CN109702120B - Net welding machine - Google Patents

Abstract

The invention discloses a net welding machine, which belongs to the field of welding equipment and comprises a material conveying mechanism and a blanking mechanism, wherein the material conveying mechanism comprises a material conveying space and a turntable knife arranged at a discharge end of the material conveying space, and a plurality of wefts are sequentially distributed in the material conveying space along the radial direction to prevent the wefts from piling up; the rotary table knife is provided with grooves capable of receiving the wefts, and the wefts are removed one by one in the rotation process of the rotary table knife, so that the wefts are further prevented from being piled up; the blanking mechanism is arranged on the discharging side of the rotary table knife and comprises a fixed toothed plate with a plurality of first tooth grooves and a movable toothed plate with a plurality of second tooth grooves, the first tooth grooves receive wefts on the rotary table knife, the movable toothed plate moves to move one weft positioned in the first tooth grooves to the next adjacent one in the first tooth grooves relative to the fixed toothed plate, the plurality of wefts are separated to be blanked one by one, weft stacking is prevented, and continuous blanking is realized.

Description

Net welding machine

Technical Field

The invention relates to the field of welding equipment, in particular to a net welding machine.

Background

The reinforcing mesh is widely used in the fields of bridge construction, high-speed railways, buildings and the like. The mesh welding machine is a device for welding longitudinal steel bars and transverse steel bars together through electrodes to form a mesh of a steel mesh.

Be provided with weft blanking mechanism in the welding machine, weft blanking mechanism's effect is with the fixed length weft that straightens in advance and cut off through rotary drum suction material again through dialling the charging tray rotation with weft and carry the electrode under and weld. Specifically, the weft blanking mechanism comprises an inclined stock bin, transverse ribs with fixed length which are straightened and cut in advance are arranged in the stock bin, the transverse ribs can slide down to the front of a roller with magnets along a slide way, the roller rotates to adsorb the transverse ribs by the magnets to rotate along with the transverse ribs, the transverse ribs are sent to a material shifting disc, the material shifting disc is driven to rotate by a motor, the transverse ribs rotate by a certain angle, and the transverse ribs fall off and slide down to an electrode along a slide bar to be welded.

Be provided with the draw-in groove on the dial and be used for receiving horizontal muscle, but easily appear two horizontal muscle cards in a draw-in groove, arouse the jam for horizontal muscle can not drop smoothly, not only influences blanking speed, leads to the stability of equipment to reduce moreover.

Disclosure of Invention

The invention aims to provide a net welding machine so as to solve the technical problem that a stirring disc is easy to clamp in the prior art.

The technical scheme adopted by the invention is as follows:

a mesh welding machine, comprising:

the material conveying mechanism comprises a material conveying space and a rotary table knife arranged at the discharge end of the material conveying space, a plurality of wefts are sequentially arranged in the material conveying space along the radial direction, and grooves capable of receiving the wefts are formed in the rotary table knife;

the blanking mechanism is arranged on the discharging side of the rotary table knife and comprises a fixed toothed plate with a plurality of first tooth grooves and a movable toothed plate with a plurality of second tooth grooves, wherein the first tooth grooves receive wefts on the rotary table knife, and the movable toothed plate moves relative to the fixed toothed plate to move the wefts in the first tooth grooves to the next adjacent first tooth grooves.

The first tooth grooves comprise a receiving groove at the head end and a plurality of conveying grooves which are sequentially distributed from the head end to the tail end, and the number of the second tooth grooves is equal to that of the conveying grooves.

The movable toothed plate is positioned at the initial position, and the second tooth grooves are communicated with the material conveying grooves in a one-to-one correspondence manner; the movable toothed plate is positioned at the blanking position, and the second tooth slot positioned at the head end is communicated with the material receiving slot.

The movable toothed plate and the fixed toothed plate are provided with a first transmission mechanism, and the first transmission mechanism drives the movable toothed plate to move between the initial position and the blanking position.

The first transmission mechanism is a gear transmission mechanism, the gear transmission mechanism comprises a driving gear which is rotatably arranged on the fixed toothed plate, a first rotating shaft is arranged on the movable toothed plate, and the first rotating shaft is eccentrically connected with the driving gear.

The first transmission mechanism is a cylinder transmission mechanism, and comprises a first cylinder capable of driving the movable toothed plate to move along a first direction and a second cylinder capable of driving the movable toothed plate to move along a second direction, wherein the first direction and the second direction are mutually perpendicular.

And the blanking mechanisms are arranged at intervals along the axial direction of the weft.

The material conveying mechanism further comprises an upper sliding strip and a lower sliding strip, and a material conveying space is formed between the upper sliding strip and the lower sliding strip.

The material conveying mechanism further comprises a turntable cutter shaft, and the turntable cutter is arranged on the turntable cutter shaft.

The rotary table knife comprises a rotary table knife body, wherein a plurality of grooves are formed in the rotary table knife body along the circumferential direction, a positioning block is arranged on one side of the rotary table knife body, the positioning block comprises an arc-shaped positioning surface, and the axis of the positioning surface coincides with the axis of the rotary table knife body.

The invention has the beneficial effects that:

according to the mesh welding machine, a plurality of wefts are sequentially distributed along the radial direction through the material conveying space, so that the wefts are prevented from being piled up; the groove capable of receiving the wefts is formed in the turntable knife, and the wefts are removed one by one in the rotation process of the turntable knife, so that the wefts are further prevented from being piled up; the rotary table knife moves the weft into the first tooth groove of the fixed toothed plate, and moves relative to the fixed toothed plate through the movable toothed plate, so that the second tooth groove is selectively communicated with the first tooth groove, the weft positioned in the first tooth groove is moved into the next adjacent first tooth groove, and the rotary table knife reciprocates in such a way that the weft moves along the plurality of first tooth grooves until the weft is moved to fall off in the first tooth groove at the tail end of the fixed toothed plate by the movable toothed plate, and blanking is realized. The blanking process divides a plurality of wefts to be blanked one by one, prevents the wefts from piling up, realizes continuous blanking, improves the production efficiency and reduces the failure rate.

Drawings

Fig. 1 is a front view of a mesh welding machine according to a first embodiment of the present invention;

FIG. 2 is a side view of a mesh welding machine according to a first embodiment of the present invention;

FIG. 3 is a cross-sectional view taken along the direction A-A of FIG. 2;

fig. 4 is an enlarged view at B of fig. 3;

FIG. 5 is a schematic view of a portion of the structure of FIG. 2;

FIG. 6 is a top view of a mesh welding machine according to a first embodiment of the present invention;

fig. 7 is a schematic structural diagram of a blanking mechanism of a mesh welding machine according to a first embodiment of the present invention;

fig. 8 is a front view of fig. 7;

fig. 9 is a schematic structural diagram II of a blanking mechanism of a mesh welding machine according to the first embodiment of the present invention;

fig. 10 is a schematic diagram of a blanking mechanism of a mesh welding machine in an initial position according to an embodiment of the present invention;

fig. 11 is a schematic diagram of a blanking mechanism of a mesh welding machine in a blanking position according to a first embodiment of the present invention;

fig. 12 is a schematic view of a blanking mechanism of a mesh welding machine according to a first embodiment of the present invention between an initial position and a blanking position;

fig. 13 is a schematic diagram of a blanking mechanism of a mesh welding machine in an initial position according to a second embodiment of the present invention;

fig. 14 is a schematic diagram one of a blanking mechanism of a mesh welding machine provided in the second embodiment of the present invention between an initial position and a blanking position;

fig. 15 is a schematic diagram of a blanking mechanism of a mesh welding machine in a blanking position according to a second embodiment of the present invention;

fig. 16 is a schematic diagram two of a blanking mechanism of a mesh welding machine according to a second embodiment of the present invention between an initial position and a blanking position.

In the figure:

10. a frame;

211. a turntable knife; 212. a turntable cutter shaft; 221. a slide bar is arranged on the upper part; 222. a slide bar; 231. a wallboard; 232. a first fixed beam; 233. a second fixed beam; 24. a positioning block; 25. a material containing plate;

31. fixing the toothed plate; 311. a first tooth slot; 32. a movable toothed plate; 321. a second tooth slot; 331. blanking a lower beam; 332. blanking and aligning the side plates; 34. a blanking driving shaft; 351. a drive gear; 352. a first rotating shaft; 353. a driven gear; 354. a second rotating shaft; 355. a power gear; 356. an intermediate gear;

40. a weft thread;

51. aligning the material with the side plates; 52. a feeding support plate; 53. a feeding motor; 54. a feeding shaft; 55. a feeding roller; 56. a guide plate;

61. a material rubbing beam; 62. a rubbing shaft; 63. a rubbing rod; 64. a rubbing block; 65. a rubbing gear; 66. and (5) rubbing a material rack.

Detailed Description

In order to make the technical problems solved, the technical scheme adopted and the technical effects achieved by the invention more clear, the technical scheme of the invention is further described below by a specific embodiment in combination with the attached drawings. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting thereof. It should be further noted that, for convenience of description, only some, but not all of the drawings related to the present invention are shown.

Referring to fig. 1 to 12, an embodiment of the present invention provides a mesh welding machine, including a frame 10, where the frame 10 is provided with a material conveying mechanism and a blanking mechanism, the material conveying mechanism includes a material conveying space and a turntable knife 211 disposed at a discharge end of the material conveying space, a plurality of wefts 40 are sequentially arranged in the material conveying space along a radial direction, and grooves capable of receiving the wefts 40 are disposed on the turntable knife 211; the blanking mechanism is arranged on the discharging side of the rotary table knife 211 and comprises a fixed toothed plate 31 with a plurality of first tooth grooves 311 and a movable toothed plate 32 with a plurality of second tooth grooves 321, the first tooth grooves 311 receive the wefts 40 on the rotary table knife 211, and the movable toothed plate 32 moves relative to the fixed toothed plate 31 to move the wefts 40 in one first tooth groove 311 into the next adjacent first tooth groove 311.

The material transferring space is formed by the upper sliding bar 221 and the lower sliding bar 222 which are arranged at intervals, and the size of the material transferring space only allows the single-layer wefts 40 to be sequentially arranged along the radial direction, so that the wefts 40 are prevented from being piled up.

The material conveying mechanism further comprises two wallboards 231 arranged at intervals, a first fixed beam 232, a second fixed beam 233 and a blanking lower beam 331 are arranged between the two wallboards 231, the upper sliding bar 221 is arranged on the first fixed beam 232, the lower sliding bar 222 is arranged on the second fixed beam 233, and the fixed toothed plate 31 is arranged on the blanking lower beam 331.

The first fixing beam 232 is provided with two blanking alignment side plates 332 at intervals, and the distance between the two blanking alignment side plates 332 can be adjusted according to the length of the weft 40.

One side of the turntable cutter 211 is provided with a positioning block 24, the positioning block 24 comprises an arc-shaped positioning surface, and the axis of the positioning surface coincides with the axis of the turntable cutter 211. The positioning block 24 is arranged, so that the positioning block 24 can limit the weft 40 in the groove of the turntable knife 211 in the rotation process of the turntable knife 211, and the weft 40 is prevented from being separated from the notch of the groove.

The material conveying mechanism further comprises a turntable cutter shaft 212, the turntable cutter 211 is arranged on the turntable cutter shaft 212, and the turntable cutter shaft 212 is rotatably arranged on the wallboard 231. A plurality of grooves are circumferentially arranged on the turntable knife 211. The rotary table knife 211 rotates one revolution to transfer a plurality of wefts 40. The number of turntable blades 211 and the installation position are determined according to the length of the weft yarn 40, and the number is one or two.

The wallboard 231 is also rotatably provided with a blanking driving shaft 34, and the blanking driving shaft 34 and the turntable cutter shaft 212 are in meshed transmission through gears. The blanking driving shaft 34 and the turntable cutter shaft 212 are driven by a blanking motor at the same time.

The blanking mechanism is connected with a blanking lower beam 331. One side of the fixed toothed plate 31 is fixed on the blanking lower beam 331 through bolts, and the fixed toothed plate 31 is arranged on the blanking driving shaft 34 in a penetrating way. The fixed toothed plate 31 is fixed on the blanking driving shaft 34 through the fixed sleeve, the fixed toothed plate 31 is always in a fixed state, and the rotation of the blanking driving shaft 34 does not affect the fixed toothed plate 31.

Along the axial direction of the weft 40, a plurality of blanking mechanisms are arranged at intervals. The plurality of blanking mechanisms provide support to the weft 40, maintaining balance of the weft 40.

The first tooth grooves 311 comprise a receiving groove at the head end and a plurality of conveying grooves which are sequentially distributed from the head end to the tail end, and the number of the second tooth grooves 321 is equal to that of the conveying grooves. I.e., the number of first tooth slots 311 is one more than the number of second tooth slots 321.

Referring to fig. 10, the movable toothed plate 32 is positioned at the initial position, and the second tooth grooves 321 are in one-to-one correspondence with the material conveying grooves. Referring to fig. 11, the movable toothed plate 32 is located at the blanking position, and the second tooth slot 321 located at the head end is communicated with the receiving slot. When each first tooth slot 311 is provided with a weft yarn 40, if the movable toothed plate 32 is positioned at the initial position, the weft yarn 40 in the material conveying slot is also positioned in the second tooth slot 321; when the movable toothed plate 32 is positioned at the blanking position, the weft 40 in the conveying groove positioned at the tail end is supported by the movable toothed plate 32, so that the weft 40 falls down along the tail end of the movable toothed plate 32, and the weft 40 in the rest first tooth grooves 311 is supported by the movable toothed plate 32 to the second tooth grooves 321 positioned in the movable toothed plate 32; when the movable toothed plate 32 moves from the blanking position to the initial position, the weft yarn 40 positioned in the second tooth slot 321 is placed in the corresponding transfer slot, and at this time, the receiving slot is empty and is used for receiving the weft yarn 40 on the turntable knife 211. The movement of the movable tooth plate 32 enables the second tooth slot 321 to selectively communicate with the first tooth slot 311.

A first transmission mechanism is arranged between the movable toothed plate 32 and the fixed toothed plate 31, and the first transmission mechanism drives the movable toothed plate 32 to move between an initial position and a blanking position.

In this embodiment, the first transmission mechanism is a gear transmission mechanism, and the gear transmission mechanism includes a driving gear 351 rotatably disposed on a fixed toothed plate 31, and a first rotating shaft 352 is disposed on a movable toothed plate 32, and the first rotating shaft 352 is eccentrically and fixedly connected with the driving gear 351. When the driving gear 351 rotates, the first rotating shaft 352 is driven to rotate around the center of the driving gear 351, so that the movable toothed plate 32 rotates relative to the center of the driving gear 351 on the fixed toothed plate 31.

In order to ensure the stability of the movable toothed plate 32 in the rotation process, the gear transmission mechanism further comprises a driven gear 353 rotatably arranged on the fixed toothed plate 31, the movable toothed plate 32 is provided with a second rotating shaft 354, the second rotating shaft 354 is eccentrically and fixedly connected with the driven gear 353, and the central connecting line of the first rotating shaft 352 and the second rotating shaft 354 and the central connecting line of the driving gear 351 and the driven gear 353 are parallel and have the same length.

In order to make the driving gear 351, the driven gear 353 and the blanking spindle share the same driving mechanism, the blanking spindle is provided with a power gear 355, and the power gear 355 is engaged with the driving gear 351. In order to make the driving gear 351 and the driven gear 353 rotate in the same direction, an intermediate gear 356 is provided in mesh between the driving gear 351 and the driven gear 353.

Of course, the first transmission mechanism may be a four-bar mechanism other than the above-described gear transmission mechanism, and may be a parallelogram four-bar mechanism.

Still be provided with feed mechanism and feed auxiliary mechanism on the frame 10, feed mechanism and feed auxiliary mechanism set gradually in the upper reaches of passing material mechanism, have increased the storage function, can reduce the number of times of artifical feed, reduce the labour, improve work efficiency.

The feeding mechanism comprises two feeding alignment side plates 51 and a plurality of feeding support plates 52, wherein the two feeding alignment side plates 51 are arranged on the frame 10, the distance between the two feeding alignment side plates 51 is adjustable, the distance is equal to the length of the weft 40, and a certain number of the weft 40 with fixed length which is straightened in advance are arranged on the feeding support plates 52. The frame 10 is provided with a feeding motor 53, the feeding motor 53 is connected with a feeding shaft 54, the feeding shaft 54 is arranged on the frame 10 through a bearing with a seat, the feeding shaft 54 is provided with a feeding roller 55 with magnetism, the feeding roller 55 is positioned at one end of a feeding supporting plate 52, and the weft 40 is transferred to a feeding auxiliary mechanism.

At the feeding end of the feeding space, a loading plate 25 is arranged on the lower slide bar 222, and a guide plate 56 is arranged on the loading plate 25 and is used for guiding the weft 40 on the feeding roller 55 to fall onto the loading plate 25.

The feeding auxiliary mechanism comprises a material rubbing beam 61 fixed on the wallboard 231, and a plurality of material rubbing shaft supporting seats are arranged on the material rubbing beam 61 and are used for installing the material rubbing shafts 62. The material rubbing shaft 62 is provided with a plurality of material rubbing rods 63, the material rubbing rods 63 are arranged in one-to-one correspondence with the upper sliding strips 221, and each material rubbing rod 63 is provided with a material rubbing block 64. The material rubbing rod 63 is connected with the material rubbing block 64, and the material rubbing rod 63 drives the material rubbing block 64 to swing in the rotation process of the material rubbing shaft 62.

One end of the material rubbing shaft 62 is installed on the wallboard 231 and extends out of the wallboard 231 to be connected with a second transmission mechanism, and the second transmission mechanism comprises a material rubbing gear 65 installed on the material rubbing shaft 62, an air cylinder installed on the wallboard 231 and a material rubbing rack 66 installed on the air cylinder, wherein the material rubbing rack 66 is meshed with the material rubbing gear 65.

The cylinder rod stretches out to drive the material rubbing rod 63 to stir the material rubbing block 64 to the highest position; the cylinder rod retracts, bringing the rub block 64 back to the lowermost position. The reciprocating motion of the cylinder rod completes the rubbing process of the rubbing block 64 on the plurality of wefts 40.

When the mesh welding machine is used, a large number of previously straightened wefts 40 with fixed length are placed on a feeding support plate 52 of a feeding mechanism, a feeding alignment side plate 51 is adjusted to a proper position according to the length of the wefts 40, a feeding motor 53 is started to drive a feeding roller 55 to rotate, and when the position with magnetism in the feeding roller 55 rotates to pass through the wefts 40 on the feeding support plate 52, a certain number of wefts 40 are adsorbed, and the wefts 40 are continuously rotated to be sent to a containing plate 25.

The cylinder rod reciprocates and stretches so that the rubbing block 64 swings to rub the weft yarn 40 flat, and the weft yarn 40 is orderly arranged into the material conveying space.

The blanking motor rotates to enable the blanking driving shaft 34 to rotate to drive the movable toothed plate 32 to move, meanwhile, the turntable cutter shaft 212 is driven to rotate, the turntable cutter 211 hooks the wefts 40 in the material conveying space into the first tooth grooves 311 of the fixed toothed plate 31, the movable toothed plate 32 conveys the wefts 40 taken out of the first tooth grooves 311 into the second first tooth grooves 311 of the fixed toothed plate 31, and the like, and the wefts 40 are sent to the position under the electrode tip step by step to be welded.

Example two

Fig. 13 to 16 show a second embodiment, in which the same or corresponding parts as those of the first embodiment are given the same reference numerals as those of the first embodiment. For simplicity, only the points of distinction between the second embodiment and the first embodiment will be described. The difference is that the first transmission mechanism is a cylinder transmission mechanism, and the cylinder transmission mechanism comprises a first cylinder capable of driving the movable toothed plate 32 to move along a first direction and a second cylinder capable of driving the movable toothed plate 32 to move along a second direction, wherein the first direction and the second direction are mutually perpendicular. Arrow C1 in fig. 13 indicates a first direction, and arrow C2 indicates a second direction.

The movable toothed plate 32 is positioned at the initial position, and the second tooth grooves 321 are communicated with the material conveying grooves in a one-to-one correspondence. The first cylinder drives the movable toothed plate 32 to move along the first direction by a first preset distance, and the second tooth slot 321 is far away from the first tooth slot 311. The second cylinder drives the movable toothed plate 32 to move a second preset distance along a second direction, the movable toothed plate 32 is positioned at the blanking position, and the second tooth slot 321 positioned at the head end is communicated with the receiving slot. The first cylinder drives the movable toothed plate 32 to move a first preset distance along the direction opposite to the first direction, so that the second tooth slot 321 is positioned above the material conveying slot. At this time, the second cylinder drives the movable toothed plate 32 to move a second preset distance in a direction opposite to the second direction, and the movable toothed plate 32 returns to the initial position.

The above embodiments merely illustrate the basic principle and features of the present invention, and the present invention is not limited to the above embodiments, but may be varied and altered without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (8)

1. A mesh welding machine, comprising:

the material conveying mechanism comprises a material conveying space and a rotary table knife (211) arranged at the discharge end of the material conveying space, wherein a plurality of wefts (40) are sequentially distributed in the material conveying space along the radial direction, and grooves capable of receiving the wefts (40) are formed in the rotary table knife (211);

the blanking mechanism is arranged on the discharging side of the rotary table knife (211) and comprises a fixed toothed plate (31) with a plurality of first tooth grooves (311) and a movable toothed plate (32) with a plurality of second tooth grooves (321), the first tooth grooves (311) receive wefts (40) on the rotary table knife (211), and the movable toothed plate (32) moves relative to the fixed toothed plate (31) to move one weft (40) positioned in the first tooth groove (311) into the next adjacent first tooth groove (311);

the first tooth grooves (311) comprise material receiving grooves at the head end and a plurality of material conveying grooves which are sequentially distributed from the head end to the tail end, and the number of the second tooth grooves (321) is equal to that of the material conveying grooves; the number of the first tooth grooves (311) is one more than the number of the second tooth grooves (321);

the rotary table knife (211) is provided with a plurality of grooves along the circumferential direction, one side of the rotary table knife (211) is provided with a positioning block (24), the positioning block (24) comprises an arc-shaped positioning surface, and the axis of the positioning surface coincides with the axis of the rotary table knife (211).

2. The mesh welding machine according to claim 1, wherein the movable toothed plate (32) is located at an initial position, and the second tooth grooves (321) are communicated with the material conveying grooves in a one-to-one correspondence manner; the movable toothed plate (32) is located at a blanking position, and the second tooth groove (321) located at the head end is communicated with the material receiving groove.

3. The mesh welding machine according to claim 2, characterized in that a first transmission mechanism is arranged between the movable toothed plate (32) and the fixed toothed plate (31), and the first transmission mechanism drives the movable toothed plate (32) to move between the initial position and the blanking position.

4. A mesh welding machine according to claim 3, wherein the first transmission mechanism is a gear transmission mechanism, the gear transmission mechanism comprises a driving gear (351) rotatably arranged on the fixed toothed plate (31), a first rotating shaft (352) is arranged on the movable toothed plate (32), and the first rotating shaft (352) is eccentrically connected with the driving gear (351).

5. A net welder according to claim 3, wherein the first transmission mechanism is a cylinder transmission mechanism, the cylinder transmission mechanism comprises a first cylinder capable of driving the movable toothed plate (32) to move along a first direction and a second cylinder capable of driving the movable toothed plate (32) to move along a second direction, and the first direction and the second direction are mutually perpendicular.

6. The wire bonding machine according to claim 1, characterized in that a plurality of said blanking mechanisms are arranged at intervals along the axial direction of said weft thread (40).

7. The wire bonding machine according to any one of claims 1-6, wherein the material transfer mechanism further comprises an upper slide (221) and a lower slide (222), the upper slide (221) and the lower slide (222) forming the material transfer space therebetween.

8. The mesh welding machine according to any one of claims 1-6, wherein the material transfer mechanism further comprises a turret cutter shaft (212), the turret cutter (211) being arranged on the turret cutter shaft (212).