CN216829308U - Welding machine conveyer and welding machine - Google Patents
Welding machine conveyer and welding machine Download PDFInfo
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- CN216829308U CN216829308U CN202220009798.6U CN202220009798U CN216829308U CN 216829308 U CN216829308 U CN 216829308U CN 202220009798 U CN202220009798 U CN 202220009798U CN 216829308 U CN216829308 U CN 216829308U
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Abstract
The utility model relates to a welding engineering technical field particularly, relates to a welding machine conveyer and welding machine. The utility model provides a problem: the problem of not being able to continuously heat the bit body coated with the solder paste. In order to solve the above problem, an embodiment of the present invention provides a conveying device, which includes: the heating part is provided with a heating space and is used for heating the bit body; the conveying part is provided with an installation position for installing the bit body, and the conveying part is used for conveying the bit body to the heating part; the plurality of installation positions are arranged, and the plurality of bit bodies sequentially pass through the heating space when the conveying part conveys the bit bodies.
Description
Technical Field
The utility model relates to a welding engineering technical field particularly, relates to a welding machine conveyer and welding machine.
Background
In order to improve the drilling hardness and the drilling efficiency of the construction drill, the conventional construction drill is generally provided with a hard alloy sheet embedded in the head of a drill bit to form a drill bit body, and the drill bit and the alloy sheet are connected more firmly by smearing soldering paste and heating and melting the soldering paste.
At present, the existing automatic welding machine can only heat a single bit body, and the bit body coated with soldering paste cannot be continuously heated, so that the working efficiency is low.
SUMMERY OF THE UTILITY MODEL
The utility model provides a problem: the problem of not being able to continuously heat the bit body coated with the solder paste.
In order to solve the above problem, an embodiment of the utility model provides a welding machine conveyer, conveyer includes: the heating part is provided with a heating space and is used for heating the bit body; the conveying part is provided with an installation position for installing the bit body, and the conveying part is used for conveying the bit body to the heating part; the plurality of installation positions are arranged, and the plurality of bit bodies sequentially pass through the heating space when the conveying part conveys the bit bodies.
Compared with the prior art, the technical scheme has the following technical effects: the heating part can heat the bit body, and finally after the heating part is heated to a certain temperature, the soldering paste on the bit body can be melted, so that the welding of the bit body is realized; the realization of the setting of sensor is through setting up sensor and heating element to the detection of welding portion temperature, has promoted the welding efficiency of welding portion, has also reduced the welding time simultaneously.
In an embodiment of the present invention, the transfer portion includes: a rotating member that can rotate relative to the heating portion; the first end of the mounting plate is connected with the rotating piece, and the mounting position is arranged at the second end of the mounting plate; the drill bit body is arranged on the mounting plate, and the mounting plate moves along with the rotating piece and drives the drill bit body.
Compared with the prior art, the technical scheme has the following technical effects: the sunken bit body that lets on the mounting panel can be more stable places on the mounting panel, and the rotation piece can drive the mounting panel and remove, lets in the bit body can get into the heating space, and the setting of circulation pivoted lets in the heating space continuously keep having the bit body to pass through, has increased work efficiency.
In an embodiment of the present invention, the present invention further includes: and the connecting plate is arranged on the rotating piece, is positioned between the rotating piece and the mounting plate and is used for supporting the mounting plate.
Compared with the prior art, the technical scheme has the following technical effects: the setting of connecting plate lets the mounting panel more stable when rotating along with, also lets the position that the bit body was placed can adjust according to the difference of bit body model and other actual conditions, has increased conveyer's practicality.
In an embodiment of the present invention, the present invention further includes: the number of the connecting plates is multiple, and each connecting plate is connected with two adjacent connecting plates in a matching way; the rotating piece can continuously convey the drill bit body to the heating space when rotating.
Compared with the prior art, the technical scheme has the following technical effects: a plurality of connecting plate final phase of a project are connected and are covered whole rotation piece, let rotate when the circulation rotates, the drill bit body can be stable place on the mounting panel, can not appear the unable condition of placing the drill bit body of transport mechanism when rotating to certain position, also let whole conveyer become more pleasing to the eye simultaneously.
In an embodiment of the present invention, the mounting plate includes: the first mounting plate is arranged on one side, away from the heating part, of the connecting plate, and the distance between one end, away from the connecting plate, of the first mounting plate and the connecting plate is a first distance H1(ii) a A second mounting plate, wherein the first mounting plate is arranged on one side of the connecting plate close to the heating part, and the distance between one end of the first mounting plate far away from the connecting plate and the connecting plate is a second distance H2(ii) a Wherein the first distance H1At a second distance H2Satisfies the following conditions: h1≤H2(ii) a The first mounting plate is provided with a first notch, the second mounting plate is provided with a second notch, and two ends of the drill bit body are respectively arranged in the first notch and the second notch.
Compared with the prior art, the technical scheme has the following technical effects: the position of the drill bit body placed by the conveying mechanism is more accurate due to the arrangement of the first notch and the second notch, the drill bit body is supported by the first mounting plate and the second mounting plate together, the placement of the drill bit body is more stable, and the first distance H is longer1At a second distance H2The arrangement of the welding head enables the drill bit body to be in an inclined state in the moving process, and solder paste at one end, close to the heating part, of the drill bit body can flow along the drill bit body when being melted, so that the welding of the drill bit and the alloy sheet is faster and firmer.
In an embodiment of the present invention, the present invention further includes: a baffle plate, wherein the distance between one end of the baffle plate far away from the connecting plate and the connecting plate is a third distance H3First distance H1At a third distance H3Satisfies the following conditions: h3≤H1。
Compared with the prior art, the technical scheme has the following technical effects: the arrangement of the baffle plate enables the inclined drill body not to fall along the inclined direction in the moving process, and the stability of the conveying device is improved.
In an embodiment of the present invention, the heating part includes: a heater; the heating plate is connected with the heater, and the heating plate is bent to form a heating space.
Compared with the prior art, the technical scheme has the following technical effects: the heater and the heating plate are arranged to form a heating space, so that the soldering paste at one end of the bit body close to the heating part can be melted in the moving process, and the welding work is completed.
In an embodiment of the present invention, the present invention further includes: a gas protection device disposed in the heating space and connected to the heater.
Compared with the prior art, the technical scheme has the following technical effects: the gas protection device is arranged between the upper layer of heating plate and the lower layer of heating plate, one side of the gas protection device close to the bit body is provided with a plurality of small holes, and when the bit body passes through the heating space, protective gas is sprayed out of the small holes to protect the welding of the bit body.
The utility model discloses an in an embodiment, still provide a welding machine, the welding machine is used for the welding between drill bit and the alloy piece, and the welding machine includes: a third mounting plate; the conveying device is arranged on one side of the third mounting plate; the alignment mechanism is arranged on one side, far away from the conveying device, of the third mounting plate and used for adjusting the direction of the drill bit; the chip mounting mechanism is arranged on one side, close to the alignment mechanism, of the third mounting plate and can assemble the drill bit and the alloy chips to form a drill bit body; the paste dispensing mechanism is arranged on the third mounting plate, is positioned between the chip mounting mechanism and the conveying device and is used for dispensing paste on the bit body; and the conveying mechanism is used for conveying the drill bit and the drill bit body.
Compared with the prior art, the technical scheme has the following technical effects: the alignment mechanism aligns the position of the drill bit, the sheet loading mechanism is convenient to install the alloy sheet, the paste dispensing mechanism dispenses paste on the joint of the alloy sheet and the drill bit, the drill bit body is welded when passing through the heating part, and the conveying mechanism transfers the drill bit or the drill bit body in the mechanism, so that the continuous work of welding the drill bit body is realized, and the working efficiency is improved.
To sum up, adopt the technical scheme of the utility model afterwards, can reach following technological effect:
i) the hot part can heat the bit body, and finally after the bit body is heated to a certain temperature, the soldering paste on the bit body can be melted, so that the welding of the bit body is realized; the sensor is arranged to detect the temperature of the welding part, the welding efficiency of the welding part is improved by arranging the sensor and the heating assembly, and meanwhile, the welding time is also reduced;
ii) the drill bit body can be stably placed on the mounting plate due to the recess in the mounting plate, the rotating piece can drive the mounting plate to move, the drill bit body can enter the heating space, and the drill bit body can be continuously kept to pass through the heating space due to the circular rotation arrangement, so that the working efficiency is improved;
and iii) the alignment mechanism aligns the position of the drill bit, so that the alloy sheet is conveniently installed by the sheet loading mechanism, the paste dispensing mechanism dispenses paste at the joint of the alloy sheet and the drill bit, the drill bit body is welded when passing through the heating part, and the conveying mechanism transfers the drill bit or the drill bit body in the mechanism, so that the continuous operation of welding the drill bit body is realized, and the working efficiency is improved.
Drawings
FIG. 1 is a schematic view of the overall structure of the present invention;
FIG. 2 is a side view of FIG. 1;
FIG. 3 is a schematic structural view of the drill bit of the present invention when connected to the mounting plate;
fig. 4 is a schematic structural view of the first mounting plate and the baffle plate of the present invention;
fig. 5 is a schematic structural diagram of a second mounting plate of the present invention;
fig. 6 is a schematic structural view of the alignment mechanism of the present invention;
FIG. 7 is a schematic structural view of the paste dispensing mechanism of the present invention connected to a third mounting plate;
fig. 8 is a schematic structural view of the connection between the transportation mechanism and the third mounting plate of the present invention;
FIG. 9 is a schematic structural view of the loading mechanism of the present invention;
FIG. 10 is a schematic view of the overall structure of the welding machine;
FIG. 11 is a schematic view of the installation of the gas protecting device of the present invention;
FIG. 12 is a schematic view of the combination of the bit body and the gas shield apparatus of the present invention;
FIG. 13 is a front view of FIG. 12;
fig. 14 is an enlarged view at C in fig. 13.
Description of reference numerals:
100-a transfer section; 110-a rotating member; 120-a mounting plate; 130-a connecting plate; 121-a first mounting plate; 121 a-first notch; 122-a second mounting plate; 122 a-a second gap; 123-a second end; 124-a first end; 140-a heater; 150-a heating plate; 151-a heating space; 160-a baffle; 200-a bit body; 210-a drill bit; 220-alloy sheet; 300-a third mounting plate; 400-a welding machine; 410-an alignment mechanism; 420-paste dispensing mechanism; 430-a transport mechanism; 431-a first finger; 432-a second finger; 433-third finger grip; 440-a mounting mechanism; 450-gas protection device; 451-small holes; 500-a transfer device; first distance-H1(ii) a Second distance-H2(ii) a Third distance-H3。
Detailed Description
In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, embodiments accompanied with figures are described in detail below.
[ first embodiment ] A
Referring to fig. 1, 2, and 10, in one particular embodiment, the present invention provides a conveyor 500, the conveyor 500 comprising: a heating part provided with a heating space 151 for heating the bit body 200; the conveying part 100, the conveying part 100 is provided with an installation position for installing the bit body 200, and the conveying part 100 is used for conveying the bit body 200 to the heating part; wherein, a plurality of installation positions are provided, and when the transfer part 100 conveys the bit body 200, the plurality of bit bodies 200 are sequentially passed through the heating space 151.
The conveying device 500 conveys the bit body 200 conveyed by the conveying mechanism 430 through the conveying part 100, the conveying mechanism 430 places the bit body 200 on the installation position of the conveying part 100, a plurality of installation positions are arranged on the conveying part 100, the bit body 200 can be placed on each installation position, the bit body 200 passes through the heating space 151 under the driving of the conveying part 100 and falls to an external storage place after being heated by the heating part, and the heating part is provided with a temperature sensor for detecting the temperature in the heating space 151.
The bit body 200 is composed of a drill 210 and an alloy sheet 220, the transport mechanism 430 transports the bit body 200 coated with solder paste to the installation position of the transfer part 100, the transfer part 100 drives the bit body 200 to move through rotation, the joint of the drill 210 and the alloy sheet 220 enters the heating space 151, the solder paste is rapidly melted under the temperature rise, the alloy sheet 220 and the drill 210 are firmly connected, and when one bit body 200 leaves the transfer part 100 to enter and exit an external storage part in the motion direction of the transfer part 100, the transport mechanism 430 can place a new bit body 200 on the transfer part 100, and the continuous welding operation is ensured.
Preferably, the temperature sensor is used for observing the temperature in the heating space 151, and when the production needs to be accelerated, the temperature of the heating part is controlled to accelerate the melting speed of the solder paste, and meanwhile, the conveying interval of the conveying mechanism 430 and the conveying speed of the conveyor belt are accelerated, so that the bit body 200 can rapidly pass through the heating space 151, and the number of the bit bodies 200 which are heated in unit time is increased.
The heating part can heat the bit body 200, and finally, after the heating part is heated to a certain temperature, the soldering paste on the bit body 200 can be melted, so that the welding of the bit body 200 is realized; the realization of the setting of sensor is through setting up sensor and heating element to the detection of welding portion temperature, has promoted the welding efficiency of welding portion, has also reduced the welding time simultaneously.
[ second embodiment ] A
In a particular embodiment, the transfer portion 100 includes: a rotating member 110, the rotating member 110 being rotatable with respect to the heating part; a mounting plate 120, a first end of the mounting plate 120 being connected to the rotating member 110, and a mounting location being provided at a second end of the mounting plate 120; the bit body 200 is placed on the mounting plate 120, and the mounting plate 120 moves along with the rotary member 110 and drives the bit body 200.
The rotating part 110 is located at the lower end of the heating part, the mounting plate 120 is in an L shape, the first end of the mounting plate 120 is connected with the rotating part 110, the second end of the mounting plate 120 is bent in a V shape, the bit bodies 200 are placed in the V-shaped concave positions of the second end of the mounting plate 120, two V-shaped concave positions are arranged on the second end, the two bit bodies 200 can be placed on the mounting plate 120 in parallel, the side surface of the rotating part 110 is in a straight groove shape and rotates circularly, the side, close to the heating part, of the rotating part 110 and the side, far away from the heating part, of the rotating part are horizontal planes, the other parts are cambered surfaces, the bit bodies 200 are placed on the mounting plate 120, close to the heating part, of the rotating part 110, and leave the conveying part 100 to enter an external storage place when the rotating part 110 moves into the cambered surface.
When the transmission device 500 is operated, the rotation member 110 starts to rotate circularly by the driving of the driving device, the mounting plate 120 mounted on the rotation member 110 follows the rotation member 110, when the rotation member 110 moves to a side close to the heating space 151, the transport mechanism 430 places the bit body 200 coated with the solder paste at an installation position, the vertical height of the front end of the bit body 200 is within the height ranges of the upper and lower ends of the heating space 151, during the moving process, the front end of the bit body 200 enters the heating space 151, the solder paste melts in the heating space 151 to make the connection between the drill 210 and the alloy sheet 220 more firm, and after the heating is completed, the bit body 200 falls when the mounting plate 120 moves to the arc surface, the mounting plate 120 returns to the side close to the heating part after rotating the rotating member 110 for one turn, and at the moment, the transportation mechanism 430 puts a new bit body 200 on the mounting position again, so that the cycle work of welding the front end of the bit body 200 is realized.
Preferably, the V-shaped recess on the mounting plate 120 may be increased, so that more bit bodies 200 may be placed on one mounting plate 120, or different mounting plates 120 may be replaced according to different sizes of drill bits 210, so that more bit bodies 200 may pass through the heating space 151 in a unit time, thereby improving the working efficiency.
The recess on the mounting plate 120 allows the bit body 200 to be more stably placed on the mounting plate 120, the rotating member 110 can drive the mounting plate 120 to move, the bit body 200 can enter the heating space 151, and the circulating rotation arrangement allows the heating space 151 to continuously keep the bit body 200 passing through, so that the working efficiency is increased.
[ third embodiment ]
In a specific embodiment, the method further comprises the following steps: the connecting plate 130 is disposed on the rotating member 110, and is located between the rotating member 110 and the mounting plate 120, for supporting the mounting plate 120.
The connecting plate 130 is connected to the rotating member 110, the second end of the mounting plate 120 is attached to the side of the connecting plate 130 near the heating space 151, and the mounting plate 120 and the connecting plate 130 rotate together with the rotating member 110.
Preferably, the mounting position of the mounting plate 120 on the connecting plate 130 can be adjusted, so that the transportation mechanism 430 can more accurately place the bit body 200 on the mounting position, when the bit body 200 to be welded is shorter, the mounting plate 120 can be appropriately moved to the side close to the heating space 151, and when the bit body 200 to be welded is longer, the mounting plate 120 can be appropriately moved to the side away from the heating space 151, so that the transportation device 500 can transport bit bodies 200 of different models.
The arrangement of the connecting plate 130 makes the mounting plate 120 more stable when rotating with the rotary member 110, and also makes the position of the bit body 200 adjustable according to the type of the bit body 200 and other practical conditions, thereby increasing the practicability of the transmission device 500.
[ fourth example ] A
In a specific embodiment, the method further comprises the following steps: the number of the connecting plates 130 is multiple, and each connecting plate 130 is connected with two adjacent connecting plates 130 in a matching way; the rotary member 110 can continuously deliver the bit body 200 to the heating space 151 while rotating.
The upper and lower ends of the connecting plates 130 are provided with through holes, the through hole at the lower end of the previous connecting plate 130 is connected with the through hole at the upper end of the next connecting plate 130, the connecting plates 130 are provided in plurality, the plurality of connecting plates 130 are connected in a tail-end manner to cover the rotation path of the rotating member 110, and each connecting plate 130 is correspondingly provided with a mounting plate 120 for placing the bit body 200.
The plurality of connecting plates 130 are connected in a terminating manner to cover the entire rotating member 110, so that the bit body 200 can be stably placed on the mounting plate 120 when the rotating member 110 rotates circularly, the situation that the transporting mechanism 430 cannot place the bit body 200 when the rotating member rotates to a certain position is avoided, and the whole conveying device 500 is more attractive.
[ fifth embodiment ]
Referring to fig. 3, 4, and 5, in one particular embodiment, the mounting plate 120 includes: a first mounting plate 121, the first mounting plate 121 is disposed on one side of the connecting plate 130 away from the heating portion, and a distance between one end of the first mounting plate 121 away from the connecting plate 130 and the connecting plate 130 is a first distance H1(ii) a A second mounting plate 122, wherein the first mounting plate 121 is disposed on one side of the connecting plate 130 close to the heating portion, and the first mounting plate 121 is far away from the connecting plate 130The distance between one end and the connecting plate 130 is a second distance H2(ii) a Wherein the first distance H1At a second distance H2Satisfies the following conditions: h1≤H2(ii) a The first mounting plate 121 is provided with a first notch 121a, the second mounting plate 122 is provided with a second notch 122a, and two ends of the bit body 200 are respectively disposed in the first notch 121a and the second notch 122 a.
The first mounting plate 121 is mounted on the connecting plate 130, the upper end of the first mounting plate 121 is bent to form a first notch 121a, the lower end of the first mounting plate is attached to the connecting plate 130, two straight notches are formed in the attachment surface of the first mounting plate 121 and the connecting plate 130, and the first mounting plate 121 is fixedly connected with the connecting plate 130 through the straight notches; the second connecting plate 130 is installed on the connecting plate 130, the upper end of the second mounting plate 122 is bent to form a second notch 122a, two through holes are formed in the binding face with the connecting plate 130, the second mounting plate 122 is bound and connected with the connecting plate 130 through the through holes, and a mounting position is formed between the first notch 121a and the second notch 122 a.
Each connecting plate 130 is provided with a first mounting plate 121 and a second mounting plate 122, the distance from the end of the first mounting plate 121 far away from the heating portion to the end of the connecting plate 130 far away from the heating portion on each connecting plate 130 is the same, the distance from the end of the second mounting plate 122 near the heating portion to the end of the connecting plate 130 near the heating portion is the same, the first gap 121a and the second gap 122a are generally V-shaped, and when the bit body 200 is placed on the mounting plates, the first gap 121a and the second gap 122a slide down.
When the transfer device 500 is operated, the mounting plate 120 moves along with the connecting plate 130, the transport mechanism 430 places the bit body 200 on the mounting plate 120, one end of the bit body 200 is placed in the first gap 121a, the other end of the bit body 200 is placed in the second gap 122a, and when the first distance H is reached1Is equal to the second distance H2The bit body 200 is horizontally disposed when the first distance H is1Less than the second distance H2When the bit body 200 is heated in the heating space 151, the solder paste on the side of the bit body 200 that is raised upward melts at a high temperature, and the melted solder paste flows along the inclined direction of the bit body 200, thereby facilitating the welding of the bit 210 and the alloy sheet 220.
Preferably, by varying the first distance H1At a second distance H2The ratio of the first temperature and the second temperature may be adjusted to adjust the angle at which the bit body 200 is raised, and then the temperature in the heating space 151 may be adjusted to match the angle, so that the melted solder paste may not directly drop off the bit body 200.
Preferably, the first notch 121a and the second notch 122a may also be circular arcs, and the circular arcs are more attached to the outer surface of the bit body 200, so that the bit body 200 is more stable when moving on the conveyor 500 and is not easily dropped due to the vibration of the external environment.
The first gap 121a and the second gap 122a are arranged to enable the position of the transportation mechanism 430 for placing the bit body 200 to be more accurate, the first mounting plate 121 and the second mounting plate 122 support the bit body 200 together, the placement of the bit body 200 is enabled to be more stable, and the first distance H is longer1At a second distance H2The arrangement of the welding structure enables the drill bit body 200 to be in an inclined state in the moving process, and solder paste at one end, close to the heating part, of the drill bit body 200 can flow along the drill bit body 200 when being melted, so that the welding of the drill bit 210 and the alloy sheet 220 is faster and firmer.
[ sixth embodiment ]
Referring to fig. 4, in a specific embodiment, the method further includes: the distance between one end of the baffle 160 far away from the connecting plate 130 and the connecting plate 130 is a third distance H3First distance H1At a third distance H3Satisfies the following conditions: h3≤H1。
The baffle 160 is connected to the first mounting plate 121, the baffle 160 and the second mounting plate 122 are disposed on opposite sides of the first mounting plate 121, and a third distance H is formed between the baffle 160 and one end of the connecting plate 1303Is less than or equal to the first distance H1。
When the conveying device 500 works, the whole body of the bit body 200 is obliquely arranged and slides down towards the direction of the baffle 160 under the action of gravity, in the sliding process, one end of the bit body 200, which is far away from the heating part, is in contact with the baffle 160 and stops sliding under the supporting action of the baffle 160, the arrangement of the first notch 121a and the second notch 122a also prevents the bit body 200 from rolling on an installation position, and when the bit body 200 is in contact with the baffle 160, one end of the bit body 200, which is close to the heating part, is still positioned in the heating space 151, so that the normal operation of the welding process is ensured.
Preferably, when the bit body 200 to be transported is too long, one end of the baffle 160 may be directly connected to the connection plate 130, and the third distance H may be adjusted accordingly3The value of (a) and the distance between the first mounting plate 121 and the baffle 160 ensure that the rear end of the bit body 200 can contact the baffle 160 in the case that the front end of the bit body 200 enters the heating space 151, so that the transfer device 500 can transfer bit bodies 200 of different lengths.
The provision of the baffle 160 allows the angled bit body 200 to be moved without falling in an oblique direction, which increases the stability of the transport apparatus.
[ seventh example ]
Referring to fig. 2, in one particular embodiment, the heating part includes: a heater 140; the heating plate 150, the heating plate 150 is connected with the heater 140, and the heating plate 150 is bent to form a heating space 151.
The heating plate 150 is connected with the heater 140, the heating plate 150 is bent to form an upper layer and a lower layer, a heating space 151 is formed between the upper layer and the lower layer, the height of the upper layer of the heating plate 150 is higher than the height of the bit body 200 close to one end of the heating part, the height of the lower layer of the heating plate 150 is lower than the height of the bit body 200 close to one end of the heating part, and the height difference between the upper layer and the lower layer is larger than the thickness of the bit body 200.
During transportation, the bit body 200 passes through the heating space 151, and the solder paste at the end of the bit body 200 close to the heating part is melted by the heating action of the heating space 151.
Preferably, the heating time of the solder paste can be increased by changing the coverage of the heating space 151, thereby reducing the heating power provided by the heater 140 and reducing the energy consumption.
The heater 140 and the heating plate 150 are arranged to form a heating space 151, so that the solder paste on the end of the bit body 200 close to the heating portion can be melted during the movement process, thereby completing the soldering operation.
[ eighth embodiment ]
Referring to fig. 6-10, in a specific embodiment, the present invention also provides a welding machine 400, the welding machine 400 being used for welding between the drill bit 200 and the alloy sheet 220, the welding machine 400 comprising: a third mounting plate 300; a transfer device 500 disposed at one side of the third mounting plate 300; the alignment mechanism 410, the alignment mechanism 410 is disposed on the third mounting plate 300, away from the side of the conveying device 500, and is used for adjusting the direction of the drill 200; the chip mounting mechanism 440, the chip mounting mechanism 440 is disposed on the third mounting plate 300, near one side of the alignment mechanism 410, and the chip mounting mechanism 440 can assemble the drill bit 200 with the alloy sheet 220 to form the drill bit body 200; the paste dispensing mechanism 420 is arranged on the third mounting plate 300, is positioned between the chip loading mechanism 440 and the conveying device 500, and is used for dispensing paste on the bit body 200; a transport mechanism 430, the transport mechanism 430 being used for transporting the drill bit 200 and the bit body 200.
The alignment mechanism 410 aligns the drill bit 200, the drill bit is transported to the chip loading mechanism 440 through the transport mechanism 430 after being aligned, the chip loading mechanism 440 embeds the alloy chip 220 into the drill bit 200 to form the drill bit body 200, the alloy chip is transported to the paste dispensing mechanism 420 through the transport mechanism 430, the paste dispensing mechanism 420 dispenses paste on the drill bit body 200 and then transports the dispensed paste to the transport device 500 through the transport mechanism 430, and the solder paste is melted through the heating part during the transport process to complete the welding.
The alignment mechanism 410 aligns the position of the drill bit 200, so that the sheet loading mechanism 440 can conveniently mount the alloy sheet 220, the paste dispensing mechanism 420 dispenses paste at the joint of the alloy sheet 220 and the drill bit 200, the drill bit 200 is welded when passing through the heating part, and the conveying mechanism 430 transfers the drill bit 200 or the drill bit 200 in the mechanisms, so that the continuous welding work of the drill bit 200 is realized, and the working efficiency is increased.
[ ninth example ] A
Referring to fig. 11-14, in one embodiment, a gas guard 450 is disposed within the heating space 151 and coupled to the heater 140 for delivering a shielding gas to the bit body 200.
The gas protection device 450 is arranged between the upper and lower layers of heating plates 150, and the gas protection device 450 is provided with a plurality of small holes 451 at one side close to the bit body 200, for example, the protection gas may be nitrogen, and when the bit body 200 passes through the heating space 151, the nitrogen is ejected from the small holes 451, thereby protecting the welding of the bit body 200; of course, the shielding gas may be helium, neon, or some other inert gas.
[ tenth embodiment ]
In one particular embodiment, transport mechanism 430 includes: a first finger 431, the first finger 431 being disposed on the third mounting plate 300 for transferring the drill bit 200 to the loading mechanism 440; a second claw 432, wherein the second claw 432 is arranged on the third mounting plate 300 and is used for conveying the bit body 200 to the paste dispensing mechanism 420; a third finger 433, the third finger 433 being disposed on the third mounting plate 300 for transferring the bit body 200 to the transfer device 500.
After the position of the drill bit is aligned by the alignment mechanism 410, the first finger 431 conveys the drill bit 200 to the chip loading mechanism 440, after the chip loading mechanism 440 loads the alloy chip 220 into the drill bit 200 to form the drill bit 200, the second finger 432 conveys the drill bit 200 to the paste dispensing mechanism 420, after the paste dispensing mechanism 420 dispenses paste, the third finger 433 conveys the drill bit 200 to the conveying mechanism, the first finger 431, the second finger 432 and the third finger 433 can work simultaneously, when one drill bit 200 leaves the paste dispensing mechanism 420 and enters the conveying device 500, a new drill bit 200 enters the chip loading mechanism 440 from the alignment mechanism 410, and the welding work is continued.
The first finger 431 is arranged to realize the transmission of the drill bit 210, and the first finger 431 can transmit the drill bit 210 to the loading mechanism 440; the second finger 432 can convey the assembled bit body 200 to the paste dispensing mechanism 420, so that the paste dispensing mechanism 420 can dispense paste onto the bit body 200; the third finger 433 can transport the bit body 200 after paste dispensing to the conveyer 500 by the paste dispensing mechanism 420, and further, the heating part performs welding; the transfer efficiency of the drill bit 210 and bit body 200 is improved by the provision of the first finger 431, the second finger 432, and the third finger 433, thereby reducing the transfer time.
Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be effected therein by one of ordinary skill in the pertinent art without departing from the scope or spirit of the present invention, and the scope of the present invention is defined by the appended claims.
Claims (10)
1. A welder transfer device (500), characterized in that the transfer device (500) comprises:
a heating part provided with a heating space (151) for heating the bit body (200);
a transfer section (100), wherein the transfer section (100) is provided with a mounting position for mounting the bit body (200), and the transfer section (100) is used for conveying the bit body (200) to the heating part;
wherein the installation positions are provided in plurality, and the plurality of bit bodies (200) are sequentially passed through the heating space (151) when the conveying part (100) conveys the bit bodies (200).
2. The transfer device (500) of claim 1, wherein the transfer portion (100) comprises:
a rotating member (110), the rotating member (110) being rotatable relative to the heating portion;
a mounting plate (120), a first end of the mounting plate (120) being connected to the rotating member (110), the mounting location being disposed at a second end of the mounting plate (120);
the bit body (200) is arranged on the mounting plate (120), and the mounting plate (120) moves along with the rotating piece (110) and drives the bit body (200).
3. The transfer device (500) of claim 2, further comprising:
a connecting plate (130), the connecting plate (130) set up in rotate piece (110), and be located rotate piece (110) with between mounting panel (120), be used for supporting mounting panel (120).
4. The transfer device (500) of claim 3, further comprising: the number of the connecting plates (130) is multiple, and each connecting plate (130) is in fit connection with two adjacent connecting plates (130);
the rotary part (110) can continuously convey the bit body (200) to the heating space (151) when rotating.
5. The transfer device (500) of claim 3, wherein the mounting plate (120) comprises:
a first mounting plate (121), the first mounting plate (121) is disposed on one side of the connecting plate (130) far away from the heating portion, and a distance between one end of the first mounting plate (121) far away from the connecting plate (130) and the connecting plate (130) is a first distance H1;
A second mounting plate (122), wherein the first mounting plate (121) is arranged on one side of the connecting plate (130) close to the heating part, and the distance between one end of the first mounting plate (121) far away from the connecting plate (130) and the connecting plate (130) is a second distance H2;
Wherein the first distance H1At the second distance H2Satisfies the following conditions: h1≤H2。
6. The transfer device (500) of claim 5, further comprising:
the drill bit is characterized in that a first notch (121a) is formed in the first mounting plate (121), a second notch (122a) is formed in the second mounting plate (122), and two ends of the drill bit body (200) are arranged in the first notch (121a) and the second notch (122a) respectively.
7. The transfer device (500) of claim 5, further comprising:
a baffle (160), wherein the distance between one end of the baffle (160) far away from the connecting plate (130) and the connecting plate (130) is a third distance H3The first distance H1At the third distance H3Satisfies the following conditions: h3≤H1;
The baffle plate (160) is used for preventing the bit body (200) from sliding off along the installation position in the direction away from the heating part.
8. The transfer device (500) of any of claims 1 to 7, wherein the heating section comprises:
a heater (140);
the heating plate (150), the heating plate (150) with heater (140) are connected, heating plate (150) bending type sets up and forms heating space (151).
9. The transfer device (500) of claim 8, wherein the heating portion further comprises:
a gas protection device (450), the gas protection device (450) being disposed within the heating space (151) and connected to the heater (140).
10. A welder (400), the welder (400) for welding between a drill (210) and an alloy sheet (220), characterized in that the welder (400) comprises:
a third mounting plate (300);
-a conveyor (500), the conveyor (500) according to any one of claims 1 to 8, arranged on one side of the third mounting plate (300);
the alignment mechanism (410) is arranged on the third mounting plate (300) at the side far away from the conveying device (500) and is used for adjusting the direction of the drill bit (210);
the chip mounting mechanism (440) is arranged on the third mounting plate (300) and close to one side of the alignment mechanism (410), and the chip mounting mechanism (440) can assemble the drill bit (210) and the alloy sheet (220) to form a drill body (200);
the paste dispensing mechanism (420) is arranged on the third mounting plate (300) and is positioned between the chip loading mechanism (440) and the conveying device (500) and used for dispensing paste on the bit body (200);
a transport mechanism (430), the transport mechanism (430) for transporting the drill bit (210) and the bit body (200).
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202220009798.6U CN216829308U (en) | 2022-01-05 | 2022-01-05 | Welding machine conveyer and welding machine |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202220009798.6U CN216829308U (en) | 2022-01-05 | 2022-01-05 | Welding machine conveyer and welding machine |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN216829308U true CN216829308U (en) | 2022-06-28 |
Family
ID=82114234
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202220009798.6U Active CN216829308U (en) | 2022-01-05 | 2022-01-05 | Welding machine conveyer and welding machine |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN216829308U (en) |
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2022
- 2022-01-05 CN CN202220009798.6U patent/CN216829308U/en active Active
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Address after: 315000 No. 929 Binhai Avenue, Danxi street, Xiangshan County, Ningbo City, Zhejiang Province Patentee after: Ningbo Intelligent Machine Tool Research Institute Co., Ltd. of China National Machinery Institute Group Address before: 315000 No. 929 Binhai Avenue, Danxi street, Xiangshan County, Ningbo City, Zhejiang Province Patentee before: China Machinery Intelligent Equipment Innovation Research Institute (Ningbo) Co.,Ltd. |