CN116192035A - Embedded photovoltaic light stacking controller - Google Patents

Abstract

The invention relates to the technical field of photovoltaic production, in particular to an embedded photovoltaic laminated controller which comprises a controller body and an embedded microelectronic technology chip arranged in the controller body, wherein a wiring group of modularized wiring is arranged at a wiring end of the controller body, and the wiring group comprises a wire plug module, a supporting plate, a photovoltaic panel group, a storage battery and a display lamp tube, wherein the wire plug module is sleeved with a plurality of data wires and wires, the supporting plate is elastically sleeved with the wire plug module, and the photovoltaic panel group, the storage battery and the display lamp tube are electrically connected with the wire plug module. According to the invention, a plug wire module is designed according to the position matching of the wiring port of the controller body, then the wiring terminals of other electric appliances and loads are correspondingly inserted into the wire slots of the plug wire module according to the charge-discharge route, so that the front end and the rear end of the controller body are clamped by the plug wire module and the baffle plate, the route is smoothly and rapidly connected, and the controller body can be judged to be qualified under the conditions that the display lamp tube emits light normally and the charge-discharge detector displays the voltage stability of the storage battery in the process of switching the charge-discharge switch.

Description

Embedded photovoltaic light stacking controller

Technical Field

The invention relates to the technical field of photovoltaic production, in particular to an embedded photovoltaic light-stacking controller.

Background

The embedded photovoltaic laminated controller adopts electronic equipment or devices controlled by the embedded microelectronic technology chip, and can complete various automatic processing tasks such as monitoring, control and the like. The automatic control device is used in a solar power generation system, and is an automatic control device for controlling a plurality of solar cell matrixes to charge a storage battery and the storage battery to supply power to a solar inverter load, and mainly adopts a microprocessor chip, a timer and an A/D (analog to digital) converter, thereby being a microcomputer data acquisition and monitoring control system.

Because the internal electrical components and circuits are densely integrated, the problem of working faults is easy to occur, and the controller is used for controlling and monitoring the charge and discharge of the storage battery, the effect is very important, and if the working qualification rate of the storage battery is not ensured one by one in the production link, the use faults of the photovoltaic panel group can occur and the working condition is not caused. However, the controllers are more in wiring, which is a barrier for preventing the qualification rate from being detected one by one, so that the percent qualification rate of the controllers is ensured for improving the detection efficiency, and a scheme for accelerating the detection process is provided.

Disclosure of Invention

In order to overcome the defects in the prior art, an object of the present invention is to provide an embedded photovoltaic light-stacking controller, so as to solve the problems set forth in the background art.

In order to achieve the above purpose, the invention provides an embedded photovoltaic stacking controller, which comprises a controller body and an embedded microelectronic technology chip installed in the controller body, wherein a wiring group of modularized wiring is arranged at a wiring end of the controller body, the wiring group comprises a wiring module sleeved with a plurality of data wires and leads, a supporting plate elastically sleeved with the wiring module, a baffle plate for supporting the rear end of the controller body, and a photovoltaic panel group, a storage battery and a display lamp tube which are electrically connected, wherein the photovoltaic panel group is connected with the storage battery in series through the leads, the controller body and the display lamp tube are connected with the storage battery in parallel through the leads, the controller body is also connected with a data port through the data wires, in addition, a charging switch connected with the controller body is installed in a circuit of the photovoltaic panel group and the storage battery, and a discharging switch connected with the controller body is installed in a circuit of the display lamp tube and the storage battery;

the controller body is used for monitoring the end voltage of the storage battery, the storage battery is charged by the photovoltaic panel group when the charging switch is closed, the storage battery supplies power to the display lamp tube when the discharging switch is closed, the storage battery is electrically connected with a charging and discharging detector through a lead, and after the charging and discharging switch is switched, the controller body can be judged to be qualified under the conditions that the display lamp tube normally emits light and the voltage of the storage battery is stable.

As a further improvement of the technical scheme, the bottoms of the supporting plates and the baffle plates are all provided with connecting plates in a vertical extending mode, the two connecting plates are hinged, a control group is arranged below the controller body, and the control group comprises a pair of supporting rods which are connected with the two connecting plates in a sliding mode respectively, an adjusting plate used for pulling the bottoms of the pair of supporting rods and a fixing frame used for supporting the rotating of the adjusting plate.

As a further improvement of the technical scheme, the side surface of the top of the adjusting plate is provided with an arc-shaped guide groove, the bottom hinge shafts of the pair of supporting rods are inserted and slide with the guide groove, and the vertical distance between the two ends of the guide groove and the rotating shaft of the adjusting plate is unequal.

As a further improvement of the technical scheme, a sliding groove connected with the supporting rod in a clamping mode is formed in the middle line of the bottom surface of the connecting plate, a slot communicated with the sliding groove is formed in the side face of the connecting plate, and pins are embedded into two sides of the top end of the supporting rod and penetrate through the slot.

As a further improvement of the technical scheme, a transmission frame extends from one side of the rotating end of the adjusting plate, the transmission frame points to one end close to the guide groove, a spring is embedded in the top edge of the front end of the plug wire module, a fixing pin is bonded at the front end of the spring, and the fixing pin is bonded with the supporting plate.

As a further improvement of the technical scheme, a wiring table for placing the controller body is arranged above the control group, bayonets and clamping grooves are respectively formed in the front edge and the rear edge of the top surface of the wiring table, the bayonets are rectangular and penetrate through the front side surface of the wiring table, and the clamping grooves are U-shaped and are clamped with the baffle plates.

As a further improvement of the technical scheme, the outer ends of the hinge shafts of the two connecting plates are sleeved with supporting strips, the supporting strips are fixedly connected with the bottom surface of the wiring table through bolts, and the supporting strips are located between the bayonets and the clamping grooves.

As a further improvement of the technical scheme, the rear end of the bayonet is embedded with a pulling line, and when the pulling line is jacked up by the connecting plate, the top surface of the pulling line is lower than the bottom surface of the plug wire module.

As a further improvement of the technical scheme, the back of the photovoltaic panel set is fixedly connected with a supporting frame in a bending state through bolts, two sides of the top of the photovoltaic panel set are sleeved with rotating frames, L-shaped rods are welded on the outer sides of the rotating frames, strong light tubes are sleeved between the outer ends of the long sections of the pair of L-shaped rods, and the other ends of the pair of L-shaped rods are sleeved with display tubes.

As a further improvement of the technical scheme, the middle part and two sides of the wiring table are provided with conveying belt groups.

Compared with the prior art, the invention has the beneficial effects that:

this embedded photovoltaic folding light controller through according to the wiring port position matching design plug wire module of controller body, then with other electrical apparatus and loaded wiring end according to charge-discharge route correspond insert plug wire module's wire casing in, directly use plug wire module and baffle to clip the controller body front and back end like this, and smooth quick connect line, in the switching charge-discharge switch in-process, obtain the display fluorescent tube and normally give out light and charge-discharge detector shows under the battery voltage stabilization condition, can judge that the controller body is qualified.

Drawings

The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way. In addition, the shapes, proportional sizes, and the like of the respective components in the drawings are merely illustrative for aiding in understanding the present invention, and are not particularly limited. Those skilled in the art with access to the teachings of the present invention can select a variety of possible shapes and scale sizes to practice the present invention as the case may be.

FIG. 1 is a schematic diagram of the overall assembly test state of the present invention;

FIG. 2 is a schematic diagram of the assembly structure of the controller body, the wiring block and the control block according to the present invention;

FIG. 3 is a schematic view of the assembly structure of the wiring block and control block of the present invention;

FIG. 4 is a schematic view of the assembled photovoltaic panel of the present invention;

FIG. 5 is a full cross-sectional view of the terminal block of the present invention;

FIG. 6 is a front view of the wiring block and control block assembly of the present invention;

FIG. 7 is a top view of the controller body wiring state of the present invention;

FIG. 8 is an assembled top view of the wiring block and control block of the present invention;

FIG. 9 is a schematic view of a partial structure of a wiring block according to the present invention;

FIG. 10 is a schematic view of an assembly structure of a junction block according to the present invention;

FIG. 11 is a schematic diagram of the control group assembly structure of the present invention;

FIG. 12 is a schematic drawing of a drawn line structure of the present invention;

FIG. 13 is a schematic view of the spring and anchor pin assembly of the present invention;

fig. 14 is a schematic diagram of the charge and discharge operation of the controller body according to the present invention.

The meaning of each reference sign in the figure is:

100. a controller body;

200. a wiring group; 210. a plug wire module; 220. a supporting plate; 221. a spring; 222. a fixing pin;

230. a baffle; 231. a connecting plate; 232. a chute; 233. a slot; 234. a support bar;

240. a photovoltaic panel set; 241. a supporting frame; 242. a rotating frame; 250. a storage battery;

260. a strong light tube; 261. a display tube; 270. drawing lines; 271. a limit groove; 272. a limit rod;

300. a control group; 310. a brace rod; 320. an adjusting plate; 321. a guide groove; 330. a transmission frame; 340. a fixing frame;

400. a wiring table; 401. a clamping groove; 402. a bayonet; 410. a conveyor belt group.

Detailed Description

The details of the invention will be more clearly understood in conjunction with the accompanying drawings and description of specific embodiments of the invention. However, the specific embodiments of the invention described herein are for the purpose of illustration only and are not to be construed as limiting the invention in any way. Given the teachings of the present invention, one of ordinary skill in the related art will contemplate any possible modification based on the present invention, and such should be considered to be within the scope of the present invention. The terms "mounted" and "connected" are to be interpreted broadly, as they may be directly connected, or indirectly connected through an intermediary.

The terms "central axis," "vertical," "horizontal," "front," "rear," "upper," "lower," "left," "right," "top," "bottom," "inner," "outer," and the like as used herein are based on the orientation or positional relationship shown in the drawings and are merely for convenience of description and to simplify the description, rather than to indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operate in a particular orientation, and thus should not be construed as limiting the invention. Furthermore, in the description of the invention, the meaning of "a number" is two or more, unless explicitly defined otherwise.

Referring to fig. 1-14, the present invention provides an embedded photovoltaic stacking controller, which includes a controller body 100 and an embedded microelectronic chip mounted therein, wherein the embedded microelectronic chip includes a series of microelectronic devices such as a microprocessor chip, a timer, a sequencer, or a controller, so as to control electronic devices or apparatuses, and can complete various automatic processing tasks such as monitoring and control.

Specifically, the wiring end of the controller body 100 is provided with a wiring group 200 with modularized wiring, namely, the wiring to be spliced with the controller body 100 in advance is well positioned so as to be spliced at one time; the wiring group 200 comprises a wiring module 210 sleeved with a plurality of data wires and leads, a supporting plate 220 elastically sleeved with the wiring module 210, a baffle 230 for supporting the rear end of the controller body 100, a photovoltaic panel group 240, a storage battery 250 and a display lamp 261 which are electrically connected, wherein the wiring module 210 is designed according to the matching of the wiring port positions of the controller body 100, and then the wiring terminals of other electrical appliances and loads are correspondingly inserted into the wiring grooves of the wiring module 210, so that the wiring module 210 and the baffle 230 are directly used for clamping the front end and the rear end of the controller body 100, and the wiring is smoothly and quickly connected.

As shown in fig. 14, in which the photovoltaic panel set 240 and the storage battery 250 are connected in series by a wire, the controller body 100 and the display lamp 261 are connected in parallel with the storage battery 250 by a wire, the controller body 100 is also connected with the photovoltaic panel set 240 by a data line to a data port, in addition, a charge switch connected with the controller body 100 is installed in a circuit of the photovoltaic panel set 240 and the storage battery 250, and a discharge switch connected with the controller body 100 is installed in a circuit of the display lamp 261 and the storage battery 250;

the controller body 100 is used for monitoring the voltage of the end of the storage battery 250, the storage battery 250 is charged by the photovoltaic panel set 240 when the charging switch is closed, the display lamp 261 is powered by the storage battery 250 when the discharging switch is closed, the storage battery 250 is electrically connected with a charging and discharging detector through a lead, and after the charging and discharging switch is switched, the controller body 100 can be judged to be qualified under the conditions that the display lamp 261 emits light normally and the voltage of the storage battery 250 is stable.

Specifically, the bottoms of the supporting plate 220 and the baffle 230 are respectively provided with a connecting plate 231 in a vertical extending manner, the two connecting plates 231 are hinged, a control group 300 is arranged below the controller body 100, and the control group 300 comprises a pair of supporting rods 310 which are respectively connected with the two connecting plates 231 in a sliding manner, an adjusting plate 320 for pulling the bottom ends of the pair of supporting rods 310, and a fixing frame 340 for supporting the adjusting plate 320 to rotate.

Further, an arc-shaped guiding groove 321 is formed on the top side surface of the adjusting plate 320, the bottom hinge shafts of the pair of supporting rods 310 are inserted and slid with the guiding groove 321, the vertical distances between the two ends of the guiding groove 321 and the rotating shaft of the adjusting plate 320 are unequal, namely, when the adjusting plate 320 is rotated to enable the two ends of the guiding groove 321 to be placed on top in a reciprocating manner, a difference of height positions is formed, and accordingly the bottoms of the pair of supporting rods 310 are pulled to lift;

when the bottoms of the pair of stay bars 310 are lifted, the pair of connecting plates 231 are jacked to be flattened, so that the controller body 100 is clamped by the plug wire module 210 and the baffle 230 to complete the connection, and when the bottoms of the pair of stay bars 310 are lowered, the pair of connecting plates 231 are pulled down to be folded and folded, so that the plug wire module 210 and the baffle 230 are turned down to be separated from the controller body 100, and the controller body 100 can be taken away.

It should be noted that, the bottom center line of the connecting plate 231 is provided with a chute 232 clamped with the supporting rod 310, the side surface of the connecting plate 231 is provided with a slot 233 communicated with the chute 232, and two sides of the top end of the supporting rod 310 are embedded with pins and the pins penetrate through the slot 233, so that the supporting rod 310 can slide freely, and the connecting plate 231 is driven to retract and expand.

Further, a driving frame 330 extends from one side of the rotating end of the adjusting plate 320, and the driving frame 330 points to the end near to the guiding slot 321, so that a worker can step on or hook the bottom of the driving frame 330 to control the adjusting plate 320 to rotate;

the spring 221 is embedded in the top edge of the front end of the plug wire module 210, the front end of the spring 221 is adhered with the fixing pin 222, the fixing pin 222 is adhered with the supporting plate 220, and when the plug wire module 210 rotates to be horizontal, the terminal inside the plug wire module can be in butt joint insertion with the terminal of the controller body 100 under the elastic force of the spring 221 due to the fact that the plug wire module 210 is in butt joint sliding with the supporting plate 220.

In addition, a wiring table 400 for placing the controller body 100 is arranged above the control group 300, and a bayonet 402 and a clamping groove 401 are respectively arranged at the front edge and the rear edge of the top surface of the wiring table 400, and the bayonet 402 is rectangular and penetrates through the front side surface of the wiring table 400, so that the plug wire module 210 and the supporting plate 220 can be turned smoothly; the clamping groove 401 is U-shaped and is clamped with the baffle 230, and the inner width of the clamping groove 401 is larger than the thickness of the baffle 230, so that the baffle 230 can be smoothly rotated in;

the middle part and both sides of the wiring board 400 are provided with a conveyer belt group 410 for conveying the controller body 100 so that a worker can take, place, detect and transfer after detection.

In addition, the outer end of the hinge shaft of the two connecting plates 231 is sleeved with a supporting strip 234, the supporting strip 234 is fixedly connected with the bottom surface of the wiring table 400 through bolts, and the supporting strip 234 is positioned between the bayonet 402 and the clamping groove 401, so that the hinge position of the two connecting plates 231 is positioned and rotated.

Further, the pull-out line 270 is embedded at the rear end of the bayonet 402, when the pull-out line 270 is jacked up by the connecting plate 231, the top surface of the pull-out line 270 is lower than the bottom surface of the plug wire module 210, and when the plug wire module 210 is turned down, the pull-out line 270 is not completely separated from the front end surface of the controller body 100, so that a retaining effect is formed, and the wires in the terminals of the controller body 100 are pulled out smoothly;

the height of the wire drawing line 270 is equal to the thickness of the wiring table 400, a limit groove 271 is formed in the side face of the wire drawing line 270, a limit rod 272 is embedded in the bottom side edge of the rear end of the bayonet 402, the limit rod 272 is in sliding connection with the limit groove 271, convex strips are arranged on two sides of the top face of the wire drawing line 270 and used for blocking the controller body 100, and the wire is drawn when the wire inserting module 210 is separated; as shown in fig. 6, a through hole inserted into the plug wire module 210 is formed in the middle of the supporting plate 220, and the bottom surface of the through hole is an arc surface toward the inner half side, so that the supporting plate 220 does not interfere with the plug wire module 210 when being turned down, and meanwhile, the supporting plate 220 turns down to pull the spring 221, so that the plug wire module 210 is instantly driven to be separated from the terminal of the controller body 100 horizontally.

Specifically, the back of the photovoltaic panel set 240 is fixedly connected with a support frame 241 in a bending state through bolts, when the photovoltaic panel set 240 is unfolded, the bottom end of the support frame 241 is used for supporting the ground, and the support frame 241 is turned upwards by a small range of angles, so that the photovoltaic panel set 240 can be turned onto the wiring table 400 to be stored;

the revolving frame 242 is sleeved on the two sides of the top of the photovoltaic panel group 240, the L-shaped rods are welded on the outer sides of the revolving frame 242, strong light tubes 260 are sleeved between the outer ends of the long sections of the pair of L-shaped rods, the light waves of the strong light tubes 260 are in a visible light wave band of 0.3-0.75 mu m, the absorption of the amorphous silicon cell plates of the photovoltaic panel group 240 is facilitated, so that the strong light tubes 260 can be turned to the front side of the photovoltaic panel group 240 and are electrified for irradiation when the photovoltaic panel group 240 is in a cloudy day, and the normal operation of the photovoltaic panel group 240 is ensured; the other ends of the pair of L-shaped rods are sleeved with the display lamp tube 261.

In the detection of the embedded photovoltaic light-stacking controller, the controller body 100 is taken from the conveyer belt group 410 in the middle of the wiring table 400 and is placed between the clamping groove 401 and the bayonet 402 of the wiring table 400, the foot hook transmission frame 330 drives the adjusting plate 320 to rotate forwards, so that the bottom hinge shaft of the stay bar 310 slides to the high end of the guide groove 321, the included angle of the stay bar 310 is further enlarged, and a pair of connecting plates 231 can be spread and flattened, so that the wire inserting module 210 and the baffle 230 are clamped at the front end and the rear end of the controller body 100, and the wire connecting end at the end part of the wire inserting module 210 is pushed to be in butt joint with the wire connecting port of the controller body 100 under the resilience force of the spring 221;

when the charging switch is closed, the photovoltaic panel set 240 charges the storage battery 250, after a predetermined time, the charging switch is opened and the discharging switch is closed, the storage battery 250 supplies power to the display lamp 261, in the process of switching the charging and discharging switch, the controller body 100 can be judged to be qualified under the condition that the display lamp 261 emits light normally and the voltage of the storage battery 250 is stable by the charging and discharging detector, a worker steps on the transmission frame 330 reversely to drive the plug wire module 210 and the baffle 230 to turn down and separate from the controller body 100, and at the moment, the controller body 100 can be taken away and placed on the conveyor belt set 410 at the side end of the wiring table 400 to be transmitted to the packaging procedure.

It should be noted that the foregoing embodiments are merely illustrative of the technical concept and features of the present invention, and are intended to enable those skilled in the art to understand the present invention and implement the same, not to limit the scope of the present invention. All equivalent changes or modifications made in accordance with the spirit of the present invention should be construed to be included in the scope of the present invention.

Claims (10)

1. An embedded photovoltaic light stacking controller, includes controller body (100) and internally mounted's embedded microelectronics technology chip, its characterized in that: the wiring terminal of the controller body (100) is provided with a wiring group (200) with modularized wiring, the wiring group (200) comprises a wiring module (210) sleeved with a plurality of data wires and leads, a supporting plate (220) elastically sleeved with the wiring module (210), a baffle (230) used for supporting the rear end of the controller body (100), a photovoltaic panel group (240), a storage battery (250) and a display lamp tube (261) which are electrically connected, wherein the photovoltaic panel group (240) and the storage battery (250) are connected in series through the leads, the controller body (100) and the display lamp tube (261) are connected with the storage battery (250) in parallel through the leads, the controller body (100) is also connected with a data port through the data wires, in addition, a charging switch connected with the controller body (100) is arranged in a circuit of the photovoltaic panel group (240) and the storage battery (250), and a discharging switch connected with the controller body (100) is arranged in a circuit of the display lamp tube (261) and the storage battery (250);

the controller body (100) is used for monitoring the end voltage of the storage battery (250), the storage battery (250) is charged by the photovoltaic panel group (240) when the charging switch is closed, the storage battery (250) supplies power to the display lamp tube (261) when the discharging switch is closed, the storage battery (250) is electrically connected with a charging and discharging detector through a lead, and after the charging and discharging switch is switched, the controller body (100) can be judged to be qualified under the conditions that the display lamp tube (261) emits light normally and the voltage of the storage battery (250) is stable.

2. The embedded photovoltaic stack controller of claim 1 wherein: the bottom of layer board (220) and baffle (230) all is the perpendicular extension and is equipped with connecting plate (231), and two connecting plates (231) are articulated, the below of controller body (100) is provided with control group (300), control group (300) include with two connecting plates (231) respectively sliding connection's a pair of vaulting pole (310), be used for pulling regulating plate (320) of a pair of vaulting pole (310) bottom and be used for supporting regulating plate (320) pivoted mount (340).

3. The embedded photovoltaic stack controller of claim 2, wherein: the top side of regulating plate (320) has offered and has been curved guide slot (321), a pair of bottom articulated shaft and guide slot (321) grafting slip of vaulting pole (310), the both ends of guide slot (321) are unequal with the rotation axis perpendicular distance of regulating plate (320).

4. The embedded photovoltaic stack controller of claim 3 wherein: the bottom surface central line of connecting plate (231) has seted up spout (232) with vaulting pole (310) joint, slot (233) that are linked together with spout (232) are seted up to the side of connecting plate (231), pin and pin pass slot (233) are inlayed on vaulting pole (310) top both sides.

5. The embedded photovoltaic stack controller of claim 4 wherein: one side of the rotating end of the adjusting plate (320) is extended to be provided with a transmission frame (330), the transmission frame (330) points to one end, close to the guide groove (321), of the guide groove, a spring (221) is embedded in the top edge of the front end of the plug wire module (210), a fixing pin (222) is bonded at the front end of the spring (221), and the fixing pin (222) is bonded with the supporting plate (220).

6. The embedded photovoltaic stack controller of claim 5 wherein: the control group (300) is provided with wiring platform (400) that are used for placing controller body (100) above, bayonet socket (402) and draw-in groove (401) are respectively equipped with in the top surface front and back edge of wiring platform (400), bayonet socket (402) are rectangle and run through wiring platform (400) leading flank, draw-in groove (401) are U type and with baffle (230) joint.

7. The embedded photovoltaic stack controller of claim 6 wherein: the outer ends of the hinge shafts of the two connecting plates (231) are sleeved with supporting strips (234), the supporting strips (234) are fixedly connected with the bottom surface of the wiring table (400) through bolts, and the supporting strips (234) are located between the bayonets (402) and the clamping grooves (401).

8. The embedded photovoltaic stack controller of claim 7 wherein: the rear end of the bayonet (402) is embedded with a pulling line (270), and when the pulling line (270) is jacked up by the connecting plate (231), the top surface of the pulling line is lower than the bottom surface of the plug wire module (210).

9. The embedded photovoltaic stack controller of claim 1 wherein: the back of photovoltaic board group (240) is through bolt fixedly connected with strut (241) that is the state of bending, the top both sides cover of photovoltaic board group (240) is equipped with revolving rack (242), the outside welding of revolving rack (242) has L type pole, and overlaps between the outer end of a pair of L type pole long section and be equipped with highlight fluorescent tube (260), cup joints with display fluorescent tube (261) between a pair of L type pole other end.

10. The embedded photovoltaic stack controller of claim 6 wherein: the middle part and both sides of wiring platform (400) are provided with conveyer belt group (410).

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