TW201525479A - Solar panel inspection machine table - Google Patents

Abstract

The present invention relates to a solar panel inspection machine table; more particularly, the present invention relates to a solar panel inspection machine table capable of moving probes in large-scale. The solar panel inspection machine table of the present invention comprises a base, a lower inspection frame, a plurality of upper probe frame modules, a lower inspection frame and a plurality of lower probe frame modules. Two side edges of the upper and lower inspection frames are respectively provided with a sliding rail such that each of the probe frame modules can be movably arranged on the sliding rail and connected to each probe via metal strips. By means of the solar panel inspection machine table of the present invention, not only the position of the probe frame can be moved according to different demands, but also the machine structure can be simplified by reducing wires connected to each probe to enhance the electrical performance of the machine table, thus reducing the covering area of the solar panel.

Description

Solar panel inspection machine

The invention relates to a solar panel detecting machine, in particular to a solar panel detecting machine capable of moving a probe in a wide range.

In order to detect whether a solar cell produces a defective cell or a crack during the manufacturing process, the method used in the industry is to contact the probe on the solar cell with a probe on the probe row and introduce a current to cause each of the solar panels. The unit emits light, and then visually checks or detects whether each unit contains a dark area by a visual, image sensor or photographic equipment. If there is a dark area, it can be determined that the unit is bad.
In addition, measuring the photoelectric conversion efficiency of the solar panel, the high-intensity parallel light is vertically irradiated to the light-receiving surface of the solar panel to be tested, and at the same time, the probe on the probe row contacts the bus electrode on the solar panel, thereby measuring The voltage and current generated on the solar panel when illuminated by strong light.
Conventionally used probes are arranged on a probe holder to provide a plurality of probes, each of which is soldered with a wire, which is connected to the electrode of the detection machine by a wire for supplying current or measuring voltage and current.
Due to the different sizes of solar panels, the size of each cell is not the same, and the number of rows and columns of the cells are different. Therefore, the inspection machine often needs to use different specifications and the number of probe rows. When replacing the probe row, it is necessary to arrange a large number of wires welded to the probe, which leads to time-consuming and labor-intensive work, and increases the inefficiency. In addition, the shielding area produced by many wires when viewing the solar panel and the shadow area generated when the light illuminates the solar panel affect the accuracy of the detection. Therefore, how to improve the structure of the inspection machine is an urgent problem to be solved in the industry.

An object of the present invention is to provide a solar panel detecting machine, and more particularly to a solar panel detecting machine capable of moving a probe in a wide range.
Another object of the present invention is to provide a solar panel detecting machine which can move the position of the probe in a wide range by using a structure in which the electrodes are arranged in parallel with the slide rails without arranging the wires.
Another object of the present invention is to provide a solar panel detecting machine, wherein the probes are connected by metal strips, and the metal strip is disposed on the upper end surface or the lower end surface of the probe holder, which can provide good conduction effect without additional shielding. Or a shadow is produced.
The invention provides a solar panel detecting machine, comprising: a base; an upper detecting frame, disposed above the front end of the base, wherein the upper side of the upper detecting frame is respectively provided with an upper sliding rail, and at least one side of the upper detecting frame An upper electrode is disposed, the upper electrode is disposed in parallel with the upper sliding rail; and a plurality of upper probe holder modules are respectively slidably disposed on the two sides of the upper probe bracket module, and the upper probes are respectively The rack module is respectively provided with a plurality of probes and an upper metal strip, the upper metal strips are connected to the probes, and the upper electrodes are connected via an upper electrode contact group; the lower detection frame is disposed under the front end of the base, A sliding rail is disposed on each side of the lower detecting frame, and an electrode is disposed on at least one side of the lower detecting frame, the lower electrode is disposed in parallel with the lower sliding rail; and a plurality of lower probe frame modules, each lower probe frame module The two ends of the probe frame are respectively slidably disposed on the sliding rails on both sides, and each of the lower probe frame modules is respectively provided with a plurality of probes and a lower metal strip, and the lower metal strips are connected to the probes and connected through the lower electrode contact groups. The lower electrode; wherein the upper detection frame and the lower detection frame It is detected by a probe holding solar panel.
In an embodiment of the solar panel detecting machine, each of the upper probe rack modules comprises: two upper sliders, respectively slidably sleeved on the two sides of the sliding rail; an upper probe frame, respectively disposed at both ends a first upper metal strip disposed on an upper end surface or a lower end surface of the upper probe holder; a plurality of probes disposed on the upper probe holder and respectively connected to the first upper metal strip; and one or two The upper electrode contact group is respectively disposed on one of the two upper sliders, so that the first upper metal strip is electrically connected to the upper electrode.
An embodiment of the solar panel detecting machine, wherein each of the upper electrode contact groups comprises: a contact seat connected to the upper slider; at least one electrode contact disposed on the contact seat for electrically connecting with the upper electrode Sexual connection.
In an embodiment of the solar panel detecting machine, each of the upper electrode contact groups further includes a knob for adjusting the height of the contact seat, so that the electrode contacts can contact or leave the upper electrode.
In one embodiment of the solar panel inspection machine, the electrode contacts of each of the upper probe holder modules are connected to the first upper metal strip by a wire.
In one embodiment of the solar panel detecting machine, each of the lower probe rack modules comprises: two lower sliding blocks respectively slidably disposed on the sliding rails on both sides; and a lower probe holder, the two ends of which are respectively disposed on the lower sliding block a first lower metal strip disposed on the upper end surface or the lower end surface of the lower probe holder; a plurality of probes disposed on the lower probe holder and respectively connected to the first lower metal strip; and one or two lower electrode contacts The group is respectively disposed on one of the two lower sliders, so that the first lower metal strip is electrically connected to the lower electrode.
An embodiment of the solar panel detecting machine, wherein each of the lower electrode contact groups comprises: a contact seat connected to the lower slider; at least one electrode contact disposed on the contact seat for electrically connecting the lower electrode connection.
In one embodiment of the solar panel detecting machine, each of the lower electrode contact groups further includes a knob for adjusting the height of the contact seat, so that the electrode contacts can contact or leave the lower electrode.
In one embodiment of the solar panel inspection machine, the electrode contacts of each lower probe holder module are connected to the first lower metal strip by a wire.
In one embodiment of the solar panel inspection machine, each of the probes includes a sleeve and a contact end.
In an embodiment of the solar panel detecting machine, each of the upper probe rack modules comprises: two upper sliders, respectively slidably sleeved on the two sides of the sliding rail; an upper probe frame, respectively disposed at both ends a first upper metal strip disposed on the lower end surface of the upper probe holder; a second upper metal strip disposed on the upper end surface of the upper probe holder; a plurality of probes disposed on the upper probe holder And two upper electrode contact groups are respectively disposed on the two upper sliders, so that the first upper metal strip and the second upper metal strip and the upper electrode respectively form an electrical connection; wherein a part of the plurality of probes are connected to the probe One upper metal strip and the other part of the probe are connected to the second upper metal strip.
In one embodiment of the solar panel detecting machine, each of the lower probe rack modules comprises: two lower sliding blocks respectively slidably disposed on the sliding rails on both sides; and a lower probe holder, the two ends of which are respectively disposed on the lower sliding block a first lower metal strip disposed on the lower end surface of the lower probe holder; a second lower metal strip disposed on the upper end surface of the lower probe holder; a plurality of probes disposed on the lower probe holder; and two lower The electrode contact groups are respectively disposed on the two lower sliders, so that the first lower metal strip and the second lower metal strip and the lower electrode are respectively electrically connected; wherein a part of the plurality of probes are connected to the first lower metal strip, Another part of the probe is connected to the second lower metal strip.

10‧‧‧Solar panel inspection machine
12‧‧‧ Pedestal
14‧‧‧Upper inspection rack
141‧‧‧Upper rail
143‧‧‧Upper electrode
15‧‧‧ probe
151‧‧‧ sleeve
153‧‧‧Contact end
16‧‧‧下下架
161‧‧‧Lower rail
163‧‧‧ lower electrode
18‧‧‧Upper probe frame module
181‧‧‧Upper slider
182‧‧‧Upper probe holder
183‧‧‧Metal strip
184‧‧‧Upper electrode contact group
185‧‧‧Contact Block
186‧‧‧ knob
187‧‧‧Electrode contacts
19‧‧‧Lower probe frame module
191‧‧‧ Lower slider
192‧‧‧Lower probe holder
193‧‧‧lower conductor
194‧‧‧ lower electrode contact group
195‧‧‧Contact Block
196‧‧‧ knob
197‧‧‧Electrode contacts

Fig. 1 is a schematic view showing an embodiment of the present invention.
Fig. 2 is a partially enlarged view of the embodiment of the present invention as shown in Fig. 1.

Please refer to FIG. 1 and FIG. 2 , which are respectively a schematic view and a partial enlarged view of an embodiment of a solar panel detecting machine of the present invention. As shown in the figure, the solar panel inspection machine 10 of the present invention comprises: a base 12, an upper detection frame 14, a plurality of upper probe holder modules 18, a lower detection frame 16 and a plurality of lower probe frame molds. Group 19.
The upper detecting frame 14 is disposed above the front end of the base 12, and an upper sliding rail 141 is disposed on each of the two sides, and an upper electrode 143 is disposed on at least one side thereof, and the upper electrode 143 is disposed in parallel with the upper sliding rail 141.
The two ends of the upper probe frame module 18 are slidably disposed on the two sides of the slide rails 141, and each of the upper probe rack modules 18 is respectively provided with a plurality of probes 15 and an upper metal strip 183. Each of the probes 15 is connected to the upper metal strip 183, and is connected to the upper electrode 143 via an upper electrode contact group 184.
The lower detecting frame 16 is disposed below the front end of the base 12, and a sliding rail 161 is disposed on each of the two sides, and the lower electrode 163 is disposed on at least one side, and the lower electrode 163 is disposed in parallel with the lower rail 161.
The two ends of each of the lower probe holder modules 19 are slidably disposed on the sliding rails 161 on both sides, and each of the lower probe holder modules 19 is provided with a plurality of probes 15 and a lower metal strip 193, respectively. Each of the probes 15 is connected to the lower metal strip 193, and is connected to the lower electrode 163 via a lower electrode contact group 194.
With the configuration of the solar panel detecting machine 10 of the present invention, a solar panel (not shown) can be sandwiched by the probes 15 provided on the upper detecting frame 14 and the lower detecting frame 16 for detection.
In an embodiment of the present invention, each of the upper probe holder module 18 and the lower probe holder module 19 can be respectively slid on the upper detection frame 14 and the lower detection frame 16, and the probes can be freely adjusted according to requirements. The position of the needle holder module is used for the detection.
In an embodiment of the present invention, each of the upper probe holder modules 18 includes: two upper sliders 181, an upper probe holder 182, an upper metal strip 183, a plurality of probes 15 and an upper electrode contact. Group 184. The two upper sliders 181 are slidably sleeved on the upper rails 141 of the upper detection frame 14 . The two ends of the upper probe holder 182 are respectively disposed on the upper side of the upper slider 181; the upper metal strip 183 is disposed on the upper end surface or the lower end surface of the upper probe holder 182 (the illustrated embodiment is disposed on the lower end surface). A plurality of probes 15 are disposed on the upper probe holder 182 and electrically connected to the upper metal strips 183, respectively. The upper electrode contact group 184 is disposed on one of the two upper sliders 181 to electrically connect the upper metal strip 183 and the upper electrode 143.
By using the solar panel detecting machine 10 structure of the embodiment, the shielding area or shadow caused by the machine on the solar panel can be reduced, the accuracy of detection can be improved, and the electrical performance and heat dissipation efficiency of the machine can be improved.
In an embodiment of the present invention, another upper electrode contact group 184 is disposed on the other slider 181 with respect to the upper electrode contact group 184, and the upper metal strip 183 is passed through the other upper electrode contact group. The 184 is electrically connected to the upper electrode 143 on the other side. By using the solar panel detecting machine 10 structure of the embodiment, the current path can be dispersed during the detection, the heat generation of each path can be reduced, and the safety and reliability of the device can be improved.
In an embodiment of the present invention, each of the upper electrode contact groups 184 includes a contact pad 185 and at least one electrode contact 187. The contact pad 185 is disposed on the upper slider 181. The electrode contact 187 is disposed on the contact pad 185 for electrically connecting with the upper electrode 143.
In an embodiment of the present invention, each of the upper electrode contact groups 184 is further provided with a knob 186 for adjusting the height of the contact base 185 to contact or leave the upper electrode 143. With the configuration of the embodiment, when the upper probe frame module 18 needs to be moved or not used, the electrode contact 187 is separated from the upper electrode 143, thereby reducing the friction loss between the electrode contact 187 and the upper electrode 143, and Prevent the risk of accidental electric shock.
In one embodiment of the invention, the electrode contacts 187 of each of the upper probe holder modules 18 are connected to the metal strips 183 by a wire (not shown).
In one embodiment of the present invention, each of the lower probe holder modules 19 includes a lower slider 191, a lower probe holder 192, a lower metal strip 193, a plurality of probes 15 and a lower electrode contact group 194. The two lower sliders 191 are respectively slidably sleeved on the sliding rails 161 on both sides of the lower detecting frame 16 . The two ends of the lower probe holder 192 are respectively disposed on the lower side sliders 191; the lower metal strips 193 are disposed on the upper end surface or the lower end surface of the lower probe holder 192 (the illustrated embodiment is disposed on the upper end surface). A plurality of probes 15 are disposed on the lower probe holder 192 and electrically connected to the lower metal strips 193, respectively. The lower electrode contact group 194 is disposed on one of the two lower sliders 191 to electrically connect the lower metal strip 193 and the lower electrode 163.
By using the solar panel detecting machine 10 structure of the embodiment, the accuracy of the detection can be improved, and the electrical performance and heat dissipation efficiency of the machine can be improved.
In an embodiment of the present invention, another lower electrode contact group 194 is disposed on the other slider 191 of the lower electrode contact group 194, and the lower metal strip 193 is passed through the other lower electrode contact group 194. The lower side electrode 163 on the other side forms an electrical connection. By using the solar energy detecting machine 10 structure of the embodiment, the current path can be dispersed during the detection, the heat generation of each path can be reduced, and the safety and reliability of the device can be improved.
In one embodiment of the present invention, each of the lower electrode contact groups 194 includes a contact pad 195 and at least one electrode contact 197. The contact pad 195 is disposed on the lower slider 191. The electrode contact 197 is disposed on the contact pad 195 for electrically connecting with the lower electrode 163.
In one embodiment of the present invention, each of the lower electrode contact sets 194 is further provided with a knob 196 for adjusting the height of the contact base 195 to allow the electrode contacts 197 to contact or leave the lower electrode 163. With the configuration of the embodiment, when the lower probe holder module 19 needs to be moved or not used, the electrode contact 197 is separated from the lower electrode 163, thereby reducing the friction loss between the electrode contact 197 and the lower electrode 163. Prevent the risk of accidental electric shock.
In one embodiment of the invention, the electrode contacts 197 of each of the lower probe holder modules 19 are connected to the lower metal strip 193 by a wire (not shown).
In an embodiment of the present invention, the upper probe holder 182 is disposed on the other end surface of the upper metal strip 183 (such as the upper end surface as shown) and another upper metal strip (not shown) on the opposite side. The other slider 181 of the electrode contact group 184 is provided with another upper electrode contact group 184, and the other upper metal strip is electrically connected to the other upper electrode 143 through the other upper electrode contact group 184. . Wherein, one of the plurality of probes 15 is connected to the metal strip 183, and the other part of the probe is connected to the other upper metal strip.
In an embodiment of the present invention, another lower metal strip (not shown) may be disposed on the other end surface of the lower probe holder 192 with respect to the lower end of the lower metal strip 193 (not shown), relative to the lower electrode. The other slider 191 of the contact group 194 is provided with another lower electrode contact group 194, and the other lower metal strip is electrically connected to the other lower electrode 163 through the other lower electrode contact group 194. Wherein, one of the plurality of probes 15 is connected to the lower metal strip 193, and the other part of the probe is connected to the other lower metal strip.
By using the configuration of the embodiment, and the upper electrode 143 on both sides of the upper detecting frame 14 and the lower electrode 163 on the lower sides of the lower detecting frame 16 are respectively connected to different detecting instruments, two values can be simultaneously detected in the same machine. In order to shorten the testing process and time.
As can be seen from the above description, by using the structure of the solar panel detecting machine 10 of the present invention, in addition to the position where the probe holder can be moved as needed, the wire connecting the probes can be simplified to simplify the structure of the machine, and the power of the machine can be enhanced. Sexual performance, and can reduce the shadow or shadow area on the solar panel.
The above is only the embodiment of the present invention, and is not intended to limit the scope of the present invention, that is, the equivalent changes and modifications of the shapes, structures, features, methods and spirits described in the claims of the present invention. All should be included in the scope of the patent application of the present invention.

10‧‧‧Solar panel inspection machine

12‧‧‧ Pedestal

14‧‧‧Upper inspection rack

141‧‧‧Upper rail

143‧‧‧Upper electrode

15‧‧‧ probe

16‧‧‧下下架

161‧‧‧Lower rail

163‧‧‧ lower electrode

18‧‧‧Upper probe frame module

181‧‧‧Upper slider

182‧‧‧Upper probe holder

183‧‧‧Metal strip

184‧‧‧Upper electrode contact group

185‧‧‧Contact Block

186‧‧‧ knob

187‧‧‧Electrode contacts

19‧‧‧Lower probe frame module

191‧‧‧ Lower slider

192‧‧‧Lower probe holder

193‧‧‧Metal strip

194‧‧‧ lower electrode contact group

195‧‧‧Contact Block

196‧‧‧ knob

197‧‧‧Electrode contacts

Claims (1)

A solar panel detecting machine comprises: a base; an upper detecting frame, disposed above the front end of the base, the upper side of the upper detecting frame is respectively provided with an upper sliding rail, and an upper side is disposed on at least one side thereof An electrode, the upper electrode is disposed in parallel with the upper sliding rail; a plurality of upper probe frame modules, the two ends of each upper probe frame module are slidably disposed on the two sides of the sliding rail, and each upper probe frame module Each of the plurality of probes and a first upper metal strip are respectively connected to the probes, and the upper electrodes are connected via an upper electrode contact group; the lower detection frame is disposed below the front end of the base. A sliding rail is disposed on each side of the lower detecting frame, and an electrode is disposed on at least one side of the lower detecting frame, the lower electrode is disposed in parallel with the lower sliding rail; and a plurality of lower probe holder modules, each lower probe frame module The two ends of the group are respectively slidably disposed on the sliding rails on both sides, and each of the lower probe rack modules is respectively provided with a plurality of probes and a first lower metal strip, and the first lower metal strip is connected to each probe, and a lower electrode contact group is connected to the lower electrode; wherein the upper detection frame and the lower Measuring carrier can be detected with a probe holding a solar panel.
2. The solar panel inspection machine according to claim 1, wherein each of the upper probe frame modules comprises: two upper sliders, respectively slidably sleeved on the two sides of the slide rail; The needle holder has two ends respectively disposed on the upper slider; a first upper metal strip is disposed on the upper end surface or the lower end surface of the upper probe holder; a plurality of probes are disposed on the upper probe holder and respectively connected to the first upper metal And one or two upper electrode contact groups are respectively disposed on one of the two upper sliders, so that the first upper metal strip and the upper electrode are electrically connected.
3. The solar panel inspection machine of claim 2, wherein each of the upper electrode contact groups comprises: a contact seat connected to the upper slider; at least one electrode contact disposed at the contact seat For electrically connecting to the upper electrode.
4. The solar panel inspection machine of claim 3, wherein each of the upper electrode contact groups further includes a knob for adjusting the height of the contact seat, so that the electrode contacts contact or leave the upper electrode. .
5. The solar panel inspection machine of claim 3, wherein the electrode contacts of each of the upper probe holder modules are connected to the first upper metal strip by a wire.
6. The solar panel inspection machine of claim 1, wherein each lower probe frame module comprises: two lower sliders, respectively slidable on the sliding rails on both sides; a lower probe holder, The two ends are respectively disposed on the lower slider; a first lower metal strip is disposed on the upper end surface or the lower end surface of the lower probe holder; a plurality of probes are disposed on the lower probe holder and respectively connected to the first lower metal strip; and one Or two lower electrode contact groups are respectively disposed on one of the two lower sliders, so that the first lower metal strip and the lower electrode form an electrical connection.
7. The solar panel inspection machine according to claim 6, wherein each of the lower electrode contact groups comprises: a contact seat connected to the lower slider; at least one electrode contact is disposed at the contact seat, It is used to electrically connect with the lower electrode.
8. The solar panel inspection machine according to claim 7, wherein each of the lower electrode contact groups further comprises a knob for adjusting the height of the contact seat, so that the contact points of the electrodes contact or leave the lower electrode. .
9. The solar panel inspection machine of claim 7, wherein the electrode contacts of each of the lower probe holder modules are connected to the first lower metal strip by a wire.
10. The solar panel inspection machine of claim 1, wherein each of the probes comprises a sleeve and a contact end.
11. The solar panel inspection machine of claim 1, wherein each of the upper probe frame modules comprises: two upper sliders, respectively slidably sleeved on the two sides of the slide rail; The needle holder has two ends respectively disposed on the upper slider; a first upper metal strip disposed on the lower end surface of the upper probe holder; a second upper metal strip disposed on the upper end surface of the upper probe holder; a plurality of probes , disposed on the upper probe holder; and two upper electrode contact groups, respectively disposed on the two upper sliders, so that the first upper metal strip and the second upper metal strip and the upper electrode respectively form an electrical connection; wherein, a plurality of probes A part of the probe is connected to the first upper metal strip, and the other part of the probe is connected to the second upper metal strip.
12. The solar panel inspection machine of claim 1, wherein each of the lower probe holder modules comprises: two lower sliders, respectively slidably disposed on the sliding rails on both sides; a lower probe holder, The two ends are respectively disposed on the lower slider; a first lower metal strip is disposed on the lower end surface of the lower probe holder; a second lower metal strip is disposed on the upper end surface of the lower probe holder; a plurality of probes are disposed under The probe holder and the two lower electrode contact groups are respectively disposed on the two lower sliders, so that the first lower metal strip and the second lower metal strip and the lower electrode respectively form an electrical connection; wherein a part of the plurality of probes are electrically connected The first lower metal strip is connected, and the other part of the probe is connected to the second lower metal strip.