JP3761495B2 - Lead welding equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a lead welding apparatus for welding a lead to a solar battery cell.
[0002]
[Prior art]
Generally, a solar cell module is manufactured in a planar shape by connecting a plurality of solar cells to form a string and connecting a plurality of rows of strings. In this case, when a plurality of solar cells are connected to form a string, adjacent solar cells are connected via a conductor formed in a flat cross section, for example, a lead made of copper wire. Yes. Specifically, as shown in FIG. 4, leads L are welded through solder over the surface of one solar cell P and the back surface of the adjacent solar cell P, and are sequentially connected.
[0003]
Specifically, the lead is disposed and pressed at the welding position of the solar battery cell, hot air is supplied to the lead to melt the solder, and the lead is welded to the solar battery cell.
[0004]
Here, in consideration of the melting temperature of the solder being 180 to 230 ° C., the temperature of the hot air at the outlet is set.
[0005]
[Problems to be solved by the invention]
By the way, when hot air is supplied to the lead to melt the solder and the lead is welded to the solar battery cell, the hot air is normally blown inward from the outside toward the lead, so that heat stays in the center. Cheap. In addition, even if the leads are welded, the hot air continues to be blown, so that the device disposed under the lead is always exposed to the hot air of high temperature. As a result, the piping and wiring of the equipment may be melted, deformed, or broken.
[0006]
In particular, in the case where the welding of the lead to the solar battery cell is continuously performed in the transport process of the solar battery cell, the hot air is constantly blown out from the outlet, so that the heat is stored and the operator cannot approach the device. The heat effect on the equipment was large.
[0007]
Although it is conceivable to provide a shielding cover on the device, the inside of the shielding cover is prevented from smooth circulation of the outside air, so that it reaches a considerably high temperature in a short time and has almost no effect.
[0008]
The present invention has been made in view of such a problem, and provides a lead welding apparatus capable of preventing as much as possible an adverse effect on a device due to hot air for welding a lead.
[0009]
[Means for Solving the Problems]
The present invention presses a lead transferred to a welding position of a solar battery cell via a pressing device that can move up and down, supplies hot air to the lead through a hot air device that can move up and down, and melts the solder so that the solar cell A lead welding apparatus for welding leads to a cell, wherein the guide plate is curved from the horizontal direction toward the diagonally upward and outward direction on the support frame of the pressing device, and the guide plate has a plurality of glazed openings, and the guide A shield plate made of heat insulating material is provided on the upper surface of the inner end side horizontal portion of the plate, and hot air from the hot air device collides with the heat insulating material to rise along the guide plate, and the outside air on the lower surface side of the guide plate Is sucked from the opening.
[0010]
According to the present invention, the lead is transferred to the welding position of the solar battery cell, pressed through the pressing device, hot air is supplied to the lead through the hot air device, the solder is melted, and the lead is supplied to the solar battery cell. Weld. When the welding of the leads is completed, the hot air device is retracted to the raised position. At this time, the hot air from the hot air device changes its direction after colliding with the heat insulating material, and is discharged obliquely upward and outward along the guide plate. Here, when the hot air passes over the louvered opening, the outside air on the lower surface side of the guide plate is sucked through the louvered opening. For this reason, the high-temperature air around the solar cells is sucked and the outside air flows into the periphery of the solar cells by convection, so that the surroundings of the solar cells are cooled and the heat stays and accumulates heat. Can be prevented.
[0011]
As a result, the equipment arranged around the solar battery cell is not always exposed to hot air, or heat does not stay around the equipment, so that the equipment piping and wiring are melted, deformed, or Failure can be reliably prevented without providing a cooling device or the like.
[0012]
In the present invention, a support block that can be moved up and down controlled below a melting temperature of the solder is provided facing the lower side of the pressing device, and when the solar battery cell is supported via the support block, The pressing of the lead by the pressing device can be supported, the lower surface side of the solar battery cell can be heated, and the temperature difference from the upper surface side by the hot air device can be reduced. Moreover, when a hot air apparatus raises, the heat | fever of a photovoltaic cell can be absorbed.
[0013]
In the present invention, when the blowing nozzle of the hot air device is formed obliquely downward and outward, the hot air from the hot air device is blown obliquely downward and outward, so that hot air is retained in the central portion. Can be prevented.
[0014]
In the present invention, when the support frame of the pressing device is formed in a frame shape and the hot air device moves up and down inside the frame-shaped support frame, the overall size can be formed compactly.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0016]
1 and 2 show an embodiment of a lead welding apparatus 1 according to the present invention.
[0017]
The welding device 1 is provided facing the side of the transport device 2 at a set position of the transport device 2 that intermittently transports the solar cells P and the solar cells P transported via the transport device 2. The lead L transfer device 3, the lead L pressing device 4 provided above the conveyance device 2, the hot air device 5 provided above the conveyance device 2, and the conveyance device 2 below And a support device 6 provided facing the vehicle.
[0018]
Although not shown in detail, the conveying device 2 includes a pair of toothed pulleys and a toothed belt 21 wound between the pair of toothed pulleys, and an electric motor is connected to one toothed pulley. In addition, small holes 21a are formed in the toothed belt 21 at regular intervals, and the inner surface of the toothed belt 21 is connected to a vacuum source (not shown).
[0019]
Therefore, the solar cells P placed on the toothed belt 21 are positioned by the toothed belt 21 by being sucked through the small holes 21a of the toothed belt 21, and an electric motor (not shown) is driven in this state. Then, it is conveyed backward.
[0020]
The width of the toothed belt 21 is set smaller than the width of the solar battery cell P.
[0021]
As shown in FIG. 2, the transfer device 3 is connected to a cradle 31 arranged on the side of the transport device 2 and a vacuum source (not shown) at the set position of the solar battery cell P, and is supplied to the cradle 31. The adsorbing member 32 has a plurality of adsorbing portions 321 that adsorb the lead L having the set length, and the adsorbing member 32 is usually positioned above the cradle 31 although not shown in detail. It is provided so as to be able to move up and down, and is provided so as to be capable of reciprocating between the cradle 31 and the position where the lead is welded to the solar cell P transported to the set position by the transport device 2.
[0022]
Therefore, the lead L supplied to the cradle 31 can be adsorbed via the adsorbing member 32 and transferred to the welding position of the solar battery cell P.
[0023]
Here, the welding position of the lead L with respect to the solar cell P is set to the left and right end portions of the solar cell P outside the left and right end edges of the toothed belt 21 of the transport device 2.
[0024]
The pressing device 4 includes a rectangular frame-shaped support frame 41, a plurality of attachment members 42 fixed to the left and right outer surfaces of the support frame 41 at intervals in the front-rear direction, and a spring (not shown) on each attachment member 42. The support frame 41 is provided so as to be movable up and down via a cylinder (not shown in detail).
[0025]
Therefore, when the cylinder (not shown) is expanded and contracted, the support frame 41, that is, the probe pin 43 provided on the support frame 41 via the mounting member 42 is moved up and down, and the transfer device 3 is moved to the welding position of the solar battery cell P. The lead L placed therethrough can be pressed by a spring (not shown) or retracted upward from the pressing position. At this time, the solar battery cell P is supported by a support device 6 described later.
[0026]
Here, the arrangement positions of the probe pins 43 are set so as not to interfere with the suction portions 321 of the suction member 32 in the transfer device 3.
[0027]
In addition, an air passage 41a connected to an air source (not shown) is formed in the support frame 41, and an air passage 42a is also formed in each mounting member 42 in communication with the air passage 41a. The air passage 42 a of the attachment member 42 is communicated with a blowout opening that is opened toward the welding position of the solar battery cell P.
[0028]
Note that shielding plates 7 described later are fixed to the left and right of the support frame 41, respectively.
[0029]
The hot-air device 5 is fixed symmetrically with a set interval in the front-rear direction on the left and right of the mounting frame 51, and a plurality of heaters 52 each connected to an air source (not shown) by piping, Although not shown in detail, the mounting frame 51 is provided so as to be movable up and down via a cylinder. Moreover, the front-end | tip of each heater 52 is formed in the flat blowing nozzle 521 which goes to diagonally downward outer direction.
[0030]
Therefore, the air supplied to each heater 52 is heated and blown from the blowing nozzle 521 toward the diagonally downward and outward direction. In this state, the mounting frame 51, that is, each heater 52 is moved up and down by extending and retracting a cylinder (not shown), and hot air is blown to the lead L placed via the transfer device 3 at the welding position of the solar battery cell P. It can be supplied or retreated upward. At this time, each heater 52 moves up and down in a space defined by the support frame 41 of the pressing device 4. When the heater 52 is lowered, the hot air blown obliquely downward and outward from the flat blowing nozzle 521 acts almost uniformly on the leads L placed at the welding positions of the solar cells P.
[0031]
In addition, when it is necessary to weld the lead L to the solar cell P in a spot manner, the diameter is gradually reduced so that hot air can be locally supplied instead of the flat blowing nozzle 521. A tapered blowing nozzle may be employed.
[0032]
In this embodiment, the hot air temperature immediately after being blown from the blowing nozzle 521 so that hot air of about 180 to 230 ° C., which is the melting temperature of the solder, acts on the lead L that is about 20 cm away from the opening end of the blowing nozzle 521. Is set to about 600 ° C.
[0033]
The support device 6 includes a support block 61 disposed facing the left and right outer sides of the toothed belt 21 of the transport device 2 at a set position of the solar battery cell P, and a cylinder 62 that moves the support block 61 up and down. By extending and retracting the cylinder 62, the support block 61 is supported at the left and right end portions of the solar cells P protruding outward from the left and right end edges of the toothed belt 21, and is retracted downward. Can be raised and lowered in between.
[0034]
Here, when each support block 61 rises to support the left and right ends of the solar battery cell P, the lead L placed on the welding position of the solar battery cell P by the probe pin 43 of the pressing device 4 described above. The pressure can be supported.
[0035]
The support block 61 is made of copper having good heat conduction, and is controlled so as to maintain a set temperature equal to or lower than the melting temperature of the solder. For this reason, when each support block 61 supports the left and right end portions of the solar battery cell P, the lower surface side of the solar battery cell P is heated, and thus the upper surface side heated by hot air from the heater 52 of the hot air device 5. And the deformation of the solar battery cell P due to the thermal stress accompanying the large temperature difference can be prevented. Further, when the hot air device 5 is raised, the heat of the solar battery cell P whose upper surface is heated to the vicinity of the melting temperature of the solder by the hot air can be absorbed through the support block 61 having a relatively lower temperature than that. The solar battery cell P can be quickly cooled.
[0036]
On the other hand, each shielding plate 7 provided on the support frame 41 of the pressing device 4 includes a guide plate 71 formed in a curved shape from the horizontal direction toward the diagonally upper and outer direction, and an inner end side horizontal portion of the guide plate 71. And a heat insulating material 72 disposed on the upper surface. The guide plate 71 has rising pieces 711 raised from the front and rear end edges by a predetermined length, and a plurality of gallery-like openings 71a are formed at intervals in the front-rear direction and the vertical direction. .
[0037]
For this reason, the hot air from the hot air device 5 retracted upward can be guided from the horizontal direction to the obliquely upward and outward direction along the guide plate 71 having the rising pieces 711 raised at the front and rear end edges. At this time, hot air passes above the louvered openings 71a, so that the outside air on the lower surface side of the guide plate 71 is sucked through the louvered openings 71a. The heat insulating plate 72 is provided in accordance with a position where hot air blown from the blowing nozzle 511 of the heater 51 of the hot air device 5 retracted upward is collided, and high temperature hot air directly acts on the guide plate 71. It functions to change the direction of hot air in the horizontal direction.
[0038]
Next, the operation of the lead L welding apparatus 1 configured as described above will be described.
[0039]
First, in the initial state, as shown in FIGS. 1 and 2, the support frame 41 of the pressing device 4 and the mounting frame 51 of the hot air device 5 are each retracted to the raised position, and the support block of the support device 6. 62 is also retracted to the lower position. Although not shown in detail, the transfer device 3 operates in synchronization with the conveyance of the solar battery cell P by the conveyance device 2, and the lead L is cut to a set length and placed on the cradle 31. Yes.
[0040]
In such a state, when the transport device 2 is operated, the solar cells P placed on the toothed belt 21 are attracted to the toothed belt 21 and transported backward. When the solar battery cell P reaches the set position, the operation of the transfer device 2 is stopped.
[0041]
Next, the support block 61 ascends via the cylinder 62, and the left and right end portions of the solar cell P protruding from the toothed belt 21 so that the solar cell P slightly floats from the upper surface of the toothed belt 21. Lift and support. At this time, the solar battery cell P is heated by the support block 61 heated to a constant temperature.
[0042]
Further, the adsorbing member 32 of the transfer device 3 adsorbs the lead L and moves to the welding position for the solar battery cell P held by the toothed belt 21 at the set position.
[0043]
If the lead L is placed at the welding position of the solar battery cell P, the support frame 41 is lowered via the cylinder, and the probe pin 43 causes the lead L to be moved by the spring at a position where it does not interfere with the suction portion 321 of the suction member 32. Press against the solar cell P. At this time, since the solar battery cell P is supported by the support block 61 of the support device 6 including its welding position, the support block 61 applies the urging force of the spring of the probe pin 43 via the solar battery cell P. Can support.
[0044]
On the other hand, if the lead L is pressed to the welding position of the solar battery cell P by the probe pin 43, the adsorption member 32 of the transfer device 3 moves to the original position, and the mounting frame 51 of the hot air device 5 is moved through the cylinder. Lower (see FIG. 3). At this time, the heater 52 of the hot air device 5 descends in the support frame 41 of the pressing device 4. Then, the heater 52 lowered to the working position supplies hot air from the blowing nozzle 521 toward the lead L, and melts the solder of the lead L.
[0045]
When the solder melts, the heater 52 is moved to the upper retreat position via the cylinder. At this time, since the solder melts, the lead L sinks into the melted solder. In this state, an air source (not shown) is operated, and compressed air is supplied to the air passage 41a of the support frame 41 and the air of each mounting member 42. When ejected from the outlet through the passage 42a, the molten solder is cooled and solidified, and the lead L can be welded to the welding position of the solar battery cell P. Further, since the relatively low temperature support block 61 is in contact with the lower surface of the solar battery cell P, the heat of the solar battery cell P heated to a high temperature through the support block 61 is absorbed. In combination, the solar battery cell P can be quickly cooled.
[0046]
On the other hand, the hot air from the hot air device 5 that has risen to the retracted position is continuously blown out from the blowing nozzle 521, first collides with the heat insulating material 72 of the shielding plate 7, then changes direction, and along the guide plate 71. It is emitted diagonally upward and outward. Here, when the hot air is discharged along the guide plate 71, the hot air passes above the louvered opening 71a, so that the outside air on the lower surface side of the guide plate 71 is sucked through the louvered opening 71a. Therefore, outside air on the lower surface side of the guide plate 71, that is, heated by the support block 61, while hot air around the solar cells P heated by the hot air supplied from the hot air device 5 is sucked. Since the outside air flows into the periphery of the solar battery cell P by convection, the periphery of the solar battery cell P is cooled, and heat is prevented from being accumulated and stored.
[0047]
As a result, the equipment arranged around the solar battery cell is not always exposed to hot air, or heat does not stay around the equipment, so that the equipment piping and wiring are melted, deformed, or Failure can be reliably prevented without providing a cooling device or the like.
[0048]
If the lead L is welded to the welding position of the solar battery cell P, the pressing device 4 is raised to the retracted position via the cylinder, and the probe pin 43 is detached from the lead L, and then the support block 61 is interposed via the cylinder 62. Is lowered to the retracted position. Also during this time, the hot air from the blowing nozzle 521 of the hot air device 5 is continuously blown out and discharged obliquely upward and outward along the guide plate 71. While high-temperature air around the cell P is sucked, outside air flows around the solar battery cell P by convection. For this reason, the support block 61 of the support device 6 that has received the hot air from the hot air device 5 and has risen above the set temperature also detects its own temperature and shuts off the heating, and the outside air that flows around the solar cells P Air-cooled rapidly. Therefore, it is possible to reliably prevent heat from being gradually accumulated in the support block 61 and exceeding the set temperature, that is, to a temperature at which the solder of the solar battery cell P is melted.
[0049]
Thereafter, the transport device 2 is operated to transport the solar battery cell P on which the lead L is welded, and to transport a new solar battery cell P to the set position. And if the new photovoltaic cell P is conveyed to the setting position, a work will be restarted from the raise of the support block 61 maintained at preset temperature.
[0050]
【The invention's effect】
As described above, according to the present invention, when a lead is welded to a solar battery cell with hot air, adverse effects on the device due to the hot air can be prevented as much as possible.
[Brief description of the drawings]
FIG. 1 is a perspective view showing a lead welding apparatus according to an embodiment of the present invention with a part thereof omitted.
2 is a front view schematically showing the lead welding apparatus of FIG. 1; FIG.
3 is a front view schematically showing a welding process of the lead welding apparatus of FIG. 1; FIG.
FIG. 4 is a plan view and a side view of a string formed by connecting a plurality of solar cells via leads.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Welding apparatus 2 Conveying apparatus 21 Toothed belt 3 Transfer apparatus 32 Adsorption member 4 Pressing apparatus 41 Support frame 42 Mounting member 43 Probe pin 5 Hot air apparatus 51 Mounting frame 52 Heater 521 Outlet nozzle 6 Support apparatus 61 Support block 62 Cylinder P Solar cell Cell L lead

Claims (4)

The lead transferred to the welding position of the solar battery cell is pressed through a pressing device that can be moved up and down, and hot air is supplied to the lead through a hot air device that can be moved up and down to melt the solder so that the lead is placed in the solar cell. A welding apparatus for welding leads, wherein the supporting frame of the pressing device is curved from the horizontal direction toward the diagonally upward and outward direction, and has a plurality of glazed openings, and an inner end of the guide plate A shielding plate made of heat insulating material is installed on the upper surface of the side horizontal part, and hot air from the hot air device collides with the heat insulating material to rise along the guide plate, and the outside air on the lower surface side of the guide plate opens Lead welding apparatus characterized by sucking from a lead. 2. A support block that can be moved up and down controlled to a set temperature not higher than a melting temperature of solder is provided facing the lower side of the pressing device, and the solar battery cell is supported through the support block. Lead welding equipment. 3. The lead welding apparatus according to claim 1, wherein the blowing nozzle of the hot air device is formed obliquely downward and outward. 4. The lead welding apparatus according to claim 1, wherein a support frame of the pressing device is formed in a frame shape, and a hot air device moves up and down inside the frame-shaped support frame.

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