CN112865704A - Connector lug for testing photovoltaic module - Google Patents

Abstract

The invention relates to a connector lug, in particular to a connector lug for testing a photovoltaic module. The utility model provides a can detect automatically, work efficiency is high, and the security performance is high is used for connector lug for photovoltaic module test. A connector lug for photovoltaic module test, including: a base; the two mounting racks are mounted on the mounting racks; the placing assembly is arranged on the mounting frame and placed in a sliding mode; the detection assembly is installed on the base and is used for detecting in a sliding mode. According to the photovoltaic module detection device, the photovoltaic module to be detected can be placed through the placing assembly, the detection assembly can detect the photovoltaic module, the guiding assembly can guide the photovoltaic module during detection, the first frame body can not be pushed one by one manually through rotating the pulling assembly, a large amount of manpower is saved, the gear can be fixed during detection through the clamping assembly, and the first frame body is prevented from being loosened.

Description

Connector lug for testing photovoltaic module

Technical Field

The invention relates to a connector lug, in particular to a connector lug for testing a photovoltaic module.

Background

Photovoltaic modules are generally referred to as solar modules. Because the output voltage of the single solar cell is low, and the electrodes of the unpackaged cells are easy to fall off due to the influence of the environment, a certain number of single cells are sealed into a solar cell module in a series-parallel connection mode so as to avoid the corrosion of the cell electrodes and interconnection lines.

The photovoltaic module needs to be detected in the production process, so that the phenomenon that the quality of the photovoltaic module does not reach the standard is avoided, and the follow-up use is influenced. At present, generally detect photovoltaic module through the manual work, this kind of mode that detects through the manual work need consume a large amount of manpowers, and work efficiency is low, detects through the manual work moreover and has certain potential safety hazard.

Therefore, it is necessary to design a connector lug for photovoltaic module testing, which can automatically detect, has high working efficiency and high safety performance, and solves the problem of complaints.

Disclosure of Invention

In order to overcome the defects of low working efficiency and certain potential safety hazard caused by manual detection, the invention has the technical problems that: the utility model provides a can detect automatically, work efficiency is high, and the security performance is high is used for connector lug for photovoltaic module test.

The technical implementation scheme of the invention is as follows: a connector lug for photovoltaic module test, including: a base; two mounting racks are arranged and are mounted on the base; the placing assembly is arranged on the mounting frame and placed in a sliding mode; the detection assembly is installed on the base and is used for detecting in a sliding mode.

Further, the placing component comprises: at least two placing plates are arranged and are mounted on the mounting frame; at least two sliding rods are arranged and are arranged on the placing plate in a sliding manner; the number of the first springs is at least two, and the first springs are arranged between the sliding rod and the placing plate; the first wedge block, first wedge block is two at least, all installs between two slide bars.

Further, the detection assembly comprises: at least two sliding rails are arranged and are arranged on the base in a sliding manner; the two first frame bodies are arranged between the two slide rails; at least two metal detection cylinders are arranged on the first frame body; the first frame body is connected with the square plate in a sliding manner; at least two second springs are arranged and are arranged between the square plate and the first frame body; the display instrument, the display instrument is two at least, all installs on first framework.

Further, still including the direction subassembly, the direction subassembly includes: at least two L-shaped rods are arranged on the mounting frame; connecting cylinders, connecting cylinder are two at least, all slidingtype installs on L shape pole, and the connecting cylinder all is connected with first framework.

Further, still include rotatory pulling component, rotatory pulling component includes: the handle is rotatably arranged on the placing plate; a gear mounted on the handle; two connecting plates are arranged and are mounted on the first frame body; the racks are arranged on the connecting plate and are meshed with the gear.

Further, still including the screens subassembly, the screens subassembly is including: the clamping rod is arranged on the placing plate in a sliding mode and is matched with the gear; and the third spring is installed between the clamping rod and the placing plate.

Further, still including sheltering from the subassembly, shelter from the subassembly including: two second frame bodies are arranged on the base; two shielding plates are arranged and are arranged in the second frame in a sliding manner; two second wedge-shaped blocks are arranged on the shielding plate; the push rods are two and are all installed on the first frame body, and the push rods are all matched with the second wedge-shaped block.

Further, the handle is star-shaped.

The invention has the beneficial effects that: the photovoltaic module to be detected can be placed through the placing component, the detection component can detect the photovoltaic module, the guiding component can guide the photovoltaic module during detection, the first frame body can not be pushed one by one manually through rotating the pulling component, a large amount of manpower is saved, the gear can be fixed during detection through the clamping component, the first frame body is prevented from loosening, the side face of the first frame body can be blocked during detection through the shielding component, and workers are prevented from being accidentally injured.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of the placement module of the present invention.

Fig. 3 is a schematic perspective view of the detecting assembly of the present invention.

Fig. 4 is a perspective view of the guide assembly of the present invention.

Fig. 5 is a schematic perspective view of the rotational pulling assembly and the locking assembly of the present invention.

FIG. 6 is a schematic perspective view of a shielding assembly according to the present invention.

The meaning of the reference symbols in the figures: 1_ base, 11_ mounting bracket, 2_ placing component, 21_ placing plate, 22_ sliding rod, 23_ first spring, 24_ first wedge block, 3_ detecting component, 31_ slide rail, 32_ first frame, 33_ metal detecting cylinder, 34_ square plate, 35_ second spring, 36_ display, 4_ guide component, 42_ L-shaped rod, 43_ connecting cylinder, 5_ rotary pulling component, 51_ handle, 52_ gear, 53_ connecting plate, 54_ rack, 6_ clamping component, 61_ clamping rod, 62_ third spring, 7_ shielding component, 71_ second frame, 72_ shielding plate, 73_ second wedge block and 74_ push rod.

Detailed Description

The invention is further described with reference to the following figures and detailed description.

Example 1

The utility model provides a be used for connector lug for photovoltaic module test, as shown in figure 1, including base 1, mounting bracket 11, place subassembly 2 and determine module 3, both parts all are equipped with mounting bracket 11 around base 1, are equipped with on the mounting bracket 11 and carry out the subassembly 2 of placing through gliding mode, are equipped with the determine module 3 that detects through gliding mode on the base 1.

When using the device, the staff puts the photovoltaic module that will detect to placing subassembly 2 on fixed, puts the back, detects the photovoltaic module through detecting component 3, detects the completion back, and the staff takes off photovoltaic module and changes.

As shown in fig. 1 and fig. 2, the placing assembly 2 includes a placing plate 21, sliding rods 22, first springs 23 and first wedge blocks 24, a row of placing plates 21 is disposed on the top of the mounting frame 11, two sliding rods 22 are slidably disposed on the front and rear sides of the placing plate 21, the first springs 23 are respectively wound between the sliding rods 22 and the placing plate 21, and the first wedge blocks 24 are disposed between the two sliding rods 22.

When detecting photovoltaic module, the staff puts the photovoltaic module that needs to detect to first wedge 24 top, subsequently, the staff promotes photovoltaic module downstream, photovoltaic module downstream promotes first wedge 24 and outwards removes, first wedge 24 outwards removes and drives slide bar 22 and outwards slides on placing board 21, first spring 23 is stretched, when photovoltaic module downstream to with place board 21 contact, the staff no longer promotes photovoltaic module, under the effect of first spring 23, first wedge 24 presss from both sides photovoltaic module tightly, detect the completion back, the staff takes off photovoltaic module, at this moment, under the effect that first spring 23 resets, slide bar 22 drives first wedge 24 inwards to remove and reset thereupon, so, can place the photovoltaic module that needs to detect.

As shown in fig. 1 and fig. 3, the detecting assembly 3 includes a slide rail 31, a first frame body 32, a metal detecting cylinder 33, a square plate 34, a second spring 35 and a display 36, two slide rails 31 are slidably arranged on the left and right sides of the base 1, a first frame body 32 is arranged between the two slide rails 31 on the left and right sides, a row of metal detecting cylinders 33 is arranged in the first frame body 32, a square plate 34 is arranged on the base 1, the first frame body 32 is slidably connected with the square plate 34, a row of second springs 35 is arranged between the square plate 34 and the first frame body 32, and a row of display 36 is arranged on the outer side of the first frame body 32 on the rear portion.

When detecting photovoltaic module, the staff inserts photovoltaic module's electric wire on the metal detection section of thick bamboo 33, after inserting, the staff promotes first framework 32 and inwards slides on square board 34, second spring 35 is compressed, first framework 32 inwards slides and drives metal detection section of thick bamboo 33 inwards and removes, when the metal detection section of thick bamboo 33 on both sides contacts each other, the staff observes photovoltaic module's detection data through display 36, after the detection is accomplished, the staff loosens first framework 32, under the effect that second spring 35 resets, first framework 32 drives metal detection section of thick bamboo 33 outwards and removes and resets thereupon, afterwards, the staff takes out photovoltaic module's electric wire, thus, can detect photovoltaic module.

Example 2

On the basis of embodiment 1, as shown in fig. 1 and 4, the device further includes a guide assembly 4, the guide assembly 4 includes L-shaped rods 42 and connecting cylinders 43, a row of L-shaped rods 42 is disposed on each mounting frame 11, the connecting cylinders 43 are slidably disposed on the L-shaped rods 42, and the connecting cylinders 43 are connected to the first frame 32.

When detecting photovoltaic module, first framework 32 slides inwards and drives connecting cylinder 43 and inwards slides on L shape pole 42, detects the completion back, and first framework 32 outwards slides and resets and drive connecting cylinder 43 and outwards slide on L shape pole 42 and reset, so, can lead when detecting photovoltaic module.

On the basis of embodiment 1, as shown in fig. 1 and 5, the present invention further includes a rotating and pulling assembly 5, the rotating and pulling assembly 5 includes a handle 51, a gear 52, a connecting plate 53 and a rack 54, the handle 51 is rotatably disposed on the left placing plate 21, the gear 52 is disposed on the handle 51, the connecting plate 53 is disposed on the upper portion of the left side of the first frame 32, the racks 54 are disposed on the connecting plate 53, and the racks 54 are engaged with the gear 52.

When detecting photovoltaic module, the staff rotates handle 51, handle 51 rotates and drives gear 52 and rotate, gear 52 rotates and drives rack 54 inwards to move, rack 54 inwards moves and drives first framework 32 inwards to slide through connecting plate 53, after the completion, the staff loosens handle 51, first framework 32 outwards slides and resets and drives rack 54 outwards to move through connecting plate 53 and resets, gear 52 drives handle 51 reversal thereupon and resets, so, no longer need promote first framework 32 one by one through the manual work, a large amount of manpowers have been saved.

Based on the embodiment 1, as shown in fig. 1 and 5, the device further includes a locking assembly 6, the locking assembly 6 includes a locking rod 61 and a third spring 62, the left placing plate 21 is slidably provided with the locking rod 61, the locking rod 61 is engaged with the gear 52, and the third spring 62 is wound between the locking rod 61 and the placing plate 21.

When detecting photovoltaic module, the staff slides to pulling kelly 61 left and no longer blocks gear 52, and third spring 62 is compressed, and after gear 52 rotated to suitable position, the staff unclamped kelly 61, and under the effect that third spring 62 reset, kelly 61 followed the right slip and blocked gear 52, so, can be when detecting fixed gear 52, avoid first framework 32 to become flexible.

On the basis of embodiment 1, as shown in fig. 1 and 6, the portable electronic device further includes a shielding assembly 7, the shielding assembly 7 includes a second frame 71, a shielding plate 72, a second wedge block 73 and a push rod 74, the second frame 71 is disposed at both left and right sides of the base 1, the shielding plate 72 is slidably disposed in the second frame 71, the second wedge block 73 is disposed on the shielding plate 72, the push rods 74 are disposed at both left and right sides of the front first frame 32, and the push rods 74 are engaged with the second wedge block 73.

When the photovoltaic module is detected, the first frame body 32 slides inwards to drive the push rod 74 to move backwards, when the push rod 74 moves backwards to be in contact with the second wedge-shaped block 73, the push rod 74 pushes the second wedge-shaped block 73 to move upwards, the second wedge-shaped block 73 moves upwards to drive the shielding plate 72 to slide upwards on the second frame body 71, after the detection is completed, the first frame body 32 slides outwards to reset to drive the push rod 74 to move forwards to reset, and the second wedge-shaped block 73 is not pushed any more, at this time, under the action of gravity, the second wedge-shaped block 73 drives the shielding plate 72 to slide downwards to reset, so that the side face of the first frame body 32 can be shielded when the detection is performed, and the staff is prevented from being accidentally injured.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (8)

1. The utility model provides a be used for lug for photovoltaic module test, characterized by, including:

a base (1);

two mounting racks (11), wherein the two mounting racks (11) are respectively mounted on the base (1);

the placing assembly (2) is arranged on the mounting rack (11) and placed in a sliding mode;

and the detection assembly (3) is arranged on the base (1) and is used for detecting in a sliding mode.

2. The connector lug for photovoltaic module testing according to claim 1, wherein the placement module (2) comprises:

at least two placing plates (21) are arranged, and are mounted on the mounting rack (11);

at least two sliding rods (22), wherein the sliding rods (22) are arranged on the placing plate (21) in a sliding manner;

at least two first springs (23) are arranged and are mounted between the sliding rod (22) and the placing plate (21);

the number of the first wedge blocks (24) is at least two, and the first wedge blocks (24) are all arranged between the two sliding rods (22).

3. The connector lug for photovoltaic module testing according to claim 1, wherein the inspection module (3) comprises:

at least two sliding rails (31) are arranged on the base (1) in a sliding manner;

two first frame bodies (32), wherein the two first frame bodies (32) are arranged between the two slide rails (31);

at least two metal detection cylinders (33), wherein the metal detection cylinders (33) are installed on the first frame body (32);

the square plate (34) is arranged on the base (1), and the first frame bodies (32) are connected with the square plate (34) in a sliding mode;

at least two second springs (35) are arranged and are mounted between the square plate (34) and the first frame body (32);

at least two display instruments (36) are arranged, and the display instruments (36) are all arranged on the first frame body (32).

4. The connector lug for photovoltaic module testing according to claim 2 or 3, further comprising a guiding member (4), wherein the guiding member (4) comprises:

at least two L-shaped rods (42) are arranged on the mounting frame (11);

at least two connecting cylinders (43), wherein the connecting cylinders (43) are arranged on the L-shaped rod (42) in a sliding way,

the connecting cylinders (43) are connected to the first frame (32).

5. The connector lug for photovoltaic module testing according to claim 4, further comprising a rotation pulling member (5), wherein the rotation pulling member (5) comprises:

a handle (51) rotatably mounted on the placement plate (21);

a gear (52) mounted on the handle (51);

two connecting plates (53), wherein the two connecting plates (53) are arranged on the first frame body (32);

two racks (54) are arranged on the connecting plate (53), and the racks (54) are meshed with the gear (52).

6. The connector lug for testing the photovoltaic module as claimed in claim 5, further comprising a clamping assembly (6), wherein the clamping assembly (6) comprises:

the clamping rod (61) is arranged on the placing plate (21) in a sliding mode, and the clamping rod (61) is matched with the gear (52);

and a third spring (62) mounted between the clamp rod (61) and the placing plate (21).

7. The connector lug for the photovoltaic module test according to claim 6, further comprising a shielding component (7), wherein the shielding component (7) comprises:

two second frames (71), wherein the two second frames (71) are arranged on the base (1);

two shielding plates (72), wherein the two shielding plates (72) are arranged in the second frame body (71) in a sliding manner;

two second wedge-shaped blocks (73), wherein the two second wedge-shaped blocks (73) are arranged on the baffle plate (72);

push rods (74), push rods (74) are two, all install on first framework (32), and push rods (74) all cooperate with second wedge block (73).

8. The connector lug for photovoltaic module testing according to claim 5, wherein the handle (51) is star-shaped.

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