KR101220438B1 - Terminal rail of junction box for a photovoltaic module - Google Patents

Abstract

PURPOSE: A terminal rail of a connection terminal is provided to prevent malfunction of a bypass diode by inserting a heat sink into the lower side of a diode connection unit. CONSTITUTION: A diode connection unit is integrated with the rear side of a thin conductive connection unit(2). A cable connection unit is integrated with the rear of the diode connection unit. A through hole(3) for the thin conductive connection unit passes through the front of the thin conductive connection unit. A protrusion insertion hole(4) passes through the rear of the thin conductive connection unit. A protrusion for an ultrasonic melting is formed on the inner lower side of a housing.

Description

Terminal rail of junction box for photovoltaic module

The present invention relates to a terminal rail mounted to a connection terminal box for a solar cell module, and more particularly to a thinner conductor drawn out from the solar cell module when the solar cell module is connected to the terminal rail of the connection terminal box. This ensures a stable electrical connection between the flaky conductor and the terminal rail, which not only improves durability, but also generates heat from the bypass diode through the heat sink when current flows through the bypass diode. By dissipating efficiently, it prevents the bypass diode from overheating, thereby preventing the malfunction of the bypass diode and significantly increasing the durability of the bypass diode. Also, when assembling the terminal box, the terminal rail mounted on the inner bottom of the housing Assembly process by facilitating assembly It possible to implement the automation to enable the mass production of the junction box relates to a solar cell module terminal of the junction box for rail.

In general, a photovoltaic module used to directly convert solar energy into electrical energy is a thin piece of conductor on a top surface of a base plate 101 that is flat in shape as shown in FIG. A plurality of solar cells 102 to be connected are mounted, and a cover plate 103 made of a transparent material is covered thereon.

The rear part of the solar cell module 100, as shown in (b) of FIG. 1, the terminal box for stable electrical connection of the lamella conductor drawn from the solar cell module 100 and the distribution cable 105 (30). ) Is adhesively installed by the sealing material.

As the prior art for the connection terminal box 30 is known as a "connection terminal box for solar cell modules", which is previously filed by the present applicant and registered in Patent No. 10-0884815 (2009.02.13).

The connection terminal box for a known conventional solar cell module is provided with a housing 31 in the form of a box, which is opened and closed by a cover 32, as shown in FIG. 2, and a flaky conductor on the inner bottom of the housing 31. A plurality of terminal rails 33 for connecting the 102a and the distribution cable 105 are installed in parallel at regular intervals, and a plurality of solar cells provided in the solar cell module between the plurality of terminal rails 33. When some of the contamination or damage is configured so that the bypass diodes 34 for preventing the reverse current caused by the potential difference between the generated voltage between the solar cells, respectively.

However, the connection terminal box for a conventional solar cell module configured as described above is connected to each of the thin-film conductors 102a drawn from the solar cell module to the plurality of terminal rails 33 by soldering or by using screws or clamps. , The connection method by soldering or screw maintains the solid connection state, but it takes a lot of time and effort for the connection work, and the workability is deteriorated. Due to the weakening of the elastic force of the clamping spring there is a problem that the durability is reduced as the connection state is loosened.

In addition, the connection terminal box for a conventional solar cell module is shaded in some sections of the solar cell module or a portion of the plurality of solar cells provided in the solar cell module is contaminated or damaged by bypass connected between the plurality of terminal rails 33. When the current flows through the diode 34, as the bypass diode 34 overheats, a malfunction of the bypass diode 34 is caused or the durability of the bypass diode 34 is notably degraded. When excessive current flows in 34, the bypass diode 34 overheats and damages the solar cell module or causes a fire accident.

In addition, the connection terminal box for a conventional solar cell module has to be fixed by fitting a plurality of terminal rails 33 installed on the inner bottom of the housing 31 at the rail mounting portion formed on the inner bottom of the housing 31 during assembly. As the work is cumbersome and inconvenient, it is difficult to implement automation of the assembly process, and thus there was a problem that mass production was not easy.

Republic of Korea Patent No. 10-0884815

The present invention is to solve the above problems, it is possible to more securely connect the thin foil conductors drawn from the solar cell module to the terminal rail of the connection terminal box during the wiring operation of the solar cell module, the stable electricity between the thin foil conductor and the terminal rail It can maintain the connection status, which not only improves the durability, but also heats the bypass diode more efficiently through the heatsink when current flows in the bypass diode to prevent overheating of the bypass diode. This prevents the bypass diode from malfunctioning and significantly increases the durability of the bypass diode, and facilitates assembly of the terminal rail mounted on the inner bottom of the housing during assembly of the connection terminal box. To allow implementation The implication that the bulk of production to be a technical problem.

The present invention for achieving the above technical problem is mounted on the inner bottom of the housing provided in the connection terminal box for solar cell module connection terminal box for connecting the flake conductor and the distribution cable drawn from the solar cell module to each other. In the terminal rail of, the diode connecting portion bent in an inverted-shape is integrally formed at the rear end of the thin plate-like conductor connecting portion in a flat plate shape, and the cable connecting portion bent in a B shape is integrally formed at the rear end of the diode connecting portion. In front of the lamella conductor connection part, a through hole for fixing the lamella conductor is formed through and a projection insertion hole into which an ultrasonic welding protrusion is formed on the inner bottom of the housing is formed through the lamella conductor connection part, and a shear part C is formed at both ends of the lamella conductor connection part. It consists of a leaf spring bent in a shape of a child, Spring support pieces are provided with fitting grooves into which the rear ends of the clamping springs to be fitted are formed, respectively, and the front end portions of the foil conductors inserted into the through holes for fixing the foil conductors are clamped by the clamping springs under the front ends of the clamping springs. Fixing protrusions which are bent and fixed to each other are formed to protrude downward, and heat sink support pieces for supporting a heat sink inserted to be in close contact with the bottom surface of the diode connection portion are formed at both end portions of the diode connection portion, respectively. Both sides are formed through the projection insertion hole is inserted into the ultrasonic fusion projections formed on the inner bottom of the housing and characterized in that the heat dissipation pieces are formed on each side end.

As described above, the terminal rail of the connection terminal box for the solar cell module according to the present invention has a fixing protrusion for bending the front end portion of the thin sheet conductor in a zigzag form and fixing the front end portion of the clamping spring installed on the upper surface of the thin conductor connection portion. It is formed so as to protrude through the thin-film conductor connecting portion is formed to pass through the thin-film conductor fixing through which the fixing projection of the clamping spring is inserted, thereby connecting the thin-film conductor drawn out from the solar cell module during the connection of the solar cell module. The terminal rail can be more firmly connected to maintain a stable electrical connection state between the lamella conductor and the terminal rail, thereby improving the durability significantly.

In addition, the terminal rail of the connection terminal box for a solar cell module according to the present invention is configured so that a heat sink is inserted into the lower portion of the diode connection portion, and when a current flows in the bypass diode, the terminal rail is generated from the bypass diode through the heat sink. By dissipating heat more efficiently, the overheating of the bypass diode is prevented, thereby preventing malfunction of the bypass diode and significantly increasing the durability of the bypass diode.

In addition, the terminal rail of the connection terminal box for a solar cell module according to the present invention is configured such that the projection insertion hole into which the fusion conductor for ultrasonic welding formed on the inner bottom of the housing is inserted through the thin conductor connection part and the cable connection part, thereby assembling the connection terminal box. Since the assembly of the terminal rail mounted on the inner bottom of the housing can be facilitated during operation, the automation of the assembly process can be realized, thereby enabling mass production of the connection terminal box.

1 (a) (b) is a perspective view showing a typical solar cell module.
Figure 2 is an exploded perspective view showing a connection terminal box for a solar cell module registered and filed by the applicant.
Figure 3 is an exploded perspective view showing a terminal rail of the connection terminal box for a solar cell module according to the present invention.
Figure 4 is an explanatory diagram showing a process of mounting the terminal rail according to the present invention for the connection terminal box for a solar cell module.
5 is a plan view showing a state in which the terminal rail according to the present invention mounted on the connection terminal box for a solar cell module.
6 is a cross-sectional view taken along the line AA of FIG. 5.
7 is a cross-sectional view taken along line BB of FIG. 5.

Hereinafter, the present invention for achieving the above object will be described in detail with reference to FIGS. 3 to 7.

Terminal rail of the connection terminal box for a solar cell module according to the present invention, as shown in Figs. 3 to 7, the thin plate conductor connecting portion (2) of the plate shape and the diode connecting portion (7) and b bent in inverted a-shape The cable connecting portion 9 bent into a shape is configured to be integrally formed.

The lamella conductor connection part 2 is a portion to which the lamella conductor 102a drawn out from the solar cell module is connected, and a through hole 3 for fixing the lamella conductor is formed in the front, and a connection terminal box for the solar cell module is formed in the rear. The projection insertion hole 4 into which the ultrasonic welding projection 31a formed on the inner bottom of the housing 31 is inserted is formed, and both ends are formed in a plate spring shape in which the front end portion is bent into a C shape. Spring support pieces 5 each having a fitting groove 5a into which the rear end of the clamping spring 6 to be seated on the upper surface of (2) are formed are formed.

At this time, the lower end of the clamping spring (6) seated on the upper surface of the lamella conductor connecting portion (2) is formed so that the fixing projection (6a) inserted into the lamella conductor fixing through-hole (3) protrudes downward, The fixing projection 6a is inserted into the upper surface of the thin conductor connecting portion 2 and serves to fix the front end portion of the thin conductor 102a that is clamped by the clamping spring 6 in a zigzag form to firmly fix it.

Fixing protrusion 6a and the thin conductor connection part 2 formed to protrude downward from the front end of the clamping spring 6 with the thin foil conductor 102a drawn out from the solar cell module during the connection of the solar cell module. When inserted between the thin foil conductor fixing through-holes (3) formed in the front of the, the flaky conductor (102a) of the thin film conductor (102a) by the fixing projection (6a) is formed to protrude downward on the lower surface of the front end of the clamping spring (6) As the front end portion is bent in a zigzag shape, the front end portion can be more firmly connected.

The diode connecting portion 7 is a portion in which a bypass diode connected between the plurality of terminal rails 1 is mounted, and both ends thereof support the heat sink 8 inserted to be in close contact with the bottom surface of the diode connecting portion 7. Heat sink support pieces 7a are formed, respectively.

At this time, the heat sink 8 inserted to be in close contact with the bottom surface of the diode connection part 7 may be shaded in some sections of the solar cell module or some of the plurality of solar cells provided in the solar cell module may be contaminated or damaged. When current flows through the bypass diode 34 connected between the two terminal rails 1, the heat generated from the bypass diode 34 is more efficiently dissipated.

The cable connecting portion 9 is a portion to which the distribution cable 105 is connected, and the ultrasonic welding projection 31a formed on the inner bottom of the housing 31 constituting the connection terminal box for the solar cell module is inserted at both sides of the upper surface. Protrusion insertion hole 10 is formed through, the heat dissipation piece (9a) is formed at both ends.

At this time, the heat dissipation piece 9a serves to increase the surface area of the terminal rail 1 as much as possible so that heat generated from the bypass diode can be dissipated through the terminal rail 1.

Referring to the assembly and operation of the terminal rail of the connection terminal box for a solar cell module according to the present invention configured as described above are as follows.

As shown in FIG. 3, the terminal rail according to the present invention clamps the rear end of the clamping spring 6 to the fitting groove 5a of the spring support piece 5 formed at both ends of the lamella conductor connecting portion 2. After assembling the spring 6, the heat sink 8 can be easily assembled by inserting and fixing the heat sink 8 between the heat sink support pieces 7a formed at both ends of the diode connecting portion 7.

At this time, between the lower surface of the diode connecting portion 7 and the upper surface of the heat sink 8, heat generated in the bypass diode seated on the upper surface of the diode connecting portion 7 can be smoothly transferred to the heat sink 8. It is preferable to apply a thermally conductive adhesive or thermally conductive grease so as to.

On the other hand, when the terminal rail 1 according to the present invention is mounted on the inner bottom surface of the housing 31 constituting the connection terminal box for the solar cell module, as shown in Figs. A plurality of ultrasonic welding projections 31a in which the projection insertion hole 4 formed through the front of the back) and the projection insertion hole 10 formed on both sides of the upper surface of the cable connecting portion 9 are formed on the inner bottom of the housing 31. 6 and 7, the ultrasonic wave protrudes from the protrusion insertion hole 4 of the lamella conductor connection part 2 and the protrusion insertion hole 10 of the cable connection part 9 as shown in FIGS. 6 and 7. Ultrasonic fusion and fixation of the distal end of the fusion projection 31a enables easy mounting.

After the terminal rail 1 according to the present invention is mounted on the inner bottom of the housing 31, a bypass diode 34 connecting the plurality of terminal rails 1 to the diode connection part of each terminal rail 1 ( 7) After seating on the upper surface of the bypass diode 34 by soldering and connecting the respective terminals on the upper surface of the neighboring terminal rail (1), respectively, by connecting the cover 32 to the upper portion of the housing 31 The assembly of the terminal box for the battery module is completed.

The connection terminal box for the solar cell module assembled as described above is adhesively installed by using a sealing material on the rear surface of the solar cell module. At this time, the thin foil conductor 102a drawn out from the solar cell module is formed through the foil of the housing 31. After inserting into the housing 31 through the tonsil insertion hole, it is connected to the lamella conductor connecting portion 2 of the terminal rail 1 according to the present invention mounted on the inner bottom of the housing 31.

When connecting the lamella conductor 102a drawn out from the solar cell module to the terminal rail 1 according to the present invention mounted on the inner bottom of the housing 31, the lamella conductor connection part 2 is performed using a tool such as a screw driver. Lift the front end of the clamping spring 6 seated on the upper surface of the clamping spring 6, and open it between the lower surface of the clamping spring 6 and the upper surface of the flaky conductor connecting portion 2, and then insert the end of the flaky conductor 102a into the gap. The clamping spring 6 is repositioned so that the end portion of the flaky conductor 102a is firmly snapped by the elastic force of the clamping spring 6 so that the clamping spring 6 can be easily connected, and is inserted into the upper surface of the flaky conductor connecting part 2. The front end portion of the lamella conductor 102a clamped by the clamping spring 6 penetrates in front of the fixing projection 6a and the lamella conductor connection portion 2 which protrude downward from the lower end face of the clamping spring 6. Formed As it is bent in a zigzag form by the thin-film conductor fixing through-hole 3, it can be more firmly connected.

As described above, the terminal rail 1 of the connection terminal box for the solar cell module according to the present invention has a front end portion of the foil conductor 102a at the front end of the clamping spring 6 installed on the top surface of the foil conductor connecting portion 2. A fastening protrusion 6a for bending and fixing in a zigzag shape is formed to protrude downward, and a thin-film conductor fixing through hole in which the fastening protrusion 6a of the clamping spring 6 is inserted in front of the thin-film conductor connecting portion 2 ( 3) is configured to penetrate through the thin-film conductor 102a, which can be more firmly connected to the terminal rail 1 of the connection terminal box when the thin-film conductor 102a withdrawn from the solar cell module is connected during the connection operation of the solar cell module. Since it is possible to maintain a stable electrical connection state between the terminal rail 1 and the durability can be significantly improved.

In addition, the terminal rail 1 of the connection terminal box for a solar cell module according to the present invention is configured such that the heat sink 8 is inserted into the lower portion of the diode connection portion 7, so that a shade of a portion of the solar cell module is shaded. When some of the plurality of solar cells provided in the solar cell module is polluted or damaged so that a current flows in the bypass diode 34 connected between the plurality of terminal rails 1, the heat sink installed under the diode connection unit 7. Through (8) it is possible to more efficiently dissipate heat generated in the bypass diode 34 to prevent overheating of the bypass diode 34, thereby preventing malfunction of the bypass diode 34 as well. It is possible to significantly increase the durability of the bypass diode 34.

In addition, the terminal rail 1 of the solar cell module connection terminal box according to the present invention is formed on the inner bottom surface of the housing 31 constituting the solar cell module connection terminal box in the thin conductor connection part 2 and the cable connection part 9. As the projection insertion hole 4 (10) into which the ultrasonic welding projection 31a is inserted is formed to penetrate through, respectively, the terminal mounted on the inner bottom of the housing 31 during the assembly operation of the connection terminal box for the solar cell module. Since the rail 1 can be assembled more easily, it is possible to implement the automation of the assembly process, thereby enabling mass production of the connection terminal box.

1: terminal rail 2: flaky conductor connection
3: through hole for securing thin flake conductor 4: protrusion insertion hole
5: spring support piece 5a: fitting groove
6: clamping spring 6a: fixing protrusion
7: diode connection 7a: heat sink support piece
8 heat sink 9 cable connection
9a: heat sink 10: projection insertion hole

Claims (1)

In the terminal rail of the solar cell module connection terminal box mounted on the inner bottom of the housing provided in the connection terminal box for the solar cell module to connect the thin-film conductor and the distribution cable to each other,
At the rear end of the thin plate-shaped conductor connecting portion 2, a diode connecting portion 7 bent in an inverted-shape is integrally formed, and at the rear end of the diode connecting portion 7, the cable connecting portion 9 is bent in a B-shape. Formed integrally,
In front of the lamella conductor connection part 2 is formed through the through hole for fixing the lamella conductor (3) is formed through the projection insertion hole (4) is inserted into the ultrasonic welding projection formed in the inner bottom of the housing,
Both grooves of the thin-film conductor connecting portion 2 are fitted into the rear end portion of the clamping spring 6, which is formed in a leaf spring shape in which the front end portion is bent into a C-shape and is seated on the upper surface of the thin-film conductor connecting portion 2a. The provided spring support piece 5 is formed, respectively,
On the lower end of the front end of the clamping spring 6, a fixing protrusion 6a inserted into the through hole 3 for securing the foil conductor and bending the front end of the foil conductor being clamped by the clamping spring 6 in a zigzag form is fixed. Is formed to protrude downward,
Heat sink support pieces 7a for supporting the heat sink 8 inserted in close contact with the bottom surface of the diode connection part 7 are formed at both ends of the diode connection part 7, respectively.
On both sides of the upper surface of the cable connecting portion 9, the projection insertion hole 10 into which the ultrasonic fusion projections formed on the inner bottom of the housing are inserted is formed, and the heat dissipation pieces 9a are formed on both side ends, respectively. Terminal rail of the junction box for solar cell modules.

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