CN211105691U - Ear belt welding device and plane mask ear belt welding machine - Google Patents

Abstract

The utility model provides an ear band welding device and a plane mask ear band welding machine, wherein the ear band welding device comprises a fixed plate, a movable plate, a first cylinder, a linkage plate, two linkage rods, two pressure springs and two welding heads, the rotary disc, driving motor, the second cylinder, the third cylinder, two pressure heads, two pressure plates and line ball board, first cylinder installs on the fixed plate and steerable moving plate removes, the first end of two trace bars is connected with the moving plate respectively, the second end of two trace bars is connected with two soldered connections through the trace board respectively, a pressure spring cup joints on a trace bar and supports and press between moving plate and the trace board, two soldered connections are provided with ultrasonic transducer under vertical direction, driving motor control rotary disc is rotatory, the rotary disc is provided with detains the claw, the rotary disc still is provided with the winding band board, locking subassembly forces a detain the claw and keep the lock/open state. The ear belt welding device is simple in structure and stable and reliable in work.

Description

Ear belt welding device and plane mask ear belt welding machine

Technical Field

The utility model belongs to the technical field of plane gauze mask automated production equipment technique and specifically relates to a flat gauze mask ear area welding machine that ear area welding set and have this ear area welding set is related to.

Background

The flat mask comprises a mask body which is formed by laminating multiple layers of cloth, such as non-woven cloth. The two sides of the mask body are provided with ear bands used for wearing the mask on ears of a user. Ear straps 12 of a general flat mask are disposed outside both ends of a mask body 11, commonly called an external ear mask 1, as shown in fig. 1. In order to facilitate packaging of the flat mask and reduce the size of the mask packaging bag or box, ear straps 22 of the flat mask are provided on the inner sides of the two ends of the mask body 21, commonly referred to as inner ear mask 2, as shown in fig. 2.

At present, when the ear zone to plane gauze mask welds, a plane gauze mask ear area welding machine can not be shared to external ear gauze mask 1 and interior ear gauze mask 2 and produces, then need according to the different ear area welding machine of external ear gauze mask 1 and interior ear gauze mask 2 design, greatly increased the manufacturing cost of enterprise. Meanwhile, the existing ear belt welding machine can only meet the requirement that the plane mask with one length dimension is produced, a plurality of ear belt welding machines are required to be designed according to the plane masks with different length dimensions, the production cost of enterprises is greatly increased, and the production efficiency is lower.

Disclosure of Invention

The utility model discloses a first purpose provides a simple structure and reliable operation's ear area welding set.

The second purpose of the utility model is to provide a plane gauze mask ear area welding machine with above-mentioned ear area welding set.

In order to realize the first purpose of the utility model, the utility model provides an ear belt welding device, which comprises a fixed plate, a movable plate, a first cylinder, a linkage plate, two linkage rods, two pressure springs, two welding heads, a rotating disk, a driving motor, a second cylinder, a third cylinder, two pressure heads, two pressure plates and a line pressing plate, wherein the movable plate is arranged below the fixed plate in the vertical direction, the first cylinder is arranged on the fixed plate and can control the movable plate to move in the vertical direction, the linkage plate is arranged below the movable plate in the vertical direction, the first ends of the two linkage rods are respectively connected with the movable plate, the second ends of the two linkage rods are respectively connected with the two welding heads through the linkage plate, one pressure spring is sleeved on one linkage rod and is pressed between the movable plate and the linkage plate, two welding heads are provided with an ultrasonic transducer under the vertical direction, one end of the plane mask can be placed on an ultrasonic transducer, a rotating disc is positioned below a linkage plate in the vertical direction, a driving motor is installed on the linkage plate and controls the rotating disc to rotate, two buckling claws are arranged on a first side of the rotating disc, two buckling claws are also arranged on a second side of the rotating disc, which is opposite to the first side, a third side and a fourth side, which are opposite to the rotating disc, are respectively provided with a tape winding plate, one tape winding plate can be positioned below a wire pressing plate in the vertical direction, a second air cylinder is installed on the linkage plate and controls the wire pressing plate and two pressing plates to move in the vertical direction, the first side and the second side of the rotating disc are respectively provided with oppositely arranged avoiding grooves, one avoiding groove is positioned between the two buckling claws on the same side, a welding head can be inserted into one avoiding groove, each buckling claw is hinged with the rotating disc, each buckling claw is provided with a buckling end and an opening arm, a third air cylinder is installed on the linkage plate and, the two pressing heads can be pressed on the buckling ends of the two buckling claws positioned on the same side to force the two buckling claws to be buckled on the side surface of the rotating disc, the two pressing plates can be pressed on the opening arms of the two buckling claws close to the pressing plate and positioned on the two opposite sides to force the two buckling claws to be opened, the rotating disc is provided with a stopping component below each buckling claw, and one stopping component forces one buckling claw to keep a buckling/opening state.

According to the scheme, a pressure spring of the ear band welding device is sleeved on a linkage rod and is abutted between a moving plate and the linkage plate, when a first cylinder controls the moving plate to drive the linkage plate, two welding heads and a rotating disk to move downwards in the vertical direction together through the two linkage rods, the rotating disk firstly abuts and presses one end of the plane mask to be fixed on an ultrasonic transducer, the two linkage rods drive the two welding heads to continuously move downwards along with the first cylinder to be inserted into two avoiding grooves formed in the rotating disk oppositely, so that the ear band is welded on one end of the plane mask, and the pressure spring sleeved on the linkage rod is in a compression state. Subsequently, the first cylinder control moving plate drives the two welding heads to move upwards in the vertical direction through the two linkage rods to reset, the two welding heads are reset from a compression state along with the compression spring, the linkage plate is forced to drive the rotating disc to keep one end of the plane mask to be pressed and fixed on the ultrasonic transducer, when the two welding heads are separated from the plane mask and the ear bands, the rotating disc still presses and fixes one end of the plane mask on the ultrasonic transducer, the plane mask or the ear bands are prevented from being taken when the welding heads are separated from the plane mask and the ear bands, the structure is simple, the reliability and the stability of work are improved, the product quality is greatly improved, and the product reject ratio is reduced.

The further scheme is that the ear belt welding device further comprises a belt feeding plate and a belt leading rod, the belt feeding plate is installed on the linkage plate, a first belt penetrating hole with an axis parallel to the vertical direction is formed in the belt feeding plate, the first end of the belt leading rod is connected with the belt feeding plate, a second belt penetrating hole with an axis perpendicular to the vertical direction is formed in the second end of the belt leading rod, the belt leading rod and the wire pressing plate are located on two opposite sides of the linkage plate respectively, and stability and reliability of ear belt feeding and wiring are improved.

The further scheme is that the ear belt welding device further comprises two belt blocking plates, one belt blocking plate is installed above one belt winding plate and extends outwards to form a protruding eaves portion, and stability and reliability of winding of the ear belt on the belt winding plate are improved.

The further scheme is that a winding belt groove is formed in the outer wall of each winding belt plate and extends in the rotating direction of the rotating disc, and the stability and the reliability of winding of the ear belt on the winding belt plates are improved.

The further scheme is that each strip winding plate is provided with a first avoidance groove, each strip blocking plate is provided with a second avoidance groove corresponding to the first avoidance groove, a pressing block is arranged on the wire pressing plate, and the pressing block can be inserted into the first avoidance groove and the second avoidance groove to improve the working stability and reliability.

The further scheme is that the ear belt welding device further comprises a photoelectric sensor, the top end of the driving motor is connected with a rotating disc, the driving motor controls the rotating disc to rotate synchronously with the rotating disc, the photoelectric sensor is provided with a groove, the periphery of the rotating disc is embedded into the groove, two notches are formed in the periphery of the rotating disc in an adjacent mode, and the two notches are symmetrically arranged about the axis of the rotating disc. When the driving motor controls the rotating disc and the rotating disc to synchronously rotate for a half circle, the photoelectric sensor can sense through the notch, and the accuracy and the reliability of work are improved.

According to a further scheme, the ear belt welding device further comprises a proximity switch, a guide rod and a connecting plate, the wire pressing plate and the two pressing plates are connected with the connecting plate respectively, the second cylinder controls the connecting plate to move in the vertical direction, the first end of the guide rod is connected with the connecting plate, the second end of the guide rod movably penetrates through the linkage plate, the proximity switch is located above the linkage plate and used for sensing the second end of the guide rod, and working accuracy is improved.

According to a further scheme, the ear belt welding device further comprises four shaft pins, an annular groove is formed in the peripheral wall of each shaft pin, each buckling claw is provided with a hinge through hole, the rotating disc is provided with an accommodating groove corresponding to each buckling claw, a first side wall and a second side wall opposite to each accommodating groove are provided with a first through hole and a second through hole which are corresponding respectively, a third through hole which is communicated with the second through hole and is vertically arranged is further formed in the second side wall of the accommodating groove, one shaft pin is inserted into one first through hole, one hinge through hole and one second through hole, the annular groove of one shaft pin is located at the communicated position of the second through hole and the third through hole, and a fastener is inserted into the third through hole and abutted against the.

According to the scheme, one shaft pin is inserted into the first through hole, the hinge through hole and the second through hole, the annular groove of the shaft pin is positioned at the communication position of the second through hole and the third through hole, and the fastener is inserted into the third through hole and abuts against the annular groove, so that the reliability and the stability of the work are improved.

In a further aspect, the bottom of each of the snap claws has a flange, and each of the stop assemblies includes a ball, a spring and a sleeve, the sleeve is mounted in the rotating disc, the ball is rotatably located at the top end of the sleeve, the spring is located in the sleeve and abuts between the ball and the bottom of the sleeve, and the flange and the ball abut against each other.

According to the scheme, the flange of the buckling claw is abutted to the ball, the spring is located in the sleeve and abutted between the ball and the bottom of the sleeve, and therefore when the buckling claw is buckled or opened under the action of external force, the ball can be retracted downwards through the spring. After the buckling or opening action of the buckling claw is finished, the ball upwards props against the flange of the buckling claw under the action of the resilience force of the spring, the buckling claw is forced to be kept in a buckling or opening state by means of the spherical peripheral wall of the ball, the structure is simple, and the reliability and the stability of the work are improved.

In order to achieve the second object of the utility model, the utility model provides a welding machine for ear belt of plane mask, which comprises a welding device for ear belt, the welding device for ear belt comprises a fixed plate, a movable plate, a first cylinder, a linkage plate, two linkage rods, two compression springs, two welding joints, a rotary disk, a driving motor, a second cylinder, a third cylinder, two pressure-resisting heads, two pressure-resisting plates and a wire-pressing plate, the movable plate is arranged below the fixed plate in the vertical direction, the first cylinder is arranged on the fixed plate and can control the movable plate to move in the vertical direction, the linkage plate is arranged below the movable plate in the vertical direction, the first ends of the two linkage rods are respectively connected with the movable plate, the second ends of the two linkage rods are respectively connected with the two welding joints through the linkage plate, one compression spring is sleeved on one linkage rod and is pressed between the movable plate and the linkage plate, two ultrasonic transducers are arranged under the vertical direction, one end of the plane mask can be placed on an ultrasonic transducer, a rotating disc is positioned below a linkage plate in the vertical direction, a driving motor is installed on the linkage plate and controls the rotating disc to rotate, two buckling claws are arranged on a first side of the rotating disc, two buckling claws are also arranged on a second side of the rotating disc, which is opposite to the first side, a third side and a fourth side, which are opposite to the rotating disc, are respectively provided with a tape winding plate, one tape winding plate can be positioned below a wire pressing plate in the vertical direction, a second air cylinder is installed on the linkage plate and controls the wire pressing plate and two pressing plates to move in the vertical direction, the first side and the second side of the rotating disc are respectively provided with oppositely arranged avoiding grooves, one avoiding groove is positioned between the two buckling claws on the same side, a welding head can be inserted into one avoiding groove, each buckling claw is hinged with the rotating disc, each buckling claw is provided with a buckling end and an opening arm, a third air cylinder is installed on the linkage plate and, the two pressing heads can be pressed on the buckling ends of the two buckling claws positioned on the same side to force the two buckling claws to be buckled on the side surface of the rotating disc, the two pressing plates can be pressed on the opening arms of the two buckling claws close to the pressing plate and positioned on the two opposite sides to force the two buckling claws to be opened, the rotating disc is provided with a stopping component below each buckling claw, and one stopping component forces one buckling claw to keep a buckling/opening state.

Drawings

Fig. 1 is a structural view of an external ear mask.

Fig. 2 is a structural view of the inner ear mask.

Fig. 3 is a first view structural diagram of the flat mask ear belt welding machine of the present invention.

Fig. 4 is a second view structure diagram of the flat mask ear belt welding machine of the present invention.

Fig. 5 is a structural diagram of a conveying device in the embodiment of the flat mask ear belt welding machine of the invention.

Fig. 6 is an exploded view of the jig and the conveying chain in the embodiment of the welding machine for the ear band of the flat mask of the present invention.

Fig. 7 is an exploded view of a first partial structure of a driving mechanism in an embodiment of a flat mask ear strip welding machine of the present invention.

Fig. 8 is a second partial exploded view of the driving mechanism of the embodiment of the flat mask ear belt welding machine of the present invention.

Fig. 9 is an exploded view of a third partial structure of a driving mechanism in an embodiment of the flat mask ear belt welding machine of the present invention.

Fig. 10 is a first structural cross-sectional view of a conveying device in an embodiment of a flat mask ear strip welding machine of the present invention.

Fig. 11 is a structural diagram of a guide plate in an embodiment of the flat mask ear belt welding machine of the present invention.

Fig. 12 is a second structural cross-sectional view of the conveying device in the embodiment of the flat mask ear belt welding machine of the present invention.

Fig. 13 is a structural diagram of an ultrasonic transducer in an embodiment of the flat mask ear strip welding machine of the present invention.

Fig. 14 is a structural diagram of a discharging device in an embodiment of the welding machine for the ear band of the flat mask of the utility model.

Fig. 15 is a partial structural cross-sectional view of the flat mask ear strip welding machine of the present invention.

Fig. 16 is a structural diagram of an ear band cutting device in an embodiment of the flat mask ear band welding machine of the present invention.

Fig. 17 is a structural diagram of the two sets of ear band feeding devices, the assembling plate and the two sets of ear band welding devices in the embodiment of the flat mask ear band welding machine of the present invention.

Fig. 18 is a first view angle partial structure diagram of an ear band feeding device in an embodiment of the flat mask ear band welding machine of the present invention.

Fig. 19 is a second view angle partial structure diagram of the ear band feeding device in the embodiment of the flat mask ear band welding machine of the present invention.

Fig. 20 is a partially exploded view of an ear strap feeding device in an embodiment of the flat mask ear strap welding machine of the present invention.

Fig. 21 is a structural diagram of an assembly plate in an embodiment of the welding machine for the ear band of the flat mask of the present invention.

Fig. 22 is a structural diagram of an ear band welding device in an embodiment of the flat mask ear band welding machine of the present invention.

Fig. 23 is a first view angle partial structure diagram of an ear band welding device in an embodiment of the flat mask ear band welding machine of the present invention.

Fig. 24 is a second view angle partial structure diagram of the ear band welding device in the embodiment of the flat mask ear band welding machine of the present invention.

Fig. 25 is a third view angle partial structure diagram of the ear band welding device in the embodiment of the flat mask ear band welding machine of the present invention.

Fig. 26 is a partially exploded view of an ear strap welding device in an embodiment of the flat mask ear strap welding machine of the present invention.

Fig. 27 is a partial cross-sectional view of an ear strap welding device in an embodiment of the flat mask ear strap welding machine of the present invention.

Fig. 28 is a structural view of the working state of the flat mask ear belt welding machine of the embodiment of the present invention.

The present invention will be further explained with reference to the drawings and examples.

Detailed Description

Referring to fig. 3 and 4, the welding machine 3 for ear bands of flat masks comprises a frame 4, a conveying device 5, a discharging device 10, an assembling plate 7, two sets of ear band welding devices 8, two ultrasonic transducers 20 (see fig. 10), two sets of ear band feeding devices 6 and four sets of ear band shearing devices 9, the conveying device 5 is arranged on the frame 4, the conveying device 5 comprises a driving mechanism, two conveying chains 51 and a plurality of jigs 52, the two conveying chains 51 are arranged in parallel, the driving mechanism controls the two conveying chains 51 to synchronously move in the same direction, and the plurality of jigs 52 are respectively located on the two conveying chains 51 and place the flat masks 1 and 2. Discharging device 10 is located the rear end of two conveyor chains 51 on conveyor chain 51 moving direction, and assembly plate 7 is located conveyor chain 51's top on vertical direction, and assembly plate 7 is connected with frame 4 through four stands 31, and two sets of ear area welding set 8 are connected with assembly plate 7 respectively, and two sets of ear area welding set 8 are about tool 52 mirror image setting, and two sets of ear area welding set 8 stagger the setting in conveyor chain 51 moving direction. Meanwhile, the two sets of ear band feeding devices 6 are installed on the assembling plate 7 in a mirror image mode about the jig 52, the two sets of ear band feeding devices 6 are arranged in a staggered mode in the moving direction of the conveying chain 51, and one set of ear band feeding devices 6 is matched with one set of ear band welding devices 8. The two sets of ear band cutting devices 9 are adapted to the one set of ear band welding devices 8, and the two sets of ear band cutting devices 9 are respectively positioned at two ends of the one set of ear band welding devices 8 in the moving direction of the conveying chain 51 and are arranged in a mirror image mode about the axis of the rotating disc 814 of the ear band welding devices 8.

Referring to fig. 5 to 13, the conveying device 5 further includes two guide plates 55, a first side plate 53, a second side plate 54, two supporting pieces 518, two first inductors 519 and a second inductor 520, each inner chain plate 511 of each conveying chain 51 extends inward to form a mounting plate 512, each mounting plate 512 is provided with a through hole 513, the jigs 52 are located on the mounting plates 512 and are placed on the plane masks 1 and 2, each jig 52 is provided with two first mounting holes 521, the two first mounting holes 521 of each jig 52 correspond to the through holes 513 of the two opposite mounting plates 512 one by one and are connected through first fasteners (not shown), and the first fasteners include but are not limited to pull nails, screws or bolts and nuts. The two guide plates 55 are respectively located outside the two conveyor chains 51, and the two guide plates 55 are arranged to be offset in the moving direction of the conveyor chains 51. The guide plate 55 has a guide segment 551 and a support segment 552 connected to each other, the guide segment 551 is disposed obliquely and located at the front end of the moving direction of the conveying chain 51, one end of the planar masks 1 and 2 can be located on the guide segment 551 and the support segment 552, and the support segment 552 is used for disposing the ultrasonic transducer 20 below in the vertical direction. One guide plate 55 is located at the front end of one ultrasonic transducer 20 in the moving direction of the conveyor chain 51, and the support section 552 of one guide plate 55 is located above one ultrasonic transducer 20 in the vertical direction.

Each guide plate 55 further has a fixing section 553 connected to the support section 552, the fixing section 553 is perpendicular to the support section 552 and forms a catching groove 555 with the guide section 551, and the fixing section 553 is opened with a second mounting hole 554, and the second mounting hole 554 extends in a vertical direction. The first side plate 53 and the second side plate 54 are respectively located outside the two conveying chains 51, the first side plate 53 and the second side plate 54 are both provided with third mounting holes (not marked), the fixing section 553 of one guide plate 55 is located on the side surface of the first side plate 53/the second side plate 54, one second mounting hole 554 is correspondingly arranged with the third mounting hole and is connected through a second fastener (not marked), the end wall of the first side plate 53/the second side plate 54 is embedded into the clamping groove 555 of one guide plate 55, and the second fastener includes, but is not limited to, a screw or a bolt and a nut matching and the like. Each supporting piece 518 extends along the moving direction of the conveying chain 51, the two supporting pieces 518 are respectively positioned under the two conveying chains 51 on which the plane masks 1 and 2 are placed, and the two conveying chains 51 on which the plane masks 1 and 2 are placed respectively abut against the two supporting pieces 518. Specifically, two supporting pieces 518 are respectively installed on the frame 4 for supporting the two conveying chains 51 on the frame 4.

A first sensor 519 and a guide plate 55 are located at the same station and respectively located at the outer sides of the two conveying chains 51, and the first sensor 519 is used for detecting whether the plane masks 1 and 2 are in place on the ultrasonic transducer 20. The second sensor 520 is located between the two conveying chains 51 and located at the front end of the front end guide plate 55 in the moving direction of the conveying chains 51, and the second sensor 520 is used for detecting whether the planar masks 1 and 2 of the to-be-welded ear bands at the front end stations of the front end guide plate 55 are in position. Wherein the driving mechanism comprises a motor 59, a driving shaft 56, three driven shafts 57, 58 and eight chain wheels 510, two driven shafts 58 on a first horizontal plane are rotatably supported at both ends of the frame 4, the driving shaft 56 and one driven shaft 57 on a second horizontal plane are rotatably supported in the frame 4, and the second horizontal plane is vertically below the first horizontal plane. Two chain wheels 510 are sleeved on the driving shaft 56, two chain wheels 510 are sleeved on one driven shaft 57 and one driven shaft 58, one conveying chain 51 is sleeved between one chain wheel 510 of the driving shaft 56 and three chain wheels 510 of the three driven shafts 57 and 58, and the motor 59 is installed in the machine frame 4 and controls the driving shaft 56 to rotate. The driving shaft 56 is provided with a first limiting bar 561 and a second limiting bar 562 which protrude in the radial direction, each driven shaft 57 and 58 is provided with a third limiting bar 571, 581 and a fourth limiting bar 572, 582 which protrude in the radial direction, each chain wheel 510 is axially provided with a through groove 5101 which is communicated with the shaft hole, and one through groove 5101 is sleeved on the first limiting bar 561/the second limiting bar 562/the third limiting bar 571, 581/the fourth limiting bar 572, 582. Each sprocket 510 is radially provided with a fastening hole 5102 communicating with the shaft hole, a third fastening member (not shown) is inserted into the fastening hole 5102 and abuts against the outer peripheral wall of the driving/driven shafts 56, 57, 58, the third fastening member includes, but is not limited to, a screw, a bolt, an expansion pin and the like, and the expansion pin operates in a manner similar to an expansion bolt. When the third fastening member is a fastening part having an external thread such as a screw, a bolt, etc., the corresponding fastening hole 5102 has an internal thread such that the third fastening member is screw-fitted to the fastening hole 5102 and one end abuts on the outer circumferential wall of the driving shaft 56/driven shafts 57, 58.

The driving mechanism of the present embodiment further includes eight first bearings 514, two first bearings 514 are sleeved at two ends of the driving shaft 56, two ends of one driven shaft 57, 58 are respectively sleeved with the first bearings 514, that is, one driven shaft 57, 58 is adapted with two first bearings 514. Two first bearings 514 on the driving shaft 56 are respectively supported and installed in the machine frame 4 through a first supporting seat 515, two first bearings 514 on the driven shaft 57 on the second horizontal plane are respectively supported and installed in the machine frame 4 through a second supporting seat 516, and four first bearings 514 on the two driven shafts 58 on the first horizontal plane are respectively supported and installed at two ends of the machine frame 4 through a third supporting seat 517.

Referring to fig. 14, the discharging device 10 includes two side plates 101, a first driving roller 105, a second driving roller 106, a first driven roller 107, a second driven roller 108, two first synchronous belts 109, two second synchronous belts 1010, a control motor 102, a driving wheel 103 and two driven wheels 104, the two side plates 101 are located at the rear ends of the two conveying chains 51 in the moving direction of the conveying chains 51 and are connected to one end of the frame 4, the first driving roller 105 and the second driving roller 106 are arranged side by side in the vertical direction and rotatably supported at the first ends of the two side plates 101, and the first driven roller 107 and the second driven roller 108 are arranged side by side in the vertical direction and rotatably supported at the second ends of the two side plates 101. The first driving rotating roller 105 and the first driven rotating roller 107 are located on a third horizontal plane, and the two first synchronous belts 109 are respectively sleeved between the first driving rotating roller 105 and the first driven rotating roller 107. The second driving rotating roller 106 and the second driven rotating roller 108 are located on a fourth horizontal plane, the two second synchronous belts 1010 are respectively sleeved between the second driving rotating roller 106 and the second driven rotating roller 108, and the fourth horizontal plane is located below the third horizontal plane in the vertical direction.

The control motor 102 is installed on the outer side of one side plate 101, the driving wheel 103 is sleeved on a driving main shaft of the control motor 102, one driven wheel 104 is sleeved at one end of a first driving rotating roller 105, the other driven wheel 104 is sleeved at one end of a second driving rotating roller 106, and the driving wheel 103 is respectively meshed with the two driven wheels 104. Wherein, a first hold-in range 109 and a second hold-in range 1010 set up side by side in the vertical direction, are formed with the ejection of compact clearance 1011 that is used for plane gauze mask 1, 2 to pass through between a first hold-in range 109 and a second hold-in range 1010 in the vertical direction. After the ear belts 12 and 22 of the plane masks 1 and 2 are welded, the ear belts enter the discharge gap 1011, and under the effect of the control motor 102 driving the first driving rotating roller 105 and the second driving rotating roller 106 to rotate synchronously, the two first synchronous belts 109 and the two second synchronous belts 1010 are used for conveying moving power to convey the plane masks 1 and 2. The discharging device 10 and the conveying device 5 are identical in conveying speed, feeding and discharging are in seamless connection, and the working efficiency of the whole machine of the plane mask ear belt welding machine 3 is improved.

Referring to fig. 15 to 27, the mounting plate 7 is located above the conveying chain 51 in the vertical direction, the mounting plate 7 is connected to the rack 4 through the four vertical posts 31, the two sets of ear band welding devices 8 are respectively connected to the mounting plate 7, the two sets of ear band welding devices 8 are arranged in a mirror image manner with respect to the jig 52, and the two sets of ear band welding devices 8 are arranged in a staggered manner in the moving direction of the conveying chain 51. Meanwhile, the two sets of ear band feeding devices 6 are installed on the assembling plate 7 in a mirror image mode about the jig 52, the two sets of ear band feeding devices 6 are arranged in a staggered mode in the moving direction of the conveying chain 51, and one set of ear band feeding devices 6 is matched with one set of ear band welding devices 8. The two sets of ear band cutting devices 9 are adapted to the one set of ear band welding devices 8, and the two sets of ear band cutting devices 9 are respectively positioned at two ends of the one set of ear band welding devices 8 in the moving direction of the conveying chain 51 and are arranged in a mirror image mode about the axis of the rotating disc 814 of the ear band welding devices 8.

Referring to fig. 16, each set of ear band cutting devices 9 comprises a scissors mounting plate 92, a scissors driving cylinder 93 arranged on the scissors mounting plate 92, and a pneumatic scissors 94 arranged on a piston rod of the scissors driving cylinder 93, wherein the scissors driving cylinder 93 controls the pneumatic scissors 94 to extend into/exit from the position avoiding groove 8141 of the rotating disc 814 of the ear band welding device 8. Specifically, scissors mounting panel 92 is installed on frame 4 through scissors mount pad 91, scissors mounting panel 92 has seted up first pilot hole (not marking) and second pilot hole 921, scissors mount pad 91 has seted up arc through groove 911 and third pilot hole 912, first pilot hole corresponds with third pilot hole 912 and passes through fourth fastener (not marking) fixed connection, second pilot hole 921 corresponds with arc through groove 911 and passes through fourth fastener fixed connection, above-mentioned fourth fastener includes but not limited to screw or bolt and nut cooperation etc.. The arc that scissors mount pad 91 was seted up leads to groove 911 and the second pilot hole 921 of scissors mounting panel 92 corresponds the cooperation and is connected, and the accessible arc leads to groove 911 and adjusts the inclination of the piston rod that the scissors drove actuating cylinder 93, and then adjusts pneumatic scissors 94's inclination, improves the reliability and the stability of ear area cutting device 9 work greatly.

Referring to fig. 17 to 20, each set of ear belt feeding device 6 includes an upright plate 62, an ear belt rod 61, a driving mechanism 63, a wire arranging wheel 66, a tensioning wheel 65, a jumping wheel 610, a wire guiding wheel 67, an elastic member 619, a third sensor 617, a first outer hanging arm 612, a second outer hanging arm 613 and a belt guiding rod 614, the bottom end of the upright plate 62 is mounted on the mounting plate 7, a cantilever 64 is mounted on the top end of the first side surface of the upright plate 62, the cantilever 64 is provided with a first through hole 641, and the ear belt rod 61 is located above the cantilever 64. The axes of the wire straightening wheel 66, the tension wheel 65, the jumping wheel 610 and the wire guiding wheel 67 are arranged in parallel, the wire straightening wheel 66, the tension wheel 65 and the wire guiding wheel 67 are all rotatably positioned on the first side surface of the vertical plate 62, the driving mechanism 63 is installed on the second side surface of the vertical plate 62 and controls the wire straightening wheel 66 to rotate, the elastic piece 619 forces the outer peripheral wall of the tension wheel 65 to abut against the outer peripheral wall of the wire straightening wheel 66, and the abutting positions of the tension wheel 65 and the wire straightening wheel 66 are positioned right below the first through hole 641 in the vertical direction. The lower side of the wire straightening wheel 66 in the vertical direction is provided with two cylindrical rods 69, the two cylindrical rods 69 extend in the vertical direction side by side, two ends of the two cylindrical rods 69 are respectively installed on the first side face of the vertical plate 62 through an upper baffle 615 and a lower baffle 616, one end of one cylindrical rod 69 close to the upper baffle 615 is sleeved with a limiting sleeve 611, the jumping wheel 610 can rotatably vertically move between the limiting sleeve 611 and the lower baffle 616, an annular groove 6101 is formed in one axial end of the jumping wheel 610, and the two cylindrical rods 69 penetrate through the annular groove 6101. The wire guide wheel 67 is located on the side of the wire straightening wheel 66 away from the tension wheel 65, and the wire guide wheel 67 is located above the upper baffle 615 in the vertical direction.

The axes of the wire arranging wheel 66, the tension wheel 65 and the wire guiding wheel 67 are positioned on the same plane, the axes of the wire arranging wheel 66 and the jumping wheel 610 are positioned on the same plane, and the axes of the ear belt rods 61 are respectively vertical to the axis of the wire arranging wheel 66 and the vertical direction. The vertical plate 62 is provided with a slot 621 above the lower baffle 616, and the third sensor 617 is inserted into the slot 621 and used for sensing the jumping wheel 610. The driving mechanism 63 of this embodiment is a motor, and when the third sensor 617 senses the jumping wheel 610, the motor stops working, thereby stopping the feeding of the ear belt. The first outer hanging arm 612 is installed on the first side surface of the vertical plate 62 in an outward extending manner and is located below the wire guide wheel 67 in the vertical direction, the first outer hanging arm 612 is provided with a second strap passing hole 6121, and the axis of the second strap passing hole 6121 is parallel to the vertical direction. The second hanging arm 613 is installed on the first side surface of the vertical plate 62 in an outward extending manner and is located below the first hanging arm 612 in the vertical direction, the belt guiding rod 614 extends in a direction perpendicular to the vertical plate 62, the middle part of the belt guiding rod 614 is connected with the second hanging arm 613, and third belt passing holes 6141 are respectively formed in two ends of the belt guiding rod 614. In this embodiment, the first tape passing hole 641 and the second tape passing hole 6121 are respectively sleeved with a rubber sleeve.

Specifically, the ear belt feeding device 6 further includes a hinge rod 618, two second bearings 622, a shaft sleeve 623, a screw washer 620 and a screw 68, the elastic member 619 is a tension spring, the hinge rod 618 is located on the second side of the vertical plate 62, a first end of the hinge rod 618 is hinged to the vertical plate 62, two ends of the tension spring are respectively connected to the vertical plate 62 and the hinge rod 618, and the tension wheel 65 is rotatably supported at a second end of the hinge rod 618. The vertical plate 62 is provided with a strip-shaped groove 624, the strip-shaped groove 624 extends in the axial direction perpendicular to the vertical direction and the whole wire wheel 66, and the shaft sleeve 623 penetrates through the strip-shaped groove 624 and is located between the hinge rod 618 and the tension wheel 65. Two second bearings 622 are fitted in the axial holes of the tension wheel 65, and the screw 68 is connected to the second end of the hinge rod 618 through a screw washer 620, the two second bearings 622 and a shaft sleeve 623 in this order. The wire guide wheel 67 is also rotatably supported on the first side surface of the vertical plate 62 by a screw 68, and the screw 68 is connected to the vertical plate 62 by inserting a screw washer 620 and the wire guide wheel 67 in this order. The peripheral wall of this embodiment take-up pulley 65 cup joints first rubber tyer 651, and the peripheral wall of whole line wheel 66 cup joints second rubber tyer (not labeled).

Referring to fig. 21, the assembly plate 7 is provided with four belt guide holes 71, each belt guide hole 71 is sleeved with a rubber sleeve, and the two belt guide holes 71 are adapted to a group of ear belt feeding devices 6 and a group of ear belt welding devices 8. Two through holes 72 are formed in the mounting plate 7, and a group of ear band welding devices 8 are mounted on the mounting plate 7 through one of the through holes 72. Two fixing blocks 73 are mounted on the mounting plate 7, the two fixing blocks 73 are respectively close to the outer side faces of the two through holes 72, each fixing block 73 is provided with a threaded hole (not marked), each threaded hole is internally threaded and matched with a long screw 74, and the tail end of the long screw 74 is provided with an annular groove 741.

Referring to fig. 22 to 27, each of the ear band welding devices 8 includes a fixing plate 83, a moving plate 84, a first cylinder 86, a linkage plate 85, two linkages 87, two compression springs 88, two welding heads 818, a rotating disc 814, a driving motor 89, a second cylinder 822, a third cylinder 812, two pressure heads 819, two pressure plates 820 and a wire pressing plate 81, and the fixing plate 83 is mounted on the mounting plate 7. Specifically, two opposite sides of the fixing plate 83 are provided with two T-shaped notches 831 arranged oppositely, and the end of one long screw 74 is embedded into one T-shaped notch 831. The two long screws 74 are respectively matched with the thread holes of the two fixing blocks 73 in a threaded manner, so that the distance between the two sets of ear band welding devices 8 is adjusted to be suitable for ear band welding production of various length- size plane masks 1 and 2, such as 175 mm, 145 mm and 125 mm length- size plane masks 1 and 2.

The moving plate 84 is located below the fixed plate 83 in the vertical direction, and a first cylinder 86 is mounted on the fixed plate 83 and controls the moving plate 84 to move in the vertical direction. The linkage plate 85 is vertically positioned below the moving plate 84, the first ends of the two linkage rods 87 are respectively connected with the moving plate 84, the second ends of the two linkage rods 87 are respectively connected with the two welding heads 818 through the linkage plate 85, a pressure spring 88 is sleeved on one linkage rod 87 and is pressed between the moving plate 84 and the linkage plate 85, an ultrasonic transducer 20 is vertically positioned under the two welding heads 818, and one end of each of the planar masks 1 and 2 can be placed on the ultrasonic transducer 20. The rotating disc 814 is located below the linkage plate 85 in the vertical direction, the driving motor 89 is mounted on the linkage plate 85 and controls the rotating disc 814 to rotate, two buckling claws 816 are arranged on a first side of the rotating disc 814, two buckling claws 816 are also arranged on a second side, opposite to the first side, of the rotating disc 814, belt winding plates 815 are respectively arranged on a third side and a fourth side, opposite to the rotating disc 814, of the rotating disc 814, one belt winding plate 815 can be located below the wire pressing plate 81 in the vertical direction, and the second cylinder 822 is mounted on the linkage plate 85 and controls the wire pressing plate 81 and the two pressing plates 820 to move in the vertical direction.

The first side and the second side of the rotating disc 814 are respectively provided with a position-avoiding groove 8141 which are oppositely arranged, one position-avoiding groove 8141 is positioned between the two buckling claws 816 on the same side, one welding head 818 can be inserted into one position-avoiding groove 8141, each buckling claw 816 is hinged with the rotating disc 814, each buckling claw 816 is provided with a buckling end 8162 and an opening arm 8163, the third air cylinder 812 is installed on the linkage plate 85 and controls the two pressure-resisting heads 819 to move in the vertical direction, and the two pressure-resisting heads 819 can press against the buckling ends 8162 of the two buckling claws 816 on the same side to force the two buckling claws 816 to be buckled on the side surface of the rotating disc 814. The two pressing plates 820 can press against the opening arms 8163 of the two buckling claws 816 close to the line pressing plate 81 and located at two opposite sides to force the two buckling claws 816 to open, the rotating disc 814 is provided with a stopping component below each buckling claw 816, and one stopping component forces one buckling claw 816 to keep a buckling/opening state. Specifically, the bottom of each pawl 816 has a flange 8164, each stop assembly comprises a ball 830, a spring 829 and a sleeve 828, the sleeve 828 is mounted within the rotating disc 814, the ball 830 is rotatably located at the top end of the sleeve 828, the spring 829 is located within the sleeve 828 and abuts between the ball 830 and the bottom of the sleeve 828, and the flange 8164 and the ball 830 abut each other.

Each set of ear strap welding device 8 of this embodiment further includes four shaft pins 827, an annular groove 8271 is opened on an outer peripheral wall of each shaft pin 827, each buckling claw 816 is opened with a hinge through hole 8161, and the rotating disc 814 is opened with a receiving groove 8142 corresponding to each buckling claw 816. The first side wall and the second side wall opposite to each accommodating groove 8142 are respectively provided with a corresponding first through hole 8144 and a corresponding second through hole 8143, the second side wall of each accommodating groove 8142 is further provided with a third through hole 8145 which is communicated with the second through hole 8143 and is vertically arranged, a shaft pin 827 is inserted into the first through hole 8144, a hinge through hole 8161 and the second through hole 8143, an annular groove 8271 of the shaft pin 827 is positioned at the communicated part of the second through hole 8143 and the third through hole 8145, a fifth fastener (not marked) is inserted into the third through hole 8145 and is abutted against the annular groove 8271, the fifth fastener comprises but not limited to a screw, a bolt, an expansion pin, a pin column and other fastening parts, and the expansion pin has a similar operation principle as an expansion bolt. When the fifth fastening member is a fastening part having an external thread such as a screw, a bolt, or the like, the corresponding third penetration hole 8145 has an internal thread, so that the fifth fastening member is screw-fitted with the third penetration hole 8145 and one end is abutted in the annular groove 8271.

Each group of ear band welding devices 8 further comprises a band feeding plate 813 and a band guiding rod 82, the band feeding plate 813 is installed on the linkage plate 85, the band feeding plate 813 is provided with a first hole penetrating hole 8131 with the axis parallel to the vertical direction, the first end of the band guiding rod 82 is connected with the band feeding plate 813, the second end of the band guiding rod 82 is provided with a second hole penetrating hole 821 with the axis perpendicular to the vertical direction, the band guiding rod 82 and the line pressing plate 81 are respectively located on two opposite sides of the linkage plate 85, and one band guiding hole 71 is basically located right above one first hole penetrating hole 8131 in the vertical direction. The first perforating hole 8131 is sleeved with a rubber sleeve.

Each set of ear strap welding means 8 further comprises two strap baffles 817, one strap baffle 817 being mounted above one of the strap baffles 815 and having a projecting lip extending outwardly therefrom. Each of the tape winding plates 815 has a tape winding slot 8151 formed in an outer wall thereof, and the tape winding slot 8151 extends in a rotation direction of the rotating disc 814. Each of the belt winding plates 815 is provided with a first avoidance groove 8152, each of the belt blocking plates 817 is provided with a second avoidance groove 8171 corresponding to the first avoidance groove 8152, the wire pressing plate 81 is provided with a pressing block 826, and the pressing block 826 can be inserted into one of the first avoidance grooves 8152 and one of the second avoidance grooves 8171.

Each ear strap welding device 8 further comprises a photoelectric sensor 810, a rotating disc 811 is connected to the top end of the driving motor 89, and the driving motor 89 controls the rotating disc 811 to rotate synchronously with the rotating disc 814. Photoelectric sensor 810 is equipped with the recess, and the periphery of rolling disc 811 is embedded into the recess, and rolling disc 811 adjoins the periphery and has seted up two breach 8111, and two breach 8111 set up about the axis symmetry of rolling disc 811. When the driving motor 89 controls the rotating disc 811 and the rotating disc 814 to rotate synchronously for a half circle, the photoelectric sensor 810 can sense through the notch 8111, and the accuracy and reliability of the work are improved.

Each set of ear strap welding device 8 further comprises a proximity switch 823, a guide rod 824 and a connecting plate 825, wherein the wire pressing plate 81 and the two pressing plates 820 are respectively connected with the connecting plate 825, and the second cylinder 822 controls the connecting plate 825 to move in the vertical direction. The first end of the guide rod 824 is connected to the connecting plate 825, the second end of the guide rod 824 is movably disposed through the linkage plate 85, and the proximity switch 823 is located above the linkage plate 85 and is used for sensing the second end of the guide rod 824.

Referring to fig. 17, two tension plates 81 of two sets of ear band welding devices 8 adapted to the flat mask ear band welding machine 3 are respectively located at the outer sides of the two ends of the flat mask, and the flat mask ear band welding machine 3 is used for producing the external ear mask 1. The free end of the ear strap is wound around the ear strap rod 61 of the ear strap feeding device 6 and is wound on the jumping wheel 610 through the abutting positions among the first strap passing hole 641, the tension wheel 65 and the thread trimming wheel 66 in turn, then the free end of the ear strap is wound on the thread guiding wheel 67 and is passed through the second strap passing hole 6121, then the free end of the ear strap is passed through the third strap passing hole 6141 adjacent to the strap guiding hole 71 located substantially directly above the first strap passing hole 8131 and is then passed into the strap guiding hole 71 located substantially vertically directly above the first strap passing hole 8131, and then the free end of the ear strap is fastened on the first side of the rotating disk 814 by the adjacent fastening claw 816 through the first and second strap passing holes 8131 and 821 in turn. The above-described ear band feeding manner is applicable to two sets of ear band feeding devices 6, the assembly plate 7, and two sets of ear band welding devices 8.

When the second sensor 520 on the conveying device 5 detects that the planar mask 1 to be welded at the front end station of the front end guide plate 55 is in place, the driving mechanism controls the two conveying chains 51 to synchronously move in the same direction. As the two conveying chains 51 move, one end of the planar mask 1 to be welded, which is located on the front end station jig 52, is located on the front end ultrasonic transducer 20 after passing through the guide segment 551 and the support segment 552 of the front end guide plate 55, and the other end of the planar mask 1, which is located on the front end ultrasonic transducer 20 and has been welded with the ear band, is located on the rear end ultrasonic transducer 20 after passing through the guide segment 551 and the support segment 552 of the rear end guide plate 55. The two first sensors 519 of the conveying device 5 respectively sense that the plane masks 1 on the two ultrasonic transducers 20 are in place, and the two groups of ear band welding devices 8 perform ear band welding operation.

The driving motor 89 of each ear band welding device 8 controls the rotating disc 814 to rotate 180 °, and the fastening claw 816 located on the first side of the rotating disc 814 and adjacent to the second perforation hole 821 fastens the free end of the ear band on the first side of the rotating disc 814, and the ear band is wound on the winding plate 815 on the third side of the rotating disc 814 and the first side of the rotating disc 814 along with the rotation of the rotating disc 814. Then, the third air cylinder 812 controls the two pressing heads 819 to move downward in the vertical direction, so that the two pressing heads 819 press against the fastening ends 8162 of the two fastening claws 816 on the first side of the rotating disc 814, and the two fastening claws 816 on the first side of the rotating disc 814 are forced to fasten the ear straps on the first side of the rotating disc 814. Subsequently, the scissors driving cylinder 93 of the ear band cutting device 9 located at the first side of the rotating disc 814 controls the pneumatic scissors 94 to extend into the clearance slot 8141 at the first side of the rotating disc 814 to cut the ear band, at this time, the third cylinder 812 controls the two pressing heads 819 to move upwards in the vertical direction to reset, and the stopping assembly forces the two clasps 816 at the first side of the rotating disc 814 to maintain the clasped state. Then, the second cylinder 822 controls the line pressing plate 81 and the two pressing plates 820 to move downwards in the vertical direction, the line pressing plate 81 presses and fixes the outer ear bands on the ultrasonic transducer 20, the pressing block 826 on the line pressing plate 81 is inserted into the first avoiding groove 8152 and the second avoiding groove 8171, then the two pressing plates 820 press and press the opening arms 8163 of the two claws 816 close to the line pressing plate 81 and located on the two opposite sides to force the two claws 816 to open, and then the two claws 816 loosen the outer ear bands. Subsequently, the first cylinder 86 controls the moving plate 84 to move downward in the vertical direction, so that the two linkage rods 87 drive the linkage plate 85, the two welding heads 818 and the rotating disc 814 to move downward in the vertical direction together, the rotating disc 814 presses and fixes one end of the planar mask 1 on the ultrasonic transducer 20, the two linkage rods 87 drive the two welding heads 818 to move downward continuously as the moving plate 84 is controlled by the first cylinder 86, the two welding heads 818 are inserted into the two avoiding grooves 8141 which are arranged opposite to the rotating disc 814 respectively, so that the outer ear band 12 is welded to one end of the planar mask 1, and at this time, the compression spring 88 sleeved on the linkage rods 87 is in a compressed state. After that, the first cylinder 86 controls the moving plate 84 to move upward in the vertical direction for resetting, the two linkage rods 87 drive the two welding heads 818 to move upward in the vertical direction for resetting, and along with the resetting of the compression spring 88 from the compressed state, the linkage plate 85 is forced to drive the rotating disc 814 to keep pressing and fixing one end of the planar mask 1 on the ultrasonic transducer 20, so that when the two welding heads 818 are separated from the planar mask 1, the rotating disc 814 still presses and fixes one end of the planar mask 1 on the ultrasonic transducer 20, and the planar mask 1 is prevented from being brought up when the welding heads 818 are separated from the planar mask 1. Then, as the first cylinder 86 continues to control the moving plate 84 to move upward in the vertical direction for resetting, the two welding heads 818, the linkage plate 85, the rotating disk 814, the wire pressing plate 81 and the two pressing plates 820 subsequently move upward in the vertical direction for resetting.

When the proximity switch 823 senses the second end of the guide rod 824, it indicates that the ear band welding device 8 is reset in the vertical direction, and the driving mechanism of the conveying device 5 controls the two conveying chains 51 to move, so as to perform the above steps in a reciprocating cycle, so as to realize the ear band welding of the external ear mask 1.

Referring to fig. 28, two line ball boards 81 of two sets of ear strap welding set 8 of 3 adaptations of plane gauze mask ear strap welding machine are located the inboard at the both ends of plane gauze mask respectively, this moment plane gauze mask ear strap welding machine 3 is used for producing interior ear gauze mask 2, two sets of ear strap welding set 8 of plane gauze mask ear strap welding machine 3 of producing external ear gauze mask 1 rotate 180 respectively promptly and install on assembly plate 7, make two line ball boards 81 of two sets of ear strap welding set 8 be located the inboard at the both ends of plane gauze mask 2 respectively, alright make plane gauze mask ear strap welding machine 3 be used for producing interior ear gauze mask 2.

This embodiment plane gauze mask ear area welding machine 3 is applicable in production interior ear gauze mask 2 and outer ear gauze mask 1, and production simple operation realizes full automated production, uses manpower sparingly, and production efficiency is high, low in production cost.

Above embodiment is the preferred example of the utility model, and not the restriction the utility model discloses the range of implementing, the event all according to the utility model discloses the equivalent change or the decoration that structure, characteristic and principle were done of application for patent scope all should be included in the utility model discloses the patent application scope.

Claims (10)

1. Ear area welding set, including fixed plate, movable plate and first cylinder, the movable plate is located in vertical direction the below of fixed plate, first cylinder is installed on the fixed plate and steerable the movable plate moves its characterized in that in vertical direction:

the ear band welding device further comprises a linkage plate, two linkage rods, two pressure springs, two welding joints, a rotating disc, a driving motor, a second cylinder, a third cylinder, two pressure resisting heads, two pressure resisting plates and a line pressing plate, wherein the linkage plate is located below the moving plate in the vertical direction, first ends of the two linkage rods are respectively connected with the moving plate, second ends of the two linkage rods are respectively connected with the two welding joints in a manner of penetrating through the linkage plate, one pressure spring is sleeved on one linkage rod and is pressed between the moving plate and the linkage plate, an ultrasonic transducer is arranged right below the two welding joints in the vertical direction, and one end of the planar mask can be placed on the ultrasonic transducer;

the rotating disc is located below the linkage plate in the vertical direction, the driving motor is mounted on the linkage plate and controls the rotating disc to rotate, two buckling claws are arranged on the first side of the rotating disc, two buckling claws are also arranged on the second side, opposite to the first side, of the rotating disc, belt winding plates are respectively arranged on the third side and the fourth side, opposite to the rotating disc, of the rotating disc, one belt winding plate can be located below the wire pressing plate in the vertical direction, and the second cylinder is mounted on the linkage plate and controls the wire pressing plate and the two pressing plates to move in the vertical direction;

the first side and the second side of the rotating disc are respectively provided with a position avoiding groove which are oppositely arranged, one position avoiding groove is positioned between the two buckling claws at the same side, one welding head can be inserted into one position avoiding groove, each buckling claw is hinged with the rotating disc, each buckling claw is provided with a buckling end and an opening arm, the third air cylinder is arranged on the linkage plate and controls the two pressure resisting heads to move in the vertical direction, and the two pressure resisting heads can be pressed on the buckling ends of the two buckling claws at the same side to force the two buckling claws to be buckled on the side surface of the rotating disc;

the two pressing plates can be pressed on the opening arms of the two buckling claws close to the wire pressing plate and located on two opposite sides to force the two buckling claws to open, the rotating disc is provided with a stopping component below each buckling claw, and one stopping component forces one buckling claw to keep a buckling/opening state.

2. The ear band welding device according to claim 1, characterized in that:

the ear belt welding device further comprises a belt feeding plate and a belt leading rod, the belt feeding plate is installed on the linkage plate, a first belt penetrating hole with an axis parallel to the vertical direction is formed in the belt feeding plate, a first end of the belt leading rod is connected with the belt feeding plate, a second belt penetrating hole with an axis perpendicular to the vertical direction is formed in a second end of the belt leading rod, and the belt leading rod and the wire pressing plate are located on two opposite sides of the linkage plate respectively.

3. The ear band welding device according to claim 2, characterized in that:

ear area welding set still includes two fender band boards, one keep off the band board and install one it has protruding eaves portion just outwards to extend around the top of band board.

4. The ear band welding device according to claim 3, characterized in that:

and a winding belt groove is formed in the outer wall of each belt winding plate and extends along the rotating direction of the rotating disc.

5. The ear band welding device according to claim 4, characterized in that:

each the first groove of dodging has been seted up to the winding band board, each keep off the band board set up with the first second that corresponds of dodging the groove dodges the groove, be provided with the briquetting on the pressure line board, the briquetting can insert one the first groove and one of dodging the second dodges the inslot.

6. The ear band welding device according to claim 1, characterized in that:

the ear belt welding device further comprises a photoelectric sensor, the top end of the driving motor is connected with a rotating disc, and the driving motor controls the rotating disc and the rotating disc to rotate synchronously;

the photoelectric sensor is provided with a groove, the periphery of the rotating disc is embedded into the groove, two notches are formed in the periphery of the rotating disc in an adjacent mode, and the two notches are symmetrically arranged relative to the axis of the rotating disc.

7. The ear band welding device according to claim 1, characterized in that:

the ear belt welding device further comprises a proximity switch, a guide rod and a connecting plate, the wire pressing plate and the two abutting pressing plates are respectively connected with the connecting plate, and the second cylinder controls the connecting plate to move in the vertical direction;

the first end of the guide rod is connected with the connecting plate, the second end of the guide rod movably penetrates through the linkage plate, and the proximity switch is located above the linkage plate and used for sensing the second end of the guide rod.

8. The ear band welding device according to any one of claims 1 to 7, characterized in that:

the ear belt welding device further comprises four shaft pins, an annular groove is formed in the outer peripheral wall of each shaft pin, each buckling claw is provided with a hinge through hole, and the rotating disc is provided with an accommodating groove corresponding to each buckling claw;

the first side wall and the second side wall opposite to each accommodating groove are respectively provided with a first through hole and a second through hole which correspond to each other, the second side wall of each accommodating groove is further provided with a third through hole which is communicated with the second through hole and is vertically arranged, one shaft pin is inserted into one first through hole, one hinge through hole and one second through hole, the annular groove of one shaft pin is positioned at the communicated position of the second through hole and the third through hole, and a fastener is inserted into the third through hole and abuts against the annular groove.

9. The ear band welding device according to claim 8, characterized in that:

the bottom of each buckling claw is provided with a flange, each stopping component comprises a ball, a spring and a sleeve, the sleeve is installed in the rotating disc, the ball is rotatably arranged at the top end of the sleeve, the spring is arranged in the sleeve and abuts between the ball and the bottom of the sleeve, and the flange and the ball are abutted with each other.

10. Plane gauze mask ear area welding machine, including ear area welding set, its characterized in that:

the ear band welding device according to any one of the preceding claims 1 to 9.

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