CN217666982U - Hot-pressing tin melting welding equipment - Google Patents

Abstract

The embodiment of the application provides hot-pressing tin melting welding equipment; the hot-pressing tin-melting welding equipment comprises: the device comprises a bearing device, a driving device, a soldering flux setting device and a welding device; the bearing device is used for bearing a part to be welded, and the driving device is used for driving the bearing device to move; the soldering flux setting device is used for setting soldering flux to the soldering parts in the soldering flux setting area under the condition that the driving device drives the bearing device bearing the soldering parts to be soldered to move to the soldering flux setting area; and under the condition that the driving device drives the bearing device and the to-be-welded part provided with the soldering flux to move to a welding area, the welding device is used for carrying out hot-press welding on the to-be-welded part on the welding area. The hot-pressing tin melting welding equipment provided by the embodiment of the application can be used for setting the soldering flux for the to-be-welded part and welding the to-be-welded part, so that the labor intensity of operators can be reduced.

Description

Hot-pressing tin melting welding equipment

Technical Field

The application relates to the technical field of hot-press welding, in particular to hot-press tin melting welding equipment.

Background

The hot-press welding is to weld the welding piece and the welding base body together by heating and pressurizing. For example, in the process of soldering an electronic device (e.g., a memory element) to a circuit board, the electronic device may be initially fixed to a soldering portion of the circuit board by using a solder material. Furthermore, the operator can arrange the soldering flux on the electronic device, and the solder resist can flow to the soldering position automatically. Thereafter, the electronic device may be thermocompressive bonded using a bonder. In the related art, during the thermocompression bonding, flux needs to be applied to the electronic device by an operator. Thus, there is a problem that the labor intensity of the operator is large.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides hot-pressing tin melting welding equipment to solve the problem of how to reduce the labor intensity of operators.

The hot pressing tin melting welding equipment that this application embodiment provided includes: the device comprises a bearing device, a driving device, a soldering flux setting device and a welding device; the bearing device is used for bearing a part to be welded, and the driving device is used for driving the bearing device to move; the soldering flux setting device is used for setting soldering flux to the to-be-welded part positioned in the soldering flux setting area under the condition that the driving device drives the bearing device bearing the to-be-welded part to move to the soldering flux setting area; and under the condition that the driving device drives the bearing device and the to-be-welded part provided with the soldering flux to move to a welding area, the welding device is used for carrying out hot-press welding on the to-be-welded part on the welding area.

Optionally, the hot-pressing tin-melting welding device further comprises an installation base body, and the driving device, the soldering flux setting device and the welding device are all arranged on the installation base body.

Optionally, the flux setter comprises a flux applying part and a first driver, wherein the first driver is used for driving the flux applying part to move towards a direction close to or far away from the to-be-welded part carried by the carrying device; the welder comprises a hot pressing head and a second driver, wherein the second driver is used for driving the hot pressing head to move towards a direction close to or far away from the to-be-welded part carried by the carrying device.

Optionally, the first driver comprises a first lifting driving element, and the first lifting driving element is used for driving the flux applying part to move along the height direction of the hot-pressing tin-melting soldering device; the second driver comprises a second lifting driving element, and the second lifting driving element is used for driving the hot pressing head to move along the height direction of the hot pressing tin melting welding equipment.

Optionally, the carrying device comprises a jig and a tray, and the driving device comprises a third driver and a fourth driver; the jig is provided with a to-be-welded part setting area which is used for setting the to-be-welded part; the third driver is used for driving the jig to move, and the fourth driver is used for driving the tray to ascend, so that the tray is detachably connected with the jig positioned above the tray.

Optionally, the third driver includes a first conveyor belt and a second conveyor belt arranged side by side, two opposite sides of the jig are respectively supported by the first conveyor belt and the second conveyor belt, and the first conveyor belt and the second conveyor belt are used for driving the jig to move along the extending direction of the first conveyor belt; the tray set up in the first conveyer belt with the below of second conveyer belt, the fourth drive ware includes lifting mechanism, lifting mechanism is used for the drive the tray rises.

Optionally, the number of the jigs is plural, the number of the tray is one, and the tray can be detachably connected to one of the jigs.

Optionally, the hot pressing molten tin soldering device further comprises a cleaning device, and the cleaning device is used for cleaning the soldering device.

Optionally, cleaning device is including rotating driver and brush, rotate the driver with the brush drive is connected, it is used for the drive to rotate the driver the brush rotates, the welding ware includes the hot pressing head, the brush is used for right the hot pressing head cleans.

Optionally, the hot-pressing molten tin soldering equipment further comprises a camera device, and the camera device is used for acquiring an image of the part to be soldered.

The embodiment of the application adopts at least one technical scheme which can achieve the following beneficial effects:

in an embodiment of the application, the to-be-welded part may be disposed on the carrying device, and the carrying device and the to-be-welded part may be moved together to the flux disposing region by the driving device. Thus, a flux setter may be used to set flux to the parts to be soldered. Further, the carrier device can be moved by the drive device to the welding zone together with the piece to be welded. Thus, the parts to be welded can be subjected to thermocompression bonding by the bonder.

For example, the to-be-soldered parts may be an electronic device and a circuit board, a solder paste may be disposed between the electronic device and the circuit board, the electronic device may be thermally pressed by a soldering apparatus, so that the solder paste connected between the electronic device and the circuit board is melted, and the flux may prevent the melted solder paste from being oxidized. After heating and pressurizing the electronic device for a predetermined time, the bonder may be removed and the solder paste may be cooled and solidified. Therefore, the solidified tin paste can be used for welding the electronic device on the circuit board and electrically connecting the electronic device with the circuit board.

In the embodiment of the application, the hot-pressing tin melting welding equipment can be used for assisting operators or replacing the mode that the operators weld parts to be welded, so that the labor intensity of the operators is reduced.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments or related technologies of the present application, the drawings needed to be used in the description of the embodiments or related technologies are briefly introduced below, it is obvious that the drawings in the following description are only some embodiments described in the present application, and for those skilled in the art, other drawings can be obtained according to these drawings without any creative effort.

Fig. 1 is a schematic view of a hot-press molten tin soldering apparatus provided in an embodiment of the present application;

FIG. 2 is a partial schematic view of the hot compression solder melting apparatus shown in FIG. 1;

fig. 3 is a schematic diagram of a hot-pressing tin-melting welding device according to an embodiment of the present disclosure;

fig. 4 is a schematic view of a carrying device and a driving device provided in an embodiment of the present application, which shows a situation that a jig and a tray included in the carrying device are in a separated state;

fig. 5 is a schematic view of a carrying device and a driving device provided in an embodiment of the present application, which shows a situation that a jig and a tray included in the carrying device are in a detachable connection state;

fig. 6 is a schematic view of another carrier and a driving device provided in an embodiment of the present application, which illustrates a situation in which the carrier includes a plurality of jigs and a tray.

Description of reference numerals:

100-hot-pressing tin melting welding equipment; 110-a carrier; 111-a jig; 112-a tray; 120-a drive device; 121-a third driver; 1211 — a first conveyor belt; 1212-a second conveyor belt; 130-a flux setter; 131-a flux applying part; 140-a welder; 141-a hot-pressing head; 150-mounting a substrate; 160-a cleaning device; 161-brush; 170-a camera device; 200-to-be-welded.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions of the present application will be described in detail and completely with reference to the following specific embodiments of the present application and the accompanying drawings. It should be apparent that the described embodiments are only some of the embodiments of the present application, and not all of the embodiments. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments in the present application without making any creative effort belong to the protection scope of the present application.

In the description of the present application, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in this application will be understood to be a specific case for those of ordinary skill in the art.

Further, although the terms used in the present application are selected from publicly known and used terms, some of the terms mentioned in the specification of the present application may be selected by the applicant at his or her discretion, the detailed meanings of which are described in relevant parts of the description herein.

Further, it is required that the present application is understood not only by the actual terms used but also by the meaning of each term lying within.

The technical solutions provided by the embodiments of the present application are described in detail below with reference to the accompanying drawings.

The embodiment of the application provides hot-pressing tin melting welding equipment. Referring to fig. 1 to 6, a hot-press molten tin soldering apparatus 100 provided in an embodiment of the present application may include: a carrier device 110, a drive device 120, a flux setter 130, and a welder 140. The carrying device 110 can be used for carrying the parts to be welded 200, and the driving device 120 can be used for driving the carrying device 110 to move.

The flux setter 130 is configured to set flux to the to-be-welded part 200 located in the flux setting area in a case where the driving device 120 drives the carrying device 110 carrying the to-be-welded part 200 to move to the flux setting area; the welder 140 is used to perform the thermocompression welding on the to-be-welded members 200 located at the welding area, in a state where the driving device 120 drives the carrier device 110 and the to-be-welded members 200 provided with the flux to move to the welding area.

In other words, the driving device 120 may be configured to drive the carrying device 110 and the to-be-welded component 200 carried on the carrying device 110 to move together, and the driving device 120 may enable the carrying device 110 and the to-be-welded component 200 to move to the flux setting area. Thus, flux may be provided to the to-be-welded member 200 using the flux setter 130. Further, the driving device 120 may move the carrier device 110 and the to-be-welded member 200 to the welding zone. Thus, the work to be welded 200 can be thermocompression bonded using the bonder 140.

It should be noted that the flux may be a chemical substance that assists and facilitates the soldering process, and at the same time has a protective effect and prevents oxidation reactions during the soldering process. Illustratively, the flux setter 130 may be a flux sprayer. In the embodiment of the present application, the flux setter 130 may be any device capable of setting flux on the soldering site of the to-be-soldered part 200 in the prior art, and the configuration of the flux setter 130 and the operation principle thereof will not be described herein. The bonding tool 140 may be any device capable of performing thermocompression bonding to a member to be bonded in the prior art, and the structure of the bonding tool 140 and the operation thereof will not be described herein.

In this way, in the embodiment of the present application, the to-be-welded member 200 may be disposed on the carrier device 110, and the carrier device 110 and the to-be-welded member 200 may be moved together to the flux disposition region by the driving device 120. Thus, flux can be provided to the to-be-welded member 200 using the flux setter 130. Further, the carrier 110 and the to-be-welded member 200 may be moved together to the welding zone by the driving device 120. Thus, the work to be welded 200 can be thermocompression bonded using the bonder 140.

For example, the to-be-welded member 200 may be an electronic device and a circuit board, solder paste may be disposed between the electronic device and the circuit board, the electronic device may be hot-pressed by the welder 140, so that the solder paste connected between the electronic device and the circuit board is melted, and the flux may prevent the melted solder paste from being oxidized. After the electronic device is heated and pressurized for a predetermined time, the bonder 140 may be removed and the solder paste may be cooled to solidify. Thus, the solidified solder paste can be used to solder the electronic device to the circuit board and electrically connect the electronic device to the circuit board.

In the embodiment of the application, the hot-pressing tin-melting welding equipment 100 can assist an operator or replace the operator to weld the parts to be welded 200, so that the labor intensity of the operator is reduced.

In an embodiment of the present application, the hot compression solder apparatus 100 may further include a mounting base 150. The driver 120, the flux setter 130, and the welder 140 may all be disposed on the mounting base 150. The carrier 110 may be disposed on the driving device 120. Illustratively, the driving device 120 may be a conveyor belt or a roller conveyor, etc., and the carrier 110 may be driven by the driving device 120 to rest on the flux setting area and the soldering area, respectively. In an embodiment of the present application, the driving device 120 may be provided with an input port and an output port, and the input port, the flux setting region, the soldering region, and the output port may be sequentially provided.

In an embodiment of the present application, the flux setter 130 may include a flux applying part 131 and a first driver. The first driver can be used to drive the flux applying part 131 to move toward or away from the to-be-welded component 200 carried on the carrying device 110. For example, the first driver may include a first lifting driving element, and the first lifting driving element may be configured to drive the flux applying part 131 to move in the height direction of the hot press tin melting soldering apparatus 100.

For example, the first lifting driving element may be a linear motor, a hydraulic cylinder, an air cylinder, or the like. The first elevation driving element may be a combination of a rotary driving device such as a rotary electric machine, a hydraulic motor, or a pneumatic motor, and a transmission mechanism such as a screw nut mechanism that can convert rotary motion into linear motion. It should be noted that, in the embodiment of the present application, in the case where other driving elements need to achieve a function similar to that of the first elevation driving element, the other driving elements may be arranged with reference to the configuration of the first elevation driving element. The configuration of the further drive elements is not listed further below.

In this way, the carrier device 110 and the to-be-welded member 200 can be moved together to the flux setting area by the driving device 120, wherein the flux applying part 131 can be located right above the to-be-welded member 200 when the to-be-welded member 200 is located in the flux setting area. Therefore, the flux applying part 131 can be moved to a position close to the to-be-welded member 200 by driving the flux applying part 131 to move downward by the first elevation driving element. Further, solder resist may be provided to the to-be-welded member 200 by the flux setter 130.

Further, in the embodiment of the present application, the first driver may further include a first lateral driver and a first longitudinal driver, and the flux applying part 131 may be moved laterally and longitudinally in a horizontal plane by the first lateral driver and the first longitudinal driver so that the flux applying part 131 can be positioned right above the to-be-welded member 200.

In an embodiment of the present application, the welder 140 may include a thermal compression head 141 and a second driver. The second driver can be used to drive the hot-pressing head 141 to move toward or away from the to-be-welded member 200 carried by the carrier 110. For example, the second driver may include a second lifting driving element, and the second lifting driving element may be configured to drive the hot pressing head 141 to move in the height direction of the hot pressing tin melting welding apparatus 100.

In this way, the carrier device 110 and the to-be-welded member 200 provided with the flux may be moved together to the welding region by the driving device 120, wherein the hot pressing head 141 may be located directly above the to-be-welded member 200 with the to-be-welded member 200 at the welding region. Therefore, the hot pressing head 141 can be moved to a position close to the to-be-welded member 200 by driving the hot pressing head 141 to move downward by the second elevation driving element. Further, the to-be-welded member 200 provided with the flux may be subjected to thermocompression welding by the thermocompression head 141.

Further, in the embodiment of the present application, the second driver may further include a second transverse driver and a second longitudinal driver, and the hot press head 141 may be moved transversely and longitudinally in a horizontal plane by using the second transverse driver and the second longitudinal driver, so that the hot press head 141 can be located directly above the members to be welded 200.

Referring to fig. 4, in an embodiment of the present application, the carrier 110 may include a jig 111 and a tray 112. The driving device 120 may include a third driver 121 and a fourth driver. The jig 111 may be provided with a region where a member to be welded is to be set, and the region where the member to be welded is to be set is used to set the member to be welded 200. The third driver 121 can be used for driving the jigs 111 to move, and the fourth driver is used for driving the tray 112 to ascend, so that the tray 112 is detachably connected with the jigs 111 located above the tray 112.

It should be noted that the fixture 111 can be any device capable of carrying the parts to be welded 200. Of course, in the embodiment of the present application, the jig 111 may also be a device capable of carrying the to-be-welded component 200 and positioning the to-be-welded component 200. In the embodiment of the present application, the tray 112 may be located below the jig 111, and in a case where the jig 111 is moved to a position directly above the jig 111 by the third driver 121, the tray 112 may be driven to ascend by the fourth driver, so that the tray 112 is in contact with the jig 111 located above the tray 112, and the tray 112 and the jig 111 are detachably connected. In a case where the tray 112 and the jigs 111 are in a detachably connected state, the tray 112 and the jigs 111 may be moved in synchronization by the driving of the third driver 121.

For example, one of the jig 111 and the tray 112 may be provided with a positioning protrusion, and the other may be provided with a positioning recess, so that the jig 111 and the tray 112 can be connected more accurately by performing a positioning fit through the positioning protrusion and the positioning recess.

For example, the jig 111 and the tray 112 may be detachably connected by means of magnetic attraction. For example, the jig 111 and the tray 112 may be detachably connected by a snap connection. For example, the tray 112 may be provided with a clamping portion, the jig 111 may be provided with a clamping portion, and when the jig 111 is moved to a position directly above the tray 112, the fourth driver may be used to drive the tray 112 to ascend, and the clamping portion may be in clamping fit with the clamping portion, so that the tray 112 and the jig 111 may be detachably connected through the clamping fit of the clamping portion and the clamping portion.

In an embodiment of the present application, in a case where the hot-press tin-melting soldering apparatus 100 includes the mounting base 150, the mounting base 150 may be provided with a first positioning portion and a second positioning portion, and the first positioning portion and the second positioning portion may be respectively positioned and engaged with the tray 112. For example, in the case where the jig 111 and the to-be-welded member 200 are in the flux setting area, the tray 112 may be in positioning fit with the first positioning portion. With the jig 111 and the to-be-welded piece 200 in the welding area, the tray 112 may be in positioning fit with the second positioning portion. In this way, the first positioning portion and the second positioning portion can be utilized, so that the tray 112, the jig 111, and the to-be-welded piece 200 can be accurately rested on the flux setting area and the welding area. Further, after the welding of the to-be-welded member 200 is completed, the tray 112 and the jig 111 may be separated, and the jig 111 may communicate the to-be-welded member 200 after the welding is completed and output from the hot-press tin-melting welding apparatus 100.

For example, the first positioning portion and the second positioning portion may be a travel switch or a proximity switch, and in the case where the tray 112 triggers the first positioning portion, the first positioning portion may cause the third driver 121 to be in a stopped state; in the case where the tray 112 triggers the second positioning portion, the second positioning portion may cause the third driver 121 to be in a stopped state. Thus, the tray 112, the jig 111 and the parts to be welded 200 can be stopped at the flux setting area and the welding area respectively more accurately. In addition, the first positioning portion and the second positioning portion may also be a stopper, and the tray 112, the jig 111, and the to-be-welded member 200 may be stopped at the flux setting area and the welding area accurately by the stopper.

Referring to fig. 3 to 6, in an embodiment of the present application, the third driver 121 may include a first conveyor 1211 and a second conveyor 1212 arranged side by side. Two opposite sides of the jig 111 may be respectively supported by the first conveyer 1211 and the second conveyer 1212, and the first conveyer 1211 and the second conveyer 1212 are used to drive the jig 111 to move along the extending direction of the first conveyer 1211. In this way, the jig 111 is smoothly operated by supporting the opposite sides of the jig 111 on the first and second conveyor belts 1211 and 1212, respectively.

In an embodiment of the present application, the tray 112 may be disposed below the first and second conveying belts 1211 and 1212, and the fourth driver may include a lifting mechanism for driving the tray 112 to ascend. In this way, when the third driver 121 drives the jig 111 to move to a position directly above the tray 112, the lifting mechanism can drive the tray 112 to move up to contact with the tray 112, so that the tray 112 and the jig 111 can be detachably connected.

Referring to fig. 6, in the embodiment of the present application, the number of the jigs 111 may be plural, the number of the tray 112 may be one, and the tray 112 may be detachably connected to one of the plural jigs 111. Thus, the positioning engagement portion may be provided only for the tray 112, and the jig 111 and the tray 112 may be positioned by the positioning engagement portion in such a manner that the tray 112 is combined with each jig 111. Therefore, compared with the scheme that the jig 111 is positioned by separately arranging the positioning matching parts for each set of jig 111, the number of the positioning matching parts to be arranged can be reduced, and the manufacturing cost of the hot-pressing tin melting welding equipment 100 can be reduced.

Further, in an embodiment of the present application, the first conveyor belt 1211 may include a first sub conveyor belt and a second sub conveyor belt, which may be spliced end to end. The second conveyor belt 1212 may include a third sub-conveyor belt and a fourth sub-conveyor belt, which may be spliced end-to-end. The first sub-conveyor belt and the third sub-conveyor belt may be disposed side by side, and the second sub-conveyor belt and the fourth sub-conveyor belt may be disposed side by side. The jig 111 may be supported by the first sub conveyor belt and the third sub conveyor belt, or may be supported by the second sub conveyor belt and the fourth sub conveyor belt.

For example, if the plurality of jigs 111 includes a first jig and a second jig, the first jig may be supported by the first sub conveyor belt and the third sub conveyor belt, and the second jig may be supported by the second sub conveyor belt and the fourth sub conveyor belt. In the process of carrying out hot-press welding on the to-be-welded part 200 carried on the second jig, the to-be-welded part 200 carried on the first jig can carry out a flow of setting soldering flux. Thus, the processes of hot-press welding and flux setting can be performed synchronously, and the working efficiency of the hot-press tin-melting welding device 100 can be improved.

Note that, in the case where the first conveying belt 1211 includes the first sub-conveying belt and the second sub-conveying belt, and the second conveying belt 1212 includes the third sub-conveying belt and the fourth sub-conveying belt, a gap is provided between the first sub-conveying belt and the second sub-conveying belt, and a gap is provided between the third sub-conveying belt and the fourth sub-conveying belt. For example, the bearing portions of the jigs 111 may be prevented from being caught in the gaps between the sub conveyor belts by increasing the sizes of the bearing portions of the jigs 111 carried on the first and second conveyor belts 1211 and 1212.

In an embodiment of the present application, the hot pressure molten tin soldering apparatus 100 may further include a cleaning device 160, and the cleaning device 160 may be used to clean the soldering device 140. Illustratively, the cleaning device 160 may include a rotary drive and a brush 161. The rotating driver is in driving connection with the brush 161, the rotating driver can be used for driving the brush 161 to rotate, the welder 140 can comprise a hot-pressing head 141, and the brush 161 is used for cleaning the hot-pressing head 141. In this way, the hot press head 141 can be cleaned by the brush 161, and the hot press head 141 does not need to be cleaned by an operator, which can further reduce the labor intensity of the operator.

In an embodiment of the application, the hot-press tin-melting welding apparatus 100 may further include an image pickup device 170, and the image pickup device 170 may be used to acquire an image of the to-be-welded member 200. For example, before the flux is provided to the to-be-welded member 200, an image of the to-be-welded member 200 may be acquired by the imaging device 170, the acquired image may be displayed on a display screen, and an operator may determine whether or not the to-be-welded member 200 includes a welded member (e.g., an electronic device) and a welding base material (e.g., a circuit board) in a correct position by observing the acquired image of the to-be-welded member 200. For example, if the weldment is tilted relative to the welding substrate, the hot-pressing tin-melting welding device 100 can be turned off by an operator, so as to adjust the weldment 200 to be welded.

In addition, in the embodiment of the present application, an image recognition system may also be purchased from a corresponding image recognition technology facilitator, and whether the weldment to be welded 200 includes the weldment and the welding base material are in the correct position may be determined based on the acquired image of the weldment to be welded 200 by using the image recognition system. Since the technology for determining the skew of an object by using image recognition is mature, a description thereof will not be provided. It should be noted that, as the technology advances, a better technology for judging whether the weldment and the welding base material included in the to-be-welded member 200 are in the correct positions will appear in the future, and the technology for judging whether the weldment and the welding base material included in the to-be-welded member 200 are in the correct positions may also be applied to the embodiment of the present application.

In this way, in the embodiment of the present application, the to-be-welded member 200 may be disposed on the carrier device 110, and the carrier device 110 and the to-be-welded member 200 may be moved together to the flux disposition region by the driving device 120. Thus, flux can be provided to the to-be-welded member 200 using the flux setter 130. Further, the carrying device 110 and the to-be-welded member 200 can be moved together to the welding zone by the driving device 120. Thus, the work to be welded 200 can be thermocompression bonded using the bonder 140.

For example, the parts to be welded 200 may be an electronic device and a circuit board, solder paste may be disposed between the electronic device and the circuit board, the electronic device may be hot-pressed by the welder 140, so that the solder paste connected between the electronic device and the circuit board is melted, and the flux may prevent the melted solder paste from being oxidized. After heating and pressurizing the electronic device for a predetermined time, the bonder 140 may be removed and the solder paste may be cooled to solidify. Therefore, the solidified tin paste can be used for welding the electronic device on the circuit board and electrically connecting the electronic device with the circuit board.

In the embodiment of the application, the hot-pressing tin-melting welding equipment 100 can assist an operator or replace the operator to weld the parts to be welded 200, so that the labor intensity of the operator is reduced.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present application have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in the embodiments without departing from the principles and spirit of the embodiments, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. A hot-pressing molten tin soldering apparatus, comprising: the soldering flux device comprises a bearing device (110), a driving device (120), a soldering flux setter (130) and a welder (140);

the carrying device (110) is used for carrying a part to be welded (200), and the driving device (120) is used for driving the carrying device (110) to move;

the flux setter (130) is used for setting flux to the welding parts to be welded (200) in a flux setting area under the condition that the driving device (120) drives the carrying device (110) carrying the welding parts to be welded (200) to move to the flux setting area;

the welder (140) is used for performing hot-press welding on the parts to be welded (200) positioned on a welding area under the condition that the driving device (120) drives the carrying device (110) and the parts to be welded (200) provided with the soldering flux to move to the welding area.

2. The apparatus according to claim 1, further comprising a mounting base (150), wherein the driving device (120), the flux setter (130), and the welder (140) are provided to the mounting base (150).

3. The hot-pressing molten tin soldering apparatus according to claim 2, wherein the flux setter (130) includes a flux applying part (131) and a first driver for driving the flux applying part (131) to move in a direction toward or away from the member to be soldered (200) carried by the carrying device (110);

the welder (140) comprises a hot pressing head (141) and a second driver, wherein the second driver is used for driving the hot pressing head (141) to move towards a direction close to or far away from the part to be welded (200) carried on the carrying device (110).

4. The apparatus according to claim 3, wherein the first driver includes a first elevation driving element for driving the flux applying part (131) to move in a height direction of the apparatus;

the second driver comprises a second lifting driving element, and the second lifting driving element is used for driving the hot pressing head (141) to move along the height direction of the hot pressing tin melting welding equipment.

5. The hot-pressing molten tin soldering apparatus according to claim 1, wherein the carrying device (110) includes a jig (111) and a tray (112), and the driving device (120) includes a third driver (121) and a fourth driver; the jig (111) is provided with a region for arranging the parts to be welded, and the region for arranging the parts to be welded is used for arranging the parts to be welded (200);

the third driver (121) is used for driving the jig (111) to move, and the fourth driver is used for driving the tray (112) to ascend, so that the tray (112) is detachably connected with the jig (111) above the tray (112).

6. The hot-pressing molten tin soldering apparatus according to claim 5, wherein the third driver (121) comprises a first conveyer belt (1211) and a second conveyer belt (1212) which are arranged side by side, two opposite sides of the jig (111) are respectively supported by the first conveyer belt (1211) and the second conveyer belt (1212), and the first conveyer belt (1211) and the second conveyer belt (1212) are used for driving the jig (111) to move along the extending direction of the first conveyer belt (1211);

the tray (112) is disposed below the first conveyor belt (1211) and the second conveyor belt (1212), and the fourth driver includes a lifting mechanism for driving the tray (112) to ascend.

7. The hot-pressing tin-melting welding device according to claim 5, wherein the number of the jigs (111) is multiple, the number of the trays (112) is one, and the trays (112) can be detachably connected with one of the jigs (111) respectively.

8. The hot compression solder bonding apparatus of claim 1, further comprising a cleaning device (160), the cleaning device (160) being configured to clean the bonder (140).

9. The hot pressing molten tin soldering apparatus according to claim 8, wherein the cleaning device (160) comprises a rotary driver and a brush (161), the rotary driver is in driving connection with the brush (161), the rotary driver is used for driving the brush (161) to rotate, the soldering apparatus (140) comprises a hot pressing head (141), and the brush (161) is used for cleaning the hot pressing head (141).

10. The apparatus according to claim 1, further comprising an imaging device (170), wherein the imaging device (170) is configured to capture an image of the part to be welded (200).

Images