CN215151898U - Wire fusion bonding device - Google Patents

Abstract

The application discloses wire rod fusion jointing device, the device includes: the device comprises a base upper cover, a base and a heating device; the base upper cover is rotationally connected with the base; one of the base upper cover and the base is connected with the heating device; a first groove is formed in the first end face of the heating device, and a second groove corresponding to the first groove is formed in the base upper cover or the base which is not connected with the heating device; the first groove and the second groove jointly enclose a channel for accommodating the wire. In this way, the heating device can be used for heating and melting the wire in the channel, so that the wire can be jointed. Therefore, the problem that the length of the wire rod is insufficient in the printing process is solved, the remaining wire rods can be combined, and the waste of the wire rod is reduced. Simultaneously, can also combine the wire rod of different colours, realize the function that single shower nozzle 3D printer printed colored model.

Description

Wire fusion bonding device

Technical Field

The utility model relates to a print technical field, especially relate to a wire rod melting junction device.

Background

Fused Deposition Modeling (FDM) printers are manufactured by feeding hot-melt wires such as Polylactide (PLA), copolyester (Polyethylene Terephthalate (PETG), Thermoplastic polyurethane elastomer (TPU), acrylonitrile-butadiene-styrene (ABS), etc. from a wire feeding mechanism to a hot-melt nozzle, heating and melting the hot-melt wires into a semi-liquid state, and extruding and curing the semi-liquid state from the nozzle to form a 3D printing model. Because the length of a single wire is limited, when a model is built, if the wire cannot be connected in time, the model printing fails, and the model printing effect is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model provides a wire rod melting jointing device to solve when the model is founded, the wire rod if can not in time continue to lead to the model to print the failure, influence the problem that the effect was printed to the model.

In a first aspect, embodiments of the present application provide a wire fusion bonding apparatus, including: the device comprises a base upper cover, a base and a heating device;

the base upper cover is rotationally connected with the base; one of the base upper cover and the base is connected with the heating device;

a first groove is formed in the first end face of the heating device, and a second groove corresponding to the first groove is formed in the base upper cover or the base which is not connected with the heating device; the first groove and the second groove jointly enclose a channel for accommodating the wire.

Optionally, the heating device is embedded in the base seat, and the base upper cover comprises an upper cover body and a first heat-conducting member embedded in the upper cover body; the second groove is formed in the first end face of the first heat conducting piece, and the first end face of the first heat conducting piece is the end face, facing the heating device, of the first heat conducting piece.

Optionally, the heating device comprises a second thermally conductive member and a heating element; the second heat conducting piece is embedded into the base, and a first groove is formed in the first end face of the second heat conducting piece;

the heating element is arranged in the first heat-conducting member and/or the second heat-conducting member.

Optionally, the first end surface of the first heat conducting member and the first end surface of the upper cover body are located on the same plane, and the second groove extends out of two sides of the first end surface of the upper cover body;

the first end surface of the second heat conducting piece and the first end surface of the base seat are positioned on the same plane, and the first groove extends out of two sides of the first end surface of the base seat;

the first end face of the upper cover body is the end face of the upper cover body, which faces the base, and the first end face of the base is the end face of the base, which faces the upper cover body.

Optionally, the wire fusion bonding apparatus further comprises: a first insulation assembly and a second insulation assembly;

wherein the first thermal insulation assembly is disposed between the first thermal conduction member and the upper cover body;

the second thermally insulating assembly is disposed between the second thermally conductive member and the base pedestal.

Optionally, the material of the first insulating assembly and the material of the second insulating assembly comprise a silicone material.

Optionally, the wire fusion bonding apparatus further comprises: a heat radiation fan;

the heat dissipation fan is arranged on the second end face of the base seat, and the second end face of the base seat is opposite to the first end face of the base seat;

the upper cover body and the base seat are provided with heat dissipation through holes, and the axial direction of the heat dissipation through holes is intersected with the second end face of the base seat.

Optionally, the diameter of the first end of the channel is larger than that of the second end of the channel, wherein the first end of the channel is used for fixedly arranging a first wire to be fusion-jointed, the second end of the channel is used for movably arranging a second wire to be fusion-jointed, and the first end of the channel and the second end of the channel are two opposite ends of the channel;

the wire fusion splicing device further comprises a connecting assembly, wherein the connecting assembly comprises a rotating shaft and a bracket; the bracket is arranged on the upper cover body, and the rotating shaft is arranged on the base; the support is provided with a first through hole, and the rotating shaft penetrates through the first through hole and is rotatably connected with the support.

Optionally, the wire fusion bonding apparatus further comprises: a temperature detection assembly and a processor;

wherein the temperature detection assembly is disposed within the first and/or second heat-conducting member;

the temperature sensing assembly and the heating element are both electrically connected to the processor.

Optionally, the temperature detection assembly comprises a thermistor, a copper sleeve and a jackscrew;

the thermistor is arranged in the copper sleeve, the copper sleeve is arranged in the first heat-conducting piece and/or the second heat-conducting piece, and the copper sleeve is connected with the first heat-conducting piece and/or the second heat-conducting piece through the jackscrew;

the thermistor and the heating element are both electrically connected to the processor.

In an embodiment of the present application, the wire fusion bonding apparatus includes: the device comprises a base upper cover, a base and a heating device; the base upper cover is rotationally connected with the base; one of the base upper cover and the base is connected with the heating device; a first groove is formed in the first end face of the heating device, and a second groove corresponding to the first groove is formed in the base upper cover or the base which is not connected with the heating device; the first groove and the second groove jointly enclose a channel for accommodating the wire. In this way, the heating device can be used for heating and melting the wire in the channel, so that the wire can be jointed. Therefore, the problem that the length of the wire rod is insufficient in the printing process is solved, the wire rod with short residual length can be combined, and the waste of the wire rod is reduced. Simultaneously, the user can also select the wire rod of different colours to carry out the melting and combine, realizes the function that single shower nozzle 3D printer printed colored model. In addition, the upper cover of the base is rotatably connected with the base seat, so that the first groove and the second groove can be aligned accurately, and the wires in the channel can be fused and combined better.

Drawings

FIG. 1 is a schematic structural view of a wire fusion bonding apparatus provided in an embodiment of the present application;

fig. 2 is an exploded view of a wire fusion bonding apparatus provided in an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, not all, of the embodiments of the present invention. Without conflict, the embodiments and features of the embodiments described below may be combined with each other. On the basis of the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

The embodiment of the application provides a wire fusion bonding device. Referring to fig. 1, fig. 1 is a schematic structural view of a wire fusion bonding apparatus provided in an embodiment of the present application. As shown in fig. 1, the wire fusion-bonding apparatus includes: a base upper cover 100, a base 200 and a heating device 300;

the base upper cover 100 is rotatably connected with the base 200; one of the base top cover 100 and the base bottom 200 is connected to the heating device 300;

a first groove is formed on the first end surface of the heating device 300, and a second groove corresponding to the first groove is formed on the base upper cover 100 or the base 200 which is not connected with the heating device 300; the first groove and the second groove jointly enclose a channel for accommodating the wire.

Specifically, the base cover 100 and the base 200 may be rectangular, square, cylindrical or other irregular shapes, and the present application is not limited thereto. The base cover 100 can be rotated with respect to the base 200 so that the base cover 100 and the base 200 can be in a closed state or an open state.

The heating device 300 may be connected to the susceptor cover 100 or the susceptor base 200. When the heating device 300 is connected to the base cover 100, the base 200 is provided with a second groove corresponding to the first groove, so that when the base cover 100 and the base 200 are in a closed state, the first groove of the heating device 300 and the second groove of the base 200 enclose a channel for accommodating wires. When the heating device 300 is connected to the base chassis 200, a second groove corresponding to the first groove is formed on the base upper cover 100, so that when the base upper cover 100 and the base chassis 200 are in a closed state, the first groove on the heating device 300 and the second groove on the base upper cover 100 jointly enclose a channel for accommodating wires.

In this way, the wire rod in the passage is heated and melted by the heating device 300, and the wire rod can be joined. Therefore, the problem that the length of the wire rod is insufficient in the printing process is solved, the wire rod with short residual length can be combined, and the waste of the wire rod is reduced. Simultaneously, the user can also select the wire rod of different colours to carry out the melting and combine, realizes the function that single shower nozzle 3D printer printed colored model. In addition, the base upper cover 100 and the base 200 are connected in a rotating mode, so that the first groove and the second groove can be accurately aligned, wires in the channel can be better fused and combined, the base upper cover 100 and the base 200 can be more easily pressed and closed, and if needed, a user can also press the base upper cover 100 with hands, and the joint effect of the wires in the channel is further improved.

Further alternatively, the heating device 300 may be embedded in the base chassis 200, and the base cover 100 includes the cover body 110 and the first heat-conducting member 120 embedded in the cover body 110; the first end surface of the first heat conducting member 120 is provided with a second groove, and the first end surface of the first heat conducting member 120 is the end surface of the first heat conducting member 120 facing the heating device 300.

The first heat conducting member 120 may be made of a metal material with high thermal conductivity and high temperature resistance, such as aluminum, copper, iron, and the like. The first groove and the second groove may be approximately semicylindrical in shape, and the diameter thereof may be equal to or greater than that of the wire to be melted. In one embodiment, the heating device 300 is embedded in the base chassis 200, and the first heat-conducting member 120 is embedded in the cover body 110. When the base chassis 200 and the cover body 110 are in a closed state, a channel for accommodating the wire may be formed between the heating device 300 and the first heat-conducting member 120, so that the wire may be heated and fused by the heating device 300. It is understood that the base cover 100 may include only the cover body 110, and the cover body 110 may be shaped to match the base chassis 200 and the heating device 300 coupled to the base chassis 200.

Specifically, the first end surface of the heating device 300 with the first groove may protrude from the first end surface of the base chassis 200, the first end surface of the first heat conducting member 120 with the second groove may be recessed in the first end surface of the cover body 110, and when the base chassis 200 and the cover body 110 are in the closed state, the first groove and the second groove together enclose a channel for accommodating a wire. Or, the first end surface of the heating device 300 with the first groove may be recessed in the first end surface of the base chassis 200, and the first end surface of the first heat conducting member 120 with the second groove may be protruded out of the first end surface of the cover body 110, and when the base chassis 200 and the cover body 110 are in the closed state, the first groove and the second groove together enclose a channel for accommodating a wire. Or, the first end surface of the heating device 300 with the first groove may be flush with the first end surface of the base chassis 200, and the first end surface of the first heat conducting member 120 with the second groove may also be flush with the first end surface of the upper cover body 110, and when the base chassis 200 and the upper cover body 110 are in the closed state, the first groove and the second groove together enclose a channel for accommodating a wire rod.

In this embodiment, since the channel for accommodating the wire is located between the heating device 300 and the first heat-conducting member 120, when the wire is heated by the heating device 300, the heating device 300 can also heat the first heat-conducting member 120, so that the periphery of the wire is heated more uniformly.

Further, the heating device 300 includes a second heat conduction member 310 and a heating element 320; the second heat conducting member 310 is embedded in the base 200, and a first groove is formed on a first end surface of the second heat conducting member 310;

the heating element 320 is disposed in the first heat-conducting member 120 and/or the second heat-conducting member 310.

Specifically, the second heat conduction member 310 may be made of a metal material with high thermal conductivity and high temperature resistance, such as aluminum, copper, iron, and the like. The material and shape of the second heat-conducting member 310 may be the same as those of the first heat-conducting member 120, or may be different from those of the first heat-conducting member 120, and the present application is not particularly limited thereto. The heating element 320 may be a resistance heating element 320, an infrared heating element 320, an electromagnetic heating element 320, or the like.

In one embodiment, the cover body 110 and the base 200 are regular, the first thermal conductive member 120 is embedded in the cover body 110, and the first thermal conductive member 120 is detachably connected to the cover body 110. The second heat conduction member 310 is embedded in the base chassis 200, and the second heat conduction member 310 is detachably connected to the base chassis 200. When two wires 900 need to be fused and combined, the two wires 900 can be placed in the first groove, then the upper cover body 110 is covered on the base 200, so that the first groove is matched with the second groove, in this way, the two wires 900 can be located in a channel enclosed by the first groove and the second groove together, then the first heat conducting member 120 and/or the second heat conducting member 310 are heated by the heating element 320 such as a heating rod, and the temperature of the first heat conducting member 120 and the temperature of the second heat conducting member 310 reach the melting temperature of the wires 900, at this time, the two wires 900 are in a critical melting state, and the fusion and combination of the wires can be realized by manually extruding one of the wires to approach the wire. The wire rod fusion jointing is carried out by adopting the mode, the operation is simple and quick, and the wire rod fusion jointing effect is good. Therefore, the problem that the length of the wire rod is insufficient in the printing process is solved, the wire rod with short residual length can be combined, and the waste of the wire rod is reduced. Simultaneously, the user can also select the wire rod of different colours to carry out the melting and combine, realizes the function that single shower nozzle 3D printer printed colored model.

Further, the first end surface of the first heat conducting member 120 and the first end surface of the upper cover body 110 are located on the same plane, and the second groove extends out of two sides of the first end surface of the upper cover body 110;

the first end surface of the second heat conducting member 310 and the first end surface of the base chassis 200 are located on the same plane, and the first groove extends out of two sides of the first end surface of the base chassis 200;

the first end surface of the upper cover body 110 is the end surface of the upper cover body 110 facing the base chassis 200, and the first end surface of the base chassis 200 is the end surface of the base chassis 200 facing the upper cover body 110.

In an embodiment, the first end surface of the first heat conduction member 120 may be flush with the first end surface of the cap body 110, and the second groove extends from the first heat conduction member 120 to two sides of the first end surface of the cap body 110; the first end surface of the second heat conduction member 310 may be flush with the first end surface of the base chassis 200, and the first groove extends from the second heat conduction member 310 to both sides of the first end surface of the base chassis 200. Thus, the contact area between the wire fusion-bonding device and the wire can be increased, so that the wire can be well fixed.

Referring to fig. 2, fig. 2 is an exploded view of a wire fusion bonding apparatus provided in an embodiment of the present application. As shown in fig. 2, the wire fusion-bonding apparatus further includes: a first insulation assembly 400 and a second insulation assembly 500;

wherein the first heat insulating assembly 400 is disposed between the first heat conductive member 120 and the upper cover body 110;

the second thermal insulation assembly 500 is disposed between the second thermal conduction member 310 and the base chassis 200.

Specifically, the first and second insulation assemblies 400 and 500 are made of an insulating material, including but not limited to silica gel, fiberglass, asbestos, silicate, and the like. The first heat insulation assembly 400 has a shape adapted to the shape of the first heat conduction member 120, and can be embedded in the upper cover body 110 together with the first heat conduction member 120 for isolating heat between the first heat conduction member 120 and the upper cover body 110. The second heat insulating assembly 500 has a shape adapted to the shape of the second heat conducting member 310, and can be embedded in the base chassis 200 together with the second heat conducting member 310 for insulating heat between the second heat conducting member 310 and the base chassis 200. Thus, the temperature of the upper cover body 110 and the base chassis 200 may not increase with the temperature of the first heat-conducting member 120 and the second heat-conducting member 310, and the user may be prevented from being burned when operating the wire fusion-bonding apparatus.

Further, the material of the first insulation assembly 400 and the material of the second insulation assembly 500 comprise a silicone material.

In one embodiment, a silicone material may be selected for the first and second insulating assemblies 400, 500. Because the silica gel material not only has better heat-proof property, but also has characteristics of high temperature resistance, high softness and the like, therefore, the first heat-insulating component 400 and the second heat-insulating component 500 made of the silica gel material not only can have good heat-insulating effect on the upper cover body 110 and the base seat 200, but also can realize the clamping effect of the first heat-conducting piece 120 and the upper cover body 110, and the second heat-conducting piece 310 and the base seat 200.

Further, the wire fusion-bonding apparatus further includes: a heat radiation fan 600;

the heat dissipation fan 600 is disposed on a second end surface of the base chassis 200, and the second end surface of the base chassis 200 is disposed opposite to the first end surface of the base chassis 200;

the upper cover body 110 and the base chassis 200 are both provided with heat dissipation through holes, and the axial direction of the heat dissipation through holes intersects with the second end face of the base chassis 200.

Specifically, the heat dissipation fan 600 may be fixedly disposed on the second end surface of the base chassis 200 by means of screws, buckles, and the like, which is not specifically limited in the present application. As shown in fig. 2, the heat dissipation fan 600 may be fixed to the base chassis 200 by a plurality of screws 190.

Since the upper cover body 110 and the base chassis 200 are provided with the heat dissipation through holes that are mutually communicated, when the first heat conduction member 120 and/or the second heat conduction member 310 are heated, the heat dissipation fan 600 may be started to accelerate air circulation in the heat dissipation through holes through the heat dissipation fan 600, thereby achieving a heat dissipation function of the surroundings of the first heat conduction member 120 and the second heat conduction member 310.

In the base chassis 200, in an embodiment, the axial direction of the heat dissipation through hole perpendicularly intersects with the second end surface of the base chassis 200, that is, the upper cover body 110 and the base chassis 200 are provided with heat dissipation through holes vertically penetrating each other. Therefore, the airflow introduced by the heat radiation fan 600 can be better introduced into the heat radiation through hole, and the heat radiation efficiency is improved.

Further, the diameter of a first end of the channel is larger than that of a second end of the channel, wherein the first end of the channel is used for fixedly arranging the first wires to be fusion-jointed, the second end of the channel is used for movably arranging the second wires to be fusion-jointed, and the first end of the channel and the second end of the channel are two opposite ends of the channel;

the wire fusion bonding apparatus further includes: the connecting assembly 700, the connecting assembly 700 includes a rotating shaft 710 and a bracket 720; wherein, the bracket 720 is disposed on the upper cover body 110, and the rotating shaft 710 is disposed on the base chassis 200; the bracket 720 is provided with a first through hole, and the rotating shaft 710 penetrates through the first through hole and is rotatably connected with the bracket 720.

In an embodiment, the diameter of the first end of the channel may be set smaller, in particular, the diameter of the first end of the channel may be slightly smaller than or equal to the diameter of the first wire. For example, the diameter of the first end of the channel may be 0 to 0.2 millimeters less than the diameter of the first wire. The diameter of the second end of the channel is set larger, and in particular, the diameter of the second end of the channel may be larger than the diameter of the second wire. Like this, when needs carry out the fusion bonding to first wire rod and second wire rod, can pass through the first end block of passageway with first wire rod and fix, the second end of rethread passageway is with the manual extrusion of second wire rod to the position that is close to with first wire rod, can make the fusion that two wire rods can be better combine from this.

In addition, the upper cover body 110 and the base chassis 200 may be rotatably connected by the connection assembly 700, and when the wires are required to be welded, the upper cover body 110 is rotated to a position closed with the base chassis 200; when the wire fusion bonding is not required, the cover body 110 is rotated to a position separated from the base chassis 200. Specifically, the connection assembly 700 includes a rotating shaft 710 and a bracket 720, the bracket 720 is disposed on the upper cover body 110, and the rotating shaft 710 is disposed on the base chassis 200, so that the upper cover body 110 can rotate around the rotating shaft 710, thereby rotatably connecting the upper cover body 110 and the base chassis 200. Meanwhile, since the positions of the rotating shaft 710 and the bracket 720 on the base 200 and the upper cover body 110 are fixed and unchangeable, the positions of the rotating shaft 710 and the bracket 720 can be set according to the positions of the first groove and the second groove during design, so that the first groove and the second groove can be vertically corresponding when the upper cover body 110 and the base 200 are covered.

Further, the wire fusion-bonding apparatus further includes: a temperature sensing assembly 800 and a processor (not shown);

wherein, the temperature detecting assembly 800 is disposed in the first heat-conducting member 120 and/or the second heat-conducting member 310;

both the temperature sensing assembly 800 and the heating element 320 are electrically connected to the processor.

In an embodiment, the temperature detecting assembly 800 may be disposed in the first heat conducting member 120, the second heat conducting member 310, or both the first heat conducting member 120 and the second heat conducting member 310, which is not limited in this application. The temperature sensing assembly 800 may be configured to sense the temperature of the first thermal conductive member 120 and/or the second thermal conductive member 310 and transmit a sensed temperature signal to the processor. The processor may control the heating time period of the heating element 320 based on the received temperature signal. Specifically, when the temperature detected by the temperature detection assembly 800 is less than the melting temperature of the wire, the processor controls the heating element 320 to continue heating; when the temperature detected by the temperature detecting assembly 800 is greater than or equal to the melting temperature of the wire, the processor controls the heating element 320 to stop heating. In this way, it is possible to achieve precise control of the heating temperature of the first and second heat- conductive members 120 and 310, and to improve the wire fusion bonding effect.

Further, with continued reference to fig. 2, the temperature sensing assembly 800 includes a thermistor 810, a copper sleeve 820, and a jackscrew 830;

the thermistor 810 is arranged in the copper sleeve 820, the copper sleeve 820 is arranged in the first heat-conducting member 120 and/or the second heat-conducting member 310, and the copper sleeve 820 is connected with the first heat-conducting member 120 and/or the second heat-conducting member 310 through the jackscrew 830;

both thermistor 810 and heating element 320 are electrically connected to the processor.

In one embodiment, the temperature of the first thermal conduction member 120 and/or the second thermal conduction member 310 may be detected using a thermistor 810. Since the thermistor 810 is not easily directly fixed in the first heat conduction member 120 and/or the second heat conduction member 310, the thermistor 810 may be first disposed in the copper sleeve 820, the copper sleeve 820 and the thermistor 810 may be clamped by a tool such as a pair of scissors, so that the thermistor 810 may not be separated from the copper sleeve 820, the copper sleeve 820 may be then disposed in the first heat conduction member 120 and/or the second heat conduction member 310, and the copper sleeve 820 may be fixed to the first heat conduction member 120 and/or the second heat conduction member 310 by the jackscrew 830. This not only provides a good fixation of the thermistor 810, but also does not affect the detection of the temperature of the first heat-conducting member 120 and/or the second heat-conducting member 310 by the thermistor 810.

In one embodiment, the wire fusion-bonding apparatus may include the upper cover body 110, the base chassis 200, the first heat-conducting member 120, the second heat-conducting member 310, the heating element 320, the first heat-insulating assembly 400, the second heat-insulating assembly 500, the heat-dissipating fan 600, the temperature detection assembly 800, and the processor. The first thermal conductive member 120 is embedded in the cover body 110, the second thermal conductive member 310 is embedded in the base 200, and the first thermal conductive member 120 and the second thermal conductive member 310 can be in a mutually contacting state or a mutually separated state along with the rotation between the cover body 110 and the base 200. In addition, the first heat-conducting member 120 and the second heat-conducting member 310 are respectively provided with a second groove and a first groove, and a channel for accommodating wires is formed by the second groove and the first groove, so that when the first heat-conducting member 120 and the second heat-conducting member 310 are in a mutually separated state, the first wires and the second wires are placed in the channel, and then the first heat-conducting member 120 and the second heat-conducting member 310 are in a mutually contacted state, and the heating element 320 is controlled to heat the first heat-conducting member 120 and/or the second heat-conducting member 310. When the temperature of the first heat-conducting member 120 and/or the second heat-conducting member 310 is heated to the melting temperature of the wires, the first wires or the second wires may be manually pressed to melt-bond the first wires and the second wires. Therefore, the problem that the length of the wire rod is insufficient in the printing process is solved, the wire rod with short residual length can be combined, and the waste of the wire rod is reduced. Simultaneously, the user can also select the wire rod of different colours to carry out the melting and combine, realizes the function that single shower nozzle 3D printer printed colored model.

In addition, since the temperature detection assembly 800 is provided on the first heat-conductive member 120 and/or the second heat-conductive member 310 of the wire fusion-bonding apparatus, the temperature of the first heat-conductive member 120 and/or the second heat-conductive member 310 can be transmitted to the processor through the temperature detection assembly 800. When the processor detects that the temperature exceeds the melting temperature of the wire, the processor may control the heating element 320 to stop heating the first heat-conducting member 120 and/or the second heat-conducting member 310, so as to prevent the temperature of the first heat-conducting member 120 and the second heat-conducting member 310 from continuously increasing and affecting the melting and bonding effect of the wire.

In addition, the wire fusion bonding device can block the temperature on the first heat conducting member 120 from being transmitted to the upper cover body 110 through the first heat insulation assembly 400, block the temperature on the second heat conducting member 310 from being transmitted to the base 200 through the second heat insulation assembly 500, and simultaneously can also radiate the heat of the upper cover body 110 and the base 200 through the heat radiating fan 600, so that the air flow in and around the heat radiating through holes on the upper cover body 110 and the base 200 is accelerated, thereby preventing the temperature of the upper cover body 110 and the base 200 from being too high, and facilitating the operation of the upper cover body 110 by an operator.

The embodiments described above are described with reference to the drawings, and various other forms and embodiments are possible without departing from the principles of the present invention, and therefore, the present invention should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. In the drawings, the size and relative sizes of components may be exaggerated for clarity. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting. The terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, integers, components, and/or components, but do not preclude the presence or addition of one or more other features, integers, components, and/or groups thereof. Unless otherwise indicated, a range of values, when stated, includes the upper and lower limits of the range and any subranges therebetween.

The foregoing is directed to the preferred embodiments of the present invention, and it will be understood by those skilled in the art that various changes and modifications may be made without departing from the principles of the invention, and that such changes and modifications are intended to be included within the scope of the invention.

Claims (10)

1. A wire fusion bonding apparatus, characterized by comprising: the device comprises a base upper cover, a base and a heating device;

the base upper cover is rotationally connected with the base; one of the base upper cover and the base is connected with the heating device;

a first groove is formed in the first end face of the heating device, and a second groove corresponding to the first groove is formed in the base upper cover or the base which is not connected with the heating device; the first groove and the second groove jointly enclose a channel for accommodating the wire.

2. The wire fusion bonding apparatus of claim 1, wherein the heating device is embedded in the base seat, and the base cover includes an upper cover body and a first heat-conductive member embedded in the upper cover body; the second groove is formed in the first end face of the first heat conducting piece, and the first end face of the first heat conducting piece is the end face, facing the heating device, of the first heat conducting piece.

3. The wire fusion bonding apparatus according to claim 2, wherein the heating device includes a second heat-conductive member and a heating element; the second heat conducting piece is embedded into the base, and a first groove is formed in the first end face of the second heat conducting piece;

the heating element is arranged in the first heat-conducting member and/or the second heat-conducting member.

4. The wire fusion bonding apparatus according to claim 3, wherein the first end surface of the first heat-conducting member and the first end surface of the upper cover body are located on the same plane, and the second groove extends out of both sides of the first end surface of the upper cover body;

the first end surface of the second heat conducting piece and the first end surface of the base seat are positioned on the same plane, and the first groove extends out of two sides of the first end surface of the base seat;

the first end face of the upper cover body is the end face of the upper cover body, which faces the base, and the first end face of the base is the end face of the base, which faces the upper cover body.

5. The wire fusion bonding apparatus of claim 3, further comprising: a first insulation assembly and a second insulation assembly;

wherein the first thermal insulation assembly is disposed between the first thermal conduction member and the upper cover body;

the second thermally insulating assembly is disposed between the second thermally conductive member and the base pedestal.

6. The wire fusion bonding apparatus of claim 5, wherein the material of the first insulating assembly and the material of the second insulating assembly comprise a silicone material.

7. The wire fusion bonding apparatus according to any one of claims 3 to 6, further comprising: a heat radiation fan;

the heat dissipation fan is arranged on the second end face of the base seat, and the second end face of the base seat is opposite to the first end face of the base seat;

the upper cover body and the base seat are provided with heat dissipation through holes, and the axial direction of the heat dissipation through holes is intersected with the second end face of the base seat.

8. The wire fusion splicing apparatus of claim 3, wherein a diameter of a first end of the channel is larger than a diameter of a second end of the channel, wherein the first end of the channel is configured to fixedly position a first wire to be fusion spliced, the second end of the channel is configured to movably position a second wire to be fusion spliced, and the first end of the channel and the second end of the channel are opposite ends of the channel;

the wire fusion splicing device further comprises a connecting assembly, wherein the connecting assembly comprises a rotating shaft and a bracket; the bracket is arranged on the upper cover body, and the rotating shaft is arranged on the base; the support is provided with a first through hole, and the rotating shaft penetrates through the first through hole and is rotatably connected with the support.

9. The wire fusion bonding apparatus according to any one of claims 3 to 6, further comprising: a temperature detection assembly and a processor;

wherein the temperature detection assembly is disposed within the first and/or second heat-conducting member;

the temperature sensing assembly and the heating element are both electrically connected to the processor.

10. The wire fusion bonding apparatus of claim 9, wherein the temperature sensing assembly includes a thermistor, a copper sleeve, and a jackscrew;

the thermistor is arranged in the copper sleeve, the copper sleeve is arranged in the first heat-conducting piece and/or the second heat-conducting piece, and the copper sleeve is connected with the first heat-conducting piece and/or the second heat-conducting piece through the jackscrew;

the thermistor and the heating element are both electrically connected to the processor.

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