed radius ratio is arranged, so that the welding groove station switching of the rotary welding press plate can be strictly controlled, the rotary welding press plate and the material placing groove of the support table can accurately correspond to each other, and the material conveying accuracy is greatly improved;

in addition, through setting up electrode bolt and electrode, can utilize spoke or iron wire whereabouts accurate control welding jobs's opportunity to cooperate with foretell material conveying process, realize continuous automation work.

Of course, it is not necessary for any product in which the invention is practiced to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic view of an overall structure of an automatic welding device for an industrial fan mesh enclosure according to the present invention;

FIG. 2 is a top view of an automatic welding apparatus for an industrial fan guard according to the present invention;

FIG. 3 is a schematic structural view of section A-A in FIG. 2;

FIG. 4 is a partial display view of portion B of FIG. 3;

FIG. 5 is a schematic structural view of section C-C of FIG. 3;

FIG. 6 is a partial view of portion F of FIG. 5;

FIG. 7 is a partial display view of portion G of FIG. 5;

FIG. 8 is a schematic structural view of section D-D in FIG. 3;

FIG. 9 is a partial view of portion H of FIG. 8;

fig. 10 is a schematic structural view of section E-E in fig. 3.

In the drawings, the components represented by the respective reference numerals are listed below:

1. a work base plate; 2. a transmission frame; 3. a transfer arm; 101. a support table; 301. a feeding box; 302. a conveying rail frame; 201. the rotary groove is communicated; 303. a clamping shaft; 304. spin-welding a pressing plate; 3041. an electric welding electrode; 3042. welding a groove; 3043. controlling a power supply; 1011. a material placing groove; 1012. an electrode plug; 102. a support plate; 1021. a driven gear; 103. a drive motor; 1031. a drive gear; 3011. a cutter head for cutting line; 3012. a reset spring; 3013. a support plate; 305. a feeding frame; 3051. a feed shaft; 3052. a feed cam; 3054. a transmission gear; 202. a worm; 104. a linkage shaft; 105. a linkage gear; 106. a linkage belt; 306. and adjusting the cap.

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 derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "upper", "middle", "outer", "inner", and the like, indicate orientations or positional relationships, are used for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the referenced components or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Example 1:

referring to fig. 1-10, the present invention is an automatic welding device for mesh enclosure of industrial fan, including a work bottom plate 1, a transmission frame 2 and a conveying arm 3, wherein the work bottom plate 1 is connected to the conveying arm 3 through the transmission frame 2; the upper surface of the working bottom plate 1 is welded with a support table 101, the upper surface of the conveying arm 3 is bolted with a feeding box 301, the lower surface of the conveying arm is welded with a conveying rail frame 302, and the support table 101, the feeding box 301 and the conveying rail frame 302 correspond in position; the feeding box 301 is communicated with the conveying rail frame 302 and is arranged above the supporting platform 101; a gap exists between the support platform 101 and the conveying rail frame 302, a communicating rotary groove 201 is formed in the transmission frame 2, and the communicating rotary groove 201 is communicated with the gap; when the welding equipment works, the feeding box 301 receives and cuts iron wires, and after temporary storage, the iron wires are discharged to the support table 101 by the conveying rail frame 302 to participate in welding work;

a clamping shaft 303 is arranged on one surface of the conveying arm 3, and the clamping shaft 303 is in sliding fit with the conveying arm 3; the lower end face of the clamping shaft 303 is clamped with a spin welding pressing plate 304, and the spin welding pressing plate 304 is used for fixing a base steel ring of the clamping mesh enclosure; the spin-welding platen 304 is a hollow structure, and a plurality of welding electrodes 3041 are installed inside the spin-welding platen; the circumferential side surface of the spin-welding pressure plate 304 is provided with a plurality of welding grooves 3042, and the electric welding electrode 3041 extends into the welding grooves 3042; when the welding groove 3042 is screwed to the supporting table 101 on which the iron wire is placed, the electric welding electrode 3041 is started and welds the iron wire and the steel ring of the base;

a control power source 3043 is arranged in the spin-welding pressing plate 304, and a plurality of electric welding electrodes 3041 are electrically connected with the control power source 3043; a material placing groove 1011 is formed in the upper surface of the supporting table 101, two electrode pins 1012 are mounted on the inner surface of the material placing groove 1011, and the two electrode pins 1012 are electrically connected with each other; the electrode pins 1012 are electrically connected to a control power source 3043; when the wire is fed onto the supporting platform 101, the two electrode pins 1012 are simultaneously contacted with the wire to form a conductive path, and the control power source 3043 controls the electrode 3041 to start welding.

Example 2:

in order to automatically and continuously carry out the welding work and the material conveying work in the technical scheme, the upper surface of the working bottom plate 1 is connected with the supporting plate 102 in a shaft mode, the positions of the supporting plate 102 and the position of the spin-welding pressing plate 304 correspond, the sizes of the supporting plate 102 and the spin-welding pressing plate 304 are the same, and the supporting plate 102 and the spin-welding pressing plate are matched with each other to be used for fixing and clamping a base steel ring;

preferably, the rotating shaft of the support plate 102 extends to the lower part of the working base plate 1, and the driven gear 1021 is welded on the peripheral side of the rotating shaft of the support plate 102; the lower surface of the working bottom plate 1 is bolted with a driving motor 103, the peripheral side of an output shaft of the driving motor 103 is welded with a driving gear 1031, the driving gear 1031 is meshed with a driven gear 1021, the driving motor 103 is used for driving the supporting plate 102 to rotate, and the supporting plate and the spin-welding pressure plate 304 are clamped and matched to perform spin welding on a base steel ring.

Preferably, a thread cutting head 3011 is clamped in the feeding box 301, and a reset spring 3012 is welded between the thread cutting head 3011 and the inner wall of the feeding box 301; the inner surface of the feeding box 301 is elastically hinged with a supporting plate 3013, and the supporting plate 3013 is arranged below the thread cutting head 3011; the circumferential side surface of the feeding box 301 is bolted with a plurality of feeding racks 305, and a plurality of feeding shafts 3051 are axially connected between the two feeding racks 305; the feeding cam 3052 is welded on the circumferential side surface of the feeding shaft 3051, and convex teeth of the feeding cam 3052 are in contact with the wire cutting head 3011, so that the wire fed into the feeding box 301 can be cut off by rotationally extruding the wire cutting head 3011 through the feeding cam 3052.

Preferably, one end face of the feeding shaft 3051 is welded with a transmission gear 3054, and the two transmission gears 3054 are meshed with each other; the upper surface of the transmission frame 2 is connected with a worm 202 in a shaft mode, and the worm 202 is meshed with a transmission gear 3054; the upper surface of the working bottom plate 1 is coupled with a linkage shaft 104, and the linkage shaft 104 and the worm 202 are meshed and linked with each other through the arrangement of clamping teeth; one end of the linkage shaft 104 extends to the lower part of the working bottom plate 1; the lower surface of the working bottom plate 1 is coupled with a linkage gear 105, a linkage belt 106 is arranged between a rotary shaft of the linkage gear 105 and a linkage shaft 104, the linkage gear 105 is meshed with a driving gear 1031, and the driving motor 103 can be synchronously utilized to drive the cutting line to periodically work.

Preferably, the driving gear 1031 is half-circularly toothed, and at the same time, every time the driving gear 1031 rotates for one circle, the rotary welding pressure plate 304 rotates for one station of the welding groove 3042, and the half-circularly toothed gear structure can ensure that the linkage gear 105 is in an idle rotation state and the tangent line operation is stopped when the linkage gear 105 is meshed with the driven gear 1021 for rotation; on the contrary, when the tangent line work is performed, the spin welding pressure plate 304 stops rotating to start the welding work; the lower surface of the spin-welding pressure plate 304 is the same as the height of the communicating spin slot 201, and after one spoke is welded, the next station can be rotated.

Preferably, the upper surface of the conveying arm 3 is clamped with an adjusting cap 306, and a screw structure is formed between the adjusting cap 306 and the clamping shaft 303 through forming threads; the control power 3043, the electrode pins 1012, and the driving motor 103 are electrically connected to each other.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (9)

1. The utility model provides an industry fan screen panel automatic weld equipment, includes work bottom plate (1), driving frame (2) and delivery arm (3), its characterized in that: the working bottom plate (1) is connected with the conveying arm (3) through a transmission frame (2); the upper surface of the working bottom plate (1) is welded with a support table (101), the upper surface of the conveying arm (3) is bolted with a feeding box (301), the lower surface of the conveying arm is welded with a conveying rail frame (302), and the support table (101), the feeding box (301) and the conveying rail frame (302) correspond in position; the feeding box (301) is communicated with the conveying rail frame (302) and is arranged above the supporting table (101); a gap is formed between the support table (101) and the conveying rail frame (302), a communicating rotary groove (201) is formed in the transmission frame (2), and the communicating rotary groove (201) is communicated with the gap;

a clamping shaft (303) is mounted on one surface of the conveying arm (3), and the clamping shaft (303) is in sliding fit with the conveying arm (3); a spin welding pressing plate (304) is clamped on the lower end face of the clamping shaft (303); the spin welding pressure plate (304) is of a hollow structure, and a plurality of electric welding electrodes (3041) are arranged in the spin welding pressure plate; a plurality of welding grooves (3042) are formed in the peripheral side face of the rotary welding pressing plate (304), and the electric welding electrode (3041) extends into the welding grooves (3042);

a control power supply (3043) is arranged in the spin-welding pressure plate (304), and a plurality of electric welding electrodes (3041) are electrically connected with the control power supply (3043); a material placing groove (1011) is formed in the upper surface of the supporting table (101), two electrode bolts (1012) are mounted on the inner surface of the material placing groove (1011), and the two electrode bolts (1012) are electrically connected with each other; the electrode plug (1012) is electrically connected with a control power supply (3043).

2. The automatic welding equipment for the industrial fan guard is characterized in that a support plate (102) is axially connected to the upper surface of the work base plate (1), the position of the support plate (102) corresponds to that of a spin-welding pressure plate (304), and the support plate and the spin-welding pressure plate are the same in size.

3. The automatic welding equipment for the industrial fan guard is characterized in that the rotating shaft of the supporting plate (102) extends to the lower part of the working bottom plate (1), and the driven gear (1021) is welded on the peripheral side of the rotating shaft of the supporting plate (102); the lower surface of the working bottom plate (1) is connected with a driving motor (103) in a bolted mode, a driving gear (1031) is welded on the peripheral side face of an output shaft of the driving motor (103), and the driving gear (1031) is meshed with a driven gear (1021).

4. The automatic welding equipment for the industrial fan mesh enclosure is characterized in that a wire cutting tool bit (3011) is clamped inside the feeding box (301), and a reset spring (3012) is welded between the wire cutting tool bit (3011) and the inner wall of the feeding box (301); the inner surface of the feeding box (301) is elastically hinged with a supporting plate (3013), and the supporting plate (3013) is arranged below the thread cutting head (3011).

5. The automatic welding equipment for the industrial fan mesh enclosure is characterized in that a plurality of feeding racks (305) are bolted on the peripheral side face of the feeding box (301), and a plurality of feeding shafts (3051) are axially connected between the two feeding racks (305); the side surface of the feeding shaft (3051) is welded with a feeding cam (3052), and convex teeth of the feeding cam (3052) are in contact with a tangent cutter head (3011).

6. The automatic welding equipment for the industrial fan mesh enclosure is characterized in that a transmission gear (3054) is welded on one end face of the feeding shaft (3051), and the two transmission gears (3054) are meshed with each other; the upper surface of the transmission frame (2) is connected with a worm (202) in a shaft mode, and the worm (202) is meshed with the transmission gear (3054).

7. The automatic welding equipment for the industrial fan mesh enclosure is characterized in that a linkage shaft (104) is connected to the upper surface of the working base plate (1) in a shaft mode, and the linkage shaft (104) and the worm (202) are meshed and linked with each other through clamping teeth; one end of the linkage shaft (104) extends to the lower part of the working bottom plate (1); the lower surface of the working bottom plate (1) is connected with a linkage gear (105) in a shaft mode, and a linkage belt (106) is installed between a rotating shaft of the linkage gear (105) and the linkage shaft (104).

8. The industrial fan screen automatic welding apparatus according to claim 7, wherein the linkage gear (105) is engaged with a driving gear (1031); the drive gear (1031) is half-circularly toothed; the lower surface of the spin-welding pressure plate (304) is as high as the communicating spin groove (201).

9. The automatic welding equipment for the industrial fan mesh enclosure is characterized in that an adjusting cap (306) is clamped on the upper surface of the conveying arm (3), and a screw rod structure is formed between the adjusting cap (306) and the clamping shaft (303) through threads; the control power supply (3043), the electrode bolt (1012) and the driving motor (103) are electrically connected with each other.

Images